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= Sample program =
<syntaxhighlight lang="rust">
fn main() {
    println!("Hello, world!");
}
</syntaxhighlight>
= Cargo =
= Cargo =


Line 25: Line 17:
</syntaxhighlight>
</syntaxhighlight>


= Types and Variables=
=Fundamental Data Types=
==Primitive types==
Cam declare with size of type or without
<syntaxhighlight lang="rust">
// Integers


== Fundamental Data Types ==
=== Primitive types ===
Cam declare with size of type
<syntaxhighlight lang="rust">
  let a:u8 = 123; // unsigned int 8 bits number immutable
  let a:u8 = 123; // unsigned int 8 bits number immutable
  let a:i8 = 123; // signed int 8 bits number immutable
  let a:i8 = 123; // signed int 8 bits number immutable
  let mut a:u8 = 123; // unsigned int 8 bits number mutable
  let mut a:u8 = 123; // unsigned int 8 bits number mutable
</syntaxhighlight>
 
Or without e.g.
<syntaxhighlight lang="rust">
  let mut c = 123456789 // 32-bit signed i32
  let mut c = 123456789 // 32-bit signed i32
  println!("c = {}", c);
  println!("c = {}", c);
</syntaxhighlight>
 
Now variable based on OS e.g.
// Based on OS e.g.
<syntaxhighlight lang="rust">
  let z:isize = 123 // signed 64 bit if on 64 bit OS
  let z:isize = 123 // signed 64 bit if on 64 bit OS
</syntaxhighlight>


=== Decimal ===
// Decimal
  let e:f64 = 2.5 // double-precision, 8 bytes or 64-bits
  let e:f64 = 2.5 // double-precision, 8 bytes or 64-bits
=== Char ===
 
// Char
  let x:char = 'x' // Note 4 bytes unicode
  let x:char = 'x' // Note 4 bytes unicode
=== boolean ===
 
// Boolean
  let g:bool = false; // Note 4 bytes unicode
  let g:bool = false; // Note 4 bytes unicode


== Operators ==
</syntaxhighlight>
Does not support -- and ++ but does support
==Operators==
<syntaxhighlight lang="rust">
// Does not support -- and ++ but does support
  a -= 2;
  a -= 2;
Remainder can be calculated using
 
// Remainder can be calculated using
  a%3
  a%3
Bitwise
 
// Bitwise
  let c = 1 | 2 // | OR
  let c = 1 | 2 // | OR
Shift
 
// Shift  
  let two_to_10 = 1 << 10; // 1024
  let two_to_10 = 1 << 10; // 1024
Logical of standard e.g.
 
// Logical of standard e.g.
  let pi_less_4 = std::f64::consts::PI < 4.0; // true
  let pi_less_4 = std::f64::consts::PI < 4.0; // true


== Scope and shadowing ==
</syntaxhighlight>
==Scope and shadowing==
Curly braces keep scope
Curly braces keep scope
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
Line 76: Line 73:
</syntaxhighlight>
</syntaxhighlight>
Shadowing is fine though
Shadowing is fine though
<syntaxhighlight lang="toml">
<syntaxhighlight lang="rust">
  fn test()
  fn test()
  {
  {
Line 86: Line 83:
   println!("5 {a}");
   println!("5 {a}");
  }
  }
</syntaxhighlight>
==Constants==
<syntaxhighlight lang="rust">
// Standard const
const MEANING_OF_LIFE:u8 = 42;
// Static const
static Z:i32 = 123;
</syntaxhighlight>
</syntaxhighlight>


== Constants ==
=Types=
Standard const
==Tuples==
Eezy peezy lemon squeezy
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
  const MEANING_OF_LIFE:u8 = 42;
fn sum_and_product(x:i32,y:i32) -> (i32, i32)
{
(x+y, x*y)
}
 
fn main()
{
  let sp = sum_and_product(3,4);
  let (a,b) = sp;
  let sp2 = sum_and_product(4,5);
 
  // combine
  let combined = (sp, sp2);
  let ((c,d), (e,f)) = combined;
}
</syntaxhighlight>
==Arrays==
Array sizes cannot grow in rust
===Simple===
<syntaxhighlight lang="rust">
let mut a:[i32;5] = [1,2,3,4,5];
// Or
let mut a = [1,2,3,4,5];
// Length
  a.len()
// Assignment
a[0] = 321
// Printing
println!("{:?}", )
// Testing
  if a == [1,2,3,4,5]
  {
  }
// Initialise
  let b = [1,10]; // 10 array initialised to 1
 
</syntaxhighlight>
=== Multi Dimension ===
Here is a two dimension array
<syntaxhighlight lang="rust">
let mtx:[[f32;3];2] =
[
  [1.0, 0.0, 0.0],
  [0.0, 2.0, 0.0],
];
 
</syntaxhighlight>
 
==Slices==
A slice is a non-owning pointer to a block of memory. For example
<syntaxhighlight lang="rust">
 
// Create a vector
let v: Vec<i32> = {0..5}.collect();
 
// Now create a slice (reference)
let sv: &[i32]= &v;
 
// We create a slice with only some elements
let sv1: &[i32]= &v[2..4];
 
// Printing these will produce the same result
println!("{:?}",v);
println!("{:?}",sv);
 
// And the range
println!("{:?}",sv1);
 
</syntaxhighlight>
 
==Strings==
Basic String
<syntaxhighlight lang="rust">
let name = String::from("Iain");
let name = "Iain".to_string();
</syntaxhighlight>
 
Two types, static string and string type
<syntaxhighlight lang="rust">
let s = "hello";
// Cannot do
// let h = s[0]
// You can iterate as a sequence using chars e.g.
for c in s.chars()
{
  println!("{}", c);
}
</syntaxhighlight>
And now the mutable string in rust essentially an vector
// Create a string
<syntaxhighlight lang="rust">
let mut letters = String::new();
</syntaxhighlight>
<syntaxhighlight lang="rust">
// Add a char
let a = 'a' as u8;
letters.push(a as char);
 
// String to str (string slice)
let u:%str = &letters;
 
// Concatenation
let z = lettters + &letters
 
// Other examples
let mut abc = "hello world".to_string()'
abc.remove(0);
abc.push_str("!!!");
abc.replace("ello","goodbye")
</syntaxhighlight>
</syntaxhighlight>
Static const
 
==Hashmap==
Reminds me of my C++ and Java days. No surprises here for reference
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
static Z:i32 = 123;
let mut basket = HashMap::new();
 
basket.insert(String::from("banana"), 2);
basket.insert(String::from("pear"), 2);
basket.insert(String::from("peach"), 2);
</syntaxhighlight>
</syntaxhighlight>
Updating was a bit more tricky than expected. This was the copilot approach
<syntaxhighlight lang="rust">
struct TeamScores {
    goals_scored: u8,
    goals_conceded: u8,
}
fn build_scores_table(results: &str) -> HashMap<&str, TeamScores> {
    // The name of the team is the key and its associated struct is the value.
    let mut scores = HashMap::new();
    for line in results.lines() {
        let mut split_iterator = line.split(',');
        // NOTE: We use `unwrap` because we didn't deal with error handling yet.
        let team_1_name = split_iterator.next().unwrap();
        let team_2_name = split_iterator.next().unwrap();
        let team_1_score: u8 = split_iterator.next().unwrap().parse().unwrap();
        let team_2_score: u8 = split_iterator.next().unwrap().parse().unwrap();
        let team_1 = scores.entry(team_1_name).or_insert(TeamScores::default());
        team_1.goals_scored += team_1_score;
        team_1.goals_conceded += team_2_score;


== Stack and Heap ==
        let team_2 = scores.entry(team_2_name).or_insert(TeamScores::default());
Same a c++ i.e.  
        team_2.goals_scored += team_2_score;
        team_2.goals_conceded += team_1_score;
    }
 
    scores
}
</syntaxhighlight>
The suggestion was to use get_mut on hashmap but struggle to get this to work. The solution from Chris biscardi on youtube was this, clearly the rust team looked at this and did it better.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let y = Box::new(10);
fn build_scores_table(results: &str) -> HashMap<&str, TeamScores> {
println!("y = {}", *y);
...
        scores
            .entry(team_1_name)
            .and_modify(|team: &mut TeamScores| {
                team.goals_scored += team_1_score;
                team.goals_conceded += team_2_score;
            })
            .or_insert(TeamScores {
                goals_scored: team_1_score,
                goals_conceded: team_2_score,
            });
 
        scores
            .entry(team_2_name)
            .and_modify(|team: &mut TeamScores| {
                team.goals_scored += team_2_score;
                team.goals_conceded += team_1_score;
            })
            .or_insert(TeamScores {
                goals_scored: team_2_score,
                goals_conceded: team_1_score,
            });
 
</syntaxhighlight>
</syntaxhighlight>


= Control Flow =
= Control Flow =
== if statement ==
== if statement ==
Same as C++ except no brackets
Same as C++ except no brackets
Line 140: Line 309:
There is support for continue and break
There is support for continue and break


=== Loop ===
===Loop===
Loop is while true
Loop is while true
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
Line 156: Line 325:
     println!("x = {}",x);
     println!("x = {}",x);
  }
  }
</syntaxhighlight>
// You can get position in series as well
 
You can get position in series as well
<syntaxhighlight lang="rust">
  for (pos,x) in (1..11).enumerate()
  for (pos,x) in (1..11).enumerate()
  {
  {
     println!("x = {}, pos = {}",x, pos);
     println!("x = {}, pos = {}",x, pos);
  }
  }
</syntaxhighlight>
=Rust Principles=
==Ownership==
==Move==
Move is when you assign a value to another variable. If we try and use a variable after the move we will get an error.
<syntaxhighlight lang="rust">
let v = vec![1,2,3]
let v2 = v;
println!("{:?}",v2)
println!("{:?}",v) // Error
</syntaxhighlight>
==Copy==
When we copy something me make a new thing. They is not the same a let a = b, which is assignment. Copy means we duplicate the underlying data of the type. For primitives a copy is implemented by default. This is because the primitive has a know size. E.g. u32, bool etc. If you want to be able to copy a non primitive you need to add the derive macro. Note Clone must also be specified
<syntaxhighlight lang="rust">
#[derive(Copy, Clone)]
enum Direction {
    North,
    East,
    South,
    West,
}
#[derive(Copy, Clone)]
struct RoadPoint {
    direction: Direction,
    index: i32,
}
</syntaxhighlight>
==Clone==
Clone is a method you can call on a struct if you want a second instance and not move the ownership. Here is an example. The struct obviously needs to implement the Copy/Clone macro. Cloning clearly increases the memory used.
<syntaxhighlight lang="rust">
let v = vec![1,2,3]
let v2 = v.cone();
println!("{:?}",v)
println!("{:?}",v2)
</syntaxhighlight>
==References==
So references are like C++ references, but for rust this means you can pass the ownership during function call
<syntaxhighlight lang="rust">
main() {
    let mut s = String::from("Hello");
    change_string(&mut s);
}
fn change_string(some_string: &mut String) {
    some_string.push_str(", world!");
}
</syntaxhighlight>
</syntaxhighlight>
'''Note for returning a Reference'''<br>
If we are returning a reference we must be returning a parameter as all local variables are destroyed. (Clearly Rust is not going to allow new MyMemory(6502)


== Match ==
=Structs=
Match can be used like case
Struct are the nearest thing to roughly classes in rust. You make a struct and then add implementation which are methods
==General==
There are 3 types of structs, name, tuple and unit structs
*Named
*Tuples
*Unit
===Name Struct===
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let country = match country_code
struct User
{
{
    44 => "uk",
  active: bool,
    46 => "sweden",
  username: String,
    7 => "russia"
  sign_in_count: u32
    1...999 => "unknown" // other triple dot inclusive
}
    _ => "invalid" // invalid
 
};
let user1 = User{active: true, username: String::from("Biil"),
  sign_in_count: 0};
println!("{}", user1.username);
 
...
 
fn build_user(username: String) -> User {
  User {
    username,
    active:true,
    sign_in_count: 1
  }
}
</syntaxhighlight>
</syntaxhighlight>


= Data Structures =
===Tuple Struct===
== Structs ==
Tuple structs use the order in which declared to assign.
<syntaxhighlight lang="rust">
  struct Coordinates{i32,i32,i32};
  let coords = Coordinates{1,2,3};
</syntaxhighlight>
===Unit Struct===
These are used to mark the existence of something
<syntaxhighlight lang="rust">
struct UnitStruct;
let a = UnitStruct{}
</syntaxhighlight>
The example shown was when you are implementing a trait (interface) but the properties were not required for this type. So given a trait for Area, Square uses size but Point does not have an area as it is zero
<syntaxhighlight lang="rust">
trait AreaCalculator {
  fn calc_area(&self) => f64
}
 
struct Square {
  size: f64
}
 
struct Point;
 
impl AreaCalculator for Square {
  fn calc_area(&self) -> f64 {
    self.size * self.size
  }
}
 
impl AreaCalculator for Point {
  fn calc_area(&self) -> f64 {
    0.0
  }
}
</syntaxhighlight>
We can use it for error
<syntaxhighlight lang="rust">
struct DivideByZero;
 
fn divide(nom: f64, den: f64) -> Result<f64, DivideByZero> {
  if den != 0.0 {
      Ok(nom/den)
  } else {
      Err(DivideByZero)
  }
}
</syntaxhighlight>
==Example Structs==
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
struct Point
struct Point
Line 192: Line 477:
   let p = Point { x: 30.0, y: 4.0 };
   let p = Point { x: 30.0, y: 4.0 };
   println!("point is at ({},{})", p.x, p.y)
   println!("point is at ({},{})", p.x, p.y)
}
</syntaxhighlight>
==Methods on Structs==
Methods on struct require the first argument to be self
===Example Method===
Add method len to struct
<syntaxhighlight lang="rust">
struct Line
{
start: Point,
end: Point
}
// Declare impl using the keyword impl. Not ends with no semi colon.
impl Line
{
  fn len(&self) -> f64
  {
    let dx = self.start.x - self.end.x;
    let dy = self.start.y - self.end.y;
    (dx*dx+dy*dy).sqrt()
  }
}
</syntaxhighlight>
===Changing an attribute===
To change an attribute and ensure you do not break the borrowing rules we do
<syntaxhighlight lang="rust">
struct Square {
  width: u32,
  height: u32
}
impl Square
{
  fn area(&self) -> u32 {
    self.width * self.height
  }
  fn change_width(&mut self, new_width: u32) -> Self
  {
    self.width = new_width;
  }
}
...
main() {
...
  let mut sq = Square(width:5, height: 5);
  sq.change_point(10)
}
</syntaxhighlight>
=Lifetime=
==What are Dangling References==
The code below will not compile. This is because x goes out of scope before r. I am guessing this is what is known as a dangling reference.
<syntaxhighlight lang="rust">
fn test() {
    let r;
    {
        let x = 5;
        r = &x; // Error `x` does not live long enough
    }
    log::info!("{}",r);
}
</syntaxhighlight>
==Lifetime Annotations==
Not sure which way around these are but you specify lifetime annotations on functions and structs and they imply information to the compiler on how long the parameters will live for.
==Three Rules of Lifetimes==
Here are the rules but we also need to understand what they apply to. Kind of chicken and egg. An example is give below which is broken because these rules are not followed.
#Each Parameter that is a reference gets its own lifetime parameter
#If there is exactly one input lifetime parameter, that lifetime is assigned to all output lifetime parameters
#If there are multiple input lifetime parameters, but one of them is &self or &mut self the lifetime is assigned to all output lifetime parameters
==Example (Broken code)==
Here is an example of code which cannot be compiled without lifetime being specified.
<syntaxhighlight lang="rust">
pub struct TestStruct {
    length: i32,
}
fn test2(x: &TestStruct, y: &TestStruct) -> &TestStruct { // Missing lifetime specifier
    if x.length > y.length {
      x
    }
    else {
      y
    }
}
</syntaxhighlight>
==Adding Annotations==
To do this we specify annotations. The extension in vscode does this for us using the quick fix. The code now looks like this
<syntaxhighlight lang="rust">
fn test2<'a>(x: &'a TestStruct, y: &'a TestStruct) -> &'a TestStruct {
    if x.length > y.length {
      x
    }
    else {
      y
    }
}
</syntaxhighlight>
My inference from this is that all parameters have the same lifetime.
==Lifetime Annotations for Structs==
Structs can also have lifetime annotations. If you specify a reference then you will need to specify a lifetime annotation. In the example below when we make the struct of type MyString we need to make sure that str1 does not go out of scope while x of type MyString exists otherwise it would refer to something no longer in scope.
<syntaxhighlight lang="rust">
// Without lifetime annotation will not compile.
// struct MyString {
//  text: &str,
// }
struct MyString<'a> {
  text: &'a str,
}
fn main() {
    let str1 = String::from("This is my String);
    let x = MyString(text: str1.as_str());
}
</syntaxhighlight>
==Static Lifetimes==
We can also have lifetimes for statics.
<syntaxhighlight lang="rust">
let s: &'static str = "I live forever";
</syntaxhighlight>
Doing this means the values are stored in  the binary.
=Enums=
==Example 1 with Method==
Seems a bit C++ but... we can add a method as we do with structs. Note for this method we are returning something and with rust all locals are destroyed on return so we need to specify a lifetime.
<syntaxhighlight lang="rust">
enum Pet {dog, cat, fish}
impl Pet {
  fn what_am_i(self) -> &'static str {
      match self {
        Pet::dog => "I am a dog",
        Pet::cat => "I am a cat",
        Pet::fish => "I am a fish", 
      }
  }
}
}
</syntaxhighlight>
</syntaxhighlight>


== Enumerators ==
==Example 2==
=== Similar to c++ ===
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
enum Color {
enum Color {
Line 215: Line 643:
</syntaxhighlight>
</syntaxhighlight>


=== But maybe not we can add types ===
==Example 3 with Types==
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
enum Color {
enum Color {
Line 246: Line 674:
}
}
</syntaxhighlight>
</syntaxhighlight>
 
==Option<T> Enum==
== Option <T> and if let ==
This enum if provided for us by rust and looks like this
Used to avoid null or invalid values
<syntaxhighlight lang="rust">
enum Option<T> {
    None,
    Some(T)
}
</syntaxhighlight>
We would choose this type when we have a case where there could be a value or not. I guess this is the equivalent of string? in Typescript where we may or may not have a value. In rust we use match to support this type.
<syntaxhighlight lang="rust">
  let some_number = Some(5);
  let some_string = Some("a string");
  let nothing: Option<i32> = None;
</syntaxhighlight>
==Pattern Matching==
Match is '''Exhaustive approach''' to pattern matching. I.E. you need to specify something for every option you are using match for. However you can include a default. I find this a great approach
===Examples===
====Simple Match====
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let x = 3.0
match x
let y = 0.0 // Divide by zero
 
let result:Option<f64> =
  if y != 0.0 { Some(x/y) } else { None };
 
// Using match
match result
{
{
  Some(z) => println!("Goody result"),
  0 => "zero"
  None => println!("No result)
  1 | 2 => "one or two"
  9...11 => "lots of"  // two dots does not include end value (exclusive)
  _ if(blahh) => "something"
  _ => "all others"
}
}
// Using if let
if let Some(z) = result { println!("z = {}", z); }
</syntaxhighlight>
</syntaxhighlight>
 
Here is another example.
== Arrays ==
Array sizes cannot grow in rust
=== Simple ===
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut a:[i32;5] = [1,2,3,4,5];
let country = match country_code
// Or
{
let mut a = [1,2,3,4,5];
    44 => "uk",
// Length
    46 => "sweden",
a.len()
    7 => "russia"
// Assignment
    1...999 => "unknown" // other triple dot does include end value (inclusive)
a[0] = 321
    _ => "invalid" // invalid
// Printing
};
println!("{:?}", )
// Testing
  if a == [1,2,3,4,5]
  {
  }
// Initialise
  let b = [1,10]; // 10 array initialised to 1
 
</syntaxhighlight>
</syntaxhighlight>
=== Multi Dimension ===
This just shows inclusive which is ..= unlike kotlin which I think is 3 dots
Here is a two dimension array
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mtx:[[f32;3];2] =
// This function returns how much icecream there is left in the fridge.
[
// If it's before 22:00 (24-hour system), then 5 scoops are left. At 22:00,
  [1.0, 0.0, 0.0],
// someone eats it all, so no icecream is left (value 0). Return `None` if
  [0.0, 2.0, 0.0],
// `hour_of_day` is higher than 23.
];
fn maybe_icecream(hour_of_day: u16) -> Option<u16> {
    match hour_of_day {
        0..22 => Some(5),
        22..=23 => Some(0),
        _ => None,
    }
}
</syntaxhighlight>


====More Complex====
Stumped me when see thing for the first time prior to type script and possibly lambda. Here we define anonymous functions which match the type of the enum. Here is the enum which is used in another struct
<syntaxhighlight lang="rust">
enum Message {
    Move(Point),
    Echo(String),
    ChangeColor(u8, u8, u8),
    Quit,
    Resize { width: u64, height: u64 },
}
</syntaxhighlight>
</syntaxhighlight>
 
It has functions for each enum type.
== Vectors ==
Same a c++
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut a = Vec::new()
struct State {
a.push(1);
    width: u64,
a.push(2);
    height: u64,
a.push(3);
    position: Point,
// Print
    message: String,
println!("a[0] {}", a[0]);
    // RGB color composed of red, green and blue.
// Using get returns a option
    color: (u8, u8, u8),
match a.get(3333)
    quit: bool,
{
...
}
}


// Removing, pop returns an option 
impl State {
let last_elem = a.pop();
    fn resize(&mut self, width: u64, height: u64) {
        self.width = width;
        self.height = height;
    }


// Using the option type iterating over vector to print it
    fn move_position(&mut self, point: Point) {
while let Some(x) = a.pop()
        self.position = point;
{
    }
  println!("x = {}",x);
}
</syntaxhighlight>


= More Data Structures =
    fn echo(&mut self, s: String) {
== Slices ==
        self.message = s;
Get the first 3 elements of an array
    }
<syntaxhighlight lang="rust">


fn use_slice(slice: &mut[i32])
    fn change_color(&mut self, red: u8, green: u8, blue: u8) {
{
        self.color = (red, green, blue);
    }


}
    fn quit(&mut self) {
        self.quit = true;
    }


fn test()
    fn process(&mut self, message: Message) {
{
...
  let mut data = [1,2,3,4,5];
    }
  // Passes element 1-3 to use_slice as a reference
  use_slice( &mut data[1..4]);
}
}
</syntaxhighlight>
</syntaxhighlight>
== Strings ==
At first I struggled to understand how to implement process but all you need to do is provide an ()_=> {} for each type. For Quit I completely understood but for the others was confused. Obvious once you know and I am sure copilot will do this for me
Two types, static string and string type
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let s = "hello";
    fn process(&mut self, message: Message) {
// Cannot do
        match message {
// let h = s[0]
            Message::Move(point) => self.move_position(point),
// You can iterate as a sequence using chars e.g.
            Message::Echo(output) => self.echo(output),
for c in s.chars()
            Message::ChangeColor(red, green, blue) => self.change_color(red, green, blue),
{
            Message::Quit => self.quit(),
  println!("{}", c);
            Message::Resize { width, height } => self.resize(width, height),
}
        }
    }
</syntaxhighlight>
</syntaxhighlight>
And now the mutable string in rust essentially an vector
 
// Create a string
====Match on Tuples====
This is an exert from [[https://en.wikipedia.org/wiki/Conway%27s_Game_of_Life Game of Life]]. We can match on tuples, and I imagine other types too. For tuples you can specify a value or compare to a value. Note the use of '''otherwise'''
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut letters = String::new();
    let next_cell = match (cell, live_neighbors) {
      // Rule 1: Any live cell with fewer than two live neighbours
      // dies, as if caused by underpopulation.
      (Cell::Alive, x) if x < 2 => Cell::Dead,
      // Rule 2: Any live cell with two or three live neighbours
      // lives on to the next generation.
      (Cell::Alive, 2) | (Cell::Alive, 3) => Cell::Alive,
      // Rule 3: Any live cell with more than three live
      // neighbours dies, as if by overpopulation.
      (Cell::Alive, x) if x > 3 => Cell::Dead,
      // Rule 4: Any dead cell with exactly three live neighbours
      // becomes a live cell, as if by reproduction.
      (Cell::Dead, 3) => Cell::Alive,
      // All other cells remain in the same state.
      (otherwise, _) => otherwise,
};
</syntaxhighlight>
</syntaxhighlight>
Add a char
 
===Operators and Symbols===
Found in Table B-1 here  [[https://doc.rust-lang.org/book/appendix-02-operators.html Operators and Symbols]]
#[[https://doc.rust-lang.org/std/ops/struct.Range.html Range]]: 1..10
#[[https://doc.rust-lang.org/std/ops/struct.RangeFrom.html RangeFrom]]: 1..
#[[https://doc.rust-lang.org/std/ops/struct.RangeTo.html RangeTo]]: ..10
#RangeFull: ..
#RangeInclusive: 1..=10
#RangeToInclusive: ..=10
 
==Option <T> and if let==
Used to avoid null or invalid values. This was used in things where the value might be present. Maybe command line arguments where some were provide or none were provided. Lets to the classic divide by zero.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let a = 'a' as u8;
let x = 3.0
letters.push(a as char);
let y = 0.0 // Divide by zero
 
let result:Option<f64> =
  if y != 0.0 { Some(x/y) } else { None };
 
// Using match
match result {
  Some(z) => println!("Goody result"),
  None => println!("No result")
}
 
// Using if let
if let Some(z) = result { println!("z = {}", z); }
</syntaxhighlight>
</syntaxhighlight>
String to str
== More if let ==
Here is another example
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let u:%str = &letters;
let mut stack = Vec:new();
stack.push(1);
stack.push(2);
stack.push(3);
while let Some(top) = stack.pop() {
  println!("{}", top);
}
</syntaxhighlight>
</syntaxhighlight>
Concatenation
==while let ==
The above example makes great sense but while doing rustlings the was this question
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let z = lettters + &letters
  // TODO: Make this a while-let statement. Remember that `Vec::pop()`
  // adds another layer of `Option`. You can do nested pattern matching
  // in if-let and while-let statements.
  integer = optional_integers.pop() {
    assert_eq!(integer, cursor);
    cursor -= 1;
  }
</syntaxhighlight>
</syntaxhighlight>
Other examples
I did like the Some Some approach
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut abc = "hello world".to_string()'
  while let Some(Some(integer)) = optional_integers.pop() {
abc.remove(0);
    assert_eq!(integer, cursor);
abc.push_str("!!!");
    cursor -= 1;
abc.replace("ello","goodbye")
  }
</syntaxhighlight>
</syntaxhighlight>
== Tuples ==
But could not get the '''You can do nested pattern matching in if-let and while-let statements''' to look nice
Eezy peezy lemon squeezy
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
fn sum_and_product(x:i32,y:i32) -> (i32, i32)
  while let Some(integer) = if let Some(integer) = optional_integers.pop() {
{
    integer
(x+y, x*y)
  } else {
}
    None
 
  } {
fn main()
    assert_eq!(integer, cursor);
{
    cursor -= 1;
  let sp = sum_and_product(3,4);
   }
  let (a,b) = sp;
  let sp2 = sum_and_product(4,5);
    
  // combine
  let combined = (sp, sp2);
  let ((c,d), (e,f)) = combined;
}
</syntaxhighlight>
</syntaxhighlight>
== Pattern Matching ==
Just wouldn't let it lie, found a way to turn it up the right way
Various pattern matching
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
match x
  while let Some(integer) = optional_integers.pop() {
{
    if let Some(integer) = integer {
  0 => "zero"
      assert_eq!(integer, cursor);
  1 | 2 => "one or two"
      cursor -= 1;
  9...11 => "lots of"
    }
  _ if(blahh) => "something"
  }
  _ => "all others"
}
</syntaxhighlight>
</syntaxhighlight>
Using two dots .. with pattern matching allows you to ignore other values except those specified.


== Generics ==
=Generics=
Looks like templates
==Simple==
This is very similar to C++ Templates and TypeScript Generics
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
struct Point<T>
struct Point<T>
Line 425: Line 904:
}
}
</syntaxhighlight>
</syntaxhighlight>
 
==Using Implementation==
= Functions =
An example where we use an implementation
== Functions and Arguments ==
No surprises
<syntaxhighlight lang="rust">
fn print_value(x: i32)
{
  println("value = {}", x);
}
Pass by reference
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
fn increase(x: &mut i32)
struct Wrapper<T> {
{
    value: T,
  *x = 1;
}
Return value, note no semicolon
fn product(x: i32, y: i32) -> i32
{
  x * y
}
</syntaxhighlight>
== Methods on Structs ==
Add method len to struct
<syntaxhighlight lang="rust">
struct Line
{
start: Point,
end: Point
}
}


// Declare impl using the keyword impl. Not ends with no semi colon.
impl<T> Wrapper<T> {
impl Line
    fn new(value: T) -> Self {
{
        Wrapper { value }
  fn len(&self) -> f64
     }
  {
     let dx = self.start.x - self.end.x;
    let dy = self.start.y - self.end.y;
    (dx*dx+dy*dy).sqrt()
  }
}
}
</syntaxhighlight>
</syntaxhighlight>
== Closures ==
Closures are delegates. Here is an inline one
<syntaxhighlight lang="rust">
let plus_one = |x:i32| -> i32 { x + 1};
let a = 6;
println!("{}, + 1 = {}",a plus_one(a));
// another approach
let plus_to = |x|
{
let mut z = x;
z += 2;
z
};
</syntaxhighlight>
We need to ensure scope is executed before using variables again e.g.
<syntaxhighlight lang="rust">
let mut two = 2;
let plus_to = |x|
{
let mut z = x;
z += two;
z
};
let borrow_two = &mut two;
</syntaxhighlight>
This will not compile as two could be modified so you need to add bracket to ensure scope.


<syntaxhighlight lang="rust">
=Traits=
let mut two = 2;
Traits are similar to interfaces in java and c#
{
==Defining a Traits==
  let plus_to = |x|
  {
  let mut z = x;
  z += two;
  z
  };
}
let borrow_two = &mut two;
</syntaxhighlight>
 
== Higher-order functions ==
Not sure what this is, seems like just a way to chain written functions together like lamba. Here is the given example.
<syntaxhighlight lang="rust">
 
fn is_even(x: u32) -> bool
{
  x%2 == 0
}
 
fn main()
{
// Method without HOF
  let limit = 500;
  let mut sum = 0;
 
  for i in 0..
  {
    let isq = i*i;
 
    if isq > limit { break; }
    else if is_even(isq) { sum += isq; }
  }
 
  println!("loop sum = {}", sum);
 
// HOF way
 
  let sum2 =
    (0...).map(|x| x*x)
        .take_while(|&x| x < limit)
        .filter(|x| is_even(*x))
        .fold(0, |sum,x| sum+x);
 
  println!("hof sum = {}", sum2);
}
 
</syntaxhighlight>
 
== Traits ==
Traits are interfaces from maybe c#
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
trait Animal
trait Animal
Line 562: Line 933:
   }
   }
}
}
 
</syntaxhighlight>
==Implement a Trait==
Here we create a struct which will implement out trait. Note we do not have to implement all functions if the trait provides a default implementation
===Implement a Trait for Animal===
<syntaxhighlight lang="rust">
struct Human
struct Human
{
{
Line 568: Line 943:
}
}


// Implement interface
impl Animal for Human
impl Animal for Human
{
{
Line 586: Line 960:
   }
   }
}
}
 
</syntaxhighlight>
===Implement a Trait for Cat===
Here we implement the Animal Trait for Cat
<syntaxhighlight lang="rust">
struct Cat
struct Cat
{
{
Line 611: Line 988:
}
}


// Create doing


// Usage
let h:Human = Animal::create("John");
let h:Human = Animal::create("John");
let c:Cat = Animal::create("John");
let c:Cat = Animal::create("John");
</syntaxhighlight>
</syntaxhighlight>
= Lifetime =
 
== Ownership ==
===Default Trait and Spread===
Only one thing can have ownership
For a struct we can create a default for it. We can use a typescript like spread operator (although it must be last) for override these defaults
<syntaxhighlight lang="rust">
pub struct Circle {
    color: String,
    point: Point,
    radius: u16,
}
 
impl Circle {
    pub fn new(color: String, point: Point, radius: u16) -> Circle {
        Circle {
            color,
            point,
            radius,
        }
    }
 
    pub fn default_color(point: Point, radius: u16) -> Circle {
        Circle {
            point,
            radius,
            ..Default::default()
        }
    }
}
 
impl Default for Circle {
    fn default() -> Self {
        Circle {
            color: String::from("black"),
            point: Point::new(0, 0),
            radius: 0,
        }
    }
}
 
// Default Circle
let circle = Circle::default();
 
// Default Black Circle
let circle = Circle::default_color(Point::new(1, 1), 1);
</syntaxhighlight>
 
===Traits and with Dyn and Impl===
To allow any struct which implements the trait we use the '''dyn''' or '''impl''' keyword
====Difference Between dyn and impl====
*'''dyn''' means dynamic dispatch. This results in a fat pointer. One pointer pointing to the data and the other pointing to the vtable.
*'''impl''' means static dispatch. This results in a new copy of the function for each usage
====Example====
<syntaxhighlight lang="rust">
trait Licensed {
    fn licensing_info(&self) -> String {
        "Default license".to_string()
    }
}
 
struct SomeSoftware;
struct OtherSoftware;
 
impl Licensed for SomeSoftware {}
impl Licensed for OtherSoftware {}
 
// TODO: Fix the compiler error by only changing the signature of this function.
fn compare_license_types(software1: impl Licensed, software2: impl Licensed) -> bool {
    software1.licensing_info() == software2.licensing_info()
}
 
// Now we can do this
compare_license_types(SomeSoftware, OtherSoftware)
compare_license_types(OtherSoftware, SomeSoftware)
</syntaxhighlight>
====Why Box====
When can return a dyn Trait too. We clearly do not know the size of the return value. To overcome this we put the return argument in a Box which is essentially a smart pointer in C++
<syntaxhighlight lang="rust">
fn random_animal(random_number: f64) -> Box<dyn Animal> {
    if random_number < 0.5 {
        Box::new(Sheep {})
    } else {
        Box::new(Cow {})
    }
}</syntaxhighlight>
 
===Super Traits===
We can make a trait to which says you must implement these traits to implement me.
<syntaxhighlight lang="rust">
trait Amphibious : WaterCapable + LandCapable + UnderWaterCapable {} 
</syntaxhighlight>
Now when you use this trait you have to implement the other 3 traits.
 
==Provided Traits==
===Drop Trait===
Drop trait is called automatically to free up resources but you can write your own e.g. for the example above we could write
<syntaxhighlight lang="rust">
impl Drop for Course {
  fn drop(&mut self) {
    println("Dropping")
  }
}
</syntaxhighlight>
===Clone Trait===
Like the drop trait we can implement our own. Refer to the clone trait for this.
===Copy Trait===
We can either specify #[derive(Copy, Clone)] or implement our own. There are restrictions on this
===From and Into Trait===
This allow us to convert from one type to another
<syntaxhighlight lang="rust">
fn into(self) -> T
fn from(T) ->  Self
fn try_into(self) -> Result<T, Self: Error>
fn try_from(value: T) -> Result<Self, Self: Error>
</syntaxhighlight>
==Trait Bounds 1==
In order to allow use of more than on trait in a function we can use the +. This example means that item must implement both traits, i.e. SomeTrait and OtherTrait
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let v = vec![1,2,3]
fn some_func(item: impl SomeTrait + OtherTrait) -> bool {
let v2 = v;
    item.some_function() && item.other_function()
}
</syntaxhighlight>
</syntaxhighlight>
Only v can own the vector so this will not compile. Upon usage you get the error "use of moved value"
==Trait Bounds 2==
== Borrowing ==
Here is an example of doing the same thing in two ways. Because we can have anything in grade (T) we must make an implementation for std::fmt::Display. That way if we make a ReportCard with a generic which does not support Display, it will not compile
This fails because we are have two mutable accesses to a
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut a = 40;
 
let b &mut a
struct ReportCard<T> {
*b += 2;
    grade: T,
println!("a = {}", a);
    student_name: String,
    student_age: u8,
}
 
// Approach 1
impl<T> ReportCard<T>
where
    T: std::fmt::Display,
{
    fn print(&self) -> String {
        format!(
            "{} ({}) - achieved a grade of {}",
            &self.student_name, &self.student_age, &self.grade,
        )
    }
}
 
// Approach 2
impl<T: std::fmt::Display> ReportCard<T> {
    fn print(&self) -> String {
        format!(
            "{} ({}) - achieved a grade of {}",
            &self.student_name, &self.student_age, &self.grade,
        )
    }
}
</syntaxhighlight>
</syntaxhighlight>
This fails because we are have two mutable accesses to a


Same fix as before
==Trait Bounds==
The example above has two ways to achieve the same thing. If we constrain what this allowed, this is called trait bounds. Lets add a second parameter.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
let mut a = 40;
// This example only forces the struct to implement the trait
// fn overview(item1: &imp Overview, item2: &imp Overview)
 
// But this force the struct to be of the same type
// fn overview<T: Overview>(item1: &T, item2: &T)
</syntaxhighlight>
We can add more constraints with the + operator. Now they need the second trait.
<syntaxhighlight lang="rust">
// fn overview(item1: &imp Overview + AnotherTrait, item2: &imp Overview + AnotherTrait)
// fn overview<T: Overview + AnotherTrait>(item1: &T, item2: &T)
</syntaxhighlight>
Here we have an example of ensuring that the incoming parameters are constrained to be of type T
<syntaxhighlight lang="rust">
struct Pointy<T> {
    x: T,
    y: T,
}
 
impl <T> Add for Pointy <T>
where T: Add<Output = T>
{
{
  let b &mut a
    type Output = Self;
  *b += 2;
 
    fn add(self, other: Self) -> Self {
        Self {
            x: self.x + other.x,
            y: self.y + other.y,
        }
    }
}
}
println!("a = {}", a);
</syntaxhighlight>
</syntaxhighlight>
= Odds and Ends =
== Consuming Crates ==
Crates is like nuget [https://crates.io/]
<syntaxhighlight lang="toml">
[package]
name = "mypackage"
version = "0.1.0"
author = " ["Iain Wiseman iwiseman@bibble.co.nz"]


[dependencies]
==Passing Trait as Parameters==
rand = "0.3.12"
So here is an example of two structs with overview implement,one using the trait default implementation, the other its own. We can use the trait similar to a pointer to a function.
==Example==
<syntaxhighlight lang="rust">
trait Overview {
  fn overview(&self) -> String {
    format("This is a rust course")
  }
}
 
struct Course {
  headline: String,
  author: String
}
 
struct AnotherCourse {
  headline: String,
  author: String
}
 
impl Overview for Course {
}
 
impl Overview for AnotherCourse {
  fn overview(&self) -> String {
    format("{}, {}", self.author, self.headline)
  }
}
 
</syntaxhighlight>
We can use the overview trait a a fn parameter with
<syntaxhighlight lang="rust">
fn call_overview(item: &imp) {
  println("Overview: {}", item.overview())
}
 
// OR
fn call_overview<T: Overview>(item: &T) {
  println("Overview: {}", item.overview())
}
 
</syntaxhighlight>
==Passing Traits (From Youtube)==
Taken from Youtube and repeated. There are two notations for passing a trait. These are the same but the first is perhaps more readable. The second is known as a trait bound.
<syntaxhighlight lang="rust">
pub fn foo (traitor: &impl SpiDevice) {
 
}
 
pub fn foo<T: SpiDevice>(traitor: &T) {
 
}
</syntaxhighlight>
With the impl syntax we can make the parameter have more the one trait with a plus.
<syntaxhighlight lang="rust">
pub fn foo (traitor: &impl SpiDevice + AnotherTrait) {
 
}
</syntaxhighlight>
With the second syntax if we have two parameters if allows us to make sure they both share the same trait easily as the type is only specified once
<syntaxhighlight lang="rust">
pub fn foo<T: SpiDevice>(traitor1: &T, traitor2) {


}
</syntaxhighlight>
</syntaxhighlight>
And the usage
We can also add a second trait with this syntax too.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
extern crate rand; // Package
pub fn foo<T: SpiDevice + AnotherTrait>(traitor1: &T, traitor2) {
use rand::Rng; // Namespace


fn main() {
  let mut rng = rand::thread_rng();
  let b:bool = rng.gen();
}
}
</syntaxhighlight>
</syntaxhighlight>
== Building Crates and Modules ==
This starts to get messy to we can tidy this up with the Where Clause
Module example e.g. src/lib.rs
<syntaxhighlight lang="rust">
pub fn foo<T, U>(traitor1: &T, traitor2: &U) -> i32
where
    T: SpiDevice + AnotherTrait,
    U: AnotherTrait + YetAnotherTrait
        {
            42
        }
 
</syntaxhighlight>
 
==Returning Traits (From Youtube)==
We can also return traits but you cannot return different types which share the same trait at this time.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
pub mod greetings
pub fn foo() -> SpiDevice {
    // Must be of same type
}
</syntaxhighlight>
 
=Common Collections=
==Vectors==
Same a c++
<syntaxhighlight lang="rust">
let mut a = Vec::new()
a.push(1);
a.push(2);
a.push(3);
// Print
println!("a[0] {}", a[0]);
 
// We can create vector with initial capacity
let mut b = Vec::<i32>::with_capacity(2);
 
// We can initialize using an iterator values of 0-4
let c: Vect<i32> = (0..5).collect();
 
// Using get returns a option
match a.get(3333)
{
{
  pub mod english
...
   {
}
      pub fn hello() -> {"hello"->to_string() }
 
      pub fn goodbye() -> {"goodbye"->to_string() }
// Removing, pop returns an option 
  }
let last_elem = a.pop();
  pub mod french
 
  {
// Using the option type iterating over vector to print it
      pub fn hello() -> {"bonjour"->to_string() }
while let Some(x) = a.pop()
      pub fn goodbye() -> {"au revoir"->to_string() }
{
  }
   println!("x = {}",x);
}
</syntaxhighlight>
 
==Binary Heap==
This struct makes sure the highest is at the top. It has a peek function to allow you to peek at values.
<syntaxhighlight lang="rust">
let mut bHeap = BinaryHeap::new();
bHeap.push(1);
bHeap.push(18);
bHeap.push(20);
bHeap.push(5);
bHeap.pop();
 
println!("{:?}", bHeap); // 20
 
</syntaxhighlight>
 
==Maps==
Not discussed
==Sets==
Not discussed
=Error Handling=
==Panic==
Panic happens when unhandled error occurs. This happens for instance when we access out of bounds array. We can get a backtrace by setting the environment export RUST_BACKTRACE=-1
==Result Enum==
The Result an enum which has two generics Result<T, E> where T is the type an E is the error. In rust we use the match to determine what to do.
<syntaxhighlight lang="rust">
let file = File::Open("Does_not_exist.mp3");
let file match file {
    Ok(file) => file,
    Err(error) => panic("Error: {:?}", error),
};
</syntaxhighlight>
 
==Mapping Errors==
Rust likes you to make your own errors and map the ones you handle to you errors which makes sense. We make our own errors using enums
<syntaxhighlight lang="rust">
enum ParsePosNonzeroError {
    Creation(CreationError),
    ParseInt(ParseIntError),
}
</syntaxhighlight>
Now we can provide helper function to convert from one type of error to ours
<syntaxhighlight lang="rust">
impl ParsePosNonzeroError {
    fn from_creation(err: CreationError) -> Self {
        Self::Creation(err)
    }
 
    // TODO: Add another error conversion function here.
    fn from_parse_int(err: ParseIntError) -> Self {
        Self::ParseInt(err)
    }
}
</syntaxhighlight>
Now in our parse function we can map the errors in parse() to our own
<syntaxhighlight lang="rust">
#[derive(PartialEq, Debug)]
struct PositiveNonzeroInteger(u64);
 
impl PositiveNonzeroInteger {
    fn new(value: i64) -> Result<Self, CreationError> {
        match value {
            x if x < 0 => Err(CreationError::Negative),
            0 => Err(CreationError::Zero),
            x => Ok(Self(x as u64)),
        }
    }
 
    fn parse(s: &str) -> Result<Self, ParsePosNonzeroError> {
        // TODO: change this to return an appropriate error instead of panicking
        // when `parse()` returns an error.
        let x: i64 = s.parse().map_err(ParsePosNonzeroError::from_parse_int)?;
        Self::new(x).map_err(ParsePosNonzeroError::from_creation)
    }
}
</syntaxhighlight>
 
=Testing=
We specify the cfg option and use the assert library
<syntaxhighlight lang="rust">
fn sqrt(number: f64) -> Result<f64, String> {
    if number >= 0.0 {
        Ok(number.powf(0.5))
    } else {
        Err("negative floats don't have square roots".to_owned())
    }
}
 
#[cfg(test)]
mod tests {
    use super::*;
 
    #[test]
    fn test_sqrt() -> Result<(), String> {
        let x = 4.0;
        assert_eq!(sqrt(x)?.powf(2.0), x);
        Ok(())
    }
}
</syntaxhighlight>
We can run these with
<syntaxhighlight lang="bash">
cargo test
</syntaxhighlight>
=Closures=
Closures are functions you which you can use the available scope to with that function. They look like anonymous function in typescript
==Simple Example of a closure==
The adder closure takes a parameter and captures existing scope at creation to produce the answer 17.
<syntaxhighlight lang="rust">
    let x: i32 = 5;
    let adder = |a| a + x;
    let b = adder(12);
    print!("b {}", b)
</syntaxhighlight>
==Mapper Function using Closure==
Here is a closure which is like typescript mapper function using closures and rust
<syntaxhighlight lang="ts">
things.map((element: number) => element * 2)
</syntaxhighlight>
And now the same thing in rust
<syntaxhighlight lang="rs">
things.iter().map(|element| element * 2).collect()
</syntaxhighlight>
==Mapper replacing a for loop using Closure==
The key to do thing was to specify the type with the sum i.e. sum::<usize>() rather than sum()
<syntaxhighlight lang="rust">
fn count_for(map: &HashMap<String, Progress>, value: Progress) -> usize {
    let mut count = 0;
    for val in map.values() {
        if *val == value {
            count += 1;
        }
    }
    count
}
 
fn count_iterator(map: &HashMap<String, Progress>, value: Progress) -> usize {
    let count = map
        .values()
        .into_iter()
        .map(|x| if *x == value { 1 } else { 0 })
        .sum::<usize>();
    count
}
}
</syntaxhighlight>
</syntaxhighlight>
For modules within modules you can make directories. For above this would be greetings\english and greetings\french. So we could have greetings\english\english.rs
 
==Mapper replacing a two dimensional for loop using Closure==
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
  pub fn hello() -> {"hello"->to_string() }
fn count_collection_for(collection: &[HashMap<String, Progress>], value: Progress) -> usize {
  pub fn goodbye() -> {"goodbye"->to_string() }
    let mut count = 0;
    for map in collection {
        for val in map.values() {
            if *val == value {
                count += 1;
            }
        }
    }
    count
}
 
fn count_collection_iterator(collection: &[HashMap<String, Progress>], value: Progress) -> usize {
    // Return a count of all the
    let count: usize = collection
        .iter()
        .map(|x| {
            x.values()
                .into_iter()
                .map(|y| if *y == value { 1 } else { 0 })
                .sum::<usize>()
        })
        .sum();
 
    count
}
</syntaxhighlight>
</syntaxhighlight>


greetings\lib.rs
 
==More Complex Example of closure==
We use the existing struct, make a copy and call them inside the  to  pass in objects from somewhere and use their results with the closure function
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
pub mod greetings
fn create_percent_complete_fn<'a>(
{
  &'a self,
  pub mod english;
  looper: &'a LooperDuration,
  pub mod french
  interpolator: &'a AccelerateDecelerateInterpolator,
  {
) -> impl Fn(u16) -> f64 + 'a {
      pub fn hello() -> {"bonjour"->to_string() }
  let looper_ref = looper;
      pub fn goodbye() -> {"au revoir"->to_string() }
  let interpolator_ref = interpolator;
  }
  let closure = move |elapsed_time: u16| {
    let rate_of_change = looper_ref.get_t_with_elapsed_time(elapsed_time);
    let b = interpolator_ref.get_interpolar(rate_of_change);
    return b * 100 as f64;
  };
  return closure;
}
</syntaxhighlight>
==Traits provided for closures==
These traits are provided in rust
*Fn
*FnOnce
*FnMut
We need to provide some explanation for this
<syntaxhighlight lang="rs">
/*
  || drop(v)            FnOnce as we only drop once
  |args| v.contains(arg) Fn as does not modify
  |args| v.push(arg)    FnMut as it does modify
*/
</syntaxhighlight>
 
=Iterators=
Nothing fancy here except we have to make the iterator mut (not surprising but worth mentioning). An iterator is any type which implements the iter trait and an iterable is a type that implements into iterator.
<syntaxhighlight lang="rs">
let vec = [1, 2, 3];
let mut iter = vec.iter();
while let Some(i) = iter.next() {
    println!("i {}", i);
}
</syntaxhighlight>
Just like Typescript we can now use closures like the map, filter functions in typescript. E.g. given a vector of times we can filter on property
<syntaxhighlight lang="rs">
items.into_iter().filter(|i|i.name == search_name).collect()
</syntaxhighlight>
We can implement our own iterator on our struct like below
<syntaxhighlight lang="rs">
struct Range {
    start: u32,
    end: u32
}
 
 
impl Iterator for Range {
    type Item = u32;
    fn next(&mut self) -> Option<Self::Item> {
      if self.start >= self.end {
          return None
      } 
      let result = Some(self.start);
      self.start += 1;
      result
    }
}
</syntaxhighlight>
==Example 1 Iterators==
This iterates over the input slice, calling next() once. At this point first contains the first item in input and chars now contains the rest. We concatenate the two values.
<syntaxhighlight lang="rs">
fn capitalize_first(input: &str) -> String {
    let mut chars = input.chars();
    match chars.next() {
        None => String::new(),
        Some(first) => {
            let capital = first.to_uppercase();
            format!("{}{}", capital, chars.as_str())
        }
    }
}
</syntaxhighlight>
==Example 2 Iterators Mapping over slice==
This is a good example of mapping like typescript but over a slice
<syntaxhighlight lang="rs">
fn capitalize_words_vector(words: &[&str]) -> Vec<String> {
    words
        .iter()
        .map(|&element| capitalize_first(element))
        .collect::<Vec<_>>()
}
}
</syntaxhighlight>
</syntaxhighlight>


We need a package file for it
=Pointers=
<syntaxhighlight lang="TOML">
This is the same a C++ with some rusty new language. The Box is a pointer type that uniquely owns a heap allocation of type
[package]
==Box Type==
name = "phrases"  
This the basic pointer
version = "0.1.0"
<syntaxhighlight lang="rs">
author = " ["Iain Wiseman iwiseman@bibble.co.nz"]
let t = (12, "eggs");
let b = Box::new(t);
println!("b {:?}", b); // (12, "eggs")
</syntaxhighlight>
==RC Type==
This allows multiple pointers to the same thing in memory. For example
<syntaxhighlight lang="rs">
let s1 = Rc::new(String::from("Pointer));
let s2 = s1.clone();
let s3 = s2.clone();
 
println("{},{},{}",s1,s2,s3) // Pointer, Pointer, Pointer
</syntaxhighlight>
==RefCell==
A RefCell is another way to change values without needing to declare mut. It means "reference cell", and is like a Cell but uses references instead of copies, Rust refers to Interior mutability which seems to say it is a pattern where the user is allow to modify data despite the data not having a mut associated with it. The function of RefCell allow us to modify when we dereferenced.
<syntaxhighlight lang="rs">
use std::{cell::RefCell};
 
struct Flagger {
    is_true: RefCell<bool>,
}
 
// borrow returns Ref<T>
// borrow_mut returns RefMut<t>
 
let flag = flagger{ is_true: RefCell::new(true)};
 
// let reference =  flag.is_true.borrow();
// println!("{}", reference);
 
let mut mut_ref = flag.is_true.borrow_mut();
*mut_ref = false;
 
</syntaxhighlight>
</syntaxhighlight>
And then cargo build should work. To use the package you will need to specify the path to the package in the cargo file where used. e.g.
Note if we want to use it twice, i.e. uncomment the println we have to wrap the RefCell with RC
<syntaxhighlight lang="toml">
<syntaxhighlight lang="rs">
[package]
  // In struct
name = "mypackage"
  is_true: Rc<RefCell<bool>>
version = "0.1.0"
 
author = " ["Iain Wiseman iwiseman@bibble.co.nz"]
  // Initialize
  let flag = flagger{ is_true: Rc::new<RefCell::new(true))}; 


[dependencies]
rand = "0.3.12"
phrases = { path = "../Phrases" }
</syntaxhighlight>
</syntaxhighlight>
=Rust Concurrency and Asynchronous Processing=
This can be found [[Rust Concurrency and Asynchronous Processing]]
=Concurrency=
This can be found [[Rust Concurrency and Asynchronous Processing]]


== Testing ==
=Macros=
Rush comes with it's own assert library marked by #[test] e.g. for the above
Because this page was so large I moved this to [[Rust_macros]]
 
= Functions =
== Functions and Arguments ==
No surprises
<syntaxhighlight lang="rust">
fn print_value(x: i32)
{
  println("value = {}", x);
}
</syntaxhighlight>
Pass by reference
<syntaxhighlight lang="rust">
fn increase(x: &mut i32)
{
  *x = 1;
}
</syntaxhighlight>
Return value, note no semicolon
<syntaxhighlight lang="rust">
fn product(x: i32, y: i32) -> i32
{
  x * y
}
</syntaxhighlight>
Return two values, note no semicolon
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
#[test]
fn product(x: i32) -> i32
fn english_greeting_correct()
{
{
  assert_eq!("hello", greetings::english::hello());
  if x == 10 {
    123
  }
 
  321
}
}
</syntaxhighlight>
</syntaxhighlight>
== Documentation ==
 
rustdoc is used to generate.
== Higher-order functions ==
Not sure what this is, seems like just a way to chain written functions together like lamba. Here is the given example.
<syntaxhighlight lang="rust">
<syntaxhighlight lang="rust">
//! This module comment
//! and this
//! #Examples are compiled with back ticks
//! ```
//! let username = "John";
//! println!("{}", english::hello());
//! ```


/// This is for code
fn is_even(x: u32) -> bool
/// In this case, it's our `hello()` function.
{
pub fn hello() -> String {" hello".to_string() }  
  x%2 == 0
}
 
fn main()
{
// Method without HOF
  let limit = 500;
  let mut sum = 0;
 
  for i in 0..
  {
    let isq = i*i;
 
    if isq > limit { break; }
    else if is_even(isq) { sum += isq; }
  }
 
  println!("loop sum = {}", sum);
 
// HOF way
 
  let sum2 =
    (0...).map(|x| x*x)
        .take_while(|&x| x < limit)
        .filter(|x| is_even(*x))
        .fold(0, |sum,x| sum+x);
 
  println!("hof sum = {}", sum2);
}


</syntaxhighlight>
</syntaxhighlight>

Latest revision as of 02:01, 3 January 2025

Cargo

Sample file

[package]
name = "hello_world"
version = "0.0.1"
authors = [ "Iain Wiseman iwiseman@bibble.co.nz" ]

Sample commands

 cargo new hello_world --bin
 cargo build
 cargo run

Fundamental Data Types

Primitive types

Cam declare with size of type or without 

 // Integers

 let a:u8 = 123; // unsigned int 8 bits number immutable
 let a:i8 = 123; // signed int 8 bits number immutable
 let mut a:u8 = 123; // unsigned int 8 bits number mutable

 let mut c = 123456789 // 32-bit signed i32
 println!("c = {}", c);

 // Based on OS e.g.
 let z:isize = 123 // signed 64 bit if on 64 bit OS

 // Decimal
 let e:f64 = 2.5 // double-precision, 8 bytes or 64-bits

 // Char
 let x:char = 'x' // Note 4 bytes unicode

 // Boolean
 let g:bool = false; // Note 4 bytes unicode

Operators

 // Does not support -- and ++ but does support
 a -= 2;

 // Remainder can be calculated using
 a%3

 // Bitwise
 let c = 1 | 2 // | OR

 // Shift   
 let two_to_10 = 1 << 10; // 1024

 // Logical of standard e.g.
 let pi_less_4 = std::f64::consts::PI < 4.0; // true

Scope and shadowing

Curly braces keep scope 

 fn test()
 {
   {
     let a = 5; 
   }
   println!("Broken {a}");
 }

Shadowing is fine though 

 fn test()
 {
   let a = 5; 
   {
     let a = 10; 
     println!("10 {a}");
   }
   println!("5 {a}");
 }

Constants

 // Standard const
 const MEANING_OF_LIFE:u8 = 42;
 // Static const 
 static Z:i32 = 123;

Types

Tuples

Eezy peezy lemon squeezy 

fn sum_and_product(x:i32,y:i32) -> (i32, i32)
{
 (x+y, x*y)
}

fn main()
{
  let sp = sum_and_product(3,4);
  let (a,b) = sp;
  let sp2 = sum_and_product(4,5);
   
  // combine
  let combined = (sp, sp2);
  let ((c,d), (e,f)) = combined;
}

Arrays

Array sizes cannot grow in rust

Simple

let mut a:[i32;5] = [1,2,3,4,5];
// Or 
let mut a = [1,2,3,4,5];
// Length
 a.len()
// Assignment
 a[0] = 321
// Printing
 println!("{:?}", )
// Testing
  if a == [1,2,3,4,5]
  {
  }
// Initialise
  let b = [1,10]; // 10 array initialised to 1

Multi Dimension

Here is a two dimension array 

let mtx:[[f32;3];2] =
[
  [1.0, 0.0, 0.0],
  [0.0, 2.0, 0.0],
];

Slices

A slice is a non-owning pointer to a block of memory. For example 

// Create a vector
let v: Vec<i32> = {0..5}.collect();

// Now create a slice (reference)
let sv: &[i32]= &v;

// We create a slice with only some elements
let sv1: &[i32]= &v[2..4];

// Printing these will produce the same result
println!("{:?}",v);
println!("{:?}",sv);

// And the range
println!("{:?}",sv1);

Strings

Basic String 

let name = String::from("Iain");
let name = "Iain".to_string();

Two types, static string and string type 

let s = "hello";
// Cannot do
// let h = s[0]
// You can iterate as a sequence using chars e.g.
for c in s.chars()
{
  println!("{}", c);
}

And now the mutable string in rust essentially an vector // Create a string 

let mut letters = String::new();

// Add a char
let a = 'a' as u8;
letters.push(a as char);

// String to str (string slice)
let u:%str = &letters;

// Concatenation
let z = lettters + &letters

// Other examples
let mut abc = "hello world".to_string()'
abc.remove(0);
abc.push_str("!!!");
abc.replace("ello","goodbye")

Hashmap

Reminds me of my C++ and Java days. No surprises here for reference 

let mut basket = HashMap::new();

basket.insert(String::from("banana"), 2);
basket.insert(String::from("pear"), 2);
basket.insert(String::from("peach"), 2);

Updating was a bit more tricky than expected. This was the copilot approach 

struct TeamScores {
    goals_scored: u8,
    goals_conceded: u8,
}

fn build_scores_table(results: &str) -> HashMap<&str, TeamScores> {
    // The name of the team is the key and its associated struct is the value.
    let mut scores = HashMap::new();

    for line in results.lines() {
        let mut split_iterator = line.split(',');
        // NOTE: We use `unwrap` because we didn't deal with error handling yet.
        let team_1_name = split_iterator.next().unwrap();
        let team_2_name = split_iterator.next().unwrap();
        let team_1_score: u8 = split_iterator.next().unwrap().parse().unwrap();
        let team_2_score: u8 = split_iterator.next().unwrap().parse().unwrap();

        let team_1 = scores.entry(team_1_name).or_insert(TeamScores::default());
        team_1.goals_scored += team_1_score;
        team_1.goals_conceded += team_2_score;

        let team_2 = scores.entry(team_2_name).or_insert(TeamScores::default());
        team_2.goals_scored += team_2_score;
        team_2.goals_conceded += team_1_score;
    }

    scores
}

The suggestion was to use get_mut on hashmap but struggle to get this to work. The solution from Chris biscardi on youtube was this, clearly the rust team looked at this and did it better. 

fn build_scores_table(results: &str) -> HashMap<&str, TeamScores> {
...
        scores
            .entry(team_1_name)
            .and_modify(|team: &mut TeamScores| {
                team.goals_scored += team_1_score;
                team.goals_conceded += team_2_score;
            })
            .or_insert(TeamScores {
                goals_scored: team_1_score,
                goals_conceded: team_2_score,
            });

        scores
            .entry(team_2_name)
            .and_modify(|team: &mut TeamScores| {
                team.goals_scored += team_2_score;
                team.goals_conceded += team_1_score;
            })
            .or_insert(TeamScores {
                goals_scored: team_2_score,
                goals_conceded: team_1_score,
            });

Control Flow

if statement

Same as C++ except no brackets 

 if temp > 30 
 {
    println!("Blah");
 }
 else if temp < 10 
 {
    println!("Blah"); 
 }
 else
 {
    println!("Blah"); 
 }

Elvis is like 

  let a = if temp > 30 {"sunny"} else {"cloud"}

While and Loop

While

Same as C++ except no brackets 

 while x < 1000
 {
 }

There is support for continue and break

Loop

Loop is while true 

 loop
 {
    if y == 1 << 10 { break; }
 }

For Loop

A bit like kotlin loops (I think) 

 for x in 1..11
 {
    println!("x = {}",x);
 }
 // You can get position in series as well
 for (pos,x) in (1..11).enumerate()
 {
    println!("x = {}, pos = {}",x, pos);
 }

Rust Principles

Ownership

Move

Move is when you assign a value to another variable. If we try and use a variable after the move we will get an error. 

let v = vec![1,2,3]
let v2 = v;
println!("{:?}",v2)
println!("{:?}",v) // Error

Copy

When we copy something me make a new thing. They is not the same a let a = b, which is assignment. Copy means we duplicate the underlying data of the type. For primitives a copy is implemented by default. This is because the primitive has a know size. E.g. u32, bool etc. If you want to be able to copy a non primitive you need to add the derive macro. Note Clone must also be specified 

#[derive(Copy, Clone)]
enum Direction {
    North,
    East,
    South,
    West,
}

#[derive(Copy, Clone)]
struct RoadPoint {
    direction: Direction,
    index: i32,
}

Clone

Clone is a method you can call on a struct if you want a second instance and not move the ownership. Here is an example. The struct obviously needs to implement the Copy/Clone macro. Cloning clearly increases the memory used. 

let v = vec![1,2,3]
let v2 = v.cone();
println!("{:?}",v)
println!("{:?}",v2)

References

So references are like C++ references, but for rust this means you can pass the ownership during function call 

main() {
    let mut s = String::from("Hello");
    change_string(&mut s);
}

fn change_string(some_string: &mut String) {
    some_string.push_str(", world!");
}

Note for returning a Reference
If we are returning a reference we must be returning a parameter as all local variables are destroyed. (Clearly Rust is not going to allow new MyMemory(6502)

Structs

Struct are the nearest thing to roughly classes in rust. You make a struct and then add implementation which are methods

General

There are 3 types of structs, name, tuple and unit structs

  • Named
  • Tuples
  • Unit

Name Struct

struct User
{
  active: bool,
  username: String,
  sign_in_count: u32
}

let user1 = User{active: true, username: String::from("Biil"),
  sign_in_count: 0};
println!("{}", user1.username);

...

fn build_user(username: String) -> User {
   User {
     username,
     active:true,
     sign_in_count: 1
   }
}

Tuple Struct

Tuple structs use the order in which declared to assign. 

   struct Coordinates{i32,i32,i32};
   let coords = Coordinates{1,2,3};

Unit Struct

These are used to mark the existence of something 

struct UnitStruct;
let a = UnitStruct{}

The example shown was when you are implementing a trait (interface) but the properties were not required for this type. So given a trait for Area, Square uses size but Point does not have an area as it is zero 

trait AreaCalculator {
  fn calc_area(&self) => f64
}

struct Square {
  size: f64
}

struct Point;

impl AreaCalculator for Square { 
  fn calc_area(&self) -> f64 {
    self.size * self.size
  } 
} 

impl AreaCalculator for Point { 
  fn calc_area(&self) -> f64 {
    0.0
  } 
}

We can use it for error 

struct DivideByZero;

fn divide(nom: f64, den: f64) -> Result<f64, DivideByZero> {
   if den != 0.0 {
       Ok(nom/den)
   } else {
       Err(DivideByZero)
   }
}

Example Structs

struct Point
{
  x: f64,
  y: f64
}

fn main()
{
  let p = Point { x: 30.0, y: 4.0 };
  println!("point is at ({},{})", p.x, p.y)
}

Methods on Structs

Methods on struct require the first argument to be self

Example Method

Add method len to struct 

struct Line
{
 start: Point,
 end: Point
}

// Declare impl using the keyword impl. Not ends with no semi colon.
impl Line
{
  fn len(&self) -> f64
  {
    let dx = self.start.x - self.end.x;
    let dy = self.start.y - self.end.y;
    (dx*dx+dy*dy).sqrt()
  }
}

Changing an attribute

To change an attribute and ensure you do not break the borrowing rules we do 

struct Square {
   width: u32,
   height: u32
}

impl Square
{
  fn area(&self) -> u32 {
     self.width * self.height
  }

  fn change_width(&mut self, new_width: u32) -> Self
  {
    self.width = new_width;
  }
}

...
main() {
...
   let mut sq = Square(width:5, height: 5);
   sq.change_point(10) 
}

Lifetime

What are Dangling References

The code below will not compile. This is because x goes out of scope before r. I am guessing this is what is known as a dangling reference. 

fn test() {
    let r;
    {
        let x = 5;
        r = &x; // Error `x` does not live long enough
    }
    log::info!("{}",r);
}

Lifetime Annotations

Not sure which way around these are but you specify lifetime annotations on functions and structs and they imply information to the compiler on how long the parameters will live for.

Three Rules of Lifetimes

Here are the rules but we also need to understand what they apply to. Kind of chicken and egg. An example is give below which is broken because these rules are not followed.

  1. Each Parameter that is a reference gets its own lifetime parameter
  2. If there is exactly one input lifetime parameter, that lifetime is assigned to all output lifetime parameters
  3. If there are multiple input lifetime parameters, but one of them is &self or &mut self the lifetime is assigned to all output lifetime parameters

Example (Broken code)

Here is an example of code which cannot be compiled without lifetime being specified. 

pub struct TestStruct {
    length: i32,
}

fn test2(x: &TestStruct, y: &TestStruct) -> &TestStruct { // Missing lifetime specifier
    if x.length > y.length {
      x
    }
    else {
      y 
    }
}

Adding Annotations

To do this we specify annotations. The extension in vscode does this for us using the quick fix. The code now looks like this 

fn test2<'a>(x: &'a TestStruct, y: &'a TestStruct) -> &'a TestStruct {
    if x.length > y.length {
      x
    }
    else {
      y 
    }
}

My inference from this is that all parameters have the same lifetime.

Lifetime Annotations for Structs

Structs can also have lifetime annotations. If you specify a reference then you will need to specify a lifetime annotation. In the example below when we make the struct of type MyString we need to make sure that str1 does not go out of scope while x of type MyString exists otherwise it would refer to something no longer in scope. 

// Without lifetime annotation will not compile.
// struct MyString {
//   text: &str,
// }


struct MyString<'a> {
  text: &'a str,
}

fn main() {

    let str1 = String::from("This is my String);
    let x = MyString(text: str1.as_str());
}

Static Lifetimes

We can also have lifetimes for statics. 

let s: &'static str = "I live forever";

Doing this means the values are stored in the binary.

Enums

Example 1 with Method

Seems a bit C++ but... we can add a method as we do with structs. Note for this method we are returning something and with rust all locals are destroyed on return so we need to specify a lifetime. 

enum Pet {dog, cat, fish}

impl Pet {
   fn what_am_i(self) -> &'static str {
      match self {
         Pet::dog => "I am a dog", 
         Pet::cat => "I am a cat",
         Pet::fish => "I am a fish",   
      }
   }
}

Example 2

enum Color {
  Red,
  Green,
  Blue
}

fn main()
{
  let c:Color = Color::Red;
  match c
  {
     Color::Red => prinln!("Color is Red");
     Color::Green => prinln!("Color is Green");
  }
}

Example 3 with Types

enum Color {
  Red,
  Green,
  Blue,
  RgbColor(u8,u8,u8) // Tuple
  CmykColor{cyan:u8, magenta:u8, yellow:u8, black:u8,} // Struct
}

fn main()
{
  let c:Color = Color::RgbColor(10,0.0);
  match c
  {
     Color::Red => prinln!("Color is Red");
     Color::Green => prinln!("Color is Green");
     Color::RgbColor(0,0,0) => prinln!("Color is Black");
     Color::RgbColor(r,g,b) => prinln!("Color is {},{},{}", r,g,b);
  }

  let d:Color = Color::CmykColor(cyan:0, magenta:0, yellow:0, black:0);
  match d
  {
     Color::Red => prinln!("Color is Red");
     Color::Green => prinln!("Color is Green");
     Color::RgbColor(0,0,0) => prinln!("Color is Black");
     Color::CmykColor(cyan:_, magenta:_, yellow:_, black:255) => prinln!("Black");
  }
}

Option<T> Enum

This enum if provided for us by rust and looks like this 

enum Option<T> {
    None,
    Some(T)
}

We would choose this type when we have a case where there could be a value or not. I guess this is the equivalent of string? in Typescript where we may or may not have a value. In rust we use match to support this type. 

  let some_number = Some(5); 
  let some_string = Some("a string");
  let nothing: Option<i32> = None;

Pattern Matching

Match is Exhaustive approach to pattern matching. I.E. you need to specify something for every option you are using match for. However you can include a default. I find this a great approach

Examples

Simple Match

match x
{
  0 => "zero"
  1 | 2 => "one or two"
  9...11 => "lots of"  // two dots does not include end value (exclusive)
  _ if(blahh) => "something"
  _ => "all others"
}

Here is another example. 

 let country = match country_code
 {
    44 => "uk",
    46 => "sweden",
    7 => "russia"
    1...999 => "unknown" // other triple dot does include end value (inclusive)
    _ => "invalid" // invalid
 };

This just shows inclusive which is ..= unlike kotlin which I think is 3 dots 

// This function returns how much icecream there is left in the fridge.
// If it's before 22:00 (24-hour system), then 5 scoops are left. At 22:00,
// someone eats it all, so no icecream is left (value 0). Return `None` if
// `hour_of_day` is higher than 23.
fn maybe_icecream(hour_of_day: u16) -> Option<u16> {
    match hour_of_day {
        0..22 => Some(5),
        22..=23 => Some(0),
        _ => None,
    }
}

More Complex

Stumped me when see thing for the first time prior to type script and possibly lambda. Here we define anonymous functions which match the type of the enum. Here is the enum which is used in another struct 

enum Message {
    Move(Point),
    Echo(String),
    ChangeColor(u8, u8, u8),
    Quit,
    Resize { width: u64, height: u64 },
}

It has functions for each enum type. 

struct State {
    width: u64,
    height: u64,
    position: Point,
    message: String,
    // RGB color composed of red, green and blue.
    color: (u8, u8, u8),
    quit: bool,
}

impl State {
    fn resize(&mut self, width: u64, height: u64) {
        self.width = width;
        self.height = height;
    }

    fn move_position(&mut self, point: Point) {
        self.position = point;
    }

    fn echo(&mut self, s: String) {
        self.message = s;
    }

    fn change_color(&mut self, red: u8, green: u8, blue: u8) {
        self.color = (red, green, blue);
    }

    fn quit(&mut self) {
        self.quit = true;
    }

    fn process(&mut self, message: Message) {
...
    }
}

At first I struggled to understand how to implement process but all you need to do is provide an ()_=> {} for each type. For Quit I completely understood but for the others was confused. Obvious once you know and I am sure copilot will do this for me 

    fn process(&mut self, message: Message) {
        match message {
            Message::Move(point) => self.move_position(point),
            Message::Echo(output) => self.echo(output),
            Message::ChangeColor(red, green, blue) => self.change_color(red, green, blue),
            Message::Quit => self.quit(),
            Message::Resize { width, height } => self.resize(width, height),
        }
    }

Match on Tuples

This is an exert from [Game of Life]. We can match on tuples, and I imagine other types too. For tuples you can specify a value or compare to a value. Note the use of otherwise 

    let next_cell = match (cell, live_neighbors) {
      // Rule 1: Any live cell with fewer than two live neighbours
      // dies, as if caused by underpopulation.
      (Cell::Alive, x) if x < 2 => Cell::Dead,
      // Rule 2: Any live cell with two or three live neighbours
      // lives on to the next generation.
      (Cell::Alive, 2) | (Cell::Alive, 3) => Cell::Alive,
      // Rule 3: Any live cell with more than three live
      // neighbours dies, as if by overpopulation.
      (Cell::Alive, x) if x > 3 => Cell::Dead,
      // Rule 4: Any dead cell with exactly three live neighbours
      // becomes a live cell, as if by reproduction.
      (Cell::Dead, 3) => Cell::Alive,
      // All other cells remain in the same state.
      (otherwise, _) => otherwise,
};

Operators and Symbols

Found in Table B-1 here [Operators and Symbols]

  1. [Range]: 1..10
  2. [RangeFrom]: 1..
  3. [RangeTo]: ..10
  4. RangeFull: ..
  5. RangeInclusive: 1..=10
  6. RangeToInclusive: ..=10

Option <T> and if let

Used to avoid null or invalid values. This was used in things where the value might be present. Maybe command line arguments where some were provide or none were provided. Lets to the classic divide by zero. 

let x = 3.0
let y = 0.0 // Divide by zero

let result:Option<f64> = 
   if y != 0.0 { Some(x/y) } else { None };

// Using match
match result {
   Some(z) => println!("Goody result"),
   None => println!("No result")
}

// Using if let
if let Some(z) = result { println!("z = {}", z); }

More if let

Here is another example 

let mut stack = Vec:new();
stack.push(1);
stack.push(2);
stack.push(3);
while let Some(top) = stack.pop() {
   println!("{}", top);
}

while let

The above example makes great sense but while doing rustlings the was this question 

  // TODO: Make this a while-let statement. Remember that `Vec::pop()`
  // adds another layer of `Option`. You can do nested pattern matching
  // in if-let and while-let statements.
  integer = optional_integers.pop() {
    assert_eq!(integer, cursor);
    cursor -= 1;
  }

I did like the Some Some approach 

   while let Some(Some(integer)) = optional_integers.pop() {
     assert_eq!(integer, cursor);
     cursor -= 1;
   }

But could not get the You can do nested pattern matching in if-let and while-let statements to look nice 

   while let Some(integer) = if let Some(integer) = optional_integers.pop() {
     integer
   } else {
     None
   } {
     assert_eq!(integer, cursor);
     cursor -= 1;
   }

Just wouldn't let it lie, found a way to turn it up the right way 

   while let Some(integer) = optional_integers.pop() {
     if let Some(integer) = integer {
       assert_eq!(integer, cursor);
       cursor -= 1;
     }
   }

Generics

Simple

This is very similar to C++ Templates and TypeScript Generics 

struct Point<T>
{
  x: T,
  y: T
}

fn generics()
{
  let a:Point<i32> = Point {x: 0, y: 4}
}

Using Implementation

An example where we use an implementation 

struct Wrapper<T> {
    value: T,
}

impl<T> Wrapper<T> {
    fn new(value: T) -> Self {
        Wrapper { value }
    }
}

Traits

Traits are similar to interfaces in java and c#

Defining a Traits

trait Animal
{
  fn create(name:&'static str);

  fn name(&self) => &'static str;

  fn talk(&self)
  {
     println!("{} cannot talk",self.name()); 
  }
}

Implement a Trait

Here we create a struct which will implement out trait. Note we do not have to implement all functions if the trait provides a default implementation

Implement a Trait for Animal

struct Human
{
   name: &'static str;
}

impl Animal for Human
{
  fn create(name:&'static str) -> Human
  {
    Human{name: name}
  }

  fn name(&self) -> &'static str
  { 
     self.name
  }
  // override default
  fn talk(&self)
  {
     println!("{} can talk",self.name()); 
  }
}

Implement a Trait for Cat

Here we implement the Animal Trait for Cat 

struct Cat
{
   name: &'static str;
}

// Implement interface
impl Animal for Cat
{
  fn create(name:&'static str) -> Cat
  {
    Cat{name: name}
  }

  fn name(&self) -> &'static str
  { 
     self.name
  }
  // override default
  fn talk(&self)
  {
     println!("{} says meeow",self.name()); 
  }
}


// Usage
let h:Human = Animal::create("John");
let c:Cat = Animal::create("John");

Default Trait and Spread

For a struct we can create a default for it. We can use a typescript like spread operator (although it must be last) for override these defaults 

pub struct Circle {
    color: String,
    point: Point,
    radius: u16,
}

impl Circle {
    pub fn new(color: String, point: Point, radius: u16) -> Circle {
        Circle {
            color,
            point,
            radius,
        }
    }

    pub fn default_color(point: Point, radius: u16) -> Circle {
        Circle {
            point,
            radius,
            ..Default::default()
        }
    }
}

impl Default for Circle {
    fn default() -> Self {
        Circle {
            color: String::from("black"),
            point: Point::new(0, 0),
            radius: 0,
        }
    }
}

// Default Circle
let circle = Circle::default();

// Default Black Circle
let circle = Circle::default_color(Point::new(1, 1), 1);

Traits and with Dyn and Impl

To allow any struct which implements the trait we use the dyn or impl keyword

Difference Between dyn and impl

  • dyn means dynamic dispatch. This results in a fat pointer. One pointer pointing to the data and the other pointing to the vtable.
  • impl means static dispatch. This results in a new copy of the function for each usage

Example

trait Licensed {
    fn licensing_info(&self) -> String {
        "Default license".to_string()
    }
}

struct SomeSoftware;
struct OtherSoftware;

impl Licensed for SomeSoftware {}
impl Licensed for OtherSoftware {}

// TODO: Fix the compiler error by only changing the signature of this function.
fn compare_license_types(software1: impl Licensed, software2: impl Licensed) -> bool {
    software1.licensing_info() == software2.licensing_info()
}

// Now we can do this
compare_license_types(SomeSoftware, OtherSoftware)
compare_license_types(OtherSoftware, SomeSoftware)

Why Box

When can return a dyn Trait too. We clearly do not know the size of the return value. To overcome this we put the return argument in a Box which is essentially a smart pointer in C++ 

fn random_animal(random_number: f64) -> Box<dyn Animal> {
    if random_number < 0.5 {
        Box::new(Sheep {})
    } else {
        Box::new(Cow {})
    }
}

Super Traits

We can make a trait to which says you must implement these traits to implement me. 

trait Amphibious : WaterCapable + LandCapable + UnderWaterCapable {}

Now when you use this trait you have to implement the other 3 traits.

Provided Traits

Drop Trait

Drop trait is called automatically to free up resources but you can write your own e.g. for the example above we could write 

impl Drop for Course {
  fn drop(&mut self) {
     println("Dropping")
  }
}

Clone Trait

Like the drop trait we can implement our own. Refer to the clone trait for this.

Copy Trait

We can either specify #[derive(Copy, Clone)] or implement our own. There are restrictions on this

From and Into Trait

This allow us to convert from one type to another 

fn into(self) -> T
fn from(T) ->  Self
fn try_into(self) -> Result<T, Self: Error>
fn try_from(value: T) -> Result<Self, Self: Error>

Trait Bounds 1

In order to allow use of more than on trait in a function we can use the +. This example means that item must implement both traits, i.e. SomeTrait and OtherTrait 

fn some_func(item: impl SomeTrait + OtherTrait) -> bool {
    item.some_function() && item.other_function()
}

Trait Bounds 2

Here is an example of doing the same thing in two ways. Because we can have anything in grade (T) we must make an implementation for std::fmt::Display. That way if we make a ReportCard with a generic which does not support Display, it will not compile 

struct ReportCard<T> {
    grade: T,
    student_name: String,
    student_age: u8,
}

// Approach 1
impl<T> ReportCard<T>
where
    T: std::fmt::Display,
{
    fn print(&self) -> String {
        format!(
            "{} ({}) - achieved a grade of {}",
            &self.student_name, &self.student_age, &self.grade,
        )
    }
}

// Approach 2
impl<T: std::fmt::Display> ReportCard<T> {
    fn print(&self) -> String {
        format!(
            "{} ({}) - achieved a grade of {}",
             &self.student_name, &self.student_age, &self.grade,
        )
    }
}

Trait Bounds

The example above has two ways to achieve the same thing. If we constrain what this allowed, this is called trait bounds. Lets add a second parameter. 

// This example only forces the struct to implement the trait
// fn overview(item1: &imp Overview, item2: &imp Overview) 

// But this force the struct to be of the same type
// fn overview<T: Overview>(item1: &T, item2: &T)

We can add more constraints with the + operator. Now they need the second trait. 

// fn overview(item1: &imp Overview + AnotherTrait, item2: &imp Overview + AnotherTrait) 
// fn overview<T: Overview + AnotherTrait>(item1: &T, item2: &T)

Here we have an example of ensuring that the incoming parameters are constrained to be of type T 

struct Pointy<T> {
    x: T,
    y: T,
}

impl <T> Add for Pointy <T>
where T: Add<Output = T>
{
    type Output = Self;

    fn add(self, other: Self) -> Self {
        Self {
            x: self.x + other.x, 
            y: self.y + other.y,
        }
    }
}

Passing Trait as Parameters

So here is an example of two structs with overview implement,one using the trait default implementation, the other its own. We can use the trait similar to a pointer to a function.

Example

trait Overview {
  fn overview(&self) -> String {
     format("This is a rust course")
  } 
}

struct Course {
  headline: String,
  author: String
}

struct AnotherCourse {
  headline: String,
  author: String
}

impl Overview for Course {
}

impl Overview for AnotherCourse {
  fn overview(&self) -> String {
     format("{}, {}", self.author, self.headline)
  } 
}

We can use the overview trait a a fn parameter with 

fn call_overview(item: &imp) {
   println("Overview: {}", item.overview())
}

// OR 
fn call_overview<T: Overview>(item: &T) {
   println("Overview: {}", item.overview())
}

Passing Traits (From Youtube)

Taken from Youtube and repeated. There are two notations for passing a trait. These are the same but the first is perhaps more readable. The second is known as a trait bound. 

pub fn foo (traitor: &impl SpiDevice) {

}

pub fn foo<T: SpiDevice>(traitor: &T) {

}

With the impl syntax we can make the parameter have more the one trait with a plus. 

pub fn foo (traitor: &impl SpiDevice + AnotherTrait) {

}

With the second syntax if we have two parameters if allows us to make sure they both share the same trait easily as the type is only specified once 

pub fn foo<T: SpiDevice>(traitor1: &T, traitor2) {

}

We can also add a second trait with this syntax too. 

pub fn foo<T: SpiDevice + AnotherTrait>(traitor1: &T, traitor2) {

}

This starts to get messy to we can tidy this up with the Where Clause 

pub fn foo<T, U>(traitor1: &T, traitor2: &U) -> i32
where 
    T: SpiDevice + AnotherTrait,
    U: AnotherTrait + YetAnotherTrait
        {
            42
        }

Returning Traits (From Youtube)

We can also return traits but you cannot return different types which share the same trait at this time. 

pub fn foo() -> SpiDevice {
    // Must be of same type
}

Common Collections

Vectors

Same a c++ 

let mut a = Vec::new()
a.push(1);
a.push(2);
a.push(3);
// Print
println!("a[0] {}", a[0]);

// We can create vector with initial capacity
let mut b = Vec::<i32>::with_capacity(2);

// We can initialize using an iterator values of 0-4
let c: Vect<i32> = (0..5).collect();

// Using get returns a option
match a.get(3333)
{
...
}

// Removing, pop returns an option   
let last_elem = a.pop();

// Using the option type iterating over vector to print it
while let Some(x) = a.pop()
{
   println!("x = {}",x);
}

Binary Heap

This struct makes sure the highest is at the top. It has a peek function to allow you to peek at values. 

let mut bHeap = BinaryHeap::new();
bHeap.push(1);
bHeap.push(18);
bHeap.push(20);
bHeap.push(5);
bHeap.pop();

println!("{:?}", bHeap); // 20

Maps

Not discussed

Sets

Not discussed

Error Handling

Panic

Panic happens when unhandled error occurs. This happens for instance when we access out of bounds array. We can get a backtrace by setting the environment export RUST_BACKTRACE=-1

Result Enum

The Result an enum which has two generics Result<T, E> where T is the type an E is the error. In rust we use the match to determine what to do. 

let file = File::Open("Does_not_exist.mp3");
let file match file {
    Ok(file) => file,
    Err(error) => panic("Error: {:?}", error),
};

Mapping Errors

Rust likes you to make your own errors and map the ones you handle to you errors which makes sense. We make our own errors using enums 

enum ParsePosNonzeroError {
    Creation(CreationError),
    ParseInt(ParseIntError),
}

Now we can provide helper function to convert from one type of error to ours 

impl ParsePosNonzeroError {
    fn from_creation(err: CreationError) -> Self {
        Self::Creation(err)
    }

    // TODO: Add another error conversion function here.
    fn from_parse_int(err: ParseIntError) -> Self {
        Self::ParseInt(err)
    }
}

Now in our parse function we can map the errors in parse() to our own 

#[derive(PartialEq, Debug)]
struct PositiveNonzeroInteger(u64);

impl PositiveNonzeroInteger {
    fn new(value: i64) -> Result<Self, CreationError> {
        match value {
            x if x < 0 => Err(CreationError::Negative),
            0 => Err(CreationError::Zero),
            x => Ok(Self(x as u64)),
        }
    }

    fn parse(s: &str) -> Result<Self, ParsePosNonzeroError> {
        // TODO: change this to return an appropriate error instead of panicking
        // when `parse()` returns an error.
        let x: i64 = s.parse().map_err(ParsePosNonzeroError::from_parse_int)?;
        Self::new(x).map_err(ParsePosNonzeroError::from_creation)
    }
}

Testing

We specify the cfg option and use the assert library 

fn sqrt(number: f64) -> Result<f64, String> {
    if number >= 0.0 {
        Ok(number.powf(0.5))
    } else {
        Err("negative floats don't have square roots".to_owned())
    }
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_sqrt() -> Result<(), String> {
        let x = 4.0;
        assert_eq!(sqrt(x)?.powf(2.0), x);
        Ok(())
    }
}

We can run these with 

cargo test

Closures

Closures are functions you which you can use the available scope to with that function. They look like anonymous function in typescript

Simple Example of a closure

The adder closure takes a parameter and captures existing scope at creation to produce the answer 17. 

    let x: i32 = 5;
    let adder = |a| a + x;
    let b = adder(12);
    print!("b {}", b)

Mapper Function using Closure

Here is a closure which is like typescript mapper function using closures and rust 

things.map((element: number) => element * 2)

And now the same thing in rust 

things.iter().map(|element| element * 2).collect()

Mapper replacing a for loop using Closure

The key to do thing was to specify the type with the sum i.e. sum::<usize>() rather than sum() 

fn count_for(map: &HashMap<String, Progress>, value: Progress) -> usize {
    let mut count = 0;
    for val in map.values() {
        if *val == value {
            count += 1;
        }
    }
    count
}

fn count_iterator(map: &HashMap<String, Progress>, value: Progress) -> usize {
    let count = map
        .values()
        .into_iter()
        .map(|x| if *x == value { 1 } else { 0 })
        .sum::<usize>();
    count
}

Mapper replacing a two dimensional for loop using Closure

fn count_collection_for(collection: &[HashMap<String, Progress>], value: Progress) -> usize {
    let mut count = 0;
    for map in collection {
        for val in map.values() {
            if *val == value {
                count += 1;
            }
        }
    }
    count
}

fn count_collection_iterator(collection: &[HashMap<String, Progress>], value: Progress) -> usize {
    // Return a count of all the
    let count: usize = collection
        .iter()
        .map(|x| {
            x.values()
                .into_iter()
                .map(|y| if *y == value { 1 } else { 0 })
                .sum::<usize>()
        })
        .sum();

    count
}


More Complex Example of closure

We use the existing struct, make a copy and call them inside the to pass in objects from somewhere and use their results with the closure function 

fn create_percent_complete_fn<'a>(
  &'a self,
  looper: &'a LooperDuration,
  interpolator: &'a AccelerateDecelerateInterpolator,
) -> impl Fn(u16) -> f64 + 'a {
  let looper_ref = looper;
  let interpolator_ref = interpolator;
  let closure = move |elapsed_time: u16| {
    let rate_of_change = looper_ref.get_t_with_elapsed_time(elapsed_time);
    let b = interpolator_ref.get_interpolar(rate_of_change);
    return b * 100 as f64;
  };
  return closure;
}

Traits provided for closures

These traits are provided in rust

  • Fn
  • FnOnce
  • FnMut

We need to provide some explanation for this 

/*
  || drop(v)             FnOnce as we only drop once
  |args| v.contains(arg) Fn as does not modify
  |args| v.push(arg)     FnMut as it does modify 
*/

Iterators

Nothing fancy here except we have to make the iterator mut (not surprising but worth mentioning). An iterator is any type which implements the iter trait and an iterable is a type that implements into iterator. 

let vec = [1, 2, 3];
let mut iter = vec.iter();
while let Some(i) = iter.next() {
    println!("i {}", i);
}

Just like Typescript we can now use closures like the map, filter functions in typescript. E.g. given a vector of times we can filter on property 

items.into_iter().filter(|i|i.name == search_name).collect()

We can implement our own iterator on our struct like below 

struct Range {
    start: u32,
    end: u32
 }


impl Iterator for Range {
    type Item = u32;
    fn next(&mut self) -> Option<Self::Item> {
       if self.start >= self.end {
          return None 
       }  
       let result = Some(self.start);
       self.start += 1;
       result
    }
 }

Example 1 Iterators

This iterates over the input slice, calling next() once. At this point first contains the first item in input and chars now contains the rest. We concatenate the two values. 

fn capitalize_first(input: &str) -> String {
    let mut chars = input.chars();
    match chars.next() {
        None => String::new(),
        Some(first) => {
            let capital = first.to_uppercase();
            format!("{}{}", capital, chars.as_str())
        }
    }
}

Example 2 Iterators Mapping over slice

This is a good example of mapping like typescript but over a slice 

fn capitalize_words_vector(words: &[&str]) -> Vec<String> {
    words
        .iter()
        .map(|&element| capitalize_first(element))
        .collect::<Vec<_>>()
}

Pointers

This is the same a C++ with some rusty new language. The Box is a pointer type that uniquely owns a heap allocation of type

Box Type

This the basic pointer 

let t = (12, "eggs");
let b = Box::new(t);
println!("b {:?}", b); // (12, "eggs")

RC Type

This allows multiple pointers to the same thing in memory. For example 

let s1 = Rc::new(String::from("Pointer));
let s2 = s1.clone();
let s3 = s2.clone();

println("{},{},{}",s1,s2,s3) // Pointer, Pointer, Pointer

RefCell

A RefCell is another way to change values without needing to declare mut. It means "reference cell", and is like a Cell but uses references instead of copies, Rust refers to Interior mutability which seems to say it is a pattern where the user is allow to modify data despite the data not having a mut associated with it. The function of RefCell allow us to modify when we dereferenced. 

use std::{cell::RefCell};

struct Flagger {
    is_true: RefCell<bool>,
 }

// borrow returns Ref<T>
// borrow_mut returns RefMut<t>

let flag = flagger{ is_true: RefCell::new(true)};

// let reference =  flag.is_true.borrow();
// println!("{}", reference);

let mut mut_ref = flag.is_true.borrow_mut();
*mut_ref = false;

Note if we want to use it twice, i.e. uncomment the println we have to wrap the RefCell with RC 

   // In struct
   is_true: Rc<RefCell<bool>>

   // Initialize
   let flag = flagger{ is_true: Rc::new<RefCell::new(true))};

Rust Concurrency and Asynchronous Processing

This can be found Rust Concurrency and Asynchronous Processing

Concurrency

This can be found Rust Concurrency and Asynchronous Processing

Macros

Because this page was so large I moved this to Rust_macros

Functions

Functions and Arguments

No surprises 

fn print_value(x: i32)
{
  println("value = {}", x);
}

Pass by reference 

fn increase(x: &mut i32)
{
  *x = 1;
}

Return value, note no semicolon 

fn product(x: i32, y: i32) -> i32
{
  x * y
}

Return two values, note no semicolon 

fn product(x: i32) -> i32
{
  if x == 10 {
     123
  }
  
  321
}

Higher-order functions

Not sure what this is, seems like just a way to chain written functions together like lamba. Here is the given example. 

fn is_even(x: u32) -> bool 
{
   x%2 == 0 
}

fn main()
{
// Method without HOF
  let limit = 500;
  let mut sum = 0;

  for i in 0..
  {
    let isq = i*i;

    if isq > limit { break; }
    else if is_even(isq) { sum += isq; }
  }

  println!("loop sum = {}", sum);

// HOF way

  let sum2 =
     (0...).map(|x| x*x)
        .take_while(|&x| x < limit)
        .filter(|x| is_even(*x))
        .fold(0, |sum,x| sum+x);

  println!("hof sum = {}", sum2);
}
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