feat: completed solutions

2026-03-23 03:36:33 -04:00
parent 2279bea6f1
commit f568c094cb
65 changed files with 424 additions and 139 deletions
@@ -1,6 +1,6 @@
 DON'T EDIT THIS FILE!
-structs1
+as_ref_mut
 intro1
 intro2
@@ -32,3 +32,67 @@ move_semantics2
 move_semantics3
 move_semantics4
 move_semantics5
 structs1
 structs2
 structs3
 enums1
 enums2
 enums3
 strings1
 strings2
 strings3
 strings4
 modules1
 modules2
 modules3
 hashmaps1
 hashmaps2
 hashmaps3
 quiz2
 options1
 options2
 options3
 errors1
 errors2
 errors3
 errors4
 errors5
 errors6
 generics1
 generics2
 traits1
 traits2
 traits3
 traits4
 traits5
 quiz3
 lifetimes1
 lifetimes2
 lifetimes3
 tests1
 tests2
 tests3
 iterators1
 iterators2
 iterators3
 iterators4
 iterators5
 box1
 rc1
 arc1
 cow1
 threads1
 threads2
 threads3
 macros1
 macros2
 macros3
 macros4
 clippy1
 clippy2
 clippy3
 using_as
 from_into
 from_str
 try_from_into
 as_ref_mut
@@ -1,12 +1,15 @@
 struct ColorRegularStruct {
    // TODO: Add the fields that the test `regular_structs` expects.
    // What types should the fields have? What are the minimum and maximum values for RGB colors?
    red: u8,
    green: u8,
    blue: u8,
 }
-struct ColorTupleStruct(/* TODO: Add the fields that the test `tuple_structs` expects */);
+struct ColorTupleStruct(u8, u8, u8);
 #[derive(Debug)]
-struct UnitStruct;
+struct UnitStruct();
 fn main() {
    // You can optionally experiment here.
@@ -19,7 +22,11 @@ mod tests {
    #[test]
    fn regular_structs() {
        // TODO: Instantiate a regular struct.
-        // let green =
+        let green = ColorRegularStruct {
            red: 0,
            green: 255,
            blue: 0,
        };
        assert_eq!(green.red, 0);
        assert_eq!(green.green, 255);
@@ -29,7 +36,7 @@ mod tests {
    #[test]
    fn tuple_structs() {
        // TODO: Instantiate a tuple struct.
-        // let green =
+        let green = ColorTupleStruct(0, 255, 0);
        assert_eq!(green.0, 0);
        assert_eq!(green.1, 255);
@@ -39,7 +46,7 @@ mod tests {
    #[test]
    fn unit_structs() {
        // TODO: Instantiate a unit struct.
-        // let unit_struct =
+        let unit_struct = UnitStruct();
        let message = format!("{unit_struct:?}s are fun!");
        assert_eq!(message, "UnitStructs are fun!");
@@ -34,7 +34,11 @@ mod tests {
        let order_template = create_order_template();
        // TODO: Create your own order using the update syntax and template above!
-        // let your_order =
+        let your_order = Order {
            name: "Hacker in Rust".to_string(),
            count: 1,
            ..order_template
        };
        assert_eq!(your_order.name, "Hacker in Rust");
        assert_eq!(your_order.year, order_template.year);
@@ -24,14 +24,16 @@ impl Package {
    }
    // TODO: Add the correct return type to the function signature.
-    fn is_international(&self) {
+    fn is_international(&self) -> bool {
        // TODO: Read the tests that use this method to find out when a package
        // is considered international.
        self.sender_country != self.recipient_country
    }
    // TODO: Add the correct return type to the function signature.
-    fn get_fees(&self, cents_per_gram: u32) {
+    fn get_fees(&self, cents_per_gram: u32) -> u32 {
        // TODO: Calculate the package's fees.
        cents_per_gram * self.weight_in_grams
    }
 }
@@ -1,6 +1,11 @@
 #[derive(Debug)]
 enum Message {
    // TODO: Define a few types of messages as used below.
    Resize,
    Move,
    Echo,
    ChangeColor,
    Quit,
 }
 fn main() {
@@ -7,6 +7,11 @@ struct Point {
 #[derive(Debug)]
 enum Message {
    // TODO: Define the different variants used below.
    Resize { width: usize, height: usize },
    Move(Point),
    Echo(String),
    ChangeColor(u8, u8, u8),
    Quit,
 }
 impl Message {
@@ -46,6 +46,13 @@ impl State {
    fn process(&mut self, message: Message) {
        // TODO: Create a match expression to process the different message
        // variants using the methods defined above.
        match message {
            Message::Resize { width, height } => self.resize(width, height),
            Message::Move(point) => self.move_position(point),
            Message::Echo(string) => self.echo(string),
            Message::ChangeColor(red, green, blue) => self.change_color(red, green, blue),
            Message::Quit => self.quit(),
        }
    }
 }
@@ -1,5 +1,5 @@
 // TODO: Fix the compiler error without changing the function signature.
-fn current_favorite_color() -> String {
+fn current_favorite_color() -> &'static str {
    "blue"
 }
@@ -6,7 +6,7 @@ fn is_a_color_word(attempt: &str) -> bool {
 fn main() {
    let word = String::from("green"); // Don't change this line.
-    if is_a_color_word(word) {
+    if is_a_color_word(&word) {
        println!("That is a color word I know!");
    } else {
        println!("That is not a color word I know.");
@@ -1,13 +1,16 @@
 fn trim_me(input: &str) -> &str {
    // TODO: Remove whitespace from both ends of a string.
    input.trim_ascii()
 }
 fn compose_me(input: &str) -> String {
    // TODO: Add " world!" to the string! There are multiple ways to do this.
    input.to_owned() + " world!"
 }
 fn replace_me(input: &str) -> String {
    // TODO: Replace "cars" in the string with "balloons".
    input.to_owned().replace("cars", "balloons")
 }
 fn main() {
@@ -1,6 +1,3 @@
 // Calls of this function should be replaced with calls of `string_slice` or `string`.
 fn placeholder() {}
 fn string_slice(arg: &str) {
    println!("{arg}");
 }
@@ -13,25 +10,25 @@ fn string(arg: String) {
 // Your task is to replace `placeholder(…)` with either `string_slice(…)`
 // or `string(…)` depending on what you think each value is.
 fn main() {
-    placeholder("blue");
+    string_slice("blue"); // &str
-    placeholder("red".to_string());
+    string("red".to_string()); // String
-    placeholder(String::from("hi"));
+    string(String::from("hi")); // String
-    placeholder("rust is fun!".to_owned());
+    string("rust is fun!".to_owned()); // String
-    placeholder("nice weather".into());
+    string("nice weather".into()); // String
-    placeholder(format!("Interpolation {}", "Station"));
+    string(format!("Interpolation {}", "Station")); // String
    // WARNING: This is byte indexing, not character indexing.
    // Character indexing can be done using `s.chars().nth(INDEX)`.
-    placeholder(&String::from("abc")[0..1]);
+    string_slice(&String::from("abc")[0..1]); // &str
-    placeholder("  hello there ".trim());
+    string_slice("  hello there ".trim()); // &str
-    placeholder("Happy Monday!".replace("Mon", "Tues"));
+    string("Happy Monday!".replace("Mon", "Tues")); // String
-    placeholder("mY sHiFt KeY iS sTiCkY".to_lowercase());
+    string("mY sHiFt KeY iS sTiCkY".to_lowercase()); // String
 }
@@ -5,7 +5,7 @@ mod sausage_factory {
        String::from("Ginger")
    }
-    fn make_sausage() {
+    pub fn make_sausage() {
        get_secret_recipe();
        println!("sausage!");
    }
@@ -3,8 +3,8 @@
 mod delicious_snacks {
    // TODO: Add the following two `use` statements after fixing them.
-    // use self::fruits::PEAR as ???;
+    pub use self::fruits::PEAR as fruit;
-    // use self::veggies::CUCUMBER as ???;
+    pub use self::veggies::CUCUMBER as veggie;
    mod fruits {
        pub const PEAR: &str = "Pear";
@@ -3,7 +3,7 @@
 // TODO: Bring `SystemTime` and `UNIX_EPOCH` from the `std::time` module into
 // your scope. Bonus style points if you can do it with one line!
-// use ???;
+use std::time::{SystemTime, UNIX_EPOCH};
 fn main() {
    match SystemTime::now().duration_since(UNIX_EPOCH) {
@@ -8,10 +8,12 @@ use std::collections::HashMap;
 fn fruit_basket() -> HashMap<String, u32> {
    // TODO: Declare the hash map.
-    // let mut basket =
+    let mut basket = HashMap::<String, u32>::new();
    // Two bananas are already given for you :)
    basket.insert(String::from("banana"), 2);
    basket.insert(String::from("apple"), 2);
    basket.insert(String::from("mango"), 2);
    // TODO: Put more fruits in your basket.
@@ -32,6 +32,7 @@ fn fruit_basket(basket: &mut HashMap<Fruit, u32>) {
        // TODO: Insert new fruits if they are not already present in the
        // basket. Note that you are not allowed to put any type of fruit that's
        // already present!
        basket.entry(fruit).or_insert(1);
    }
 }
@@ -31,13 +31,47 @@ fn build_scores_table(results: &str) -> HashMap<&str, TeamScores> {
        // Keep in mind that goals scored by team 1 will be the number of goals
        // conceded by team 2. Similarly, goals scored by team 2 will be the
        // number of goals conceded by team 1.
-    }
+        scores
            .entry(team_1_name)
            .and_modify(|current_team_1_scores| {
                current_team_1_scores.goals_scored += team_1_score;
                current_team_1_scores.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(|current_team_2_scores| {
                current_team_2_scores.goals_scored += team_2_score;
                current_team_2_scores.goals_conceded += team_1_score
            })
            .or_insert(TeamScores {
                goals_scored: team_2_score,
                goals_conceded: team_1_score,
            });
    }
    scores
 }
 fn main() {
    // You can optionally experiment here.
    const RESULTS: &str = "England,France,4,2
 France,Italy,3,1
 Poland,Spain,2,0
 Germany,England,2,1
 England,Spain,1,0";
    let scores = build_scores_table(RESULTS);
    for (key, value) in &scores {
        println!(
            "{key}: (scored: {0}, conceeded: {1})",
            value.goals_scored, value.goals_conceded
        );
    }
 }
 #[cfg(test)]
@@ -54,9 +88,11 @@ England,Spain,1,0";
    fn build_scores() {
        let scores = build_scores_table(RESULTS);
-        assert!(["England", "France", "Germany", "Italy", "Poland", "Spain"]
+        assert!(
-            .into_iter()
+            ["England", "France", "Germany", "Italy", "Poland", "Spain"]
-            .all(|team_name| scores.contains_key(team_name)));
+                .into_iter()
                .all(|team_name| scores.contains_key(team_name))
        );
    }
    #[test]
@@ -4,6 +4,11 @@
 // `hour_of_day` is higher than 23.
 fn maybe_ice_cream(hour_of_day: u16) -> Option<u16> {
    // TODO: Complete the function body.
    match hour_of_day {
        0..22 => Some(5),
        22..=23 => Some(0),
        _ => None,
    }
 }
 fn main() {
@@ -18,7 +23,7 @@ mod tests {
    fn raw_value() {
        // TODO: Fix this test. How do you get the value contained in the
        // Option?
-        let ice_creams = maybe_ice_cream(12);
+        let ice_creams = maybe_ice_cream(12).unwrap();
        assert_eq!(ice_creams, 5); // Don't change this line.
    }
@@ -10,7 +10,7 @@ mod tests {
        let optional_target = Some(target);
        // TODO: Make this an if-let statement whose value is `Some`.
-        word = optional_target {
+        if let Some(word) = optional_target {
            assert_eq!(word, target);
        }
    }
@@ -29,7 +29,7 @@ mod tests {
        // 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() {
+        while let Some(Some(integer)) = optional_integers.pop() {
            assert_eq!(integer, cursor);
            cursor -= 1;
        }
@@ -9,7 +9,7 @@ fn main() {
    // TODO: Fix the compiler error by adding something to this match statement.
    match optional_point {
-        Some(p) => println!("Coordinates are {},{}", p.x, p.y),
+        Some(ref p) => println!("Coordinates are {},{}", p.x, p.y),
        _ => panic!("No match!"),
    }
@@ -4,12 +4,12 @@
 // construct to `Option` that can be used to express error conditions. Change
 // the function signature and body to return `Result<String, String>` instead
 // of `Option<String>`.
-fn generate_nametag_text(name: String) -> Option<String> {
+fn generate_nametag_text(name: String) -> Result<String, String> {
    if name.is_empty() {
        // Empty names aren't allowed
-        None
+        Err("Empty names aren't allowed".into())
    } else {
-        Some(format!("Hi! My name is {name}"))
+        Ok(format!("Hi! My name is {name}"))
    }
 }
@@ -21,7 +21,7 @@ fn total_cost(item_quantity: &str) -> Result<i32, ParseIntError> {
    let cost_per_item = 5;
    // TODO: Handle the error case as described above.
-    let qty = item_quantity.parse::<i32>();
+    let qty = item_quantity.parse::<i32>()?;
    Ok(qty * cost_per_item + processing_fee)
 }
@@ -15,7 +15,7 @@ fn total_cost(item_quantity: &str) -> Result<i32, ParseIntError> {
 // TODO: Fix the compiler error by changing the signature and body of the
 // `main` function.
-fn main() {
+fn main() -> Result<(), ParseIntError> {
    let mut tokens = 100;
    let pretend_user_input = "8";
@@ -24,8 +24,10 @@ fn main() {
    if cost > tokens {
        println!("You can't afford that many!");
        Ok(())
    } else {
        tokens -= cost;
        println!("You now have {tokens} tokens.");
        Ok(())
    }
 }
@@ -11,7 +11,11 @@ impl PositiveNonzeroInteger {
    fn new(value: i64) -> Result<Self, CreationError> {
        // TODO: This function shouldn't always return an `Ok`.
        // Read the tests below to clarify what should be returned.
-        Ok(Self(value as u64))
+        match value {
            x if x < 0 => Err(CreationError::Negative),
            0 => Err(CreationError::Zero),
            x => Ok(PositiveNonzeroInteger(x as u64)),
        }
    }
 }
@@ -48,7 +48,7 @@ impl PositiveNonzeroInteger {
 // TODO: Add the correct return type `Result<(), Box<dyn ???>>`. What can we
 // use to describe both errors? Is there a trait which both errors implement?
-fn main() {
+fn main() -> Result<(), Box<dyn Error>> {
    let pretend_user_input = "42";
    let x: i64 = pretend_user_input.parse()?;
    println!("output={:?}", PositiveNonzeroInteger::new(x)?);
@@ -25,7 +25,9 @@ impl ParsePosNonzeroError {
    }
    // TODO: Add another error conversion function here.
-    // fn from_parse_int(???) -> Self { ??? }
+    fn from_parse_int(err: ParseIntError) -> Self {
        Self::ParseInt(err)
    }
 }
 #[derive(PartialEq, Debug)]
@@ -43,7 +45,7 @@ impl PositiveNonzeroInteger {
    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().unwrap();
+        let x: i64 = s.parse().map_err(ParsePosNonzeroError::from_parse_int)?;
        Self::new(x).map_err(ParsePosNonzeroError::from_creation)
    }
 }
@@ -6,7 +6,7 @@ fn main() {
    // TODO: Fix the compiler error by annotating the type of the vector
    // `Vec<T>`. Choose `T` as some integer type that can be created from
    // `u8` and `i8`.
-    let mut numbers = Vec::new();
+    let mut numbers: Vec<i32> = Vec::new();
    // Don't change the lines below.
    let n1: u8 = 42;
@@ -1,12 +1,12 @@
 // This powerful wrapper provides the ability to store a positive integer value.
 // TODO: Rewrite it using a generic so that it supports wrapping ANY type.
-struct Wrapper {
+struct Wrapper<T> {
-    value: u32,
+    value: T,
 }
 // TODO: Adapt the struct's implementation to be generic over the wrapped value.
-impl Wrapper {
+impl<T> Wrapper<T> {
-    fn new(value: u32) -> Self {
+    fn new(value: T) -> Self {
        Wrapper { value }
    }
 }
@@ -6,6 +6,9 @@ trait AppendBar {
 impl AppendBar for String {
    // TODO: Implement `AppendBar` for the type `String`.
    fn append_bar(self) -> String {
        self + "Bar"
    }
 }
 fn main() {
@@ -4,6 +4,12 @@ trait AppendBar {
 // TODO: Implement the trait `AppendBar` for a vector of strings.
 // `append_bar` should push the string "Bar" into the vector.
 impl AppendBar for Vec<String> {
    fn append_bar(mut self) -> Self {
        self.push("Bar".into());
        self
    }
 }
 fn main() {
    // You can optionally experiment here.
@@ -3,7 +3,9 @@ trait Licensed {
    // implementors like the two structs below can share that default behavior
    // without repeating the function.
    // The default license information should be the string "Default license".
-    fn licensing_info(&self) -> String;
+    fn licensing_info(&self) -> String {
        "Default license".into()
    }
 }
 struct SomeSoftware {
@@ -28,10 +30,13 @@ mod tests {
    #[test]
    fn is_licensing_info_the_same() {
        let licensing_info = "Default license";
        let some_software = SomeSoftware { version_number: 1 };
        let other_software = OtherSoftware {
            version_number: "v2.0.0".to_string(),
        };
        assert_eq!(some_software.licensing_info(), licensing_info);
        assert_eq!(other_software.licensing_info(), licensing_info);
    }
@@ -11,7 +11,7 @@ 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: ???, software2: ???) -> bool {
+fn compare_license_types(software1: impl Licensed, software2: impl Licensed) -> bool {
    software1.licensing_info() == software2.licensing_info()
 }
@@ -19,7 +19,7 @@ impl SomeTrait for OtherStruct {}
 impl OtherTrait for OtherStruct {}
 // TODO: Fix the compiler error by only changing the signature of this function.
-fn some_func(item: ???) -> bool {
+fn some_func(item: impl SomeTrait + OtherTrait) -> bool {
    item.some_function() && item.other_function()
 }
@@ -4,12 +4,8 @@
 // not own their own data. What if their owner goes out of scope?
 // TODO: Fix the compiler error by updating the function signature.
-fn longest(x: &str, y: &str) -> &str {
+fn longest<'a>(x: &'a str, y: &'a str) -> &'a str {
-    if x.len() > y.len() {
+    if x.len() > y.len() { x } else { y }
        x
    } else {
        y
    }
 }
 fn main() {
@@ -1,19 +1,15 @@
 // Don't change this function.
 fn longest<'a>(x: &'a str, y: &'a str) -> &'a str {
-    if x.len() > y.len() {
+    if x.len() > y.len() { x } else { y }
        x
    } else {
        y
    }
 }
 fn main() {
    // TODO: Fix the compiler error by moving one line.
    let string1 = String::from("long string is long");
    let string2 = String::from("xyz");
    let result;
    {
        let string2 = String::from("xyz");
        result = longest(&string1, &string2);
    }
    println!("The longest string is '{result}'");
@@ -1,9 +1,9 @@
 // Lifetimes are also needed when structs hold references.
 // TODO: Fix the compiler errors about the struct.
-struct Book {
+struct Book<'a> {
-    author: &str,
+    author: &'a str,
-    title: &str,
+    title: &'a str,
 }
 fn main() {
@@ -13,11 +13,12 @@ fn main() {
 mod tests {
    // TODO: Import `is_even`. You can use a wildcard to import everything in
    // the outer module.
    use super::is_even;
    #[test]
    fn you_can_assert() {
        // TODO: Test the function `is_even` with some values.
-        assert!();
+        assert!(is_even(12));
-        assert!();
+        assert!(!is_even(13));
    }
 }
@@ -15,9 +15,9 @@ mod tests {
    #[test]
    fn you_can_assert_eq() {
        // TODO: Test the function `power_of_2` with some values.
-        assert_eq!();
+        assert_eq!(power_of_2(0), 1);
-        assert_eq!();
+        assert_eq!(power_of_2(1), 2);
-        assert_eq!();
+        assert_eq!(power_of_2(2), 4);
-        assert_eq!();
+        assert_eq!(power_of_2(3), 8);
    }
 }
@@ -29,13 +29,14 @@ mod tests {
        // TODO: This test should check if the rectangle has the size that we
        // pass to its constructor.
        let rect = Rectangle::new(10, 20);
-        assert_eq!(todo!(), 10); // Check width
+        assert_eq!(rect.width, 10); // Check width
-        assert_eq!(todo!(), 20); // Check height
+        assert_eq!(rect.height, 20); // Check height
    }
    // TODO: This test should check if the program panics when we try to create
    // a rectangle with negative width.
    #[test]
    #[should_panic]
    fn negative_width() {
        let _rect = Rectangle::new(-10, 10);
    }
@@ -43,6 +44,7 @@ mod tests {
    // TODO: This test should check if the program panics when we try to create
    // a rectangle with negative height.
    #[test]
    #[should_panic]
    fn negative_height() {
        let _rect = Rectangle::new(10, -10);
    }
@@ -13,13 +13,13 @@ mod tests {
        let my_fav_fruits = ["banana", "custard apple", "avocado", "peach", "raspberry"];
        // TODO: Create an iterator over the array.
-        let mut fav_fruits_iterator = todo!();
+        let mut fav_fruits_iterator = my_fav_fruits.iter();
        assert_eq!(fav_fruits_iterator.next(), Some(&"banana"));
-        assert_eq!(fav_fruits_iterator.next(), todo!()); // TODO: Replace `todo!()`
+        assert_eq!(fav_fruits_iterator.next(), Some(&"custard apple")); // TODO: Replace `todo!()`
        assert_eq!(fav_fruits_iterator.next(), Some(&"avocado"));
-        assert_eq!(fav_fruits_iterator.next(), todo!()); // TODO: Replace `todo!()`
+        assert_eq!(fav_fruits_iterator.next(), Some(&"peach")); // TODO: Replace `todo!()`
        assert_eq!(fav_fruits_iterator.next(), Some(&"raspberry"));
-        assert_eq!(fav_fruits_iterator.next(), todo!()); // TODO: Replace `todo!()`
+        assert_eq!(fav_fruits_iterator.next(), None); // TODO: Replace `todo!()`
    }
 }
@@ -5,9 +5,10 @@
 // "hello" -> "Hello"
 fn capitalize_first(input: &str) -> String {
    let mut chars = input.chars();
    match chars.next() {
        None => String::new(),
-        Some(first) => todo!(),
+        Some(first) => first.to_uppercase().chain(chars).collect(),
    }
 }
@@ -15,14 +16,14 @@ fn capitalize_first(input: &str) -> String {
 // Return a vector of strings.
 // ["hello", "world"] -> ["Hello", "World"]
 fn capitalize_words_vector(words: &[&str]) -> Vec<String> {
-    // ???
+    words.iter().map(|word| capitalize_first(word)).collect()
 }
 // TODO: Apply the `capitalize_first` function again to a slice of string
 // slices. Return a single string.
 // ["hello", " ", "world"] -> "Hello World"
 fn capitalize_words_string(words: &[&str]) -> String {
-    // ???
+    words.iter().map(|word| capitalize_first(word)).collect()
 }
 fn main() {
@@ -11,21 +11,36 @@ enum DivisionError {
 // TODO: Calculate `a` divided by `b` if `a` is evenly divisible by `b`.
 // Otherwise, return a suitable error.
 fn divide(a: i64, b: i64) -> Result<i64, DivisionError> {
-    todo!();
+    match (a, b) {
        (_, 0) => Err(DivisionError::DivideByZero),
        (a, b) if a == i64::MIN && b == -1 => Err(DivisionError::IntegerOverflow),
        (a, b) if a % b != 0 => Err(DivisionError::NotDivisible),
        (a, b) => Ok(a / b),
    }
 }
 // TODO: Add the correct return type and complete the function body.
 // Desired output: `Ok([1, 11, 1426, 3])`
-fn result_with_list() {
+fn result_with_list() -> Result<Vec<i64>, DivisionError> {
    let numbers = [27, 297, 38502, 81];
-    let division_results = numbers.into_iter().map(|n| divide(n, 27));
+    let result: Vec<i64> = numbers
        .into_iter()
        .map(|n| divide(n, 27))
        .collect::<Result<Vec<i64>, DivisionError>>()?;
    Ok(result)
 }
 // TODO: Add the correct return type and complete the function body.
 // Desired output: `[Ok(1), Ok(11), Ok(1426), Ok(3)]`
-fn list_of_results() {
+fn list_of_results() -> Vec<Result<i64, DivisionError>> {
    let numbers = [27, 297, 38502, 81];
-    let division_results = numbers.into_iter().map(|n| divide(n, 27));
+    let division_results: Vec<Result<i64, DivisionError>> = numbers
        .into_iter()
        .map(|n| divide(n, 27))
        .collect::<Vec<Result<i64, DivisionError>>>();
    division_results
 }
 fn main() {
@@ -10,6 +10,7 @@ fn factorial(num: u64) -> u64 {
    // - additional variables
    // For an extra challenge, don't use:
    // - recursion
    (1..=num).fold(1, |acc, e| acc * e)
 }
 fn main() {
@@ -28,6 +28,9 @@ fn count_for(map: &HashMap<String, Progress>, value: Progress) -> usize {
 fn count_iterator(map: &HashMap<String, Progress>, value: Progress) -> usize {
    // `map` is a hash map with `String` keys and `Progress` values.
    // map = { "variables1": Complete, "from_str": None, … }
    map.values()
        .filter(|excercise| **excercise == value)
        .count()
 }
 fn count_collection_for(collection: &[HashMap<String, Progress>], value: Progress) -> usize {
@@ -48,6 +51,11 @@ fn count_collection_iterator(collection: &[HashMap<String, Progress>], value: Pr
    // `collection` is a slice of hash maps.
    // collection = [{ "variables1": Complete, "from_str": None, … },
    //               { "variables2": Complete, … }, … ]
    collection
        .iter()
        .flatten()
        .filter(|excercise| *excercise.1 == value)
        .count()
 }
 fn main() {
@@ -23,13 +23,13 @@ fn main() {
    let numbers: Vec<_> = (0..100u32).collect();
    // TODO: Define `shared_numbers` by using `Arc`.
-    // let shared_numbers = ???;
+    let shared_numbers = Arc::new(numbers);
    let mut join_handles = Vec::new();
    for offset in 0..8 {
        // TODO: Define `child_numbers` using `shared_numbers`.
-        // let child_numbers = ???;
+        let child_numbers = Arc::clone(&shared_numbers);
        let handle = thread::spawn(move || {
            let sum: u32 = child_numbers.iter().filter(|&&n| n % 8 == offset).sum();
@@ -12,18 +12,18 @@
 // TODO: Use a `Box` in the enum definition to make the code compile.
 #[derive(PartialEq, Debug)]
 enum List {
-    Cons(i32, List),
+    Cons(i32, Box<List>),
    Nil,
 }
 // TODO: Create an empty cons list.
 fn create_empty_list() -> List {
-    todo!()
+    List::Nil
 }
 // TODO: Create a non-empty cons list.
 fn create_non_empty_list() -> List {
-    todo!()
+    List::Cons(64, Box::new(List::Nil))
 }
 fn main() {
@@ -39,7 +39,7 @@ mod tests {
        let mut input = Cow::from(&vec);
        abs_all(&mut input);
        // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`.
-        assert!(matches!(input, todo!()));
+        assert!(matches!(input, Cow::Borrowed(_)));
    }
    #[test]
@@ -52,7 +52,7 @@ mod tests {
        let mut input = Cow::from(vec);
        abs_all(&mut input);
        // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`.
-        assert!(matches!(input, todo!()));
+        assert!(matches!(input, Cow::Owned(_)));
    }
    #[test]
@@ -64,6 +64,6 @@ mod tests {
        let mut input = Cow::from(vec);
        abs_all(&mut input);
        // TODO: Replace `todo!()` with `Cow::Owned(_)` or `Cow::Borrowed(_)`.
-        assert!(matches!(input, todo!()));
+        assert!(matches!(input, Cow::Owned(_)));
    }
 }
@@ -60,17 +60,17 @@ mod tests {
        jupiter.details();
        // TODO
-        let saturn = Planet::Saturn(Rc::new(Sun));
+        let saturn = Planet::Saturn(Rc::clone(&sun));
        println!("reference count = {}", Rc::strong_count(&sun)); // 7 references
        saturn.details();
        // TODO
-        let uranus = Planet::Uranus(Rc::new(Sun));
+        let uranus = Planet::Uranus(Rc::clone(&sun));
        println!("reference count = {}", Rc::strong_count(&sun)); // 8 references
        uranus.details();
        // TODO
-        let neptune = Planet::Neptune(Rc::new(Sun));
+        let neptune = Planet::Neptune(Rc::clone(&sun));
        println!("reference count = {}", Rc::strong_count(&sun)); // 9 references
        neptune.details();
@@ -91,13 +91,13 @@ mod tests {
        drop(mars);
        println!("reference count = {}", Rc::strong_count(&sun)); // 4 references
-        // TODO
+        drop(earth);
        println!("reference count = {}", Rc::strong_count(&sun)); // 3 references
-        // TODO
+        drop(venus);
        println!("reference count = {}", Rc::strong_count(&sun)); // 2 references
-        // TODO
+        drop(mercury);
        println!("reference count = {}", Rc::strong_count(&sun)); // 1 reference
        assert_eq!(Rc::strong_count(&sun), 1);
@@ -20,10 +20,12 @@ fn main() {
        handles.push(handle);
    }
-    let mut results = Vec::new();
+    let mut results: Vec<_> = Vec::<_>::new();
    for handle in handles {
        // TODO: Collect the results of all threads into the `results` vector.
        // Use the `JoinHandle` struct which is returned by `thread::spawn`.
        results.push(handle.join().unwrap())
    }
    if results.len() != 10 {
@@ -2,24 +2,31 @@
 // work. But this time, the spawned threads need to be in charge of updating a
 // shared value: `JobStatus.jobs_done`
-use std::{sync::Arc, thread, time::Duration};
+use std::{
    sync::{Arc, Mutex},
    thread,
    time::Duration,
 };
 #[derive(Debug)]
 struct JobStatus {
    jobs_done: u32,
 }
 fn main() {
    // TODO: `Arc` isn't enough if you want a **mutable** shared state.
-    let status = Arc::new(JobStatus { jobs_done: 0 });
+    let status = Arc::new(Mutex::new(JobStatus { jobs_done: 0 }));
    let mut handles = Vec::new();
    for _ in 0..10 {
        let status_shared = Arc::clone(&status);
        let handle = thread::spawn(move || {
            thread::sleep(Duration::from_millis(250));
            // TODO: You must take an action before you update a shared value.
-            status_shared.jobs_done += 1;
+            let mut acquired_status = status_shared.lock().unwrap();
            acquired_status.jobs_done += 1;
        });
        handles.push(handle);
    }
@@ -30,5 +37,7 @@ fn main() {
    }
    // TODO: Print the value of `JobStatus.jobs_done`.
-    println!("Jobs done: {}", todo!());
+    let mutex = Arc::try_unwrap(status).unwrap();
    let job_status = mutex.into_inner().unwrap();
    println!("Jobs done: {}", job_status.jobs_done);
 }
@@ -17,18 +17,23 @@ impl Queue {
 fn send_tx(q: Queue, tx: mpsc::Sender<u32>) {
    // TODO: We want to send `tx` to both threads. But currently, it is moved
    // into the first thread. How could you solve this problem?
    let transmission = tx.clone();
    thread::spawn(move || {
        for val in q.first_half {
            println!("Sending {val:?}");
-            tx.send(val).unwrap();
+            transmission.send(val).unwrap();
            thread::sleep(Duration::from_millis(250));
        }
    });
    let transmission = tx.clone();
    thread::spawn(move || {
        for val in q.second_half {
            println!("Sending {val:?}");
-            tx.send(val).unwrap();
+            transmission.send(val).unwrap();
            thread::sleep(Duration::from_millis(250));
        }
    });
@@ -6,5 +6,5 @@ macro_rules! my_macro {
 fn main() {
    // TODO: Fix the macro call.
-    my_macro();
+    my_macro!();
 }
@@ -1,10 +1,10 @@
 fn main() {
    my_macro!();
 }
 // TODO: Fix the compiler error by moving the whole definition of this macro.
 macro_rules! my_macro {
    () => {
        println!("Check out my macro!");
    };
 }
 fn main() {
    my_macro!();
 }
@@ -1,6 +1,7 @@
 // TODO: Fix the compiler error without taking the macro definition out of this
 // module.
 mod macros {
    #[macro_export]
    macro_rules! my_macro {
        () => {
            println!("Check out my macro!");
@@ -3,7 +3,7 @@
 macro_rules! my_macro {
    () => {
        println!("Check out my macro!");
-    }
+    };
    ($val:expr) => {
        println!("Look at this other macro: {}", $val);
    }
@@ -6,7 +6,7 @@
 fn main() {
    // TODO: Fix the Clippy lint in this line.
-    let pi = 3.14;
+    let pi = std::f32::consts::PI;
    let radius: f32 = 5.0;
    let area = pi * radius.powi(2);
@@ -1,8 +1,9 @@
 fn main() {
    let mut res = 42;
    let option = Some(12);
    // TODO: Fix the Clippy lint.
-    for x in option {
+    if let Some(x) = option {
        res += x;
    }
@@ -7,23 +7,23 @@ fn main() {
    let my_option: Option<&str> = None;
    // Assume that you don't know the value of `my_option`.
    // In the case of `Some`, we want to print its value.
-    if my_option.is_none() {
+    if let Some(my_option) = my_option {
-        println!("{}", my_option.unwrap());
+        println!("{}", my_option);
    }
    let my_arr = &[
-        -1, -2, -3
+        -1, -2, -3,
        -4, -5, -6
    ];
    println!("My array! Here it is: {my_arr:?}");
-    let my_empty_vec = vec![1, 2, 3, 4, 5].resize(0, 5);
+    let my_empty_vec = ();
    vec![1, 2, 3, 4, 5].resize(0, 5);
    println!("This Vec is empty, see? {my_empty_vec:?}");
    let mut value_a = 45;
    let mut value_b = 66;
    // Let's swap these two!
-    value_a = value_b;
+    std::mem::swap(&mut value_a, &mut value_b);
    value_b = value_a;
    println!("value a: {value_a}; value b: {value_b}");
 }
@@ -5,20 +5,22 @@
 // Obtain the number of bytes (not characters) in the given argument
 // (`.len()` returns the number of bytes in a string).
 // TODO: Add the `AsRef` trait appropriately as a trait bound.
-fn byte_counter<T>(arg: T) -> usize {
+fn byte_counter<T: AsRef<str>>(arg: T) -> usize {
    arg.as_ref().len()
 }
 // Obtain the number of characters (not bytes) in the given argument.
 // TODO: Add the `AsRef` trait appropriately as a trait bound.
-fn char_counter<T>(arg: T) -> usize {
+fn char_counter<T: AsRef<str>>(arg: T) -> usize {
    arg.as_ref().chars().count()
 }
 // Squares a number using `as_mut()`.
 // TODO: Add the appropriate trait bound.
-fn num_sq<T>(arg: &mut T) {
+fn num_sq<T: AsMut<u32>>(arg: &mut T) {
    // TODO: Implement the function body.
    let val = *arg.as_mut();
    *arg.as_mut() = val * val;
 }
 fn main() {
@@ -34,7 +34,18 @@ impl Default for Person {
 // 5. Parse the second element from the split operation into a `u8` as the age.
 // 6. If parsing the age fails, return the default of `Person`.
 impl From<&str> for Person {
-    fn from(s: &str) -> Self {}
+    fn from(s: &str) -> Self {
        match s.split(",").collect::<Vec<&str>>().as_slice() {
            [name, age] if (!name.is_empty() && !age.is_empty()) => match age.parse::<u8>() {
                Ok(age) => Person {
                    name: name.to_string(),
                    age,
                },
                Err(_) => Person::default(),
            },
            _ => Person::default(),
        }
    }
 }
 fn main() {
@@ -41,7 +41,19 @@ enum ParsePersonError {
 impl FromStr for Person {
    type Err = ParsePersonError;
-    fn from_str(s: &str) -> Result<Self, Self::Err> {}
+    fn from_str(s: &str) -> Result<Self, Self::Err> {
        match s.split(",").collect::<Vec<&str>>().as_slice() {
            [name, age] if (!name.is_empty()) => match age.parse::<u8>() {
                Ok(age) => Ok(Person {
                    name: name.to_string(),
                    age,
                }),
                Err(err) => Err(ParsePersonError::ParseInt(err)),
            },
            ["", _] => Err(ParsePersonError::NoName),
            _ => Err(ParsePersonError::BadLen),
        }
    }
 }
 fn main() {
@@ -28,14 +28,45 @@ enum IntoColorError {
 impl TryFrom<(i16, i16, i16)> for Color {
    type Error = IntoColorError;
-    fn try_from(tuple: (i16, i16, i16)) -> Result<Self, Self::Error> {}
+    fn try_from(tuple: (i16, i16, i16)) -> Result<Self, Self::Error> {
        match tuple {
            (red, green, blue)
                if (0..=255).contains(&red)
                    && (0..=255).contains(&green)
                    && (0..=255).contains(&blue) =>
            {
                Ok(Color {
                    red: red as u8,
                    green: green as u8,
                    blue: blue as u8,
                })
            }
            _ => Err(IntoColorError::IntConversion),
        }
    }
 }
 // TODO: Array implementation.
 impl TryFrom<[i16; 3]> for Color {
    type Error = IntoColorError;
-    fn try_from(arr: [i16; 3]) -> Result<Self, Self::Error> {}
+    fn try_from(arr: [i16; 3]) -> Result<Self, Self::Error> {
        match arr.as_slice() {
            [red, green, blue] => {
                if (0..=255).contains(red) && (0..=255).contains(green) && (0..=255).contains(blue)
                {
                    Ok(Color {
                        red: *red as u8,
                        green: *green as u8,
                        blue: *blue as u8,
                    })
                } else {
                    Err(IntoColorError::IntConversion)
                }
            }
            _ => Err(IntoColorError::BadLen),
        }
    }
 }
 // TODO: Slice implementation.
@@ -43,7 +74,23 @@ impl TryFrom<[i16; 3]> for Color {
 impl TryFrom<&[i16]> for Color {
    type Error = IntoColorError;
-    fn try_from(slice: &[i16]) -> Result<Self, Self::Error> {}
+    fn try_from(slice: &[i16]) -> Result<Self, Self::Error> {
        match slice {
            [red, green, blue] => {
                if (0..=255).contains(red) && (0..=255).contains(green) && (0..=255).contains(blue)
                {
                    Ok(Color {
                        red: *red as u8,
                        green: *green as u8,
                        blue: *blue as u8,
                    })
                } else {
                    Err(IntoColorError::IntConversion)
                }
            }
            _ => Err(IntoColorError::BadLen),
        }
    }
 }
 fn main() {
@@ -5,7 +5,7 @@
 fn average(values: &[f64]) -> f64 {
    let total = values.iter().sum::<f64>();
    // TODO: Make a conversion before dividing.
-    total / values.len()
+    total / values.len() as f64
 }
 fn main() {
@@ -27,7 +27,21 @@ mod my_module {
    use super::Command;
    // TODO: Complete the function as described above.
-    // pub fn transformer(input: ???) -> ??? { ??? }
+    pub fn transformer(input: Vec<(String, Command)>) -> Vec<String> {
        let mut output: Vec<String> = Vec::new();
        for (string, command) in input {
            match command {
                Command::Uppercase => output.push(string.to_uppercase()),
                Command::Trim => output.push(string.trim().into()),
                Command::Append(number_of_times_bar_will_be_added) => {
                    output.push(string + &"bar".repeat(number_of_times_bar_will_be_added))
                }
            }
        }
        output
    }
 }
 fn main() {
@@ -37,8 +51,8 @@ fn main() {
 #[cfg(test)]
 mod tests {
    // TODO: What do we need to import to have `transformer` in scope?
    // use ???;
    use super::Command;
    use super::my_module::transformer;
    #[test]
    fn it_works() {
@@ -10,16 +10,17 @@
 //
 // Make the necessary code changes in the struct `ReportCard` and the impl
 // block to support alphabetical report cards in addition to numerical ones.
 use std::fmt::Display;
 // TODO: Adjust the struct as described above.
-struct ReportCard {
+struct ReportCard<G: Display> {
-    grade: f32,
+    grade: G,
    student_name: String,
    student_age: u8,
 }
 // TODO: Adjust the impl block as described above.
-impl ReportCard {
+impl<G: Display> ReportCard<G> {
    fn print(&self) -> String {
        format!(
            "{} ({}) - achieved a grade of {}",