1 // Rust-101, Part 07: Operator Overloading, Tests, Output
2 // ======================================================
4 pub use part05::BigInt;
6 // With our new knowledge of lifetimes, we are now able to write down the desired type
7 // of `min`: We want the function to take two borrows *of the same lifetime*, and then
8 // return a borrow of that lifetime. If the two input lifetimes would be different, we
9 // would not know which lifetime to use for the result.
11 fn min<'a>(&'a self, other: &'a Self) -> &'a Self;
14 // Now we can implement a generic function `vec_min` that works on above trait.
15 // The code is pretty much straight-forward, and Rust checks that all the
16 // lifetimes actually work out.
17 pub fn vec_min<T: Minimum>(v: &Vec<T>) -> Option<&T> {
18 let mut min: Option<&T> = None;
20 min = Some(match min {
27 // Notice that the return type `Option<&T>` is technically (leaving the borrowing story aside) a
28 // pointer to a `T`, that could optionally be invalid. In other words, it's just like a pointer in
29 // C(++) or Java that can be `NULL`! However, thanks to `Option` being an `enum`, we cannot forget
30 // to check the pointer for validity, avoiding the safety issues of C(++). At the same time, when we
31 // have a borrow like `v` above that's not an `Option`, we *know* that is has to be a valid
32 // pointer, so we don't even need to do the `NULL`-check that Java does all the time.<br/>
33 // Also, if you are worried about wasting space, notice that Rust knows that `&T` can never be
34 // `NULL`, and hence optimizes `Option<&T>` to be no larger than `&T`. The `None` case is represented
35 // as `NULL`. This is another great example of a zero-cost abstraction: `Option<&T>` is exactly like
36 // a pointer in C(++), if you look at what happens during execution - but it's much safer to use.
38 // For our `vec_min` to be usable with `BigInt`, we need to provide an implementation of
39 // `Minimum`. You should be able to pretty much copy the code you wrote for exercise 06.1.
40 impl Minimum for BigInt {
41 fn min<'a>(&'a self, other: &'a Self) -> &'a Self {
46 // ## Operator Overloading
47 // How can we know that our `min` function actually does what we want it to do? One possibility
48 // here is to do *testing*. Rust comes with nice build-in support for both unit tests and integration
49 // tests. However, before we go there, we need to have a way of checking whether the results of function calls are
50 // correct. In other words, we need to define how to test equality of `BigInt`. Being able to
51 // test equality is a property of a type, that - you guessed it - Rust expresses as a trait: `PartialEq`.
53 // Doing this for `BigInt` is fairly easy, thanks to our requirement that there be no trailing zeros.
54 // The `inline` attribute tells Rust that we will typically want this function to be inlined.
55 impl PartialEq for BigInt {
57 fn eq(&self, other: &BigInt) -> bool {
58 debug_assert!(self.test_invariant() && other.test_invariant());
59 self.data == other.data
62 // Since implementing `PartialEq` is a fairly mechanical business, you can let Rust automate this
63 // by adding the attribute `derive(PartialEq)` to the type definition. In case you wonder about
64 // the "partial", I suggest you check out the documentation of [`PartialEq`](http://doc.rust-lang.org/std/cmp/trait.PartialEq.html)
65 // and [`Eq`](http://doc.rust-lang.org/std/cmp/trait.Eq.html). `Eq` can be automatically derived as well.
67 // Now we can compare `BigInt`s using `==`! Speaking in C++ terms, we just overloaded the `==` operator
68 // for `BigInt`. Rust does not have function overloading (i.e., it will not dispatch to different
69 // functions depending on the type of the argument). Instead, one typically finds (or defines) a
70 // trait that catches the core characteristic common to all the overloads, and writes a single
71 // function that's generic in the trait. For example, instead of overloading a function for all
72 // the ways a string can be represented, one writes a generic functions over [ToString](http://doc.rust-lang.org/std/string/trait.ToString.html).
73 // Usually, there is a trait like this that fits the purpose - and if there is, this has the great
74 // advantage that any type *you* write, that can convert to a string, just has to implement
75 // that trait to be immediately usable with all the functions out there that generalize over `ToString`.
76 // Compare that to C++ or Java, where the only chance to add a new overloading variant is to
77 // edit the class of the receiver.
78 fn compare_big_ints() {
79 let b1 = BigInt::new(13);
80 let b2 = BigInt::new(37);
81 println!("b1 == b1: {} ; b1 == b2: {}; b1 != b2: {}", b1 == b1, b1 == b2, b1 != b2);
85 // With our equality test written, we are now ready to write our first testcase. It doesn't get much
86 // simpler: You just write a function (with no arguments or return value), and give it the `test` attribute.
87 // `assert!` is like `debug_assert!`, but does not get compiled away in a release build.
90 let b1 = BigInt::new(1);
91 let b2 = BigInt::new(42);
92 let b3 = BigInt::from_vec(vec![0, 1]);
94 assert!(*b1.min(&b2) == b1);
95 assert!(*b3.min(&b2) == b2);
97 // Now run `cargo test` to execute the test. If you implemented `min` correctly, it should all work!
100 // There is also a macro `assert_eq!` that's specialized to test for equality, and that prints the two
101 // values (left and right) if they differ. To be able to do that, the macro needs to know how to format
102 // the value for printing. This means that we - guess what? - have to implement an appropriate trait.
103 // Rust knows about two ways of formatting a value: `Display` is for pretty-printing something in a way
104 // that users can understand, while `Debug` is meant to show the internal state of data and targeted at
105 // the programmer. The latter is what we want for `assert_eq!`, so let's get started.
107 // All formating is handled by [`std::fmt`](http://doc.rust-lang.org/std/fmt/index.html). I won't explain
108 // all the details, and refer you to the documentation instead.
111 // In the case of `BigInt`, we'd like to just output our internal `data` array, so we
112 // simply call the formating function of `Vec<u64>`.
113 impl fmt::Debug for BigInt {
114 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
118 // `Debug` implementations can be automatically generated using the `derive(Debug)` attribute.
120 // Now we are ready to use `assert_eq!` to test `vec_min`.
123 let b1 = BigInt::new(1);
124 let b2 = BigInt::new(42);
125 let b3 = BigInt::from_vec(vec![0, 1]);
127 let v1 = vec![b2.clone(), b1.clone(), b3.clone()];
128 let v2 = vec![b2.clone(), b3.clone()];
129 assert_eq!(vec_min(&v1), Some(&b1));
130 assert_eq!(vec_min(&v2), Some(&b2));
133 // **Exercise 07.1**: Add some more testcases. In particular, make sure you test the behavior of
134 // `vec_min` on an empty vector. Also add tests for `BigInt::from_vec` (in particular, removing
135 // trailing zeros). Finally, break one of your functions in a subtle way and watch the test fail.
137 // **Exercise 07.2**: Go back to your good ol' `SomethingOrNothing`, and implement `Display` for it. (This will,
138 // of course, need a `Display` bound on `T`.) Then you should be able to use them with `println!` just like you do with numbers.
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