data: T,
}
// A node pointer is a *mutable raw pointer* to a node.
-//@ Raw pointers (`*mut T` and `*const T`) are the Rust equivalent of pointers in C. Unlike borrows, they do not come with
+//@ Raw pointers (`*mut T` and `*const T`) are the Rust equivalent of pointers in C. Unlike references, they do not come with
//@ any guarantees: Raw pointers can be null, or they can point to garbage. They don't have a lifetime, either.
type NodePtr<T> = *mut Node<T>;
//@ Clearly, that's an unsafe operation and must only be used with great care - or even better, not at all. Seriously.
//@ If at all possible, you should never use `transmute`. <br/>
//@ We are making the assumption here that a `Box` and a raw pointer have the same representation in memory. In the future,
-//@ Rust will [provide](http://doc.rust-lang.org/beta/alloc/boxed/struct.Box.html#method.from_raw) such [operations](http://doc.rust-lang.org/beta/alloc/boxed/struct.Box.html#method.into_raw) in the standard library, but the exact API is still being fleshed out.
+//@ Rust will [provide](https://doc.rust-lang.org/beta/alloc/boxed/struct.Box.html#method.from_raw) such [operations](https://doc.rust-lang.org/beta/alloc/boxed/struct.Box.html#method.into_raw) in the standard library, but the exact API is still being fleshed out.
//@ We declare `raw_into_box` to be an `unsafe` function, telling Rust that calling this function is not generally safe.
//@ This grants us the unsafe powers for the body of the function: We can dereference raw pointers, and - most importantly - we
//@ Calling `box_into_raw` gives up ownership of the box, which is crucial: We don't want the memory that it points to to be deallocated!
let new = Box::new( Node { data: t, next: ptr::null_mut(), prev: self.last } );
let new = box_into_raw(new);
- // Update other points to this node.
+ // Update other pointers to this node.
if self.last.is_null() {
debug_assert!(self.first.is_null());
// The list is currently empty, so we have to update the head pointer.
// Next, we are going to provide an iterator.
//@ This function just creates an instance of `IterMut`, the iterator type which does the actual work.
- pub fn iter_mut(&self) -> IterMut<T> {
+ pub fn iter_mut(&mut self) -> IterMut<T> {
IterMut { next: self.first, _marker: PhantomData }
}
}
//@ that it is going to visit. However, how do we make sure that this pointer remains valid? We have to
//@ get this right ourselves, as we left the safe realms of borrowing and ownership. Remember that the
//@ key ingredient for iterator safety was to tie the lifetime of the iterator to the lifetime of the
-//@ borrow used for `iter_mut`. We will thus give `IterMut` two parameters: A type parameter specifying
+//@ reference used for `iter_mut`. We will thus give `IterMut` two parameters: A type parameter specifying
//@ the type of the data, and a lifetime parameter specifying for how long the list was borrowed to the
//@ iterator.
//@ the data in the list lives at least as long as the iterator: If you drop the `T: 'a`, Rust will tell
//@ you to add it back. And secondly, Rust will complain if `'a` is not actually used in the struct.
//@ It doesn't know what it is supposed to do with that lifetime. So we use `PhantomData` again to tell
-//@ it that in terms of ownership, this type actually (mutably) borrows a linked list. This has no
+//@ it that in terms of ownership, this type actually (uniquely) borrows a linked list. This has no
//@ operational effect, but it means that Rust can deduce the intent we had when adding that
//@ seemingly useless lifetime parameter.
pub struct IterMut<'a, T> where T: 'a {
if self.next.is_null() {
None
} else {
- // Otherwise, we can convert the next pointer to a borrow, get a borrow to the data
+ // Otherwise, we can convert the next pointer to a reference, get a reference to the data
// and update the iterator.
let next = unsafe { &mut *self.next };
let ret = &mut next.data;
//@ In `next` above, we made crucial use of the assumption that `self.next` is either null or a valid pointer.
//@ This only works because if someone tries to delete elements from a list during iteration, we know that the borrow checker
//@ will catch them: If they call `next`, the lifetime `'a` we artificially added to the iterator has to still be
-//@ active, which means the mutable borrow passed to `iter_mut` is still active, which means nobody can delete
+//@ active, which means the mutable reference passed to `iter_mut` is still active, which means nobody can delete
//@ anything from the list. In other words, we make use of the expressive type system of Rust, decorating
//@ our own unsafe implementation with just enough information so that Rust can check *uses* of the linked-list.
//@ If the type system were weaker, we could not write a linked-list like the above with a safe interface!
-// **Exercise 16.2**: Add a method `iter` and a type `Iter` providing iteration for shared borrows.
+// **Exercise 16.2**: Add a method `iter` and a type `Iter` providing iteration for shared references.
// Add testcases for both kinds of iterators.
// ## `Drop`
//@ of `LinkedList`.
impl<T> Drop for LinkedList<T> {
// The destructor itself is a method which takes `self` in mutably borrowed form. It cannot own `self`, because then
- // the destructor of `self` would be called at the end pf the function, resulting in endless recursion...
+ // the destructor of `self` would be called at the end of the function, resulting in endless recursion.
fn drop(&mut self) {
let mut cur_ptr = self.first;
while !cur_ptr.is_null() {
//@ extensions here and there. The [index](main.html) contains some more links to additional resources you may find useful.
//@ With that, there's only one thing left to say: Happy Rust Hacking!
-//@ [index](main.html) | [previous](part15.html) | next
+//@ [index](main.html) | [previous](part15.html) | [raw source](workspace/src/part16.rs) | next