---

yaml
---
r: 210679
b: refs/heads/try
c: fe8a4e3
h: refs/heads/master
i:
  210677: db712b8
  210675: 14c14da
  210671: d97dfb7
v: v3

Author: steveklabnik

[refs]

@@ -2,7 +2,7 @@
 refs/heads/master: 3e561f05c00cd180ec02db4ccab2840a4aba93d2
 refs/heads/snap-stage1: e33de59e47c5076a89eadeb38f4934f58a3618a6
 refs/heads/snap-stage3: ba0e1cd8147d452c356aacb29fb87568ca26f111
-refs/heads/try: 9a3e98be1c20781e566d12d14940c8dd3d237b15
+refs/heads/try: fe8a4e3dbf71037ab5b8e1edd89b29d423287646
 refs/tags/release-0.1: 1f5c5126e96c79d22cb7862f75304136e204f105
 refs/heads/dist-snap: ba4081a5a8573875fed17545846f6f6902c8ba8d
 refs/tags/release-0.2: c870d2dffb391e14efb05aa27898f1f6333a9596

branches/try/src/doc/index.md

@@ -5,15 +5,14 @@ to jump to any particular section.
 
 # Getting Started
 
-If you haven't seen Rust at all yet, the first thing you should read is the [30
-minute intro](intro.html). It will give you an overview of the basic ideas of Rust
-at a high level.
+If you haven't seen Rust at all yet, the first thing you should read is the
+introduction to [The Rust Programming Language](book/index.html). It'll give
+you a good idea of what Rust is like.
 
-Once you know you really want to learn Rust, the next step is reading [The
-Rust Programming Language](book/index.html). It is a lengthy explanation of
-Rust, its syntax, and its concepts. Upon completing the book, you'll be an
-intermediate Rust developer, and will have a good grasp of the fundamental
-ideas behind Rust.
+The book provides a lengthy explanation of Rust, its syntax, and its
+concepts. Upon completing the book, you'll be an intermediate Rust
+developer, and will have a good grasp of the fundamental ideas behind
+Rust.
 
 [Rust By Example][rbe] was originally a community resource, but was then
 donated to the Rust project. As the name implies, it teaches you Rust through a
@@ -24,7 +23,7 @@ series of small examples.
 # Community & Getting Help
 
 If you need help with something, or just want to talk about Rust with others,
-there's a few places you can do that:
+there are a few places you can do that:
 
 The Rust IRC channels on [irc.mozilla.org](http://irc.mozilla.org/) are the
 fastest way to get help.
@@ -59,7 +58,7 @@ the language in as much detail as possible is in [the reference](reference.html)
 
 # Tools
 
-Rust's still a young language, so there isn't a ton of tooling yet, but the
+Rust is still a young language, so there isn't a ton of tooling yet, but the
 tools we have are really nice.
 
 [Cargo](http://crates.io) is Rust's package manager, and its website contains
@@ -69,16 +68,21 @@ lots of good documentation.
 
 # FAQs
 
-There are questions that are asked quite often, and so we've made FAQs for them:
+There are questions that are asked quite often, so we've made FAQs for them:
 
 * [Language Design FAQ](complement-design-faq.html)
 * [Language FAQ](complement-lang-faq.html)
 * [Project FAQ](complement-project-faq.html)
 * [How to submit a bug report](https://github.com/rust-lang/rust/blob/master/CONTRIBUTING.md#bug-reports)
 
-# The standard library
+# The Standard Library
 
 We have [API documentation for the entire standard
 library](std/index.html). There's a list of crates on the left with more
 specific sections, or you can use the search bar at the top to search for
 something if you know its name.
+
+# The Error Index
+
+If you encounter an error while compiling your code you may be able to look it
+up in the [Rust Compiler Error Index](error-index.html).

branches/try/src/doc/reference.md

@@ -15,6 +15,7 @@
     * [Concurrency](concurrency.md)
     * [Error Handling](error-handling.md)
     * [FFI](ffi.md)
+    * [Borrow and AsRef](borrow-and-asref.md)
 * [Syntax and Semantics](syntax-and-semantics.md)
     * [Variable Bindings](variable-bindings.md)
     * [Functions](functions.md)

branches/try/src/doc/trpl/SUMMARY.md

@@ -0,0 +1,93 @@
+% Borrow and AsRef
+
+The [`Borrow`][borrow] and [`AsRef`][asref] traits are very similar, but
+different. Here’s a quick refresher on what these two traits mean.
+
+[borrow]: ../std/borrow/trait.Borrow.html
+[asref]: ../std/convert/trait.AsRef.html
+
+# Borrow
+
+The `Borrow` trait is used when you’re writing a datastructure, and you want to
+use either an owned or borrowed type as synonymous for some purpose.
+
+For example, [`HashMap`][hashmap] has a [`get` method][get] which uses `Borrow`:
+
+```rust,ignore
+fn get<Q: ?Sized>(&self, k: &Q) -> Option<&V>
+    where K: Borrow<Q>,
+          Q: Hash + Eq
+```
+
+[hashmap]: ../std/collections/struct.HashMap.html
+[get]: ../std/collections/struct.HashMap.html#method.get
+
+This signature is pretty complicated. The `K` parameter is what we’re interested
+in here. It refers to a parameter of the `HashMap` itself:
+
+```rust,ignore
+struct HashMap<K, V, S = RandomState> {
+```
+
+The `K` parameter is the type of _key_ the `HashMap` uses. So, looking at
+the signature of `get()` again, we can use `get()` when the key implements
+`Borrow<Q>`. That way, we can make a `HashMap` which uses `String` keys,
+but use `&str`s when we’re searching:
+
+```rust
+use std::collections::HashMap;
+
+let mut map = HashMap::new();
+map.insert("Foo".to_string(), 42);
+
+assert_eq!(map.get("Foo"), Some(&42));
+```
+
+This is because the standard library has `impl Borrow<str> for String`.
+
+For most types, when you want to take an owned or borrowed type, a `&T` is
+enough. But one area where `Borrow` is effective is when there’s more than one
+kind of borrowed value. Slices are an area where this is especially true: you
+can have both an `&[T]` or a `&mut [T]`. If we wanted to accept both of these
+types, `Borrow` is up for it:
+
+```
+use std::borrow::Borrow;
+use std::fmt::Display;
+
+fn foo<T: Borrow<i32> + Display>(a: T) {
+    println!("a is borrowed: {}", a);
+}
+
+let mut i = 5;
+
+foo(&i);
+foo(&mut i);
+```
+
+This will print out `a is borrowed: 5` twice.
+
+# AsRef
+
+The `AsRef` trait is a conversion trait. It’s used for converting some value to
+a reference in generic code. Like this:
+
+```rust
+let s = "Hello".to_string();
+
+fn foo<T: AsRef<str>>(s: T) {
+    let slice = s.as_ref();
+}
+```
+
+# Which should I use?
+
+We can see how they’re kind of the same: they both deal with owned and borrowed
+versions of some type. However, they’re a bit different.
+
+Choose `Borrow` when you want to abstract over different kinds of borrowing, or
+when you’re building a datastructure that treats owned and borrowed values in
+equivalent ways, such as hashing and comparison.
+
+Choose `AsRef` when you want to convert something to a reference directly, and
+you’re writing generic code.

branches/try/src/doc/trpl/borrow-and-asref.md

@@ -176,7 +176,7 @@ for a full example, the core of which is reproduced here:
 
 ```ignore
 declare_lint!(TEST_LINT, Warn,
-              "Warn about items named 'lintme'")
+              "Warn about items named 'lintme'");
 
 struct Pass;
 

branches/try/src/doc/trpl/compiler-plugins.md

@@ -5,7 +5,7 @@ Rust’s most unique and compelling features, with which Rust developers should
 become quite acquainted. Ownership is how Rust achieves its largest goal,
 memory safety. There are a few distinct concepts, each with its own chapter:
 
-* [ownership][ownership], ownership, the key concept
+* [ownership][ownership], the key concept
 * [borrowing][borrowing], and their associated feature ‘references’
 * lifetimes, which you’re reading now
 

branches/try/src/doc/trpl/lifetimes.md

@@ -127,12 +127,12 @@ fn grow(&self) -> Circle {
 We just say we’re returning a `Circle`. With this method, we can grow a new
 circle to any arbitrary size.
 
-# Static methods
+# Associated functions
 
-You can also define static methods that do not take a `self` parameter. Here’s a
-pattern that’s very common in Rust code:
+You can also define associated functions that do not take a `self` parameter.
+Here’s a pattern that’s very common in Rust code:
 
-```
+```rust
 struct Circle {
     x: f64,
     y: f64,

branches/try/src/doc/trpl/method-syntax.md

@@ -6,7 +6,7 @@ become quite acquainted. Ownership is how Rust achieves its largest goal,
 memory safety. There are a few distinct concepts, each with its own
 chapter:
 
-* ownership, which you’re reading now.
+* ownership, which you’re reading now
 * [borrowing][borrowing], and their associated feature ‘references’
 * [lifetimes][lifetimes], an advanced concept of borrowing
 
@@ -23,7 +23,7 @@ Before we get to the details, two important notes about the ownership system.
 Rust has a focus on safety and speed. It accomplishes these goals through many
 ‘zero-cost abstractions’, which means that in Rust, abstractions cost as little
 as possible in order to make them work. The ownership system is a prime example
-of a zero cost abstraction. All of the analysis we’ll talk about in this guide
+of a zero-cost abstraction. All of the analysis we’ll talk about in this guide
 is _done at compile time_. You do not pay any run-time cost for any of these
 features.
 
@@ -41,7 +41,7 @@ With that in mind, let’s learn about ownership.
 
 # Ownership
 
-[`Variable bindings`][bindings] have a property in Rust: they ‘have ownership’
+[Variable bindings][bindings] have a property in Rust: they ‘have ownership’
 of what they’re bound to. This means that when a binding goes out of scope, the
 resource that they’re bound to are freed. For example:
 
@@ -106,8 +106,8 @@ take(v);
 println!("v[0] is: {}", v[0]);
 ```
 
-Same error: “use of moved value.” When we transfer ownership to something else,
-we say that we’ve ‘moved’ the thing we refer to. You don’t need some sort of
+Same error: ‘use of moved value’. When we transfer ownership to something else,
+we say that we’ve ‘moved’ the thing we refer to. You don’t need any sort of
 special annotation here, it’s the default thing that Rust does.
 
 ## The details
@@ -121,19 +121,19 @@ let v = vec![1, 2, 3];
 let v2 = v;
 ```
 
-The first line creates some data for the vector on the [stack][sh], `v`. The
-vector’s data, however, is stored on the [heap][sh], and so it contains a
-pointer to that data. When we move `v` to `v2`, it creates a copy of that pointer,
-for `v2`. Which would mean two pointers to the contents of the vector on the
-heap. That would be a problem: it would violate Rust’s safety guarantees by
-introducing a data race. Therefore, Rust forbids using `v` after we’ve done the
-move.
+The first line allocates memory for the vector object, `v`, and for the data it
+contains. The vector object is stored on the [stack][sh] and contains a pointer
+to the content (`[1, 2, 3]`) stored on the [heap][sh]. When we move `v` to `v2`,
+it creates a copy of that pointer, for `v2`. Which means that there would be two
+pointers to the content of the vector on the heap. It would violate Rust’s
+safety guarantees by introducing a data race. Therefore, Rust forbids using `v`
+after we’ve done the move.
 
 [sh]: the-stack-and-the-heap.html
 
 It’s also important to note that optimizations may remove the actual copy of
-the bytes, depending on circumstances. So it may not be as inefficient as it
-initially seems.
+the bytes on the stack, depending on circumstances. So it may not be as
+inefficient as it initially seems.
 
 ## `Copy` types
 

branches/try/src/doc/trpl/ownership.md

@@ -15,7 +15,7 @@ let x = true;
 let y: bool = false;
 ```
 
-A common use of booleans is in [`if` statements][if].
+A common use of booleans is in [`if` conditionals][if].
 
 [if]: if.html