arm/usr/lib/rustlib/src/rust/library/std/src/collections/mod.rs - manifest_repos/toolchain - Git at Google

 //! Collection types.
 //!
 //! Rust's standard collection library provides efficient implementations of the
 //! most common general purpose programming data structures. By using the
 //! standard implementations, it should be possible for two libraries to
 //! communicate without significant data conversion.
 //!
 //! To get this out of the way: you should probably just use [`Vec`] or [`HashMap`].
 //! These two collections cover most use cases for generic data storage and
 //! processing. They are exceptionally good at doing what they do. All the other
 //! collections in the standard library have specific use cases where they are
 //! the optimal choice, but these cases are borderline *niche* in comparison.
 //! Even when `Vec` and `HashMap` are technically suboptimal, they're probably a
 //! good enough choice to get started.
 //!
 //! Rust's collections can be grouped into four major categories:
 //!
 //! * Sequences: [`Vec`], [`VecDeque`], [`LinkedList`]
 //! * Maps: [`HashMap`], [`BTreeMap`]
 //! * Sets: [`HashSet`], [`BTreeSet`]
 //! * Misc: [`BinaryHeap`]
 //!
 //! # When Should You Use Which Collection?
 //!
 //! These are fairly high-level and quick break-downs of when each collection
 //! should be considered. Detailed discussions of strengths and weaknesses of
 //! individual collections can be found on their own documentation pages.
 //!
 //! ### Use a `Vec` when:
 //! * You want to collect items up to be processed or sent elsewhere later, and
 //!   don't care about any properties of the actual values being stored.
 //! * You want a sequence of elements in a particular order, and will only be
 //!   appending to (or near) the end.
 //! * You want a stack.
 //! * You want a resizable array.
 //! * You want a heap-allocated array.
 //!
 //! ### Use a `VecDeque` when:
 //! * You want a [`Vec`] that supports efficient insertion at both ends of the
 //!   sequence.
 //! * You want a queue.
 //! * You want a double-ended queue (deque).
 //!
 //! ### Use a `LinkedList` when:
 //! * You want a [`Vec`] or [`VecDeque`] of unknown size, and can't tolerate
 //!   amortization.
 //! * You want to efficiently split and append lists.
 //! * You are *absolutely* certain you *really*, *truly*, want a doubly linked
 //!   list.
 //!
 //! ### Use a `HashMap` when:
 //! * You want to associate arbitrary keys with an arbitrary value.
 //! * You want a cache.
 //! * You want a map, with no extra functionality.
 //!
 //! ### Use a `BTreeMap` when:
 //! * You want a map sorted by its keys.
 //! * You want to be able to get a range of entries on-demand.
 //! * You're interested in what the smallest or largest key-value pair is.
 //! * You want to find the largest or smallest key that is smaller or larger
 //!   than something.
 //!
 //! ### Use the `Set` variant of any of these `Map`s when:
 //! * You just want to remember which keys you've seen.
 //! * There is no meaningful value to associate with your keys.
 //! * You just want a set.
 //!
 //! ### Use a `BinaryHeap` when:
 //!
 //! * You want to store a bunch of elements, but only ever want to process the
 //!   "biggest" or "most important" one at any given time.
 //! * You want a priority queue.
 //!
 //! # Performance
 //!
 //! Choosing the right collection for the job requires an understanding of what
 //! each collection is good at. Here we briefly summarize the performance of
 //! different collections for certain important operations. For further details,
 //! see each type's documentation, and note that the names of actual methods may
 //! differ from the tables below on certain collections.
 //!
 //! Throughout the documentation, we will follow a few conventions. For all
 //! operations, the collection's size is denoted by n. If another collection is
 //! involved in the operation, it contains m elements. Operations which have an
 //! *amortized* cost are suffixed with a `*`. Operations with an *expected*
 //! cost are suffixed with a `~`.
 //!
 //! All amortized costs are for the potential need to resize when capacity is
 //! exhausted. If a resize occurs it will take *O*(*n*) time. Our collections never
 //! automatically shrink, so removal operations aren't amortized. Over a
 //! sufficiently large series of operations, the average cost per operation will
 //! deterministically equal the given cost.
 //!
 //! Only [`HashMap`] has expected costs, due to the probabilistic nature of hashing.
 //! It is theoretically possible, though very unlikely, for [`HashMap`] to
 //! experience worse performance.
 //!
 //! ## Sequences
 //!
 //! |                | get(i)                 | insert(i)               | remove(i)              | append    | split_off(i)           |
 //! |----------------|------------------------|-------------------------|------------------------|-----------|------------------------|
 //! | [`Vec`]        | *O*(1)                 | *O*(*n*-*i*)*           | *O*(*n*-*i*)           | *O*(*m*)* | *O*(*n*-*i*)           |
 //! | [`VecDeque`]   | *O*(1)                 | *O*(min(*i*, *n*-*i*))* | *O*(min(*i*, *n*-*i*)) | *O*(*m*)* | *O*(min(*i*, *n*-*i*)) |
 //! | [`LinkedList`] | *O*(min(*i*, *n*-*i*)) | *O*(min(*i*, *n*-*i*))  | *O*(min(*i*, *n*-*i*)) | *O*(1)    | *O*(min(*i*, *n*-*i*)) |
 //!
 //! Note that where ties occur, [`Vec`] is generally going to be faster than [`VecDeque`], and
 //! [`VecDeque`] is generally going to be faster than [`LinkedList`].
 //!
 //! ## Maps
 //!
 //! For Sets, all operations have the cost of the equivalent Map operation.
 //!
 //! |              | get           | insert        | remove        | range         | append       |
 //! |--------------|---------------|---------------|---------------|---------------|--------------|
 //! | [`HashMap`]  | *O*(1)~       | *O*(1)~*      | *O*(1)~       | N/A           | N/A          |
 //! | [`BTreeMap`] | *O*(log(*n*)) | *O*(log(*n*)) | *O*(log(*n*)) | *O*(log(*n*)) | *O*(*n*+*m*) |
 //!
 //! # Correct and Efficient Usage of Collections
 //!
 //! Of course, knowing which collection is the right one for the job doesn't
 //! instantly permit you to use it correctly. Here are some quick tips for
 //! efficient and correct usage of the standard collections in general. If
 //! you're interested in how to use a specific collection in particular, consult
 //! its documentation for detailed discussion and code examples.
 //!
 //! ## Capacity Management
 //!
 //! Many collections provide several constructors and methods that refer to
 //! "capacity". These collections are generally built on top of an array.
 //! Optimally, this array would be exactly the right size to fit only the
 //! elements stored in the collection, but for the collection to do this would
 //! be very inefficient. If the backing array was exactly the right size at all
 //! times, then every time an element is inserted, the collection would have to
 //! grow the array to fit it. Due to the way memory is allocated and managed on
 //! most computers, this would almost surely require allocating an entirely new
 //! array and copying every single element from the old one into the new one.
 //! Hopefully you can see that this wouldn't be very efficient to do on every
 //! operation.
 //!
 //! Most collections therefore use an *amortized* allocation strategy. They
 //! generally let themselves have a fair amount of unoccupied space so that they
 //! only have to grow on occasion. When they do grow, they allocate a
 //! substantially larger array to move the elements into so that it will take a
 //! while for another grow to be required. While this strategy is great in
 //! general, it would be even better if the collection *never* had to resize its
 //! backing array. Unfortunately, the collection itself doesn't have enough
 //! information to do this itself. Therefore, it is up to us programmers to give
 //! it hints.
 //!
 //! Any `with_capacity` constructor will instruct the collection to allocate
 //! enough space for the specified number of elements. Ideally this will be for
 //! exactly that many elements, but some implementation details may prevent
 //! this. See collection-specific documentation for details. In general, use
 //! `with_capacity` when you know exactly how many elements will be inserted, or
 //! at least have a reasonable upper-bound on that number.
 //!
 //! When anticipating a large influx of elements, the `reserve` family of
 //! methods can be used to hint to the collection how much room it should make
 //! for the coming items. As with `with_capacity`, the precise behavior of
 //! these methods will be specific to the collection of interest.
 //!
 //! For optimal performance, collections will generally avoid shrinking
 //! themselves. If you believe that a collection will not soon contain any more
 //! elements, or just really need the memory, the `shrink_to_fit` method prompts
 //! the collection to shrink the backing array to the minimum size capable of
 //! holding its elements.
 //!
 //! Finally, if ever you're interested in what the actual capacity of the
 //! collection is, most collections provide a `capacity` method to query this
 //! information on demand. This can be useful for debugging purposes, or for
 //! use with the `reserve` methods.
 //!
 //! ## Iterators
 //!
 //! Iterators are a powerful and robust mechanism used throughout Rust's
 //! standard libraries. Iterators provide a sequence of values in a generic,
 //! safe, efficient and convenient way. The contents of an iterator are usually
 //! *lazily* evaluated, so that only the values that are actually needed are
 //! ever actually produced, and no allocation need be done to temporarily store
 //! them. Iterators are primarily consumed using a `for` loop, although many
 //! functions also take iterators where a collection or sequence of values is
 //! desired.
 //!
 //! All of the standard collections provide several iterators for performing
 //! bulk manipulation of their contents. The three primary iterators almost
 //! every collection should provide are `iter`, `iter_mut`, and `into_iter`.
 //! Some of these are not provided on collections where it would be unsound or
 //! unreasonable to provide them.
 //!
 //! `iter` provides an iterator of immutable references to all the contents of a
 //! collection in the most "natural" order. For sequence collections like [`Vec`],
 //! this means the items will be yielded in increasing order of index starting
 //! at 0. For ordered collections like [`BTreeMap`], this means that the items
 //! will be yielded in sorted order. For unordered collections like [`HashMap`],
 //! the items will be yielded in whatever order the internal representation made
 //! most convenient. This is great for reading through all the contents of the
 //! collection.
 //!
 //! ```
 //! let vec = vec![1, 2, 3, 4];
 //! for x in vec.iter() {
 //!    println!("vec contained {x:?}");
 //! }
 //! ```
 //!
 //! `iter_mut` provides an iterator of *mutable* references in the same order as
 //! `iter`. This is great for mutating all the contents of the collection.
 //!
 //! ```
 //! let mut vec = vec![1, 2, 3, 4];
 //! for x in vec.iter_mut() {
 //!    *x += 1;
 //! }
 //! ```
 //!
 //! `into_iter` transforms the actual collection into an iterator over its
 //! contents by-value. This is great when the collection itself is no longer
 //! needed, and the values are needed elsewhere. Using `extend` with `into_iter`
 //! is the main way that contents of one collection are moved into another.
 //! `extend` automatically calls `into_iter`, and takes any <code>T: [IntoIterator]</code>.
 //! Calling `collect` on an iterator itself is also a great way to convert one
 //! collection into another. Both of these methods should internally use the
 //! capacity management tools discussed in the previous section to do this as
 //! efficiently as possible.
 //!
 //! ```
 //! let mut vec1 = vec![1, 2, 3, 4];
 //! let vec2 = vec![10, 20, 30, 40];
 //! vec1.extend(vec2);
 //! ```
 //!
 //! ```
 //! use std::collections::VecDeque;
 //!
 //! let vec = [1, 2, 3, 4];
 //! let buf: VecDeque<_> = vec.into_iter().collect();
 //! ```
 //!
 //! Iterators also provide a series of *adapter* methods for performing common
 //! threads to sequences. Among the adapters are functional favorites like `map`,
 //! `fold`, `skip` and `take`. Of particular interest to collections is the
 //! `rev` adapter, which reverses any iterator that supports this operation. Most
 //! collections provide reversible iterators as the way to iterate over them in
 //! reverse order.
 //!
 //! ```
 //! let vec = vec![1, 2, 3, 4];
 //! for x in vec.iter().rev() {
 //!    println!("vec contained {x:?}");
 //! }
 //! ```
 //!
 //! Several other collection methods also return iterators to yield a sequence
 //! of results but avoid allocating an entire collection to store the result in.
 //! This provides maximum flexibility as `collect` or `extend` can be called to
 //! "pipe" the sequence into any collection if desired. Otherwise, the sequence
 //! can be looped over with a `for` loop. The iterator can also be discarded
 //! after partial use, preventing the computation of the unused items.
 //!
 //! ## Entries
 //!
 //! The `entry` API is intended to provide an efficient mechanism for
 //! manipulating the contents of a map conditionally on the presence of a key or
 //! not. The primary motivating use case for this is to provide efficient
 //! accumulator maps. For instance, if one wishes to maintain a count of the
 //! number of times each key has been seen, they will have to perform some
 //! conditional logic on whether this is the first time the key has been seen or
 //! not. Normally, this would require a `find` followed by an `insert`,
 //! effectively duplicating the search effort on each insertion.
 //!
 //! When a user calls `map.entry(key)`, the map will search for the key and
 //! then yield a variant of the `Entry` enum.
 //!
 //! If a `Vacant(entry)` is yielded, then the key *was not* found. In this case
 //! the only valid operation is to `insert` a value into the entry. When this is
 //! done, the vacant entry is consumed and converted into a mutable reference to
 //! the value that was inserted. This allows for further manipulation of the
 //! value beyond the lifetime of the search itself. This is useful if complex
 //! logic needs to be performed on the value regardless of whether the value was
 //! just inserted.
 //!
 //! If an `Occupied(entry)` is yielded, then the key *was* found. In this case,
 //! the user has several options: they can `get`, `insert` or `remove` the
 //! value of the occupied entry. Additionally, they can convert the occupied
 //! entry into a mutable reference to its value, providing symmetry to the
 //! vacant `insert` case.
 //!
 //! ### Examples
 //!
 //! Here are the two primary ways in which `entry` is used. First, a simple
 //! example where the logic performed on the values is trivial.
 //!
 //! #### Counting the number of times each character in a string occurs
 //!
 //! ```
 //! use std::collections::btree_map::BTreeMap;
 //!
 //! let mut count = BTreeMap::new();
 //! let message = "she sells sea shells by the sea shore";
 //!
 //! for c in message.chars() {
 //!     *count.entry(c).or_insert(0) += 1;
 //! }
 //!
 //! assert_eq!(count.get(&'s'), Some(&8));
 //!
 //! println!("Number of occurrences of each character");
 //! for (char, count) in &count {
 //!     println!("{char}: {count}");
 //! }
 //! ```
 //!
 //! When the logic to be performed on the value is more complex, we may simply
 //! use the `entry` API to ensure that the value is initialized and perform the
 //! logic afterwards.
 //!
 //! #### Tracking the inebriation of customers at a bar
 //!
 //! ```
 //! use std::collections::btree_map::BTreeMap;
 //!
 //! // A client of the bar. They have a blood alcohol level.
 //! struct Person { blood_alcohol: f32 }
 //!
 //! // All the orders made to the bar, by client ID.
 //! let orders = vec![1, 2, 1, 2, 3, 4, 1, 2, 2, 3, 4, 1, 1, 1];
 //!
 //! // Our clients.
 //! let mut blood_alcohol = BTreeMap::new();
 //!
 //! for id in orders {
 //!     // If this is the first time we've seen this customer, initialize them
 //!     // with no blood alcohol. Otherwise, just retrieve them.
 //!     let person = blood_alcohol.entry(id).or_insert(Person { blood_alcohol: 0.0 });
 //!
 //!     // Reduce their blood alcohol level. It takes time to order and drink a beer!
 //!     person.blood_alcohol *= 0.9;
 //!
 //!     // Check if they're sober enough to have another beer.
 //!     if person.blood_alcohol > 0.3 {
 //!         // Too drunk... for now.
 //!         println!("Sorry {id}, I have to cut you off");
 //!     } else {
 //!         // Have another!
 //!         person.blood_alcohol += 0.1;
 //!     }
 //! }
 //! ```
 //!
 //! # Insert and complex keys
 //!
 //! If we have a more complex key, calls to `insert` will
 //! not update the value of the key. For example:
 //!
 //! ```
 //! use std::cmp::Ordering;
 //! use std::collections::BTreeMap;
 //! use std::hash::{Hash, Hasher};
 //!
 //! #[derive(Debug)]
 //! struct Foo {
 //!     a: u32,
 //!     b: &'static str,
 //! }
 //!
 //! // we will compare `Foo`s by their `a` value only.
 //! impl PartialEq for Foo {
 //!     fn eq(&self, other: &Self) -> bool { self.a == other.a }
 //! }
 //!
 //! impl Eq for Foo {}
 //!
 //! // we will hash `Foo`s by their `a` value only.
 //! impl Hash for Foo {
 //!     fn hash<H: Hasher>(&self, h: &mut H) { self.a.hash(h); }
 //! }
 //!
 //! impl PartialOrd for Foo {
 //!     fn partial_cmp(&self, other: &Self) -> Option<Ordering> { self.a.partial_cmp(&other.a) }
 //! }
 //!
 //! impl Ord for Foo {
 //!     fn cmp(&self, other: &Self) -> Ordering { self.a.cmp(&other.a) }
 //! }
 //!
 //! let mut map = BTreeMap::new();
 //! map.insert(Foo { a: 1, b: "baz" }, 99);
 //!
 //! // We already have a Foo with an a of 1, so this will be updating the value.
 //! map.insert(Foo { a: 1, b: "xyz" }, 100);
 //!
 //! // The value has been updated...
 //! assert_eq!(map.values().next().unwrap(), &100);
 //!
 //! // ...but the key hasn't changed. b is still "baz", not "xyz".
 //! assert_eq!(map.keys().next().unwrap().b, "baz");
 //! ```
 //!
 //! [IntoIterator]: crate::iter::IntoIterator "iter::IntoIterator"

 #![stable(feature = "rust1", since = "1.0.0")]

 #[stable(feature = "rust1", since = "1.0.0")]
 // FIXME(#82080) The deprecation here is only theoretical, and does not actually produce a warning.
 #[deprecated(note = "moved to `std::ops::Bound`", since = "1.26.0")]
 #[doc(hidden)]
 pub use crate::ops::Bound;

 #[stable(feature = "rust1", since = "1.0.0")]
 pub use alloc_crate::collections::{binary_heap, btree_map, btree_set};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use alloc_crate::collections::{linked_list, vec_deque};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use alloc_crate::collections::{BTreeMap, BTreeSet, BinaryHeap};
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use alloc_crate::collections::{LinkedList, VecDeque};

 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::hash_map::HashMap;
 #[stable(feature = "rust1", since = "1.0.0")]
 pub use self::hash_set::HashSet;

 #[stable(feature = "try_reserve", since = "1.57.0")]
 pub use alloc_crate::collections::TryReserveError;
 #[unstable(
     feature = "try_reserve_kind",
     reason = "Uncertain how much info should be exposed",
     issue = "48043"
 )]
 pub use alloc_crate::collections::TryReserveErrorKind;

 mod hash;

 #[stable(feature = "rust1", since = "1.0.0")]
 pub mod hash_map {
     //! A hash map implemented with quadratic probing and SIMD lookup.
     #[stable(feature = "rust1", since = "1.0.0")]
     pub use super::hash::map::*;
 }

 #[stable(feature = "rust1", since = "1.0.0")]
 pub mod hash_set {
     //! A hash set implemented as a `HashMap` where the value is `()`.
     #[stable(feature = "rust1", since = "1.0.0")]
     pub use super::hash::set::*;
 }
	//! Collection types.
	//!
	//! Rust's standard collection library provides efficient implementations of the
	//! most common general purpose programming data structures. By using the
	//! standard implementations, it should be possible for two libraries to
	//! communicate without significant data conversion.
	//!
	//! To get this out of the way: you should probably just use [`Vec`] or [`HashMap`].
	//! These two collections cover most use cases for generic data storage and
	//! processing. They are exceptionally good at doing what they do. All the other
	//! collections in the standard library have specific use cases where they are
	//! the optimal choice, but these cases are borderline niche in comparison.
	//! Even when `Vec` and `HashMap` are technically suboptimal, they're probably a
	//! good enough choice to get started.
	//!
	//! Rust's collections can be grouped into four major categories:
	//!
	//! * Sequences: [`Vec`], [`VecDeque`], [`LinkedList`]
	//! * Maps: [`HashMap`], [`BTreeMap`]
	//! * Sets: [`HashSet`], [`BTreeSet`]
	//! * Misc: [`BinaryHeap`]
	//!
	//! # When Should You Use Which Collection?
	//!
	//! These are fairly high-level and quick break-downs of when each collection
	//! should be considered. Detailed discussions of strengths and weaknesses of
	//! individual collections can be found on their own documentation pages.
	//!
	//! ### Use a `Vec` when:
	//! * You want to collect items up to be processed or sent elsewhere later, and
	//! don't care about any properties of the actual values being stored.
	//! * You want a sequence of elements in a particular order, and will only be
	//! appending to (or near) the end.
	//! * You want a stack.
	//! * You want a resizable array.
	//! * You want a heap-allocated array.
	//!
	//! ### Use a `VecDeque` when:
	//! * You want a [`Vec`] that supports efficient insertion at both ends of the
	//! sequence.
	//! * You want a queue.
	//! * You want a double-ended queue (deque).
	//!
	//! ### Use a `LinkedList` when:
	//! * You want a [`Vec`] or [`VecDeque`] of unknown size, and can't tolerate
	//! amortization.
	//! * You want to efficiently split and append lists.
	//! * You are absolutely certain you really, truly, want a doubly linked
	//! list.
	//!
	//! ### Use a `HashMap` when:
	//! * You want to associate arbitrary keys with an arbitrary value.
	//! * You want a cache.
	//! * You want a map, with no extra functionality.
	//!
	//! ### Use a `BTreeMap` when:
	//! * You want a map sorted by its keys.
	//! * You want to be able to get a range of entries on-demand.
	//! * You're interested in what the smallest or largest key-value pair is.
	//! * You want to find the largest or smallest key that is smaller or larger
	//! than something.
	//!
	//! ### Use the `Set` variant of any of these `Map`s when:
	//! * You just want to remember which keys you've seen.
	//! * There is no meaningful value to associate with your keys.
	//! * You just want a set.
	//!
	//! ### Use a `BinaryHeap` when:
	//!
	//! * You want to store a bunch of elements, but only ever want to process the
	//! "biggest" or "most important" one at any given time.
	//! * You want a priority queue.
	//!
	//! # Performance
	//!
	//! Choosing the right collection for the job requires an understanding of what
	//! each collection is good at. Here we briefly summarize the performance of
	//! different collections for certain important operations. For further details,
	//! see each type's documentation, and note that the names of actual methods may
	//! differ from the tables below on certain collections.
	//!
	//! Throughout the documentation, we will follow a few conventions. For all
	//! operations, the collection's size is denoted by n. If another collection is
	//! involved in the operation, it contains m elements. Operations which have an
	//! amortized cost are suffixed with a ``. Operations with an expected*
	//! cost are suffixed with a `~`.
	//!
	//! All amortized costs are for the potential need to resize when capacity is
	//! exhausted. If a resize occurs it will take O(n) time. Our collections never
	//! automatically shrink, so removal operations aren't amortized. Over a
	//! sufficiently large series of operations, the average cost per operation will
	//! deterministically equal the given cost.
	//!
	//! Only [`HashMap`] has expected costs, due to the probabilistic nature of hashing.
	//! It is theoretically possible, though very unlikely, for [`HashMap`] to
	//! experience worse performance.
	//!
	//! ## Sequences
	//!
	//! \| \| get(i) \| insert(i) \| remove(i) \| append \| split_off(i) \|
	//! \|----------------\|------------------------\|-------------------------\|------------------------\|-----------\|------------------------\|
	//! \| [`Vec`] \| O(1) \| O(n-i)* \| O(n-i) \| O(m)* \| O(n-i) \|
	//! \| [`VecDeque`] \| O(1) \| O(min(i, n-i))* \| O(min(i, n-i)) \| O(m)* \| O(min(i, n-i)) \|
	//! \| [`LinkedList`] \| O(min(i, n-i)) \| O(min(i, n-i)) \| O(min(i, n-i)) \| O(1) \| O(min(i, n-i)) \|
	//!
	//! Note that where ties occur, [`Vec`] is generally going to be faster than [`VecDeque`], and
	//! [`VecDeque`] is generally going to be faster than [`LinkedList`].
	//!
	//! ## Maps
	//!
	//! For Sets, all operations have the cost of the equivalent Map operation.
	//!
	//! \| \| get \| insert \| remove \| range \| append \|
	//! \|--------------\|---------------\|---------------\|---------------\|---------------\|--------------\|
	//! \| [`HashMap`] \| O(1)~ \| O(1)~* \| O(1)~ \| N/A \| N/A \|
	//! \| [`BTreeMap`] \| O(log(n)) \| O(log(n)) \| O(log(n)) \| O(log(n)) \| O(n+m) \|
	//!
	//! # Correct and Efficient Usage of Collections
	//!
	//! Of course, knowing which collection is the right one for the job doesn't
	//! instantly permit you to use it correctly. Here are some quick tips for
	//! efficient and correct usage of the standard collections in general. If
	//! you're interested in how to use a specific collection in particular, consult
	//! its documentation for detailed discussion and code examples.
	//!
	//! ## Capacity Management
	//!
	//! Many collections provide several constructors and methods that refer to
	//! "capacity". These collections are generally built on top of an array.
	//! Optimally, this array would be exactly the right size to fit only the
	//! elements stored in the collection, but for the collection to do this would
	//! be very inefficient. If the backing array was exactly the right size at all
	//! times, then every time an element is inserted, the collection would have to
	//! grow the array to fit it. Due to the way memory is allocated and managed on
	//! most computers, this would almost surely require allocating an entirely new
	//! array and copying every single element from the old one into the new one.
	//! Hopefully you can see that this wouldn't be very efficient to do on every
	//! operation.
	//!
	//! Most collections therefore use an amortized allocation strategy. They
	//! generally let themselves have a fair amount of unoccupied space so that they
	//! only have to grow on occasion. When they do grow, they allocate a
	//! substantially larger array to move the elements into so that it will take a
	//! while for another grow to be required. While this strategy is great in
	//! general, it would be even better if the collection never had to resize its
	//! backing array. Unfortunately, the collection itself doesn't have enough
	//! information to do this itself. Therefore, it is up to us programmers to give
	//! it hints.
	//!
	//! Any `with_capacity` constructor will instruct the collection to allocate
	//! enough space for the specified number of elements. Ideally this will be for
	//! exactly that many elements, but some implementation details may prevent
	//! this. See collection-specific documentation for details. In general, use
	//! `with_capacity` when you know exactly how many elements will be inserted, or
	//! at least have a reasonable upper-bound on that number.
	//!
	//! When anticipating a large influx of elements, the `reserve` family of
	//! methods can be used to hint to the collection how much room it should make
	//! for the coming items. As with `with_capacity`, the precise behavior of
	//! these methods will be specific to the collection of interest.
	//!
	//! For optimal performance, collections will generally avoid shrinking
	//! themselves. If you believe that a collection will not soon contain any more
	//! elements, or just really need the memory, the `shrink_to_fit` method prompts
	//! the collection to shrink the backing array to the minimum size capable of
	//! holding its elements.
	//!
	//! Finally, if ever you're interested in what the actual capacity of the
	//! collection is, most collections provide a `capacity` method to query this
	//! information on demand. This can be useful for debugging purposes, or for
	//! use with the `reserve` methods.
	//!
	//! ## Iterators
	//!
	//! Iterators are a powerful and robust mechanism used throughout Rust's
	//! standard libraries. Iterators provide a sequence of values in a generic,
	//! safe, efficient and convenient way. The contents of an iterator are usually
	//! lazily evaluated, so that only the values that are actually needed are
	//! ever actually produced, and no allocation need be done to temporarily store
	//! them. Iterators are primarily consumed using a `for` loop, although many
	//! functions also take iterators where a collection or sequence of values is
	//! desired.
	//!
	//! All of the standard collections provide several iterators for performing
	//! bulk manipulation of their contents. The three primary iterators almost
	//! every collection should provide are `iter`, `iter_mut`, and `into_iter`.
	//! Some of these are not provided on collections where it would be unsound or
	//! unreasonable to provide them.
	//!
	//! `iter` provides an iterator of immutable references to all the contents of a
	//! collection in the most "natural" order. For sequence collections like [`Vec`],
	//! this means the items will be yielded in increasing order of index starting
	//! at 0. For ordered collections like [`BTreeMap`], this means that the items
	//! will be yielded in sorted order. For unordered collections like [`HashMap`],
	//! the items will be yielded in whatever order the internal representation made
	//! most convenient. This is great for reading through all the contents of the
	//! collection.
	//!
	//! ```
	//! let vec = vec![1, 2, 3, 4];
	//! for x in vec.iter() {
	//! println!("vec contained {x:?}");
	//! }
	//! ```
	//!
	//! `iter_mut` provides an iterator of mutable references in the same order as
	//! `iter`. This is great for mutating all the contents of the collection.
	//!
	//! ```
	//! let mut vec = vec![1, 2, 3, 4];
	//! for x in vec.iter_mut() {
	//! *x += 1;
	//! }
	//! ```
	//!
	//! `into_iter` transforms the actual collection into an iterator over its
	//! contents by-value. This is great when the collection itself is no longer
	//! needed, and the values are needed elsewhere. Using `extend` with `into_iter`
	//! is the main way that contents of one collection are moved into another.
	//! `extend` automatically calls `into_iter`, and takes any <code>T: [IntoIterator]</code>.
	//! Calling `collect` on an iterator itself is also a great way to convert one
	//! collection into another. Both of these methods should internally use the
	//! capacity management tools discussed in the previous section to do this as
	//! efficiently as possible.
	//!
	//! ```
	//! let mut vec1 = vec![1, 2, 3, 4];
	//! let vec2 = vec![10, 20, 30, 40];
	//! vec1.extend(vec2);
	//! ```
	//!
	//! ```
	//! use std::collections::VecDeque;
	//!
	//! let vec = [1, 2, 3, 4];
	//! let buf: VecDeque<_> = vec.into_iter().collect();
	//! ```
	//!
	//! Iterators also provide a series of adapter methods for performing common
	//! threads to sequences. Among the adapters are functional favorites like `map`,
	//! `fold`, `skip` and `take`. Of particular interest to collections is the
	//! `rev` adapter, which reverses any iterator that supports this operation. Most
	//! collections provide reversible iterators as the way to iterate over them in
	//! reverse order.
	//!
	//! ```
	//! let vec = vec![1, 2, 3, 4];
	//! for x in vec.iter().rev() {
	//! println!("vec contained {x:?}");
	//! }
	//! ```
	//!
	//! Several other collection methods also return iterators to yield a sequence
	//! of results but avoid allocating an entire collection to store the result in.
	//! This provides maximum flexibility as `collect` or `extend` can be called to
	//! "pipe" the sequence into any collection if desired. Otherwise, the sequence
	//! can be looped over with a `for` loop. The iterator can also be discarded
	//! after partial use, preventing the computation of the unused items.
	//!
	//! ## Entries
	//!
	//! The `entry` API is intended to provide an efficient mechanism for
	//! manipulating the contents of a map conditionally on the presence of a key or
	//! not. The primary motivating use case for this is to provide efficient
	//! accumulator maps. For instance, if one wishes to maintain a count of the
	//! number of times each key has been seen, they will have to perform some
	//! conditional logic on whether this is the first time the key has been seen or
	//! not. Normally, this would require a `find` followed by an `insert`,
	//! effectively duplicating the search effort on each insertion.
	//!
	//! When a user calls `map.entry(key)`, the map will search for the key and
	//! then yield a variant of the `Entry` enum.
	//!
	//! If a `Vacant(entry)` is yielded, then the key was not found. In this case
	//! the only valid operation is to `insert` a value into the entry. When this is
	//! done, the vacant entry is consumed and converted into a mutable reference to
	//! the value that was inserted. This allows for further manipulation of the
	//! value beyond the lifetime of the search itself. This is useful if complex
	//! logic needs to be performed on the value regardless of whether the value was
	//! just inserted.
	//!
	//! If an `Occupied(entry)` is yielded, then the key was found. In this case,
	//! the user has several options: they can `get`, `insert` or `remove` the
	//! value of the occupied entry. Additionally, they can convert the occupied
	//! entry into a mutable reference to its value, providing symmetry to the
	//! vacant `insert` case.
	//!
	//! ### Examples
	//!
	//! Here are the two primary ways in which `entry` is used. First, a simple
	//! example where the logic performed on the values is trivial.
	//!
	//! #### Counting the number of times each character in a string occurs
	//!
	//! ```
	//! use std::collections::btree_map::BTreeMap;
	//!
	//! let mut count = BTreeMap::new();
	//! let message = "she sells sea shells by the sea shore";
	//!
	//! for c in message.chars() {
	//! *count.entry(c).or_insert(0) += 1;
	//! }
	//!
	//! assert_eq!(count.get(&'s'), Some(&8));
	//!
	//! println!("Number of occurrences of each character");
	//! for (char, count) in &count {
	//! println!("{char}: {count}");
	//! }
	//! ```
	//!
	//! When the logic to be performed on the value is more complex, we may simply
	//! use the `entry` API to ensure that the value is initialized and perform the
	//! logic afterwards.
	//!
	//! #### Tracking the inebriation of customers at a bar
	//!
	//! ```
	//! use std::collections::btree_map::BTreeMap;
	//!
	//! // A client of the bar. They have a blood alcohol level.
	//! struct Person { blood_alcohol: f32 }
	//!
	//! // All the orders made to the bar, by client ID.
	//! let orders = vec![1, 2, 1, 2, 3, 4, 1, 2, 2, 3, 4, 1, 1, 1];
	//!
	//! // Our clients.
	//! let mut blood_alcohol = BTreeMap::new();
	//!
	//! for id in orders {
	//! // If this is the first time we've seen this customer, initialize them
	//! // with no blood alcohol. Otherwise, just retrieve them.
	//! let person = blood_alcohol.entry(id).or_insert(Person { blood_alcohol: 0.0 });
	//!
	//! // Reduce their blood alcohol level. It takes time to order and drink a beer!
	//! person.blood_alcohol *= 0.9;
	//!
	//! // Check if they're sober enough to have another beer.
	//! if person.blood_alcohol > 0.3 {
	//! // Too drunk... for now.
	//! println!("Sorry {id}, I have to cut you off");
	//! } else {
	//! // Have another!
	//! person.blood_alcohol += 0.1;
	//! }
	//! }
	//! ```
	//!
	//! # Insert and complex keys
	//!
	//! If we have a more complex key, calls to `insert` will
	//! not update the value of the key. For example:
	//!
	//! ```
	//! use std::cmp::Ordering;
	//! use std::collections::BTreeMap;
	//! use std::hash::{Hash, Hasher};
	//!
	//! #[derive(Debug)]
	//! struct Foo {
	//! a: u32,
	//! b: &'static str,
	//! }
	//!
	//! // we will compare `Foo`s by their `a` value only.
	//! impl PartialEq for Foo {
	//! fn eq(&self, other: &Self) -> bool { self.a == other.a }
	//! }
	//!
	//! impl Eq for Foo {}
	//!
	//! // we will hash `Foo`s by their `a` value only.
	//! impl Hash for Foo {
	//! fn hash<H: Hasher>(&self, h: &mut H) { self.a.hash(h); }
	//! }
	//!
	//! impl PartialOrd for Foo {
	//! fn partial_cmp(&self, other: &Self) -> Option<Ordering> { self.a.partial_cmp(&other.a) }
	//! }
	//!
	//! impl Ord for Foo {
	//! fn cmp(&self, other: &Self) -> Ordering { self.a.cmp(&other.a) }
	//! }
	//!
	//! let mut map = BTreeMap::new();
	//! map.insert(Foo { a: 1, b: "baz" }, 99);
	//!
	//! // We already have a Foo with an a of 1, so this will be updating the value.
	//! map.insert(Foo { a: 1, b: "xyz" }, 100);
	//!
	//! // The value has been updated...
	//! assert_eq!(map.values().next().unwrap(), &100);
	//!
	//! // ...but the key hasn't changed. b is still "baz", not "xyz".
	//! assert_eq!(map.keys().next().unwrap().b, "baz");
	//! ```
	//!
	//! [IntoIterator]: crate::iter::IntoIterator "iter::IntoIterator"

	#![stable(feature = "rust1", since = "1.0.0")]

	#[stable(feature = "rust1", since = "1.0.0")]
	// FIXME(#82080) The deprecation here is only theoretical, and does not actually produce a warning.
	#[deprecated(note = "moved to `std::ops::Bound`", since = "1.26.0")]
	#[doc(hidden)]
	pub use crate::ops::Bound;

	#[stable(feature = "rust1", since = "1.0.0")]
	pub use alloc_crate::collections::{binary_heap, btree_map, btree_set};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use alloc_crate::collections::{linked_list, vec_deque};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use alloc_crate::collections::{BTreeMap, BTreeSet, BinaryHeap};
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use alloc_crate::collections::{LinkedList, VecDeque};

	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::hash_map::HashMap;
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use self::hash_set::HashSet;

	#[stable(feature = "try_reserve", since = "1.57.0")]
	pub use alloc_crate::collections::TryReserveError;
	#[unstable(
	feature = "try_reserve_kind",
	reason = "Uncertain how much info should be exposed",
	issue = "48043"
	)]
	pub use alloc_crate::collections::TryReserveErrorKind;

	mod hash;

	#[stable(feature = "rust1", since = "1.0.0")]
	pub mod hash_map {
	//! A hash map implemented with quadratic probing and SIMD lookup.
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use super::hash::map::*;
	}

	#[stable(feature = "rust1", since = "1.0.0")]
	pub mod hash_set {
	//! A hash set implemented as a `HashMap` where the value is `()`.
	#[stable(feature = "rust1", since = "1.0.0")]
	pub use super::hash::set::*;
	}