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+#![deny(missing_debug_implementations)]
+#![deny(missing_docs)]
+#![deny(unreachable_pub)]
+#![warn(rust_2018_idioms)]
+
+//! Data-parallelism library that makes it easy to convert sequential
+//! computations into parallel
+//!
+//! Rayon is lightweight and convenient for introducing parallelism into existing
+//! code. It guarantees data-race free executions and takes advantage of
+//! parallelism when sensible, based on work-load at runtime.
+//!
+//! # How to use Rayon
+//!
+//! There are two ways to use Rayon:
+//!
+//! - **High-level parallel constructs** are the simplest way to use Rayon and also
+//!   typically the most efficient.
+//!   - [Parallel iterators][iter module] make it easy to convert a sequential iterator to
+//!     execute in parallel.
+//!     - The [`ParallelIterator`] trait defines general methods for all parallel iterators.
+//!     - The [`IndexedParallelIterator`] trait adds methods for iterators that support random
+//!       access.
+//!   - The [`par_sort`] method sorts `&mut [T]` slices (or vectors) in parallel.
+//!   - [`par_extend`] can be used to efficiently grow collections with items produced
+//!     by a parallel iterator.
+//! - **Custom tasks** let you divide your work into parallel tasks yourself.
+//!   - [`join`] is used to subdivide a task into two pieces.
+//!   - [`scope`] creates a scope within which you can create any number of parallel tasks.
+//!   - [`ThreadPoolBuilder`] can be used to create your own thread pools or customize
+//!     the global one.
+//!
+//! [iter module]: iter/index.html
+//! [`join`]: fn.join.html
+//! [`scope`]: fn.scope.html
+//! [`par_sort`]: slice/trait.ParallelSliceMut.html#method.par_sort
+//! [`par_extend`]: iter/trait.ParallelExtend.html#tymethod.par_extend
+//! [`ThreadPoolBuilder`]: struct.ThreadPoolBuilder.html
+//!
+//! # Basic usage and the Rayon prelude
+//!
+//! First, you will need to add `rayon` to your `Cargo.toml`.
+//!
+//! Next, to use parallel iterators or the other high-level methods,
+//! you need to import several traits. Those traits are bundled into
+//! the module [`rayon::prelude`]. It is recommended that you import
+//! all of these traits at once by adding `use rayon::prelude::*` at
+//! the top of each module that uses Rayon methods.
+//!
+//! These traits give you access to the `par_iter` method which provides
+//! parallel implementations of many iterative functions such as [`map`],
+//! [`for_each`], [`filter`], [`fold`], and [more].
+//!
+//! [`rayon::prelude`]: prelude/index.html
+//! [`map`]: iter/trait.ParallelIterator.html#method.map
+//! [`for_each`]: iter/trait.ParallelIterator.html#method.for_each
+//! [`filter`]: iter/trait.ParallelIterator.html#method.filter
+//! [`fold`]: iter/trait.ParallelIterator.html#method.fold
+//! [more]: iter/trait.ParallelIterator.html#provided-methods
+//! [`ParallelIterator`]: iter/trait.ParallelIterator.html
+//! [`IndexedParallelIterator`]: iter/trait.IndexedParallelIterator.html
+//!
+//! # Crate Layout
+//!
+//! Rayon extends many of the types found in the standard library with
+//! parallel iterator implementations. The modules in the `rayon`
+//! crate mirror [`std`] itself: so, e.g., the `option` module in
+//! Rayon contains parallel iterators for the `Option` type, which is
+//! found in [the `option` module of `std`]. Similarly, the
+//! `collections` module in Rayon offers parallel iterator types for
+//! [the `collections` from `std`]. You will rarely need to access
+//! these submodules unless you need to name iterator types
+//! explicitly.
+//!
+//! [the `option` module of `std`]: https://doc.rust-lang.org/std/option/index.html
+//! [the `collections` from `std`]: https://doc.rust-lang.org/std/collections/index.html
+//! [`std`]: https://doc.rust-lang.org/std/
+//!
+//! # Targets without threading
+//!
+//! Rayon has limited support for targets without `std` threading implementations.
+//! See the [`rayon_core`] documentation for more information about its global fallback.
+//!
+//! # Other questions?
+//!
+//! See [the Rayon FAQ][faq].
+//!
+//! [faq]: https://github.com/rayon-rs/rayon/blob/master/FAQ.md
+
+#[macro_use]
+mod delegate;
+
+#[macro_use]
+mod private;
+
+mod split_producer;
+
+pub mod array;
+pub mod collections;
+pub mod iter;
+pub mod option;
+pub mod prelude;
+pub mod range;
+pub mod range_inclusive;
+pub mod result;
+pub mod slice;
+pub mod str;
+pub mod string;
+pub mod vec;
+
+mod math;
+mod par_either;
+
+mod compile_fail;
+
+pub use rayon_core::FnContext;
+pub use rayon_core::ThreadBuilder;
+pub use rayon_core::ThreadPool;
+pub use rayon_core::ThreadPoolBuildError;
+pub use rayon_core::ThreadPoolBuilder;
+pub use rayon_core::{broadcast, spawn_broadcast, BroadcastContext};
+pub use rayon_core::{current_num_threads, current_thread_index, max_num_threads};
+pub use rayon_core::{in_place_scope, scope, Scope};
+pub use rayon_core::{in_place_scope_fifo, scope_fifo, ScopeFifo};
+pub use rayon_core::{join, join_context};
+pub use rayon_core::{spawn, spawn_fifo};
+pub use rayon_core::{yield_local, yield_now, Yield};
+
+/// We need to transmit raw pointers across threads. It is possible to do this
+/// without any unsafe code by converting pointers to usize or to AtomicPtr<T>
+/// then back to a raw pointer for use. We prefer this approach because code
+/// that uses this type is more explicit.
+///
+/// Unsafe code is still required to dereference the pointer, so this type is
+/// not unsound on its own, although it does partly lift the unconditional
+/// !Send and !Sync on raw pointers. As always, dereference with care.
+struct SendPtr<T>(*mut T);
+
+// SAFETY: !Send for raw pointers is not for safety, just as a lint
+unsafe impl<T: Send> Send for SendPtr<T> {}
+
+// SAFETY: !Sync for raw pointers is not for safety, just as a lint
+unsafe impl<T: Send> Sync for SendPtr<T> {}
+
+impl<T> SendPtr<T> {
+    // Helper to avoid disjoint captures of `send_ptr.0`
+    fn get(self) -> *mut T {
+        self.0
+    }
+}
+
+// Implement Clone without the T: Clone bound from the derive
+impl<T> Clone for SendPtr<T> {
+    fn clone(&self) -> Self {
+        *self
+    }
+}
+
+// Implement Copy without the T: Copy bound from the derive
+impl<T> Copy for SendPtr<T> {}