src/lib.rs - platform/external/rust/cxx - Git at Google

 //! [![github]](https://github.com/dtolnay/cxx)&ensp;[![crates-io]](https://crates.io/crates/cxx)&ensp;[![docs-rs]](https://docs.rs/cxx)
 //!
 //! [github]: https://img.shields.io/badge/github-8da0cb?style=for-the-badge&labelColor=555555&logo=github
 //! [crates-io]: https://img.shields.io/badge/crates.io-fc8d62?style=for-the-badge&labelColor=555555&logo=rust
 //! [docs-rs]: https://img.shields.io/badge/docs.rs-66c2a5?style=for-the-badge&labelColor=555555&logoColor=white&logo=data:image/svg+xml;base64,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
 //!
 //! <br>
 //!
 //! This library provides a **safe** mechanism for calling C++ code from Rust
 //! and Rust code from C++, not subject to the many ways that things can go
 //! wrong when using bindgen or cbindgen to generate unsafe C-style bindings.
 //!
 //! This doesn't change the fact that 100% of C++ code is unsafe. When auditing
 //! a project, you would be on the hook for auditing all the unsafe Rust code
 //! and *all* the C++ code. The core safety claim under this new model is that
 //! auditing just the C++ side would be sufficient to catch all problems, i.e.
 //! the Rust side can be 100% safe.
 //!
 //! <br>
 //!
 //! *Compiler support: requires rustc 1.42+ and c++11 or newer*<br>
 //! *[Release notes](https://github.com/dtolnay/cxx/releases)*
 //!
 //! <br>
 //!
 //! # Overview
 //!
 //! The idea is that we define the signatures of both sides of our FFI boundary
 //! embedded together in one Rust module (the next section shows an example).
 //! From this, CXX receives a complete picture of the boundary to perform static
 //! analyses against the types and function signatures to uphold both Rust's and
 //! C++'s invariants and requirements.
 //!
 //! If everything checks out statically, then CXX uses a pair of code generators
 //! to emit the relevant `extern "C"` signatures on both sides together with any
 //! necessary static assertions for later in the build process to verify
 //! correctness. On the Rust side this code generator is simply an attribute
 //! procedural macro. On the C++ side it can be a small Cargo build script if
 //! your build is managed by Cargo, or for other build systems like Bazel or
 //! Buck we provide a command line tool which generates the header and source
 //! file and should be easy to integrate.
 //!
 //! The resulting FFI bridge operates at zero or negligible overhead, i.e. no
 //! copying, no serialization, no memory allocation, no runtime checks needed.
 //!
 //! The FFI signatures are able to use native types from whichever side they
 //! please, such as Rust's `String` or C++'s `std::string`, Rust's `Box` or
 //! C++'s `std::unique_ptr`, Rust's `Vec` or C++'s `std::vector`, etc in any
 //! combination. CXX guarantees an ABI-compatible signature that both sides
 //! understand, based on builtin bindings for key standard library types to
 //! expose an idiomatic API on those types to the other language. For example
 //! when manipulating a C++ string from Rust, its `len()` method becomes a call
 //! of the `size()` member function defined by C++; when manipulation a Rust
 //! string from C++, its `size()` member function calls Rust's `len()`.
 //!
 //! <br>
 //!
 //! # Example
 //!
 //! A runnable version of this example is provided under the *demo-rs* directory
 //! of [https://github.com/dtolnay/cxx] (with the C++ side of the implementation
 //! in the *demo-cxx* directory). To try it out, jump into demo-rs and run
 //! `cargo run`.
 //!
 //! ```no_run
 //! #[cxx::bridge]
 //! mod ffi {
 //!     // Any shared structs, whose fields will be visible to both languages.
 //!     struct SharedThing {
 //!         z: i32,
 //!         y: Box<ThingR>,
 //!         x: UniquePtr<ThingC>,
 //!     }
 //!
 //!     extern "C" {
 //!         // One or more headers with the matching C++ declarations. Our code
 //!         // generators don't read it but it gets #include'd and used in static
 //!         // assertions to ensure our picture of the FFI boundary is accurate.
 //!         include!("demo-cxx/demo.h");
 //!
 //!         // Zero or more opaque types which both languages can pass around but
 //!         // only C++ can see the fields.
 //!         type ThingC;
 //!
 //!         // Functions implemented in C++.
 //!         fn make_demo(appname: &str) -> UniquePtr<ThingC>;
 //!         fn get_name(thing: &ThingC) -> &CxxString;
 //!         fn do_thing(state: SharedThing);
 //!     }
 //!
 //!     extern "Rust" {
 //!         // Zero or more opaque types which both languages can pass around but
 //!         // only Rust can see the fields.
 //!         type ThingR;
 //!
 //!         // Functions implemented in Rust.
 //!         fn print_r(r: &ThingR);
 //!     }
 //! }
 //! #
 //! # pub struct ThingR(usize);
 //! #
 //! # fn print_r(r: &ThingR) {
 //! #     println!("called back with r={}", r.0);
 //! # }
 //! #
 //! # fn main() {}
 //! ```
 //!
 //! Now we simply provide C++ definitions of all the things in the `extern "C"`
 //! block and Rust definitions of all the things in the `extern "Rust"` block,
 //! and get to call back and forth safely.
 //!
 //! Here are links to the complete set of source files involved in the demo:
 //!
 //! - [demo-rs/src/main.rs](https://github.com/dtolnay/cxx/blob/master/demo-rs/src/main.rs)
 //! - [demo-rs/build.rs](https://github.com/dtolnay/cxx/blob/master/demo-rs/build.rs)
 //! - [demo-cxx/demo.h](https://github.com/dtolnay/cxx/blob/master/demo-cxx/demo.h)
 //! - [demo-cxx/demo.cc](https://github.com/dtolnay/cxx/blob/master/demo-cxx/demo.cc)
 //!
 //! To look at the code generated in both languages for the example by the CXX
 //! code generators:
 //!
 //! ```console
 //!    # run Rust code generator and print to stdout
 //!    # (requires https://github.com/dtolnay/cargo-expand)
 //! $ cargo expand --manifest-path demo-rs/Cargo.toml
 //!
 //!    # run C++ code generator and print to stdout
 //! $ cargo run --manifest-path gen/cmd/Cargo.toml -- demo-rs/src/main.rs
 //! ```
 //!
 //! <br>
 //!
 //! # Details
 //!
 //! As seen in the example, the language of the FFI boundary involves 3 kinds of
 //! items:
 //!
 //! - **Shared structs** &mdash; their fields are made visible to both
 //!   languages. The definition written within cxx::bridge is the single source
 //!   of truth.
 //!
 //! - **Opaque types** &mdash; their fields are secret from the other language.
 //!   These cannot be passed across the FFI by value but only behind an
 //!   indirection, such as a reference `&`, a Rust `Box`, or a `UniquePtr`. Can
 //!   be a type alias for an arbitrarily complicated generic language-specific
 //!   type depending on your use case.
 //!
 //! - **Functions** &mdash; implemented in either language, callable from the
 //!   other language.
 //!
 //! Within the `extern "C"` part of the CXX bridge we list the types and
 //! functions for which C++ is the source of truth, as well as the header(s)
 //! that declare those APIs. In the future it's possible that this section could
 //! be generated bindgen-style from the headers but for now we need the
 //! signatures written out; static assertions will verify that they are
 //! accurate.
 //!
 //! Within the `extern "Rust"` part, we list types and functions for which Rust
 //! is the source of truth. These all implicitly refer to the `super` module,
 //! the parent module of the CXX bridge. You can think of the two items listed
 //! in the example above as being like `use super::ThingR` and `use
 //! super::print_r` except re-exported to C++. The parent module will either
 //! contain the definitions directly for simple things, or contain the relevant
 //! `use` statements to bring them into scope from elsewhere.
 //!
 //! Your function implementations themselves, whether in C++ or Rust, *do not*
 //! need to be defined as `extern "C"` ABI or no\_mangle. CXX will put in the
 //! right shims where necessary to make it all work.
 //!
 //! <br>
 //!
 //! # Comparison vs bindgen and cbindgen
 //!
 //! Notice that with CXX there is repetition of all the function signatures:
 //! they are typed out once where the implementation is defined (in C++ or Rust)
 //! and again inside the cxx::bridge module, though compile-time assertions
 //! guarantee these are kept in sync. This is different from [bindgen] and
 //! [cbindgen] where function signatures are typed by a human once and the tool
 //! consumes them in one language and emits them in the other language.
 //!
 //! [bindgen]: https://github.com/rust-lang/rust-bindgen
 //! [cbindgen]: https://github.com/eqrion/cbindgen/
 //!
 //! This is because CXX fills a somewhat different role. It is a lower level
 //! tool than bindgen or cbindgen in a sense; you can think of it as being a
 //! replacement for the concept of `extern "C"` signatures as we know them,
 //! rather than a replacement for a bindgen. It would be reasonable to build a
 //! higher level bindgen-like tool on top of CXX which consumes a C++ header
 //! and/or Rust module (and/or IDL like Thrift) as source of truth and generates
 //! the cxx::bridge, eliminating the repetition while leveraging the static
 //! analysis safety guarantees of CXX.
 //!
 //! But note in other ways CXX is higher level than the bindgens, with rich
 //! support for common standard library types. Frequently with bindgen when we
 //! are dealing with an idiomatic C++ API we would end up manually wrapping that
 //! API in C-style raw pointer functions, applying bindgen to get unsafe raw
 //! pointer Rust functions, and replicating the API again to expose those
 //! idiomatically in Rust. That's a much worse form of repetition because it is
 //! unsafe all the way through.
 //!
 //! By using a CXX bridge as the shared understanding between the languages,
 //! rather than `extern "C"` C-style signatures as the shared understanding,
 //! common FFI use cases become expressible using 100% safe code.
 //!
 //! It would also be reasonable to mix and match, using CXX bridge for the 95%
 //! of your FFI that is straightforward and doing the remaining few oddball
 //! signatures the old fashioned way with bindgen and cbindgen, if for some
 //! reason CXX's static restrictions get in the way. Please file an issue if you
 //! end up taking this approach so that we know what ways it would be worthwhile
 //! to make the tool more expressive.
 //!
 //! <br>
 //!
 //! # Cargo-based setup
 //!
 //! For builds that are orchestrated by Cargo, you will use a build script that
 //! runs CXX's C++ code generator and compiles the resulting C++ code along with
 //! any other C++ code for your crate.
 //!
 //! The canonical build script is as follows. The indicated line returns a
 //! [`cc::Build`] instance (from the usual widely used `cc` crate) on which you
 //! can set up any additional source files and compiler flags as normal.
 //!
 //! [`cc::Build`]: https://docs.rs/cc/1.0/cc/struct.Build.html
 //!
 //! ```toml
 //! # Cargo.toml
 //!
 //! [build-dependencies]
 //! cxx-build = "0.3"
 //! ```
 //!
 //! ```no_run
 //! // build.rs
 //!
 //! fn main() {
 //!     cxx_build::bridge("src/main.rs")  // returns a cc::Build
 //!         .file("../demo-cxx/demo.cc")
 //!         .flag_if_supported("-std=c++11")
 //!         .compile("cxxbridge-demo");
 //!
 //!     println!("cargo:rerun-if-changed=src/main.rs");
 //!     println!("cargo:rerun-if-changed=../demo-cxx/demo.h");
 //!     println!("cargo:rerun-if-changed=../demo-cxx/demo.cc");
 //! }
 //! ```
 //!
 //! <br><br>
 //!
 //! # Non-Cargo setup
 //!
 //! For use in non-Cargo builds like Bazel or Buck, CXX provides an alternate
 //! way of invoking the C++ code generator as a standalone command line tool.
 //! The tool is packaged as the `cxxbridge-cmd` crate on crates.io or can be
 //! built from the *cmd* directory of [https://github.com/dtolnay/cxx].
 //!
 //! ```bash
 //! $ cargo install cxxbridge-cmd
 //!
 //! $ cxxbridge src/main.rs --header > path/to/mybridge.h
 //! $ cxxbridge src/main.rs > path/to/mybridge.cc
 //! ```
 //!
 //! <br>
 //!
 //! # Safety
 //!
 //! Be aware that the design of this library is intentionally restrictive and
 //! opinionated! It isn't a goal to be powerful enough to handle arbitrary
 //! signatures in either language. Instead this project is about carving out a
 //! reasonably expressive set of functionality about which we can make useful
 //! safety guarantees today and maybe extend over time. You may find that it
 //! takes some practice to use CXX bridge effectively as it won't work in all
 //! the ways that you are used to.
 //!
 //! Some of the considerations that go into ensuring safety are:
 //!
 //! - By design, our paired code generators work together to control both sides
 //!   of the FFI boundary. Ordinarily in Rust writing your own `extern "C"`
 //!   blocks is unsafe because the Rust compiler has no way to know whether the
 //!   signatures you've written actually match the signatures implemented in the
 //!   other language. With CXX we achieve that visibility and know what's on the
 //!   other side.
 //!
 //! - Our static analysis detects and prevents passing types by value that
 //!   shouldn't be passed by value from C++ to Rust, for example because they
 //!   may contain internal pointers that would be screwed up by Rust's move
 //!   behavior.
 //!
 //! - To many people's surprise, it is possible to have a struct in Rust and a
 //!   struct in C++ with exactly the same layout / fields / alignment /
 //!   everything, and still not the same ABI when passed by value. This is a
 //!   longstanding bindgen bug that leads to segfaults in absolutely
 //!   correct-looking code ([rust-lang/rust-bindgen#778]). CXX knows about this
 //!   and can insert the necessary zero-cost workaround transparently where
 //!   needed, so go ahead and pass your structs by value without worries. This
 //!   is made possible by owning both sides of the boundary rather than just
 //!   one.
 //!
 //! - Template instantiations: for example in order to expose a UniquePtr\<T\>
 //!   type in Rust backed by a real C++ unique\_ptr, we have a way of using a
 //!   Rust trait to connect the behavior back to the template instantiations
 //!   performed by the other language.
 //!
 //! [rust-lang/rust-bindgen#778]: https://github.com/rust-lang/rust-bindgen/issues/778
 //!
 //! <br>
 //!
 //! # Builtin types
 //!
 //! In addition to all the primitive types (i32 &lt;=&gt; int32_t), the
 //! following common types may be used in the fields of shared structs and the
 //! arguments and returns of functions.
 //!
 //! <table>
 //! <tr><th>name in Rust</th><th>name in C++</th><th>restrictions</th></tr>
 //! <tr><td>String</td><td>rust::String</td><td></td></tr>
 //! <tr><td>&amp;str</td><td>rust::Str</td><td></td></tr>
 //! <tr><td>&amp;[u8]</td><td>rust::Slice&lt;uint8_t&gt;</td><td><sup><i>arbitrary &amp;[T] not implemented yet</i></sup></td></tr>
 //! <tr><td><a href="struct.CxxString.html">CxxString</a></td><td>std::string</td><td><sup><i>cannot be passed by value</i></sup></td></tr>
 //! <tr><td>Box&lt;T&gt;</td><td>rust::Box&lt;T&gt;</td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
 //! <tr><td><a href="struct.UniquePtr.html">UniquePtr&lt;T&gt;</a></td><td>std::unique_ptr&lt;T&gt;</td><td><sup><i>cannot hold opaque Rust type</i></sup></td></tr>
 //! <tr><td>Vec&lt;T&gt;</td><td>rust::Vec&lt;T&gt;</td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
 //! <tr><td><a href="struct.CxxVector.html">CxxVector&lt;T&gt;</a></td><td>std::vector&lt;T&gt;</td><td><sup><i>cannot be passed by value, cannot hold opaque Rust type</i></sup></td></tr>
 //! <tr><td>fn(T, U) -&gt; V</td><td>rust::Fn&lt;V(T, U)&gt;</td><td><sup><i>only passing from Rust to C++ is implemented so far</i></sup></td></tr>
 //! <tr><td>Result&lt;T&gt;</td><td>throw/catch</td><td><sup><i>allowed as return type only</i></sup></td></tr>
 //! </table>
 //!
 //! The C++ API of the `rust` namespace is defined by the *include/cxx.h* file
 //! in [https://github.com/dtolnay/cxx]. You will need to include this header in
 //! your C++ code when working with those types.
 //!
 //! The following types are intended to be supported "soon" but are just not
 //! implemented yet. I don't expect any of these to be hard to make work but
 //! it's a matter of designing a nice API for each in its non-native language.
 //!
 //! <table>
 //! <tr><th>name in Rust</th><th>name in C++</th></tr>
 //! <tr><td>BTreeMap&lt;K, V&gt;</td><td><sup><i>tbd</i></sup></td></tr>
 //! <tr><td>HashMap&lt;K, V&gt;</td><td><sup><i>tbd</i></sup></td></tr>
 //! <tr><td>Arc&lt;T&gt;</td><td><sup><i>tbd</i></sup></td></tr>
 //! <tr><td><sup><i>tbd</i></sup></td><td>std::map&lt;K, V&gt;</td></tr>
 //! <tr><td><sup><i>tbd</i></sup></td><td>std::unordered_map&lt;K, V&gt;</td></tr>
 //! <tr><td><sup><i>tbd</i></sup></td><td>std::shared_ptr&lt;T&gt;</td></tr>
 //! </table>
 //!
 //! [https://github.com/dtolnay/cxx]: https://github.com/dtolnay/cxx

 #![doc(html_root_url = "https://docs.rs/cxx/0.3.4")]
 #![deny(improper_ctypes)]
 #![allow(non_camel_case_types)]
 #![allow(
     clippy::cognitive_complexity,
     clippy::declare_interior_mutable_const,
     clippy::inherent_to_string,
     clippy::large_enum_variant,
     clippy::len_without_is_empty,
     clippy::missing_safety_doc,
     clippy::module_inception,
     clippy::needless_doctest_main,
     clippy::new_without_default,
     clippy::or_fun_call,
     clippy::ptr_arg,
     clippy::toplevel_ref_arg,
     clippy::useless_let_if_seq
 )]

 #[macro_use]
 mod macros;

 mod cxx_string;
 mod cxx_vector;
 mod exception;
 mod extern_type;
 mod function;
 mod opaque;
 mod result;
 mod rust_sliceu8;
 mod rust_str;
 mod rust_string;
 mod rust_vec;
 mod unique_ptr;
 mod unwind;

 #[cfg(not(no_export_symbols))]
 mod symbols;

 pub use crate::cxx_string::CxxString;
 pub use crate::cxx_vector::CxxVector;
 pub use crate::exception::Exception;
 pub use crate::extern_type::ExternType;
 pub use crate::unique_ptr::UniquePtr;
 pub use cxxbridge_macro::bridge;

 /// For use in impls of the `ExternType` trait. See [`ExternType`].
 pub use cxxbridge_macro::type_id;

 // Not public API.
 #[doc(hidden)]
 pub mod private {
     pub use crate::cxx_vector::VectorElement;
     pub use crate::extern_type::verify_extern_type;
     pub use crate::function::FatFunction;
     pub use crate::opaque::Opaque;
     pub use crate::result::{r#try, Result};
     pub use crate::rust_sliceu8::RustSliceU8;
     pub use crate::rust_str::RustStr;
     pub use crate::rust_string::RustString;
     pub use crate::rust_vec::RustVec;
     pub use crate::unique_ptr::UniquePtrTarget;
     pub use crate::unwind::catch_unwind;
 }

 macro_rules! chars {
     ($($ch:ident)*) => {
         $(
             #[doc(hidden)]
             pub enum $ch {}
         )*
     };
 }

 chars! {
     _0 _1 _2 _3 _4 _5 _6 _7 _8 _9
     A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
     a b c d e f g h i j k l m n o p q r s t u v w x y z
     __ // underscore
 }
	//! [![github]](https://github.com/dtolnay/cxx)&ensp;[![crates-io]](https://crates.io/crates/cxx)&ensp;[![docs-rs]](https://docs.rs/cxx)
	//!
	//! [github]: https://img.shields.io/badge/github-8da0cb?style=for-the-badge&labelColor=555555&logo=github
	//! [crates-io]: https://img.shields.io/badge/crates.io-fc8d62?style=for-the-badge&labelColor=555555&logo=rust
	//! [docs-rs]: https://img.shields.io/badge/docs.rs-66c2a5?style=for-the-badge&labelColor=555555&logoColor=white&logo=data:image/svg+xml;base64,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
	//!
	//! <br>
	//!
	//! This library provides a safe mechanism for calling C++ code from Rust
	//! and Rust code from C++, not subject to the many ways that things can go
	//! wrong when using bindgen or cbindgen to generate unsafe C-style bindings.
	//!
	//! This doesn't change the fact that 100% of C++ code is unsafe. When auditing
	//! a project, you would be on the hook for auditing all the unsafe Rust code
	//! and all the C++ code. The core safety claim under this new model is that
	//! auditing just the C++ side would be sufficient to catch all problems, i.e.
	//! the Rust side can be 100% safe.
	//!
	//! <br>
	//!
	//! Compiler support: requires rustc 1.42+ and c++11 or newer<br>
	//! [Release notes](https://github.com/dtolnay/cxx/releases)
	//!
	//! <br>
	//!
	//! # Overview
	//!
	//! The idea is that we define the signatures of both sides of our FFI boundary
	//! embedded together in one Rust module (the next section shows an example).
	//! From this, CXX receives a complete picture of the boundary to perform static
	//! analyses against the types and function signatures to uphold both Rust's and
	//! C++'s invariants and requirements.
	//!
	//! If everything checks out statically, then CXX uses a pair of code generators
	//! to emit the relevant `extern "C"` signatures on both sides together with any
	//! necessary static assertions for later in the build process to verify
	//! correctness. On the Rust side this code generator is simply an attribute
	//! procedural macro. On the C++ side it can be a small Cargo build script if
	//! your build is managed by Cargo, or for other build systems like Bazel or
	//! Buck we provide a command line tool which generates the header and source
	//! file and should be easy to integrate.
	//!
	//! The resulting FFI bridge operates at zero or negligible overhead, i.e. no
	//! copying, no serialization, no memory allocation, no runtime checks needed.
	//!
	//! The FFI signatures are able to use native types from whichever side they
	//! please, such as Rust's `String` or C++'s `std::string`, Rust's `Box` or
	//! C++'s `std::unique_ptr`, Rust's `Vec` or C++'s `std::vector`, etc in any
	//! combination. CXX guarantees an ABI-compatible signature that both sides
	//! understand, based on builtin bindings for key standard library types to
	//! expose an idiomatic API on those types to the other language. For example
	//! when manipulating a C++ string from Rust, its `len()` method becomes a call
	//! of the `size()` member function defined by C++; when manipulation a Rust
	//! string from C++, its `size()` member function calls Rust's `len()`.
	//!
	//! <br>
	//!
	//! # Example
	//!
	//! A runnable version of this example is provided under the demo-rs directory
	//! of [https://github.com/dtolnay/cxx] (with the C++ side of the implementation
	//! in the demo-cxx directory). To try it out, jump into demo-rs and run
	//! `cargo run`.
	//!
	//! ```no_run
	//! #[cxx::bridge]
	//! mod ffi {
	//! // Any shared structs, whose fields will be visible to both languages.
	//! struct SharedThing {
	//! z: i32,
	//! y: Box<ThingR>,
	//! x: UniquePtr<ThingC>,
	//! }
	//!
	//! extern "C" {
	//! // One or more headers with the matching C++ declarations. Our code
	//! // generators don't read it but it gets #include'd and used in static
	//! // assertions to ensure our picture of the FFI boundary is accurate.
	//! include!("demo-cxx/demo.h");
	//!
	//! // Zero or more opaque types which both languages can pass around but
	//! // only C++ can see the fields.
	//! type ThingC;
	//!
	//! // Functions implemented in C++.
	//! fn make_demo(appname: &str) -> UniquePtr<ThingC>;
	//! fn get_name(thing: &ThingC) -> &CxxString;
	//! fn do_thing(state: SharedThing);
	//! }
	//!
	//! extern "Rust" {
	//! // Zero or more opaque types which both languages can pass around but
	//! // only Rust can see the fields.
	//! type ThingR;
	//!
	//! // Functions implemented in Rust.
	//! fn print_r(r: &ThingR);
	//! }
	//! }
	//! #
	//! # pub struct ThingR(usize);
	//! #
	//! # fn print_r(r: &ThingR) {
	//! # println!("called back with r={}", r.0);
	//! # }
	//! #
	//! # fn main() {}
	//! ```
	//!
	//! Now we simply provide C++ definitions of all the things in the `extern "C"`
	//! block and Rust definitions of all the things in the `extern "Rust"` block,
	//! and get to call back and forth safely.
	//!
	//! Here are links to the complete set of source files involved in the demo:
	//!
	//! - [demo-rs/src/main.rs](https://github.com/dtolnay/cxx/blob/master/demo-rs/src/main.rs)
	//! - [demo-rs/build.rs](https://github.com/dtolnay/cxx/blob/master/demo-rs/build.rs)
	//! - [demo-cxx/demo.h](https://github.com/dtolnay/cxx/blob/master/demo-cxx/demo.h)
	//! - [demo-cxx/demo.cc](https://github.com/dtolnay/cxx/blob/master/demo-cxx/demo.cc)
	//!
	//! To look at the code generated in both languages for the example by the CXX
	//! code generators:
	//!
	//! ```console
	//! # run Rust code generator and print to stdout
	//! # (requires https://github.com/dtolnay/cargo-expand)
	//! $ cargo expand --manifest-path demo-rs/Cargo.toml
	//!
	//! # run C++ code generator and print to stdout
	//! $ cargo run --manifest-path gen/cmd/Cargo.toml -- demo-rs/src/main.rs
	//! ```
	//!
	//! <br>
	//!
	//! # Details
	//!
	//! As seen in the example, the language of the FFI boundary involves 3 kinds of
	//! items:
	//!
	//! - Shared structs — their fields are made visible to both
	//! languages. The definition written within cxx::bridge is the single source
	//! of truth.
	//!
	//! - Opaque types — their fields are secret from the other language.
	//! These cannot be passed across the FFI by value but only behind an
	//! indirection, such as a reference `&`, a Rust `Box`, or a `UniquePtr`. Can
	//! be a type alias for an arbitrarily complicated generic language-specific
	//! type depending on your use case.
	//!
	//! - Functions — implemented in either language, callable from the
	//! other language.
	//!
	//! Within the `extern "C"` part of the CXX bridge we list the types and
	//! functions for which C++ is the source of truth, as well as the header(s)
	//! that declare those APIs. In the future it's possible that this section could
	//! be generated bindgen-style from the headers but for now we need the
	//! signatures written out; static assertions will verify that they are
	//! accurate.
	//!
	//! Within the `extern "Rust"` part, we list types and functions for which Rust
	//! is the source of truth. These all implicitly refer to the `super` module,
	//! the parent module of the CXX bridge. You can think of the two items listed
	//! in the example above as being like `use super::ThingR` and `use
	//! super::print_r` except re-exported to C++. The parent module will either
	//! contain the definitions directly for simple things, or contain the relevant
	//! `use` statements to bring them into scope from elsewhere.
	//!
	//! Your function implementations themselves, whether in C++ or Rust, do not
	//! need to be defined as `extern "C"` ABI or no\_mangle. CXX will put in the
	//! right shims where necessary to make it all work.
	//!
	//! <br>
	//!
	//! # Comparison vs bindgen and cbindgen
	//!
	//! Notice that with CXX there is repetition of all the function signatures:
	//! they are typed out once where the implementation is defined (in C++ or Rust)
	//! and again inside the cxx::bridge module, though compile-time assertions
	//! guarantee these are kept in sync. This is different from [bindgen] and
	//! [cbindgen] where function signatures are typed by a human once and the tool
	//! consumes them in one language and emits them in the other language.
	//!
	//! [bindgen]: https://github.com/rust-lang/rust-bindgen
	//! [cbindgen]: https://github.com/eqrion/cbindgen/
	//!
	//! This is because CXX fills a somewhat different role. It is a lower level
	//! tool than bindgen or cbindgen in a sense; you can think of it as being a
	//! replacement for the concept of `extern "C"` signatures as we know them,
	//! rather than a replacement for a bindgen. It would be reasonable to build a
	//! higher level bindgen-like tool on top of CXX which consumes a C++ header
	//! and/or Rust module (and/or IDL like Thrift) as source of truth and generates
	//! the cxx::bridge, eliminating the repetition while leveraging the static
	//! analysis safety guarantees of CXX.
	//!
	//! But note in other ways CXX is higher level than the bindgens, with rich
	//! support for common standard library types. Frequently with bindgen when we
	//! are dealing with an idiomatic C++ API we would end up manually wrapping that
	//! API in C-style raw pointer functions, applying bindgen to get unsafe raw
	//! pointer Rust functions, and replicating the API again to expose those
	//! idiomatically in Rust. That's a much worse form of repetition because it is
	//! unsafe all the way through.
	//!
	//! By using a CXX bridge as the shared understanding between the languages,
	//! rather than `extern "C"` C-style signatures as the shared understanding,
	//! common FFI use cases become expressible using 100% safe code.
	//!
	//! It would also be reasonable to mix and match, using CXX bridge for the 95%
	//! of your FFI that is straightforward and doing the remaining few oddball
	//! signatures the old fashioned way with bindgen and cbindgen, if for some
	//! reason CXX's static restrictions get in the way. Please file an issue if you
	//! end up taking this approach so that we know what ways it would be worthwhile
	//! to make the tool more expressive.
	//!
	//! <br>
	//!
	//! # Cargo-based setup
	//!
	//! For builds that are orchestrated by Cargo, you will use a build script that
	//! runs CXX's C++ code generator and compiles the resulting C++ code along with
	//! any other C++ code for your crate.
	//!
	//! The canonical build script is as follows. The indicated line returns a
	//! [`cc::Build`] instance (from the usual widely used `cc` crate) on which you
	//! can set up any additional source files and compiler flags as normal.
	//!
	//! [`cc::Build`]: https://docs.rs/cc/1.0/cc/struct.Build.html
	//!
	//! ```toml
	//! # Cargo.toml
	//!
	//! [build-dependencies]
	//! cxx-build = "0.3"
	//! ```
	//!
	//! ```no_run
	//! // build.rs
	//!
	//! fn main() {
	//! cxx_build::bridge("src/main.rs") // returns a cc::Build
	//! .file("../demo-cxx/demo.cc")
	//! .flag_if_supported("-std=c++11")
	//! .compile("cxxbridge-demo");
	//!
	//! println!("cargo:rerun-if-changed=src/main.rs");
	//! println!("cargo:rerun-if-changed=../demo-cxx/demo.h");
	//! println!("cargo:rerun-if-changed=../demo-cxx/demo.cc");
	//! }
	//! ```
	//!
	//! <br><br>
	//!
	//! # Non-Cargo setup
	//!
	//! For use in non-Cargo builds like Bazel or Buck, CXX provides an alternate
	//! way of invoking the C++ code generator as a standalone command line tool.
	//! The tool is packaged as the `cxxbridge-cmd` crate on crates.io or can be
	//! built from the cmd directory of [https://github.com/dtolnay/cxx].
	//!
	//! ```bash
	//! $ cargo install cxxbridge-cmd
	//!
	//! $ cxxbridge src/main.rs --header > path/to/mybridge.h
	//! $ cxxbridge src/main.rs > path/to/mybridge.cc
	//! ```
	//!
	//! <br>
	//!
	//! # Safety
	//!
	//! Be aware that the design of this library is intentionally restrictive and
	//! opinionated! It isn't a goal to be powerful enough to handle arbitrary
	//! signatures in either language. Instead this project is about carving out a
	//! reasonably expressive set of functionality about which we can make useful
	//! safety guarantees today and maybe extend over time. You may find that it
	//! takes some practice to use CXX bridge effectively as it won't work in all
	//! the ways that you are used to.
	//!
	//! Some of the considerations that go into ensuring safety are:
	//!
	//! - By design, our paired code generators work together to control both sides
	//! of the FFI boundary. Ordinarily in Rust writing your own `extern "C"`
	//! blocks is unsafe because the Rust compiler has no way to know whether the
	//! signatures you've written actually match the signatures implemented in the
	//! other language. With CXX we achieve that visibility and know what's on the
	//! other side.
	//!
	//! - Our static analysis detects and prevents passing types by value that
	//! shouldn't be passed by value from C++ to Rust, for example because they
	//! may contain internal pointers that would be screwed up by Rust's move
	//! behavior.
	//!
	//! - To many people's surprise, it is possible to have a struct in Rust and a
	//! struct in C++ with exactly the same layout / fields / alignment /
	//! everything, and still not the same ABI when passed by value. This is a
	//! longstanding bindgen bug that leads to segfaults in absolutely
	//! correct-looking code ([rust-lang/rust-bindgen#778]). CXX knows about this
	//! and can insert the necessary zero-cost workaround transparently where
	//! needed, so go ahead and pass your structs by value without worries. This
	//! is made possible by owning both sides of the boundary rather than just
	//! one.
	//!
	//! - Template instantiations: for example in order to expose a UniquePtr\<T\>
	//! type in Rust backed by a real C++ unique\_ptr, we have a way of using a
	//! Rust trait to connect the behavior back to the template instantiations
	//! performed by the other language.
	//!
	//! [rust-lang/rust-bindgen#778]: https://github.com/rust-lang/rust-bindgen/issues/778
	//!
	//! <br>
	//!
	//! # Builtin types
	//!
	//! In addition to all the primitive types (i32 <=> int32_t), the
	//! following common types may be used in the fields of shared structs and the
	//! arguments and returns of functions.
	//!
	//! <table>
	//! <tr><th>name in Rust</th><th>name in C++</th><th>restrictions</th></tr>
	//! <tr><td>String</td><td>rust::String</td><td></td></tr>
	//! <tr><td>&str</td><td>rust::Str</td><td></td></tr>
	//! <tr><td>&[u8]</td><td>rust::Slice<uint8_t></td><td><sup><i>arbitrary &[T] not implemented yet</i></sup></td></tr>
	//! <tr><td><a href="struct.CxxString.html">CxxString</a></td><td>std::string</td><td><sup><i>cannot be passed by value</i></sup></td></tr>
	//! <tr><td>Box<T></td><td>rust::Box<T></td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
	//! <tr><td><a href="struct.UniquePtr.html">UniquePtr<T></a></td><td>std::unique_ptr<T></td><td><sup><i>cannot hold opaque Rust type</i></sup></td></tr>
	//! <tr><td>Vec<T></td><td>rust::Vec<T></td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
	//! <tr><td><a href="struct.CxxVector.html">CxxVector<T></a></td><td>std::vector<T></td><td><sup><i>cannot be passed by value, cannot hold opaque Rust type</i></sup></td></tr>
	//! <tr><td>fn(T, U) -> V</td><td>rust::Fn<V(T, U)></td><td><sup><i>only passing from Rust to C++ is implemented so far</i></sup></td></tr>
	//! <tr><td>Result<T></td><td>throw/catch</td><td><sup><i>allowed as return type only</i></sup></td></tr>
	//! </table>
	//!
	//! The C++ API of the `rust` namespace is defined by the include/cxx.h file
	//! in [https://github.com/dtolnay/cxx]. You will need to include this header in
	//! your C++ code when working with those types.
	//!
	//! The following types are intended to be supported "soon" but are just not
	//! implemented yet. I don't expect any of these to be hard to make work but
	//! it's a matter of designing a nice API for each in its non-native language.
	//!
	//! <table>
	//! <tr><th>name in Rust</th><th>name in C++</th></tr>
	//! <tr><td>BTreeMap<K, V></td><td><sup><i>tbd</i></sup></td></tr>
	//! <tr><td>HashMap<K, V></td><td><sup><i>tbd</i></sup></td></tr>
	//! <tr><td>Arc<T></td><td><sup><i>tbd</i></sup></td></tr>
	//! <tr><td><sup><i>tbd</i></sup></td><td>std::map<K, V></td></tr>
	//! <tr><td><sup><i>tbd</i></sup></td><td>std::unordered_map<K, V></td></tr>
	//! <tr><td><sup><i>tbd</i></sup></td><td>std::shared_ptr<T></td></tr>
	//! </table>
	//!
	//! [https://github.com/dtolnay/cxx]: https://github.com/dtolnay/cxx

	#![doc(html_root_url = "https://docs.rs/cxx/0.3.4")]
	#![deny(improper_ctypes)]
	#![allow(non_camel_case_types)]
	#![allow(
	clippy::cognitive_complexity,
	clippy::declare_interior_mutable_const,
	clippy::inherent_to_string,
	clippy::large_enum_variant,
	clippy::len_without_is_empty,
	clippy::missing_safety_doc,
	clippy::module_inception,
	clippy::needless_doctest_main,
	clippy::new_without_default,
	clippy::or_fun_call,
	clippy::ptr_arg,
	clippy::toplevel_ref_arg,
	clippy::useless_let_if_seq
	)]

	#[macro_use]
	mod macros;

	mod cxx_string;
	mod cxx_vector;
	mod exception;
	mod extern_type;
	mod function;
	mod opaque;
	mod result;
	mod rust_sliceu8;
	mod rust_str;
	mod rust_string;
	mod rust_vec;
	mod unique_ptr;
	mod unwind;

	#[cfg(not(no_export_symbols))]
	mod symbols;

	pub use crate::cxx_string::CxxString;
	pub use crate::cxx_vector::CxxVector;
	pub use crate::exception::Exception;
	pub use crate::extern_type::ExternType;
	pub use crate::unique_ptr::UniquePtr;
	pub use cxxbridge_macro::bridge;

	/// For use in impls of the `ExternType` trait. See [`ExternType`].
	pub use cxxbridge_macro::type_id;

	// Not public API.
	#[doc(hidden)]
	pub mod private {
	pub use crate::cxx_vector::VectorElement;
	pub use crate::extern_type::verify_extern_type;
	pub use crate::function::FatFunction;
	pub use crate::opaque::Opaque;
	pub use crate::result::{r#try, Result};
	pub use crate::rust_sliceu8::RustSliceU8;
	pub use crate::rust_str::RustStr;
	pub use crate::rust_string::RustString;
	pub use crate::rust_vec::RustVec;
	pub use crate::unique_ptr::UniquePtrTarget;
	pub use crate::unwind::catch_unwind;
	}

	macro_rules! chars {
	($($ch:ident)*) => {
	$(
	#[doc(hidden)]
	pub enum $ch {}
	)*
	};
	}

	chars! {
	_0 _1 _2 _3 _4 _5 _6 _7 _8 _9
	A B C D E F G H I J K L M N O P Q R S T U V W X Y Z
	a b c d e f g h i j k l m n o p q r s t u v w x y z
	__ // underscore
	}