CXX — safe FFI between Rust and C++
=========================================
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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.
```toml
[dependencies]
cxx = "1.0"
[build-dependencies]
cxx-build = "1.0"
```
*Compiler support: requires rustc 1.70+ and c++11 or newer*<br>
*[Release notes](https://github.com/dtolnay/cxx/releases)*
<br>
## Guide
Please see **<https://cxx.rs>** for a tutorial, reference material, and example
code.
<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 manipulating a Rust string from C++, its `size()` member
function calls Rust's `len()`.
<br>
## Example
In this example we are writing a Rust application that wishes to take advantage
of an existing C++ client for a large-file blobstore service. The blobstore
supports a `put` operation for a discontiguous buffer upload. For example we
might be uploading snapshots of a circular buffer which would tend to consist of
2 chunks, or fragments of a file spread across memory for some other reason.
A runnable version of this example is provided under the *demo* directory of
this repo. To try it out, run `cargo run` from that directory.
```rust
#[cxx::bridge]
mod ffi {
// Any shared structs, whose fields will be visible to both languages.
struct BlobMetadata {
size: usize,
tags: Vec<String>,
}
extern "Rust" {
// Zero or more opaque types which both languages can pass around but
// only Rust can see the fields.
type MultiBuf;
// Functions implemented in Rust.
fn next_chunk(buf: &mut MultiBuf) -> &[u8];
}
unsafe 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/include/blobstore.h");
// Zero or more opaque types which both languages can pass around but
// only C++ can see the fields.
type BlobstoreClient;
// Functions implemented in C++.
fn new_blobstore_client() -> UniquePtr<BlobstoreClient>;
fn put(&self, parts: &mut MultiBuf) -> u64;
fn tag(&self, blobid: u64, tag: &str);
fn metadata(&self, blobid: u64) -> BlobMetadata;
}
}
```
Now we simply provide Rust definitions of all the things in the `extern "Rust"`
block and C++ definitions of all the things in the `extern "C++"` block, and get
to call back and forth safely.
Here are links to the complete set of source files involved in the demo:
- [demo/src/main.rs](demo/src/main.rs)
- [demo/build.rs](demo/build.rs)
- [demo/include/blobstore.h](demo/include/blobstore.h)
- [demo/src/blobstore.cc](demo/src/blobstore.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/Cargo.toml
# run C++ code generator and print to stdout
$ cargo run --manifest-path gen/cmd/Cargo.toml -- demo/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 "Rust"` part of the CXX bridge we list the 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::MultiBuf` and
`use super::next_chunk` 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.
Within the `extern "C++"` part, we list 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.
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 = "1.0"
```
```rust
// build.rs
fn main() {
cxx_build::bridge("src/main.rs") // returns a cc::Build
.file("src/demo.cc")
.std("c++11")
.compile("cxxbridge-demo");
println!("cargo:rerun-if-changed=src/main.rs");
println!("cargo:rerun-if-changed=src/demo.cc");
println!("cargo:rerun-if-changed=include/demo.h");
}
```
<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
*gen/cmd* directory of this repo.
```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>&[T]</td><td>rust::Slice<const T></td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
<tr><td>&mut [T]</td><td>rust::Slice<T></td><td><sup><i>cannot hold opaque C++ type</i></sup></td></tr>
<tr><td><a href="https://docs.rs/cxx/1.0/cxx/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="https://docs.rs/cxx/1.0/cxx/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><a href="https://docs.rs/cxx/1.0/cxx/struct.SharedPtr.html">SharedPtr<T></a></td><td>std::shared_ptr<T></td><td><sup><i>cannot hold opaque Rust type</i></sup></td></tr>
<tr><td>[T; N]</td><td>std::array<T, N></td><td><sup><i>cannot hold opaque C++ 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="https://docs.rs/cxx/1.0/cxx/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>*mut T, *const T</td><td>T*, const T*</td><td><sup><i>fn with a raw pointer argument must be declared unsafe to call</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
this repo. 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>Option<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>
</table>
<br>
## Remaining work
This is still early days for CXX; I am releasing it as a minimum viable product
to collect feedback on the direction and invite collaborators. Please check the
open issues.
Especially please report issues if you run into trouble building or linking any
of this stuff. I'm sure there are ways to make the build aspects friendlier or
more robust.
Finally, I know more about Rust library design than C++ library design so I
would appreciate help making the C++ APIs in this project more idiomatic where
anyone has suggestions.
<br>
#### License
<sup>
Licensed under either of <a href="LICENSE-APACHE">Apache License, Version
2.0</a> or <a href="LICENSE-MIT">MIT license</a> at your option.
</sup>
<br>
<sub>
Unless you explicitly state otherwise, any contribution intentionally submitted
for inclusion in this project by you, as defined in the Apache-2.0 license,
shall be dual licensed as above, without any additional terms or conditions.
</sub>