https://github.com/AeneasVerif/charon

Interface with the rustc compiler for the purpose of program verification
https://github.com/AeneasVerif/charon

compiler formal-methods formal-verification program-verification rust rust-lang static-analysis

Last synced: about 1 month ago
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Interface with the rustc compiler for the purpose of program verification

• Host: GitHub
• URL: https://github.com/AeneasVerif/charon
• Owner: AeneasVerif
• License: apache-2.0
• Created: 2021-10-21T13:15:47.000Z (over 2 years ago)
• Default Branch: main
• Last Pushed: 2024-04-25T15:00:48.000Z (2 months ago)
• Last Synced: 2024-04-25T15:05:50.397Z (2 months ago)
• Topics: compiler, formal-methods, formal-verification, program-verification, rust, rust-lang, static-analysis
• Language: Rust
• Homepage:
• Size: 2.36 MB
• Stars: 42
• Watchers: 4
• Forks: 13
• Open Issues: 25
• Metadata Files:
  • Readme: README.md
  • License: LICENSE.md

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• awesome-rust-formalized-reasoning - Charon - interface with the rustc compiler for the purpose of program verification. (Projects / Verification)

README

        




Patinir, E., 1515-1524, Landscape with Charon crossing the Styx [Oil on wood].

Museo del Prado, Madrid.

Source



# Charon

Charon acts as an interface between the rustc compiler and program verification projects. Its

purpose is to process Rust crates and convert them into files easy to handle by program

verifiers. It is implemented as a custom driver for the rustc compiler.

Charon is, in Greek mythology, an old man carrying the souls of the deceased accross the

Styx, a river separating the world of the living from the world of the dead. In the

present context, Charon allows us to go from the world of Rust programs to the world of

formal verification.

We are **open to contributions**! Please contact us so that we can coordinate ourselves,

if you are willing to contribute. For this purpose you can join the [Zulip](https://aeneas-verif.zulipchat.com/).

## LLBC

Charon converts MIR code to ULLBC (Unstructured Low-Level Borrow Calculus) then

to LLBC. Both ASTs can be output by Charon.

ULLBC is a slightly simplified MIR, where we try to remove as much redundancies

as possible. For instance, we drastically simplify the representation of constants coming

from the Rust compiler.

LLBC is ULLBC where we restructured the control-flow with loops, `if

... then ... else ...`, etc. instead of gotos. Consequently, we merge MIR

statements and terminators into a single LLBC statement type. We also perform

some additional modifications, some of which are listed below:

**Remark**: most of the transformations which transform the MIR to ULLBC then LLBC are

implemented by means of micro-passes. Depending on the need, we could make them optional

and control them with flags. If you want to know more about the details, see `translate`

in `src/driver.rs`, which applies the micro-passes one after the other.

**Remark**: if you want to know the full details of (U)LLBC, have a look at: `types.rs`,

`values.rs`, `expressions.rs`, `ullbc_ast.rs` and `llbc_ast.rs`.

The extracted AST is serialized in `.ullbc` and `.llbc` files (using the JSON format).

We extract a whole crate in one file.

## Project Structure

- `charon`: the Rust implementation.

- `charon-ml`: the ML library. Provides utilities to retrieve and manipulate

  the AST in OCaml (deserialization, printing, etc.).

- `tests` and `tests-polonius`: test files directories. `tests-polonius` contains

  code which requires the Polonius borrow checker.

## Installation & Build

You first need to install [`rustup`](https://www.rust-lang.org/tools/install).

As Charon is set up with cargo, rustup will automatically download and install the proper

packages upon building the project. If you only want to build the Rust project (in

`./charon`), simply run `make build-charon-rust` in the top directory.

If you also want to build the ML library (in `./charon-ml`), you will need to

install OCaml and the proper dependencies.

We suggest you to follow those [instructions](https://ocaml.org/docs/install.html),

and install OPAM on the way (same instructions).

For Charon-ML, we use **OCaml 4.13.1**: `opam switch create 4.13.1+options`

The dependencies can be installed with the following command:

```

opam install ppx_deriving visitors easy_logging zarith yojson core_unix odoc menhir

```

You can then run `make build-charon-ml` to build the ML library, or even simply

`make` to build the whole project (Rust and OCaml). Finally, you can run the

tests with `make test`.

Alternatively, you can use Nix and do `nix develop` (or use https://direnv.net/ and `direnv allow`)

and all dependencies should be made available.

## Documentation

If you run `make`, you will generate a documentation accessible from

[`doc-rust.html`](./doc-rust.html) (for the Rust project) and

[`doc-ml.html`](./doc-ml.html) (for the ML library).

## Usage

To run Charon, you should run the Charon binary from *within* the crate that you

want to compile, as if you wanted to build the crate with `cargo build`. The

Charon executable is located at `bin/charon`.

Charon will build the crate and its dependencies, then extract the AST. Charon

provides various options and flags to tweak its behaviour: you can display a

detailed documentation with `--help`.

In particular, you can print the LLBC generated by Charon with `--print-llbc`.

**Remark**: because Charon is compiled with Rust nigthly (this is a requirement

to implement a rustc driver), it will build your crate with Rust nightly. You

can find the nightly version pinned for Charon in [`rust-toolchain.template`](rust-toolchain.template).