mirror of
https://gitlab.torproject.org/tpo/core/tor.git
synced 2024-11-28 06:13:31 +01:00
524 lines
20 KiB
Markdown
524 lines
20 KiB
Markdown
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Rust Coding Standards
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=======================
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You MUST follow the standards laid out in `.../doc/HACKING/CodingStandards.md`,
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where applicable.
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Module/Crate Declarations
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---------------------------
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Each Tor C module which is being rewritten MUST be in its own crate.
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See the structure of `.../src/rust` for examples.
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In your crate, you MUST use `lib.rs` ONLY for pulling in external
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crates (e.g. `extern crate libc;`) and exporting public objects from
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other Rust modules (e.g. `pub use mymodule::foo;`). For example, if
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you create a crate in `.../src/rust/yourcrate`, your Rust code should
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live in `.../src/rust/yourcrate/yourcode.rs` and the public interface
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to it should be exported in `.../src/rust/yourcrate/lib.rs`.
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If your code is to be called from Tor C code, you MUST define a safe
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`ffi.rs`. See the "Safety" section further down for more details.
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For example, in a hypothetical `tor_addition` Rust module:
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In `.../src/rust/tor_addition/addition.rs`:
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pub fn get_sum(a: i32, b: i32) -> i32 {
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a + b
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}
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In `.../src/rust/tor_addition/lib.rs`:
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pub use addition::*;
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In `.../src/rust/tor_addition/ffi.rs`:
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#[no_mangle]
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pub extern "C" fn tor_get_sum(a: c_int, b: c_int) -> c_int {
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get_sum(a, b)
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}
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If your Rust code must call out to parts of Tor's C code, you must
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declare the functions you are calling in the `external` crate, located
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at `.../src/rust/external`.
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<!-- XXX get better examples of how to declare these externs, when/how they -->
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<!-- XXX are unsafe, what they are expected to do —isis -->
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Modules should strive to be below 500 lines (tests excluded). Single
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responsibility and limited dependencies should be a guiding standard.
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If you have any external modules as dependencies (e.g. `extern crate
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libc;`), you MUST declare them in your crate's `lib.rs` and NOT in any
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other module.
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Dependencies and versions
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---------------------------
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In general, we use modules from only the Rust standard library
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whenever possible. We will review including external crates on a
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case-by-case basis.
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If a crate only contains traits meant for compatibility between Rust
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crates, such as [the digest crate](https://crates.io/crates/digest) or
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[the failure crate](https://crates.io/crates/failure), it is very likely
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permissible to add it as a dependency. However, a brief review should
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be conducted as to the usefulness of implementing external traits
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(i.e. how widespread is the usage, how many other crates either
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implement the traits or have trait bounds based upon them), as well as
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the stability of the traits (i.e. if the trait is going to change, we'll
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potentially have to re-do all our implementations of it).
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For large external libraries, especially which implement features which
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would be labour-intensive to reproduce/maintain ourselves, such as
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cryptographic or mathematical/statistics libraries, only crates which
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have stabilised to 1.0.0 should be considered, however, again, we may
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make exceptions on a case-by-case basis.
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Currently, Tor requires that you use the latest stable Rust version. At
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some point in the future, we will freeze on a given stable Rust version,
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to ensure backward compatibility with stable distributions that ship it.
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Updating/Adding Dependencies
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------------------------------
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To add/remove/update dependencies, first add your dependencies,
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exactly specifying their versions, into the appropriate *crate-level*
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`Cargo.toml` in `src/rust/` (i.e. *not* `/src/rust/Cargo.toml`, but
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instead the one for your crate). Also, investigate whether your
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dependency has any optional dependencies which are unnecessary but are
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enabled by default. If so, you'll likely be able to enable/disable
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them via some feature, e.g.:
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```toml
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[dependencies]
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foo = { version = "1.0.0", default-features = false }
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```
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Next, run `/scripts/maint/updateRustDependencies.sh`. Then, go into
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`src/ext/rust` and commit the changes to the `tor-rust-dependencies`
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repo.
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Documentation
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---------------
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You MUST include `#[deny(missing_docs)]` in your crate.
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For function/method comments, you SHOULD include a one-sentence, "first person"
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description of function behaviour (see requirements for documentation as
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described in `.../src/HACKING/CodingStandards.md`), then an `# Inputs` section
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for inputs or initialisation values, a `# Returns` section for return
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values/types, a `# Warning` section containing warnings for unsafe behaviours or
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panics that could happen. For publicly accessible
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types/constants/objects/functions/methods, you SHOULD also include an
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`# Examples` section with runnable doctests.
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You MUST document your module with _module docstring_ comments,
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i.e. `//!` at the beginning of each line.
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Style
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-------
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You SHOULD consider breaking up large literal numbers with `_` when it makes it
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more human readable to do so, e.g. `let x: u64 = 100_000_000_000`.
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Testing
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---------
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All code MUST be unittested and integration tested.
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Public functions/objects exported from a crate SHOULD include doctests
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describing how the function/object is expected to be used.
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Integration tests SHOULD go into a `tests/` directory inside your
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crate. Unittests SHOULD go into their own module inside the module
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they are testing, e.g. in `.../src/rust/tor_addition/addition.rs` you
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should put:
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#[cfg(test)]
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mod test {
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use super::*;
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#[test]
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fn addition_with_zero() {
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let sum: i32 = get_sum(5i32, 0i32);
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assert_eq!(sum, 5);
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}
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}
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Benchmarking
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--------------
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The external `test` crate can be used for most benchmarking. However, using
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this crate requires nightly Rust. Since we may want to switch to a more
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stable Rust compiler eventually, we shouldn't do things which will automatically
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break builds for stable compilers. Therefore, you MUST feature-gate your
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benchmarks in the following manner.
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If you wish to benchmark some of your Rust code, you MUST put the
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following in the `[features]` section of your crate's `Cargo.toml`:
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[features]
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bench = []
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Next, in your crate's `lib.rs` you MUST put:
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#[cfg(all(test, feature = "bench"))]
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extern crate test;
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This ensures that the external crate `test`, which contains utilities
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for basic benchmarks, is only used when running benchmarks via `cargo
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bench --features bench`.
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Finally, to write your benchmark code, in
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`.../src/rust/tor_addition/addition.rs` you SHOULD put:
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#[cfg(all(test, features = "bench"))]
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mod bench {
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use test::Bencher;
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use super::*;
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#[bench]
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fn addition_small_integers(b: &mut Bencher) {
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b.iter(| | get_sum(5i32, 0i32));
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}
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}
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Fuzzing
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---------
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If you wish to fuzz parts of your code, please see the
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[`cargo fuzz`](https://github.com/rust-fuzz/cargo-fuzz) crate, which uses
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[libfuzzer-sys](https://github.com/rust-fuzz/libfuzzer-sys).
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Whitespace & Formatting
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-------------------------
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You MUST run `rustfmt` (https://github.com/rust-lang-nursery/rustfmt)
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on your code before your code will be merged. You can install rustfmt
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by doing `cargo install rustfmt-nightly` and then run it with `cargo
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fmt`.
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Safety
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--------
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You SHOULD read [the nomicon](https://doc.rust-lang.org/nomicon/) before writing
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Rust FFI code. It is *highly advised* that you read and write normal Rust code
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before attempting to write FFI or any other unsafe code.
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Here are some additional bits of advice and rules:
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0. Any behaviours which Rust considers to be undefined are forbidden
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From https://doc.rust-lang.org/reference/behavior-considered-undefined.html:
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> Behavior considered undefined
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>
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> The following is a list of behavior which is forbidden in all Rust code,
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> including within unsafe blocks and unsafe functions. Type checking provides the
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> guarantee that these issues are never caused by safe code.
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>
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> * Data races
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> * Dereferencing a null/dangling raw pointer
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> * Reads of [undef](http://llvm.org/docs/LangRef.html#undefined-values)
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> (uninitialized) memory
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> * Breaking the
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> [pointer aliasing rules](http://llvm.org/docs/LangRef.html#pointer-aliasing-rules)
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> with raw pointers (a subset of the rules used by C)
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> * `&mut T` and `&T` follow LLVM’s scoped noalias model, except if the `&T`
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> contains an `UnsafeCell<U>`. Unsafe code must not violate these aliasing
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> guarantees.
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> * Mutating non-mutable data (that is, data reached through a shared
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> reference or data owned by a `let` binding), unless that data is
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> contained within an `UnsafeCell<U>`.
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> * Invoking undefined behavior via compiler intrinsics:
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> - Indexing outside of the bounds of an object with
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> `std::ptr::offset` (`offset` intrinsic), with the exception of
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> one byte past the end which is permitted.
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> - Using `std::ptr::copy_nonoverlapping_memory` (`memcpy32`/`memcpy64`
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> intrinsics) on overlapping buffers
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> * Invalid values in primitive types, even in private fields/locals:
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> - Dangling/null references or boxes
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> - A value other than `false` (0) or `true` (1) in a `bool`
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> - A discriminant in an `enum` not included in the type definition
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> - A value in a `char` which is a surrogate or above `char::MAX`
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> - Non-UTF-8 byte sequences in a `str`
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> * Unwinding into Rust from foreign code or unwinding from Rust into foreign
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> code. Rust's failure system is not compatible with exception handling in other
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> languages. Unwinding must be caught and handled at FFI boundaries.
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1. `unwrap()`
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If you call `unwrap()`, anywhere, even in a test, you MUST include
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an inline comment stating how the unwrap will either 1) never fail,
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or 2) should fail (i.e. in a unittest).
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You SHOULD NOT use `unwrap()` anywhere in which it is possible to handle the
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potential error with either `expect()` or the eel operator, `?`.
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For example, consider a function which parses a string into an integer:
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fn parse_port_number(config_string: &str) -> u16 {
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u16::from_str_radix(config_string, 10).unwrap()
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}
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There are numerous ways this can fail, and the `unwrap()` will cause the
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whole program to byte the dust! Instead, either you SHOULD use `expect()`
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(or another equivalent function which will return an `Option` or a `Result`)
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and change the return type to be compatible:
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fn parse_port_number(config_string: &str) -> Option<u16> {
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u16::from_str_radix(config_string, 10).expect("Couldn't parse port into a u16")
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}
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or you SHOULD use `or()` (or another similar method):
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fn parse_port_number(config_string: &str) -> Option<u16> {
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u16::from_str_radix(config_string, 10).or(Err("Couldn't parse port into a u16")
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}
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Using methods like `or()` can be particularly handy when you must do
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something afterwards with the data, for example, if we wanted to guarantee
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that the port is high. Combining these methods with the eel operator (`?`)
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makes this even easier:
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fn parse_port_number(config_string: &str) -> Result<u16, Err> {
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let port = u16::from_str_radix(config_string, 10).or(Err("Couldn't parse port into a u16"))?;
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if port > 1024 {
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return Ok(port);
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} else {
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return Err("Low ports not allowed");
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}
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}
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2. `unsafe`
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If you use `unsafe`, you MUST describe a contract in your
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documentation which describes how and when the unsafe code may
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fail, and what expectations are made w.r.t. the interfaces to
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unsafe code. This is also REQUIRED for major pieces of FFI between
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C and Rust.
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When creating an FFI in Rust for C code to call, it is NOT REQUIRED
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to declare the entire function `unsafe`. For example, rather than doing:
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#[no_mangle]
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pub unsafe extern "C" fn increment_and_combine_numbers(mut numbers: [u8; 4]) -> u32 {
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for number in &mut numbers {
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*number += 1;
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}
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std::mem::transmute::<[u8; 4], u32>(numbers)
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}
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You SHOULD instead do:
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#[no_mangle]
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pub extern "C" fn increment_and_combine_numbers(mut numbers: [u8; 4]) -> u32 {
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for index in 0..numbers.len() {
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numbers[index] += 1;
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}
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unsafe {
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std::mem::transmute::<[u8; 4], u32>(numbers)
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}
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}
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3. Pass only C-compatible primitive types and bytes over the boundary
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Rust's C-compatible primitive types are integers and floats.
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These types are declared in the [libc crate](https://doc.rust-lang.org/libc/x86_64-unknown-linux-gnu/libc/index.html#types).
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Most Rust objects have different [representations](https://doc.rust-lang.org/libc/x86_64-unknown-linux-gnu/libc/index.html#types)
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in C and Rust, so they can't be passed using FFI.
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Tor currently uses the following Rust primitive types from libc for FFI:
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* defined-size integers: `uint32_t`
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* native-sized integers: `c_int`
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* native-sized floats: `c_double`
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* native-sized raw pointers: `* c_void`, `* c_char`, `** c_char`
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TODO: C smartlist to Stringlist conversion using FFI
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The only non-primitive type which may cross the FFI boundary is
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bytes, e.g. `&[u8]`. This SHOULD be done on the Rust side by
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passing a pointer (`*mut libc::c_char`). The length can be passed
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explicitly (`libc::size_t`), or the string can be NUL-byte terminated
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C string.
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One might be tempted to do this via doing
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`CString::new("blah").unwrap().into_raw()`. This has several problems:
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a) If you do `CString::new("bl\x00ah")` then the unwrap() will fail
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due to the additional NULL terminator, causing a dangling
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pointer to be returned (as well as a potential use-after-free).
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b) Returning the raw pointer will cause the CString to run its deallocator,
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which causes any C code which tries to access the contents to dereference a
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NULL pointer.
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c) If we were to do `as_raw()` this would result in a potential double-free
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since the Rust deallocator would run and possibly Tor's deallocator.
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d) Calling `into_raw()` without later using the same pointer in Rust to call
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`from_raw()` and then deallocate in Rust can result in a
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[memory leak](https://doc.rust-lang.org/std/ffi/struct.CString.html#method.into_raw).
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[It was determined](https://github.com/rust-lang/rust/pull/41074) that this
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is safe to do if you use the same allocator in C and Rust and also specify
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the memory alignment for CString (except that there is no way to specify
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the alignment for CString). It is believed that the alignment is always 1,
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which would mean it's safe to dealloc the resulting `*mut c_char` in Tor's
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C code. However, the Rust developers are not willing to guarantee the
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stability of, or a contract for, this behaviour, citing concerns that this
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is potentially extremely and subtly unsafe.
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4. Perform an allocation on the other side of the boundary
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After crossing the boundary, the other side MUST perform an
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allocation to copy the data and is therefore responsible for
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freeing that memory later.
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5. No touching other language's enums
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Rust enums should never be touched from C (nor can they be safely
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`#[repr(C)]`) nor vice versa:
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> "The chosen size is the default enum size for the target platform's C
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> ABI. Note that enum representation in C is implementation defined, so this is
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> really a "best guess". In particular, this may be incorrect when the C code
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> of interest is compiled with certain flags."
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(from https://gankro.github.io/nomicon/other-reprs.html)
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6. Type safety
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Wherever possible and sensical, you SHOULD create new types in a
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manner which prevents type confusion or misuse. For example,
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rather than using an untyped mapping between strings and integers
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like so:
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use std::collections::HashMap;
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pub fn get_elements_with_over_9000_points(map: &HashMap<String, usize>) -> Vec<String> {
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...
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}
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It would be safer to define a new type, such that some other usage
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of `HashMap<String, usize>` cannot be confused for this type:
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pub struct DragonBallZPowers(pub HashMap<String, usize>);
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impl DragonBallZPowers {
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pub fn over_nine_thousand<'a>(&'a self) -> Vec<&'a String> {
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let mut powerful_enough: Vec<&'a String> = Vec::with_capacity(5);
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for (character, power) in &self.0 {
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if *power > 9000 {
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powerful_enough.push(character);
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}
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}
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powerful_enough
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}
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}
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Note the following code, which uses Rust's type aliasing, is valid
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but it does NOT meet the desired type safety goals:
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pub type Power = usize;
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pub fn over_nine_thousand(power: &Power) -> bool {
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if *power > 9000 {
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return true;
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}
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false
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}
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// We can still do the following:
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let his_power: usize = 9001;
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over_nine_thousand(&his_power);
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7. Unsafe mucking around with lifetimes
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Because lifetimes are technically, in type theory terms, a kind, i.e. a
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family of types, individual lifetimes can be treated as types. For example,
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one can arbitrarily extend and shorten lifetime using `std::mem::transmute`:
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struct R<'a>(&'a i32);
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unsafe fn extend_lifetime<'b>(r: R<'b>) -> R<'static> {
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std::mem::transmute::<R<'b>, R<'static>>(r)
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}
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unsafe fn shorten_invariant_lifetime<'b, 'c>(r: &'b mut R<'static>) -> &'b mut R<'c> {
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std::mem::transmute::<&'b mut R<'static>, &'b mut R<'c>>(r)
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}
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Calling `extend_lifetime()` would cause an `R` passed into it to live forever
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for the life of the program (the `'static` lifetime). Similarly,
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`shorten_invariant_lifetime()` could be used to take something meant to live
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forever, and cause it to disappear! This is incredibly unsafe. If you're
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going to be mucking around with lifetimes like this, first, you better have
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an extremely good reason, and second, you may as be honest and explicit about
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it, and for ferris' sake just use a raw pointer.
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In short, just because lifetimes can be treated like types doesn't mean you
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should do it.
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8. Doing excessively unsafe things when there's a safer alternative
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Similarly to #7, often there are excessively unsafe ways to do a task and a
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simpler, safer way. You MUST choose the safer option where possible.
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For example, `std::mem::transmute` can be abused in ways where casting with
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`as` would be both simpler and safer:
|
||
|
||
// Don't do this
|
||
let ptr = &0;
|
||
let ptr_num_transmute = unsafe { std::mem::transmute::<&i32, usize>(ptr)};
|
||
|
||
// Use an `as` cast instead
|
||
let ptr_num_cast = ptr as *const i32 as usize;
|
||
|
||
In fact, using `std::mem::transmute` for *any* reason is a code smell and as
|
||
such SHOULD be avoided.
|
||
|
||
9. Casting integers with `as`
|
||
|
||
This is generally fine to do, but it has some behaviours which you should be
|
||
aware of. Casting down chops off the high bits, e.g.:
|
||
|
||
let x: u32 = 4294967295;
|
||
println!("{}", x as u16); // prints 65535
|
||
|
||
Some cases which you MUST NOT do include:
|
||
|
||
* Casting an `u128` down to an `f32` or vice versa (e.g.
|
||
`u128::MAX as f32` but this isn't only a problem with overflowing
|
||
as it is also undefined behaviour for `42.0f32 as u128`),
|
||
|
||
* Casting between integers and floats when the thing being cast
|
||
cannot fit into the type it is being casted into, e.g.:
|
||
|
||
println!("{}", 42949.0f32 as u8); // prints 197 in debug mode and 0 in release
|
||
println!("{}", 1.04E+17 as u8); // prints 0 in both modes
|
||
println!("{}", (0.0/0.0) as i64); // prints whatever the heck LLVM wants
|
||
|
||
Because this behaviour is undefined, it can even produce segfaults in
|
||
safe Rust code. For example, the following program built in release
|
||
mode segfaults:
|
||
|
||
#[inline(never)]
|
||
pub fn trigger_ub(sl: &[u8; 666]) -> &[u8] {
|
||
// Note that the float is out of the range of `usize`, invoking UB when casting.
|
||
let idx = 1e99999f64 as usize;
|
||
&sl[idx..] // The bound check is elided due to `idx` being of an undefined value.
|
||
}
|
||
|
||
fn main() {
|
||
println!("{}", trigger_ub(&[1; 666])[999999]); // ~ out of bound
|
||
}
|
||
|
||
And in debug mode panics with:
|
||
|
||
thread 'main' panicked at 'slice index starts at 140721821254240 but ends at 666', /checkout/src/libcore/slice/mod.rs:754:4
|