The unique approach of the Rust programming language results in better code with fewer compromises than C, C++, Go, and the other languages you probably use. It also gets updated regularly, often every month.
Where to download the latest Rust version
If you already have a previous version of Rust installed via rustup, you can access the latest version via the following command:
$ rustup update stable
The new features in Rust 1.64
Rust 1.64.0, unveiled September 22, stabilizes the
IntoFuture trait, to enhance
.await and improve APIs.
IntoFuture is similar to the
IntoIterator trait, but instead of supporting
for … in … loops,
IntoFuture changes how
.await keyword can await more than just features; it can await anything that can be converted into a
IntoFuture, to help make APIs more user-friendly. For the future, the developers of Rust hope to simplify development of new named futures by supporting
impl Trait in
type aliases. This should make implementing
IntoFuture easier by simplifying the
type alias signature and make it more performant by removing the
Box from the
Also in Rust 1.64:
- The language provides all
c_*type aliases in
core::ffi, as well as
core::ffi::CStr, for working with C strings. Rust 1.64 also provides
alloc::ffi::CStringfor working with owned C strings using only the
alloccrate rather than the full
- rust-analyzer, an implementation of the Language Server protocol for Rust, now is included as part of the collection of tools included with Rust. This makes it easier to download and access rust-analyzer and makes it available on more platforms. The tool is available as a rustup component and can be installed with the command
rustup component add rust_analyzer.
- When working with collections of related libraries or binary crates in one Cargo workspace, developers now can avoid duplication of common field values between crates, such as common version numbers or repository URLs.
- The memory layouts of
SocketAddrV6have been changed to be more memory efficient and compact.
- Windows builds of the Rust compiler now use profile-guided optimization, improving performance.
- A number of methods and trait implementations have been stabilized, including
num::NonZero*::checked_pow, and many others.
The new features in Rust 1.63
Published August 11, Rust 1.63 adds scoped threads to the standard library. Scoped threads allow you to spawn a thread by borrowing from the local stack frame. The
std::thread::scope API provides a guarantee that any spawned threads will have exited prior to its returning, allowing for safely borrowing data. Rust 1.63 also enables non-lexical lifetimes (NLL) by default; the feature is now fully stable. NLL is the second iteration of Rust’s borrow checker.
Also in Rust 1.63:
- For I/O safety, wrapper types are provided such as
OwnedFD, which are marked as
#[repr(transparent)], meaning that
extern "C"bindings can take these types to encode ownership semantics.
RwLock::newfunctions are now callable in
constcontexts, to avoid the use of crates such as lazy_static for creating global statics with
Condvar. This builds on work in Rust 1.62 to enable faster and thinner mutexes.
- A number of APIs were stabilized including
The new features in Rust 1.62
Rust 1.62, which arrived June 30, lets developers add dependencies directly from the command line using
cargo add. This command supports specifying versions and features and also can modify existing dependencies. Rust 1.62 also allows the use of #[derive(Default)] on enums if a default variant is specified.
Other new capabilities in Rust 1.62:
- Rust’s standard library now ships with a raw futex-based implementation of locks on Linux, which is lightweight and does not carry any extra allocation. This addition is part of an effort to improve the efficiency of Rust lock types.
- It is now easier to build OS-less binaries for x86_64, for example when writing a kernel. The x86_64-unknown-none target has been promoted to Tier 2 and can be installed with rustup.
- A number of APIs have been stabilized including bool::then_some, f32::total_cmp, f64::total_cmp, and Stdin::lines.
The new features in Rust 1.61
Published May 19, Rust 1.61 highlights custom exit codes from
main. Rust proponents said that in the beginning, Rust
main functions only could return the unit type
() either implicitly or explicitly, indicating success in the exit status, and if developers wanted otherwise, they had to call
process::exit. Since Rust 1.26,
main has been allowed to return a
Ok translated to a C
EXIT_Failure. These alternate return types were unified by an unstable Termination trait. In this release,
Termination trait is stable, along with a more-general
ExitCode type that wraps platform-specific return types. The
Termination trait also can be implemented for a developer’s own types, allowing for customization of reporting before converting to an
Also in Version 1.61:
- Several incremental features have been stabilized to enable more functionality in
const. Developers now can create, pass, and cast function pointers in a
const fn, which could be useful to build compile-time function tables for an interpreter. But it is still not permitted to call
fnpointers. Developers also now can write trait bounds on generic parameters to
const fn, such as
T: Copy, where previously only
Sizedwas permitted. Also,
const fnnow can deal with trait objects, whereas arguments and return values for
const fncan be opaque
- APIs have been stabilized such as
- Previously, the creation of locked handles to
stdin/stdlout/stderrwould borrow the handles being locked, which prevented writing
let out = std::io::stdout().lock();because
outwould outlive the return value of
stdout(). This code now works, eliminating a common pitfall affecting many Rust users.
The new features in Rust 1.60.0
Rust 1.60, introduced April 7, 2022, stabilizes support for LLVM-based coverage instrumentation in
rustc. This provides for source-based code coverage. Developers can try this out by rebuilding their code with
-Cinstrument-coverage. Afterward, running the resulting binary will produce a default.profraw file in the current directory.
llvm-tools-preview component includes
llvm-profdata for processing and merging raw profile output,
llvm-profdata for processing raw file output, and
llvm-cov for report generation. Baseline functionality is stable and will exist in all future Rust releases, but the specific output format and LLVM tools that produce it are subject to change. Developers should use the same version for both
llvm-tools-preview and the
rustc binary used to compile code.
Rust 1.60 also re-enables incremental compilation. The Rust team continues to work on fixing bugs in incremental but no problems causing widespread breakage are known at this time.
Also in Rust 1.60:
- On all platforms,
Instantwill try to use an operating system API that guarantees monotonic behavior if available. In practice, such guarantees are, under rare circumstances, broken by hardware, virtualization, or operating system bugs. To work around these bugs, and to work with platforms that lack monotonic clocks,
Instant::subnow saturate to zero. In older versions of Rust, this led to a panic, instead.
- Cargo has established support for collecting information on build with the
- Namespaced dependencies and weak dependency features have been introduced to improve support for Cargo features and how they interact with optional dependencies. Cargo features provide a mechanism to express conditional compilation and optional dependencies.
- A number of APIs have been stabilized such as
The new features in Rust 1.59.0
Rust 1.59.0 was announced on February 24. A key feature is support for inline assembly, enabling many applications that need very low-level control over execution or access to specialized machine instructions. Assembly language and instructions available with inline assembly vary according to architecture. The capability currently is supported on architectures including x86 and x64, ARM, Risc-V, and AArch64.
Other new features and improvements in Rust 1.59.0:
- Developers now can use slice, tuple, and struct patterns as the left-hand side of an assignment, making assignment more consistent with
letbindings, which already support these patterns.
- Generic types now can specify default values for
- The Cargo package manager now shows warnings when a dependency will be rejected by a future version of Rust.
- For the creation of stripped binaries, cargo and rustc now support stripping when the binary is linked. Rust’s developers said it is often useful to strip unnecessary information like buginfo from binaries that are distributed, making them smaller.
- Incremental compilation is off by default. This mitigates the effect of a known bug that causes deserialization errors. A fix for this bug will be available in the Rust 1.60 beta due in six weeks.
- A number of APIs have been stabilized.
The new features in Rust 1.58.1
This point release arriving January 20, 2022, just days after Rust 1.58, fixes a race condition in the
std::fs::remove_dir_all standard library function. This vulnerability is tracked at CVE-2022-21658 and there was an advisory published. An attacker could use this security issue to trick a privileged program into deleting files and directories that the attacker otherwise could not access or delete. Rust versions 1.0 through 1.58 are affected by this vulnerability. Users are advised to update their toolchains and build programs with the updated compiler.
Rust 1.58.1 also addresses several regressions in diagnostics and tools introduced in Rust 1.58:
non_send_fields_in_send_tyClippy lint was found to have too many false positives and has been moved to the experimental lints group called “nursery”.
useless_formatClippy lint was updated to handle captured identifiers in format strings, introduced in Rust 1.58.
- A regression in
Rustfmtpreventing generated files from being formatted when passed through the standard input has been fixed.
- An incorrect error message displayed by
rustcin some cases has been fixed.
The new features in Rust 1.58
Rust 1.58, announced January 13, features captured identifiers in format strings. With this capability, format strings now can capture arguments by writing
ident in the string. Formats long have accepted positional arguments and named arguments, such as:
println!("Hello, !", get_person()); // implicit position
println!("Hello, 0!", get_person()); // explicit index
println!("Hello, person!", person = get_person()); // named
Now, named arguments also can be captured from the surrounding scope.
Also new in Rust 1.58: On Windows targets,
std::process::Command will no longer search the current directory for executables, which was an effect of the historical behavior of the win32
CreateProcess API. This fixes a situation in which searches could lead to surprising behavior or malicious results when dealing with untrusted directories.
Rust 1.58 also introduces more
#[must_use] in the standard library. The
#[must use] attribute can be applied to types or functions when failing to explicitly consider them or their output is almost certainly a bug. Rust 1.58 also has stabilized APIs such as
The new features in Rust 1.57
Rust 1.57, unveiled December 2, brings
panic! (for terminating a program in an unrecoverable state) to
const contexts. Previously, the
panic! macro was not usable in
const fn and other compile-time contexts. This has now been stabilized. Together with the stabilization of
panic!, several other standard libraries now are usable in
const, such as
assert!. But this stabilization does not yet include the full formatting infrastructure. The
panic! macro must be called with either a static string or a single interpolated value to be used with
. This support is expected to expand in the future.
Other new features and improvements in Rust 1.57:
- Cargo adds support for arbitrarily named profiles.
try_reservehas been stabilized for
VecDeque. This API enables callers to fallibly allocate backing storage for these types.
- Multiple other APIs have been stabilized including
- Macro attributes now may follow
#deriveand will see the original input.