What is rustc?
Welcome to "The rustc book"! rustc
is the compiler for the Rust programming
language, provided by the project itself. Compilers take your source code and
produce binary code, either as a library or executable.
Most Rust programmers don't invoke rustc
directly, but instead do it through
Cargo. It's all in service of rustc
though! If you
want to see how Cargo calls rustc
, you can
$ cargo build --verbose
And it will print out each rustc
invocation. This book can help you
understand what each of these options does. Additionally, while most
Rustaceans use Cargo, not all do: sometimes they integrate rustc
into other
build systems. This book should provide a guide to all of the options you'd
need to do so.
Basic usage
Let's say you've got a little hello world program in a file hello.rs
:
fn main() { println!("Hello, world!"); }
To turn this source code into an executable, you can use rustc
:
$ rustc hello.rs
$ ./hello # on a *NIX
$ .\hello.exe # on Windows
Note that we only ever pass rustc
the crate root, not every file we wish
to compile. For example, if we had a main.rs
that looked like this:
mod foo;
fn main() {
foo::hello();
}
And a foo.rs
that had this:
#![allow(unused)] fn main() { pub fn hello() { println!("Hello, world!"); } }
To compile this, we'd run this command:
$ rustc main.rs
No need to tell rustc
about foo.rs
; the mod
statements give it
everything that it needs. This is different than how you would use a C
compiler, where you invoke the compiler on each file, and then link
everything together. In other words, the crate is a translation unit, not a
particular module.
Command-line Arguments
Here's a list of command-line arguments to rustc
and what they do.
-h
/--help
: get help
This flag will print out help information for rustc
.
--cfg
: configure the compilation environment
This flag can turn on or off various #[cfg]
settings for conditional
compilation.
The value can either be a single identifier or two identifiers separated by =
.
For examples, --cfg 'verbose'
or --cfg 'feature="serde"'
. These correspond
to #[cfg(verbose)]
and #[cfg(feature = "serde")]
respectively.
-L
: add a directory to the library search path
The -L
flag adds a path to search for external crates and libraries.
The kind of search path can optionally be specified with the form -L KIND=PATH
where KIND
may be one of:
dependency
— Only search for transitive dependencies in this directory.crate
— Only search for this crate's direct dependencies in this directory.native
— Only search for native libraries in this directory.framework
— Only search for macOS frameworks in this directory.all
— Search for all library kinds in this directory. This is the default ifKIND
is not specified.
-l
: link the generated crate to a native library
Syntax: -l [KIND[:MODIFIERS]=]NAME[:RENAME]
.
This flag allows you to specify linking to a specific native library when building a crate.
The kind of library can optionally be specified with the form -l KIND=lib
where KIND
may be one of:
dylib
— A native dynamic library.static
— A native static library (such as a.a
archive).framework
— A macOS framework.
If the kind is specified, then linking modifiers can be attached to it.
Modifiers are specified as a comma-delimited string with each modifier prefixed with
either a +
or -
to indicate that the modifier is enabled or disabled, respectively.
Specifying multiple modifiers
arguments in a single link
attribute,
or multiple identical modifiers in the same modifiers
argument is not currently supported.
Example: -l static:+whole-archive=mylib
.
The kind of library and the modifiers can also be specified in a #[link]
attribute. If the kind is not specified in the link
attribute or on the command-line, it will link a dynamic library if available,
otherwise it will use a static library. If the kind is specified on the
command-line, it will override the kind specified in a link
attribute.
The name used in a link
attribute may be overridden using the form -l ATTR_NAME:LINK_NAME
where ATTR_NAME
is the name in the link
attribute,
and LINK_NAME
is the name of the actual library that will be linked.
Linking modifiers: whole-archive
This modifier is only compatible with the static
linking kind.
Using any other kind will result in a compiler error.
+whole-archive
means that the static library is linked as a whole archive
without throwing any object files away.
This modifier translates to --whole-archive
for ld
-like linkers,
to /WHOLEARCHIVE
for link.exe
, and to -force_load
for ld64
.
The modifier does nothing for linkers that don't support it.
The default for this modifier is -whole-archive
.
NOTE: The default may currently be different in some cases for backward compatibility,
but it is not guaranteed. If you need whole archive semantics use +whole-archive
explicitly.
Linking modifiers: bundle
This modifier is only compatible with the static
linking kind.
Using any other kind will result in a compiler error.
When building a rlib or staticlib +bundle
means that the native static library
will be packed into the rlib or staticlib archive, and then retrieved from there
during linking of the final binary.
When building a rlib -bundle
means that the native static library is registered as a dependency
of that rlib "by name", and object files from it are included only during linking of the final
binary, the file search by that name is also performed during final linking.
When building a staticlib -bundle
means that the native static library is simply not included
into the archive and some higher level build system will need to add it later during linking of
the final binary.
This modifier has no effect when building other targets like executables or dynamic libraries.
The default for this modifier is +bundle
.
--crate-type
: a list of types of crates for the compiler to emit
This instructs rustc
on which crate type to build. This flag accepts a
comma-separated list of values, and may be specified multiple times. The valid
crate types are:
lib
— Generates a library kind preferred by the compiler, currently defaults torlib
.rlib
— A Rust static library.staticlib
— A native static library.dylib
— A Rust dynamic library.cdylib
— A native dynamic library.bin
— A runnable executable program.proc-macro
— Generates a format suitable for a procedural macro library that may be loaded by the compiler.
The crate type may be specified with the crate_type
attribute.
The --crate-type
command-line value will override the crate_type
attribute.
More details may be found in the linkage chapter of the reference.
--crate-name
: specify the name of the crate being built
This informs rustc
of the name of your crate.
--edition
: specify the edition to use
This flag takes a value of 2015
, 2018
or 2021
. The default is 2015
. More
information about editions may be found in the edition guide.
--emit
: specifies the types of output files to generate
This flag controls the types of output files generated by the compiler. It accepts a comma-separated list of values, and may be specified multiple times. The valid emit kinds are:
asm
— Generates a file with the crate's assembly code. The default output filename isCRATE_NAME.s
.dep-info
— Generates a file with Makefile syntax that indicates all the source files that were loaded to generate the crate. The default output filename isCRATE_NAME.d
.link
— Generates the crates specified by--crate-type
. The default output filenames depend on the crate type and platform. This is the default if--emit
is not specified.llvm-bc
— Generates a binary file containing the LLVM bitcode. The default output filename isCRATE_NAME.bc
.llvm-ir
— Generates a file containing LLVM IR. The default output filename isCRATE_NAME.ll
.metadata
— Generates a file containing metadata about the crate. The default output filename islibCRATE_NAME.rmeta
.mir
— Generates a file containing rustc's mid-level intermediate representation. The default output filename isCRATE_NAME.mir
.obj
— Generates a native object file. The default output filename isCRATE_NAME.o
.
The output filename can be set with the -o
flag. A
suffix may be added to the filename with the -C extra-filename
flag. The files are written to the
current directory unless the --out-dir
flag is used. Each
emission type may also specify the output filename with the form KIND=PATH
,
which takes precedence over the -o
flag.
--print
: print compiler information
This flag prints out various information about the compiler. This flag may be
specified multiple times, and the information is printed in the order the
flags are specified. Specifying a --print
flag will usually disable the
--emit
step and will only print the requested information.
The valid types of print values are:
crate-name
— The name of the crate.file-names
— The names of the files created by thelink
emit kind.sysroot
— Path to the sysroot.target-libdir
- Path to the target libdir.cfg
— List of cfg values. See conditional compilation for more information about cfg values.target-list
— List of known targets. The target may be selected with the--target
flag.target-cpus
— List of available CPU values for the current target. The target CPU may be selected with the-C target-cpu=val
flag.target-features
— List of available target features for the current target. Target features may be enabled with the-C target-feature=val
flag. This flag is unsafe. See known issues for more details.relocation-models
— List of relocation models. Relocation models may be selected with the-C relocation-model=val
flag.code-models
— List of code models. Code models may be selected with the-C code-model=val
flag.tls-models
— List of Thread Local Storage models supported. The model may be selected with the-Z tls-model=val
flag.native-static-libs
— This may be used when creating astaticlib
crate type. If this is the only flag, it will perform a full compilation and include a diagnostic note that indicates the linker flags to use when linking the resulting static library. The note starts with the textnative-static-libs:
to make it easier to fetch the output.link-args
— This flag does not disable the--emit
step. When linking, this flag causesrustc
to print the full linker invocation in a human-readable form. This can be useful when debugging linker options. The exact format of this debugging output is not a stable guarantee, other than that it will include the linker executable and the text of each command-line argument passed to the linker.
-g
: include debug information
A synonym for -C debuginfo=2
.
-O
: optimize your code
A synonym for -C opt-level=2
.
-o
: filename of the output
This flag controls the output filename.
--out-dir
: directory to write the output in
The outputted crate will be written to this directory. This flag is ignored if
the -o
flag is used.
--explain
: provide a detailed explanation of an error message
Each error of rustc
's comes with an error code; this will print
out a longer explanation of a given error.
--test
: build a test harness
When compiling this crate, rustc
will ignore your main
function
and instead produce a test harness. See the Tests chapter
for more information about tests.
--target
: select a target triple to build
This controls which target to produce.
-W
: set lint warnings
This flag will set which lints should be set to the warn level.
Note: The order of these lint level arguments is taken into account, see lint level via compiler flag for more information.
--force-warn
: force a lint to warn
This flag sets the given lint to the forced warn level and the level cannot be overridden, even ignoring the lint caps.
-A
: set lint allowed
This flag will set which lints should be set to the allow level.
Note: The order of these lint level arguments is taken into account, see lint level via compiler flag for more information.
-D
: set lint denied
This flag will set which lints should be set to the deny level.
Note: The order of these lint level arguments is taken into account, see lint level via compiler flag for more information.
-F
: set lint forbidden
This flag will set which lints should be set to the forbid level.
Note: The order of these lint level arguments is taken into account, see lint level via compiler flag for more information.
-Z
: set unstable options
This flag will allow you to set unstable options of rustc. In order to set multiple options,
the -Z flag can be used multiple times. For example: rustc -Z verbose -Z time-passes
.
Specifying options with -Z is only available on nightly. To view all available options
run: rustc -Z help
, or see The Unstable Book.
--cap-lints
: set the most restrictive lint level
This flag lets you 'cap' lints, for more, see here.
-C
/--codegen
: code generation options
This flag will allow you to set codegen options.
-V
/--version
: print a version
This flag will print out rustc
's version.
-v
/--verbose
: use verbose output
This flag, when combined with other flags, makes them produce extra output.
--extern
: specify where an external library is located
This flag allows you to pass the name and location for an external crate of a
direct dependency. Indirect dependencies (dependencies of dependencies) are
located using the -L
flag. The given crate name is
added to the extern prelude, similar to specifying extern crate
within the
root module. The given crate name does not need to match the name
the library was built with.
Specifying --extern
has one behavior difference from extern crate
:
--extern
merely makes the crate a candidate for being linked; it does not
actually link it unless it's actively used. In rare occasions you may wish
to ensure a crate is linked even if you don't actively use it from your
code: for example, if it changes the global allocator or if it contains
#[no_mangle]
symbols for use by other programming languages. In such
cases you'll need to use extern crate
.
This flag may be specified multiple times. This flag takes an argument with either of the following formats:
CRATENAME=PATH
— Indicates the given crate is found at the given path.CRATENAME
— Indicates the given crate may be found in the search path, such as within the sysroot or via the-L
flag.
The same crate name may be specified multiple times for different crate types.
If both an rlib
and dylib
are found, an internal algorithm is used to
decide which to use for linking. The -C prefer-dynamic
flag may be used to influence which is used.
If the same crate name is specified with and without a path, the one with the path is used and the pathless flag has no effect.
--sysroot
: Override the system root
The "sysroot" is where rustc
looks for the crates that come with the Rust
distribution; this flag allows that to be overridden.
--error-format
: control how errors are produced
This flag lets you control the format of messages. Messages are printed to stderr. The valid options are:
human
— Human-readable output. This is the default.json
— Structured JSON output. See the JSON chapter for more detail.short
— Short, one-line messages.
--color
: configure coloring of output
This flag lets you control color settings of the output. The valid options are:
auto
— Use colors if output goes to a tty. This is the default.always
— Always use colors.never
— Never colorize output.
--diagnostic-width
: specify the terminal width for diagnostics
This flag takes a number that specifies the width of the terminal in characters. Formatting of diagnostics will take the width into consideration to make them better fit on the screen.
--remap-path-prefix
: remap source names in output
Remap source path prefixes in all output, including compiler diagnostics,
debug information, macro expansions, etc. It takes a value of the form
FROM=TO
where a path prefix equal to FROM
is rewritten to the value TO
.
The FROM
may itself contain an =
symbol, but the TO
value may not. This
flag may be specified multiple times.
This is useful for normalizing build products, for example by removing the
current directory out of pathnames emitted into the object files. The
replacement is purely textual, with no consideration of the current system's
pathname syntax. For example --remap-path-prefix foo=bar
will match
foo/lib.rs
but not ./foo/lib.rs
.
--json
: configure json messages printed by the compiler
When the --error-format=json
option is passed to
rustc then all of the compiler's diagnostic output will be emitted in the form
of JSON blobs. The --json
argument can be used in conjunction with
--error-format=json
to configure what the JSON blobs contain as well as
which ones are emitted.
With --error-format=json
the compiler will always emit any compiler errors as
a JSON blob, but the following options are also available to the --json
flag
to customize the output:
-
diagnostic-short
- json blobs for diagnostic messages should use the "short" rendering instead of the normal "human" default. This means that the output of--error-format=short
will be embedded into the JSON diagnostics instead of the default--error-format=human
. -
diagnostic-rendered-ansi
- by default JSON blobs in theirrendered
field will contain a plain text rendering of the diagnostic. This option instead indicates that the diagnostic should have embedded ANSI color codes intended to be used to colorize the message in the manner rustc typically already does for terminal outputs. Note that this is usefully combined with crates likefwdansi
to translate these ANSI codes on Windows to console commands orstrip-ansi-escapes
if you'd like to optionally remove the ansi colors afterwards. -
artifacts
- this instructs rustc to emit a JSON blob for each artifact that is emitted. An artifact corresponds to a request from the--emit
CLI argument, and as soon as the artifact is available on the filesystem a notification will be emitted. -
future-incompat
- includes a JSON message that contains a report if the crate contains any code that may fail to compile in the future.
Note that it is invalid to combine the --json
argument with the
--color
argument, and it is required to combine --json
with --error-format=json
.
See the JSON chapter for more detail.
@path
: load command-line flags from a path
If you specify @path
on the command-line, then it will open path
and read
command line options from it. These options are one per line; a blank line indicates
an empty option. The file can use Unix or Windows style line endings, and must be
encoded as UTF-8.
Codegen Options
All of these options are passed to rustc
via the -C
flag, short for "codegen." You can see
a version of this list for your exact compiler by running rustc -C help
.
ar
This option is deprecated and does nothing.
code-model
This option lets you choose which code model to use.
Code models put constraints on address ranges that the program and its symbols may use.
With smaller address ranges machine instructions
may be able to use more compact addressing modes.
The specific ranges depend on target architectures and addressing modes available to them.
For x86 more detailed description of its code models can be found in
System V Application Binary Interface
specification.
Supported values for this option are:
tiny
- Tiny code model.small
- Small code model. This is the default model for majority of supported targets.kernel
- Kernel code model.medium
- Medium code model.large
- Large code model.
Supported values can also be discovered by running rustc --print code-models
.
codegen-units
This flag controls how many code generation units the crate is split into. It takes an integer greater than 0.
When a crate is split into multiple codegen units, LLVM is able to process them in parallel. Increasing parallelism may speed up compile times, but may also produce slower code. Setting this to 1 may improve the performance of generated code, but may be slower to compile.
The default value, if not specified, is 16 for non-incremental builds. For incremental builds the default is 256 which allows caching to be more granular.
control-flow-guard
This flag controls whether LLVM enables the Windows Control Flow Guard platform security feature. This flag is currently ignored for non-Windows targets. It takes one of the following values:
y
,yes
,on
,checks
, or no value: enable Control Flow Guard.nochecks
: emit Control Flow Guard metadata without runtime enforcement checks (this should only be used for testing purposes as it does not provide security enforcement).n
,no
,off
: do not enable Control Flow Guard (the default).
debug-assertions
This flag lets you turn cfg(debug_assertions)
conditional
compilation on
or off. It takes one of the following values:
y
,yes
,on
, or no value: enable debug-assertions.n
,no
, oroff
: disable debug-assertions.
If not specified, debug assertions are automatically enabled only if the opt-level is 0.
debuginfo
This flag controls the generation of debug information. It takes one of the following values:
0
: no debug info at all (the default).1
: line tables only.2
: full debug info.
Note: The -g
flag is an alias for -C debuginfo=2
.
default-linker-libraries
This flag controls whether or not the linker includes its default libraries. It takes one of the following values:
y
,yes
,on
, or no value: include default libraries (the default).n
,no
, oroff
: exclude default libraries.
For example, for gcc flavor linkers, this issues the -nodefaultlibs
flag to
the linker.
embed-bitcode
This flag controls whether or not the compiler embeds LLVM bitcode into object files. It takes one of the following values:
y
,yes
,on
, or no value: put bitcode in rlibs (the default).n
,no
, oroff
: omit bitcode from rlibs.
LLVM bitcode is required when rustc is performing link-time optimization (LTO).
It is also required on some targets like iOS ones where vendors look for LLVM
bitcode. Embedded bitcode will appear in rustc-generated object files inside of
a section whose name is defined by the target platform. Most of the time this is
.llvmbc
.
The use of -C embed-bitcode=no
can significantly improve compile times and
reduce generated file sizes if your compilation does not actually need bitcode
(e.g. if you're not compiling for iOS or you're not performing LTO). For these
reasons, Cargo uses -C embed-bitcode=no
whenever possible. Likewise, if you
are building directly with rustc
we recommend using -C embed-bitcode=no
whenever you are not using LTO.
If combined with -C lto
, -C embed-bitcode=no
will cause rustc
to abort
at start-up, because the combination is invalid.
Note: if you're building Rust code with LTO then you probably don't even need the
embed-bitcode
option turned on. You'll likely want to use-Clinker-plugin-lto
instead which skips generating object files entirely and simply replaces object files with LLVM bitcode. The only purpose for-Cembed-bitcode
is when you're generating an rlib that is both being used with and without LTO. For example Rust's standard library ships with embedded bitcode since users link to it both with and without LTO.This also may make you wonder why the default is
yes
for this option. The reason for that is that it's how it was for rustc 1.44 and prior. In 1.45 this option was added to turn off what had always been the default.
extra-filename
This option allows you to put extra data in each output filename. It takes a
string to add as a suffix to the filename. See the --emit
flag for more information.
force-frame-pointers
This flag forces the use of frame pointers. It takes one of the following values:
y
,yes
,on
, or no value: force-enable frame pointers.n
,no
, oroff
: do not force-enable frame pointers. This does not necessarily mean frame pointers will be removed.
The default behaviour, if frame pointers are not force-enabled, depends on the target.
force-unwind-tables
This flag forces the generation of unwind tables. It takes one of the following values:
y
,yes
,on
, or no value: Unwind tables are forced to be generated.n
,no
, oroff
: Unwind tables are not forced to be generated. If unwind tables are required by the target an error will be emitted.
The default if not specified depends on the target.
incremental
This flag allows you to enable incremental compilation, which allows rustc
to save information after compiling a crate to be reused when recompiling the
crate, improving re-compile times. This takes a path to a directory where
incremental files will be stored.
inline-threshold
This option lets you set the default threshold for inlining a function. It takes an unsigned integer as a value. Inlining is based on a cost model, where a higher threshold will allow more inlining.
The default depends on the opt-level:
opt-level | Threshold |
---|---|
0 | N/A, only inlines always-inline functions |
1 | N/A, only inlines always-inline functions and LLVM lifetime intrinsics |
2 | 225 |
3 | 275 |
s | 75 |
z | 25 |
instrument-coverage
This option enables instrumentation-based code coverage support. See the chapter on instrumentation-based code coverage for more information.
Note that while the -C instrument-coverage
option is stable, the profile data
format produced by the resulting instrumentation may change, and may not work
with coverage tools other than those built and shipped with the compiler.
link-arg
This flag lets you append a single extra argument to the linker invocation.
"Append" is significant; you can pass this flag multiple times to add multiple arguments.
link-args
This flag lets you append multiple extra arguments to the linker invocation. The options should be separated by spaces.
link-dead-code
This flag controls whether the linker will keep dead code. It takes one of the following values:
y
,yes
,on
, or no value: keep dead code.n
,no
, oroff
: remove dead code (the default).
An example of when this flag might be useful is when trying to construct code coverage metrics.
link-self-contained
On targets that support it this flag controls whether the linker will use libraries and objects shipped with Rust instead or those in the system. It takes one of the following values:
- no value: rustc will use heuristic to disable self-contained mode if system has necessary tools.
y
,yes
,on
: use only libraries/objects shipped with Rust.n
,no
, oroff
: rely on the user or the linker to provide non-Rust libraries/objects.
This allows overriding cases when detection fails or user wants to use shipped libraries.
linker
This flag controls which linker rustc
invokes to link your code. It takes a
path to the linker executable. If this flag is not specified, the linker will
be inferred based on the target. See also the linker-flavor
flag for another way to specify the linker.
linker-flavor
This flag controls the linker flavor used by rustc
. If a linker is given with
the -C linker
flag, then the linker flavor is inferred from the
value provided. If no linker is given then the linker flavor is used to
determine the linker to use. Every rustc
target defaults to some linker
flavor. Valid options are:
em
: use Emscriptenemcc
.gcc
: use thecc
executable, which is typically gcc or clang on many systems.ld
: use theld
executable.msvc
: use thelink.exe
executable from Microsoft Visual Studio MSVC.ptx-linker
: userust-ptx-linker
for Nvidia NVPTX GPGPU support.bpf-linker
: usebpf-linker
for eBPF support.wasm-ld
: use thewasm-ld
executable, a port of LLVMlld
for WebAssembly.ld64.lld
: use the LLVMlld
executable with the-flavor darwin
flag for Apple'sld
.ld.lld
: use the LLVMlld
executable with the-flavor gnu
flag for GNU binutils'ld
.lld-link
: use the LLVMlld
executable with the-flavor link
flag for Microsoft'slink.exe
.
linker-plugin-lto
This flag defers LTO optimizations to the linker. See linker-plugin-LTO for more details. It takes one of the following values:
y
,yes
,on
, or no value: enable linker plugin LTO.n
,no
, oroff
: disable linker plugin LTO (the default).- A path to the linker plugin.
More specifically this flag will cause the compiler to replace its typical
object file output with LLVM bitcode files. For example an rlib produced with
-Clinker-plugin-lto
will still have *.o
files in it, but they'll all be LLVM
bitcode instead of actual machine code. It is expected that the native platform
linker is capable of loading these LLVM bitcode files and generating code at
link time (typically after performing optimizations).
Note that rustc can also read its own object files produced with
-Clinker-plugin-lto
. If an rlib is only ever going to get used later with a
-Clto
compilation then you can pass -Clinker-plugin-lto
to speed up
compilation and avoid generating object files that aren't used.
llvm-args
This flag can be used to pass a list of arguments directly to LLVM.
The list must be separated by spaces.
Pass --help
to see a list of options.
lto
This flag controls whether LLVM uses link time optimizations to produce better optimized code, using whole-program analysis, at the cost of longer linking time. It takes one of the following values:
y
,yes
,on
,fat
, or no value: perform "fat" LTO which attempts to perform optimizations across all crates within the dependency graph.n
,no
,off
: disables LTO.thin
: perform "thin" LTO. This is similar to "fat", but takes substantially less time to run while still achieving performance gains similar to "fat".
If -C lto
is not specified, then the compiler will attempt to perform "thin
local LTO" which performs "thin" LTO on the local crate only across its
codegen units. When -C lto
is not specified, LTO is
disabled if codegen units is 1 or optimizations are disabled (-C opt-level=0
). That is:
- When
-C lto
is not specified:codegen-units=1
: disable LTO.opt-level=0
: disable LTO.
- When
-C lto
is specified:lto
: 16 codegen units, perform fat LTO across crates.codegen-units=1
+lto
: 1 codegen unit, fat LTO across crates.
See also linker-plugin-lto for cross-language LTO.
metadata
This option allows you to control the metadata used for symbol mangling. This takes a space-separated list of strings. Mangled symbols will incorporate a hash of the metadata. This may be used, for example, to differentiate symbols between two different versions of the same crate being linked.
no-prepopulate-passes
This flag tells the pass manager to use an empty list of passes, instead of the usual pre-populated list of passes.
no-redzone
This flag allows you to disable the red zone. It takes one of the following values:
y
,yes
,on
, or no value: disable the red zone.n
,no
, oroff
: enable the red zone.
The default behaviour, if the flag is not specified, depends on the target.
no-stack-check
This option is deprecated and does nothing.
no-vectorize-loops
This flag disables loop vectorization.
no-vectorize-slp
This flag disables vectorization using superword-level parallelism.
opt-level
This flag controls the optimization level.
0
: no optimizations, also turns oncfg(debug_assertions)
(the default).1
: basic optimizations.2
: some optimizations.3
: all optimizations.s
: optimize for binary size.z
: optimize for binary size, but also turn off loop vectorization.
Note: The -O
flag is an alias for -C opt-level=2
.
The default is 0
.
overflow-checks
This flag allows you to control the behavior of runtime integer overflow. When overflow-checks are enabled, a panic will occur on overflow. This flag takes one of the following values:
y
,yes
,on
, or no value: enable overflow checks.n
,no
, oroff
: disable overflow checks.
If not specified, overflow checks are enabled if debug-assertions are enabled, disabled otherwise.
panic
This option lets you control what happens when the code panics.
abort
: terminate the process upon panicunwind
: unwind the stack upon panic
If not specified, the default depends on the target.
passes
This flag can be used to add extra LLVM passes to the compilation.
The list must be separated by spaces.
See also the no-prepopulate-passes
flag.
prefer-dynamic
By default, rustc
prefers to statically link dependencies. This option will
indicate that dynamic linking should be used if possible if both a static and
dynamic versions of a library are available. There is an internal algorithm
for determining whether or not it is possible to statically or dynamically
link with a dependency. For example, cdylib
crate types may only use static
linkage. This flag takes one of the following values:
y
,yes
,on
, or no value: use dynamic linking.n
,no
, oroff
: use static linking (the default).
profile-generate
This flag allows for creating instrumented binaries that will collect profiling data for use with profile-guided optimization (PGO). The flag takes an optional argument which is the path to a directory into which the instrumented binary will emit the collected data. See the chapter on profile-guided optimization for more information.
profile-use
This flag specifies the profiling data file to be used for profile-guided
optimization (PGO). The flag takes a mandatory argument which is the path
to a valid .profdata
file. See the chapter on
profile-guided optimization for more information.
relocation-model
This option controls generation of position-independent code (PIC).
Supported values for this option are:
Primary relocation models
-
static
- non-relocatable code, machine instructions may use absolute addressing modes. -
pic
- fully relocatable position independent code, machine instructions need to use relative addressing modes.
Equivalent to the "uppercase"-fPIC
or-fPIE
options in other compilers, depending on the produced crate types.
This is the default model for majority of supported targets. -
pie
- position independent executable, relocatable code but without support for symbol interpositioning (replacing symbols by name usingLD_PRELOAD
and similar). Equivalent to the "uppercase"-fPIE
option in other compilers.pie
code cannot be linked into shared libraries (you'll get a linking error on attempt to do this).
Special relocation models
dynamic-no-pic
- relocatable external references, non-relocatable code.
Only makes sense on Darwin and is rarely used.
If StackOverflow tells you to use this as an opt-out of PIC or PIE, don't believe it, use-C relocation-model=static
instead.ropi
,rwpi
andropi-rwpi
- relocatable code and read-only data, relocatable read-write data, and combination of both, respectively.
Only makes sense for certain embedded ARM targets.default
- relocation model default to the current target.
Only makes sense as an override for some other explicitly specified relocation model previously set on the command line.
Supported values can also be discovered by running rustc --print relocation-models
.
Linking effects
In addition to codegen effects, relocation-model
has effects during linking.
If the relocation model is pic
and the current target supports position-independent executables
(PIE), the linker will be instructed (-pie
) to produce one.
If the target doesn't support both position-independent and statically linked executables,
then -C target-feature=+crt-static
"wins" over -C relocation-model=pic
,
and the linker is instructed (-static
) to produce a statically linked
but not position-independent executable.
remark
This flag lets you print remarks for optimization passes.
The list of passes should be separated by spaces.
all
will remark on every pass.
rpath
This flag controls whether rpath
is
enabled. It takes one of the following values:
y
,yes
,on
, or no value: enable rpath.n
,no
, oroff
: disable rpath (the default).
save-temps
This flag controls whether temporary files generated during compilation are deleted once compilation finishes. It takes one of the following values:
y
,yes
,on
, or no value: save temporary files.n
,no
, oroff
: delete temporary files (the default).
soft-float
This option controls whether rustc
generates code that emulates floating
point instructions in software. It takes one of the following values:
y
,yes
,on
, or no value: use soft floats.n
,no
, oroff
: use hardware floats (the default).
split-debuginfo
This option controls the emission of "split debuginfo" for debug information
that rustc
generates. The default behavior of this option is
platform-specific, and not all possible values for this option work on all
platforms. Possible values are:
-
off
- This is the default for platforms with ELF binaries and windows-gnu (not Windows MSVC and not macOS). This typically means that DWARF debug information can be found in the final artifact in sections of the executable. This option is not supported on Windows MSVC. On macOS this options prevents the final execution ofdsymutil
to generate debuginfo. -
packed
- This is the default for Windows MSVC and macOS. The term "packed" here means that all the debug information is packed into a separate file from the main executable. On Windows MSVC this is a*.pdb
file, on macOS this is a*.dSYM
folder, and on other platforms this is a*.dwp
file. -
unpacked
- This means that debug information will be found in separate files for each compilation unit (object file). This is not supported on Windows MSVC. On macOS this means the original object files will contain debug information. On other Unix platforms this means that*.dwo
files will contain debug information.
Note that all three options are supported on Linux and Apple platforms,
packed
is supported on Windows-MSVC, and all other platforms support off
.
Attempting to use an unsupported option requires using the nightly channel
with the -Z unstable-options
flag.
strip
The option -C strip=val
controls stripping of debuginfo and similar auxiliary
data from binaries during linking.
Supported values for this option are:
none
- debuginfo and symbols (if they exist) are copied to the produced binary or separate files depending on the target (e.g..pdb
files in case of MSVC).debuginfo
- debuginfo sections and debuginfo symbols from the symbol table section are stripped at link time and are not copied to the produced binary or separate files.symbols
- same asdebuginfo
, but the rest of the symbol table section is stripped as well if the linker supports it.
symbol-mangling-version
This option controls the name mangling format for encoding Rust item names for the purpose of generating object code and linking.
Supported values for this option are:
v0
— The "v0" mangling scheme. The specific format is not specified at this time.
The default if not specified will use a compiler-chosen default which may change in the future.
target-cpu
This instructs rustc
to generate code specifically for a particular processor.
You can run rustc --print target-cpus
to see the valid options to pass
here. Each target has a default base CPU. Special values include:
native
can be passed to use the processor of the host machine.generic
refers to an LLVM target with minimal features but modern tuning.
target-feature
Individual targets will support different features; this flag lets you control
enabling or disabling a feature. Each feature should be prefixed with a +
to
enable it or -
to disable it.
Features from multiple -C target-feature
options are combined.
Multiple features can be specified in a single option by separating them
with commas - -C target-feature=+x,-y
.
If some feature is specified more than once with both +
and -
,
then values passed later override values passed earlier.
For example, -C target-feature=+x,-y,+z -Ctarget-feature=-x,+y
is equivalent to -C target-feature=-x,+y,+z
.
To see the valid options and an example of use, run rustc --print target-features
.
Using this flag is unsafe and might result in undefined runtime behavior.
See also the target_feature
attribute
for controlling features per-function.
This also supports the feature +crt-static
and -crt-static
to control
static C runtime linkage.
Each target and target-cpu
has a default set of enabled
features.
tune-cpu
This instructs rustc
to schedule code specifically for a particular
processor. This does not affect the compatibility (instruction sets or ABI),
but should make your code slightly more efficient on the selected CPU.
The valid options are the same as those for target-cpu
.
The default is None
, which LLVM translates as the target-cpu
.
This is an unstable option. Use -Z tune-cpu=machine
to specify a value.
Due to limitations in LLVM (12.0.0-git9218f92), this option is currently effective only for x86 targets.
Lints
In software, a "lint" is a tool used to help improve your source code. The Rust compiler contains a number of lints, and when it compiles your code, it will also run the lints. These lints may produce a warning, an error, or nothing at all, depending on how you've configured things.
Here's a small example:
$ cat main.rs
fn main() {
let x = 5;
}
$ rustc main.rs
warning: unused variable: `x`
--> main.rs:2:9
|
2 | let x = 5;
| ^
|
= note: `#[warn(unused_variables)]` on by default
= note: to avoid this warning, consider using `_x` instead
This is the unused_variables
lint, and it tells you that you've introduced
a variable that you don't use in your code. That's not wrong, so it's not
an error, but it might be a bug, so you get a warning.
Future-incompatible lints
Sometimes the compiler needs to be changed to fix an issue that can cause existing code to stop compiling. "Future-incompatible" lints are issued in these cases to give users of Rust a smooth transition to the new behavior. Initially, the compiler will continue to accept the problematic code and issue a warning. The warning has a description of the problem, a notice that this will become an error in the future, and a link to a tracking issue that provides detailed information and an opportunity for feedback. This gives users some time to fix the code to accommodate the change. After some time, the warning may become an error.
The following is an example of what a future-incompatible looks like:
warning: borrow of packed field is unsafe and requires unsafe function or block (error E0133)
--> lint_example.rs:11:13
|
11 | let y = &x.data.0;
| ^^^^^^^^^
|
= note: `#[warn(safe_packed_borrows)]` on by default
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #46043 <https://github.com/rust-lang/rust/issues/46043>
= note: fields of packed structs might be misaligned: dereferencing a misaligned pointer or even just creating a misaligned reference is undefined behavior
For more information about the process and policy of future-incompatible changes, see RFC 1589.
Lint Levels
In rustc
, lints are divided into five levels:
- allow
- warn
- force-warn
- deny
- forbid
Each lint has a default level (explained in the lint listing later in this chapter), and the compiler has a default warning level. First, let's explain what these levels mean, and then we'll talk about configuration.
allow
These lints exist, but by default, do nothing. For example, consider this source:
#![allow(unused)] fn main() { pub fn foo() {} }
Compiling this file produces no warnings:
$ rustc lib.rs --crate-type=lib
$
But this code violates the missing_docs
lint.
These lints exist mostly to be manually turned on via configuration, as we'll talk about later in this section.
warn
The 'warn' lint level will produce a warning if you violate the lint. For example,
this code runs afoul of the unused_variables
lint:
#![allow(unused)] fn main() { pub fn foo() { let x = 5; } }
This will produce this warning:
$ rustc lib.rs --crate-type=lib
warning: unused variable: `x`
--> lib.rs:2:9
|
2 | let x = 5;
| ^
|
= note: `#[warn(unused_variables)]` on by default
= note: to avoid this warning, consider using `_x` instead
force-warn
'force-warn' is a special lint level. It's the same as 'warn' in that a lint at this level will produce a warning, but unlike the 'warn' level, the 'force-warn' level cannot be overridden. If a lint is set to 'force-warn', it is guaranteed to warn: no more, no less. This is true even if the overall lint level is capped via cap-lints.
deny
A 'deny' lint produces an error if you violate it. For example, this code
runs into the exceeding_bitshifts
lint.
fn main() { 100u8 << 10; }
$ rustc main.rs
error: bitshift exceeds the type's number of bits
--> main.rs:2:13
|
2 | 100u8 << 10;
| ^^^^^^^^^^^
|
= note: `#[deny(exceeding_bitshifts)]` on by default
What's the difference between an error from a lint and a regular old error?
Lints are configurable via levels, so in a similar way to 'allow' lints,
warnings that are 'deny' by default let you allow them. Similarly, you may
wish to set up a lint that is warn
by default to produce an error instead.
This lint level gives you that.
forbid
'forbid' is a special lint level that fills the same role for 'deny' that
'force-warn' does for 'warn'. It's the same as 'deny' in that a lint at this
level will produce an error, but unlike the 'deny' level, the 'forbid' level
can not be overridden to be anything lower than an error. However, lint
levels may still be capped with --cap-lints
(see below) so rustc --cap-lints warn
will make lints set to 'forbid' just warn.
Configuring warning levels
Remember our missing_docs
example from the 'allow' lint level?
$ cat lib.rs
pub fn foo() {}
$ rustc lib.rs --crate-type=lib
$
We can configure this lint to operate at a higher level, both with compiler flags, as well as with an attribute in the source code.
You can also "cap" lints so that the compiler can choose to ignore certain lint levels. We'll talk about that last.
Via compiler flag
The -A
, -W
, --force-warn
-D
, and -F
flags let you turn one or more lints
into allowed, warning, force-warn, deny, or forbid levels, like this:
$ rustc lib.rs --crate-type=lib -W missing-docs
warning: missing documentation for crate
--> lib.rs:1:1
|
1 | pub fn foo() {}
| ^^^^^^^^^^^^
|
= note: requested on the command line with `-W missing-docs`
warning: missing documentation for a function
--> lib.rs:1:1
|
1 | pub fn foo() {}
| ^^^^^^^^^^^^
$ rustc lib.rs --crate-type=lib -D missing-docs
error: missing documentation for crate
--> lib.rs:1:1
|
1 | pub fn foo() {}
| ^^^^^^^^^^^^
|
= note: requested on the command line with `-D missing-docs`
error: missing documentation for a function
--> lib.rs:1:1
|
1 | pub fn foo() {}
| ^^^^^^^^^^^^
error: aborting due to 2 previous errors
You can also pass each flag more than once for changing multiple lints:
$ rustc lib.rs --crate-type=lib -D missing-docs -D unused-variables
And of course, you can mix these five flags together:
$ rustc lib.rs --crate-type=lib -D missing-docs -A unused-variables
The order of these command line arguments is taken into account. The following allows the unused-variables
lint, because it is the last argument for that lint:
$ rustc lib.rs --crate-type=lib -D unused-variables -A unused-variables
You can make use of this behavior by overriding the level of one specific lint out of a group of lints. The following example denies all the lints in the unused
group, but explicitly allows the unused-variables
lint in that group (forbid still trumps everything regardless of ordering):
$ rustc lib.rs --crate-type=lib -D unused -A unused-variables
Since force-warn
and forbid
cannot be overridden, setting
one of them will prevent any later level for the same lint from
taking effect.
Via an attribute
You can also modify the lint level with a crate-wide attribute:
$ cat lib.rs
#![warn(missing_docs)]
pub fn foo() {}
$ rustc lib.rs --crate-type=lib
warning: missing documentation for crate
--> lib.rs:1:1
|
1 | / #![warn(missing_docs)]
2 | |
3 | | pub fn foo() {}
| |_______________^
|
note: lint level defined here
--> lib.rs:1:9
|
1 | #![warn(missing_docs)]
| ^^^^^^^^^^^^
warning: missing documentation for a function
--> lib.rs:3:1
|
3 | pub fn foo() {}
| ^^^^^^^^^^^^
warn
, allow
, deny
, and forbid
all work this way. There is
no way to set a lint to force-warn
using an attribute.
You can also pass in multiple lints per attribute:
#![allow(unused)] #![warn(missing_docs, unused_variables)] fn main() { pub fn foo() {} }
And use multiple attributes together:
#![allow(unused)] #![warn(missing_docs)] #![deny(unused_variables)] fn main() { pub fn foo() {} }
Capping lints
rustc
supports a flag, --cap-lints LEVEL
that sets the "lint cap level."
This is the maximum level for all lints. So for example, if we take our
code sample from the "deny" lint level above:
fn main() { 100u8 << 10; }
And we compile it, capping lints to warn:
$ rustc lib.rs --cap-lints warn
warning: bitshift exceeds the type's number of bits
--> lib.rs:2:5
|
2 | 100u8 << 10;
| ^^^^^^^^^^^
|
= note: `#[warn(exceeding_bitshifts)]` on by default
warning: this expression will panic at run-time
--> lib.rs:2:5
|
2 | 100u8 << 10;
| ^^^^^^^^^^^ attempt to shift left with overflow
It now only warns, rather than errors. We can go further and allow all lints:
$ rustc lib.rs --cap-lints allow
$
This feature is used heavily by Cargo; it will pass --cap-lints allow
when
compiling your dependencies, so that if they have any warnings, they do not
pollute the output of your build.
Lint Groups
rustc
has the concept of a "lint group", where you can toggle several warnings
through one name.
For example, the nonstandard-style
lint sets non-camel-case-types
,
non-snake-case
, and non-upper-case-globals
all at once. So these are
equivalent:
$ rustc -D nonstandard-style
$ rustc -D non-camel-case-types -D non-snake-case -D non-upper-case-globals
Here's a list of each lint group, and the lints that they are made up of:
Additionally, there's a bad-style
lint group that's a deprecated alias for nonstandard-style
.
Finally, you can also see the table above by invoking rustc -W help
. This will give you the exact values for the specific
compiler you have installed.
Lint Listing
This section lists out all of the lints, grouped by their default lint levels.
You can also see this list by running rustc -W help
.
Allowed-by-default Lints
These lints are all set to the 'allow' level by default. As such, they won't show up unless you set them to a higher lint level with a flag or attribute.
absolute_paths_not_starting_with_crate
box_pointers
elided_lifetimes_in_paths
explicit_outlives_requirements
ffi_unwind_calls
fuzzy_provenance_casts
keyword_idents
let_underscore_drop
lossy_provenance_casts
macro_use_extern_crate
meta_variable_misuse
missing_abi
missing_copy_implementations
missing_debug_implementations
missing_docs
must_not_suspend
non_ascii_idents
non_exhaustive_omitted_patterns
noop_method_call
pointer_structural_match
rust_2021_incompatible_closure_captures
rust_2021_incompatible_or_patterns
rust_2021_prefixes_incompatible_syntax
rust_2021_prelude_collisions
single_use_lifetimes
trivial_casts
trivial_numeric_casts
unreachable_pub
unsafe_code
unsafe_op_in_unsafe_fn
unstable_features
unused_crate_dependencies
unused_extern_crates
unused_import_braces
unused_lifetimes
unused_macro_rules
unused_qualifications
unused_results
unused_tuple_struct_fields
variant_size_differences
absolute-paths-not-starting-with-crate
The absolute_paths_not_starting_with_crate
lint detects fully
qualified paths that start with a module name instead of crate
,
self
, or an extern crate name
Example
#![deny(absolute_paths_not_starting_with_crate)] mod foo { pub fn bar() {} } fn main() { ::foo::bar(); }
This will produce:
error: absolute paths must start with `self`, `super`, `crate`, or an external crate name in the 2018 edition
--> lint_example.rs:8:5
|
8 | ::foo::bar();
| ^^^^^^^^^^ help: use `crate`: `crate::foo::bar`
|
= warning: this is accepted in the current edition (Rust 2015) but is a hard error in Rust 2018!
= note: for more information, see issue #53130 <https://github.com/rust-lang/rust/issues/53130>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(absolute_paths_not_starting_with_crate)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
Rust editions allow the language to evolve without breaking
backwards compatibility. This lint catches code that uses absolute
paths in the style of the 2015 edition. In the 2015 edition, absolute
paths (those starting with ::
) refer to either the crate root or an
external crate. In the 2018 edition it was changed so that they only
refer to external crates. The path prefix crate::
should be used
instead to reference items from the crate root.
If you switch the compiler from the 2015 to 2018 edition without
updating the code, then it will fail to compile if the old style paths
are used. You can manually change the paths to use the crate::
prefix to transition to the 2018 edition.
This lint solves the problem automatically. It is "allow" by default
because the code is perfectly valid in the 2015 edition. The cargo fix
tool with the --edition
flag will switch this lint to "warn"
and automatically apply the suggested fix from the compiler. This
provides a completely automated way to update old code to the 2018
edition.
box-pointers
The box_pointers
lints use of the Box type.
Example
#![allow(unused)] #![deny(box_pointers)] fn main() { struct Foo { x: Box<isize>, } }
This will produce:
error: type uses owned (Box type) pointers: Box<isize>
--> lint_example.rs:4:5
|
4 | x: Box<isize>,
| ^^^^^^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(box_pointers)]
| ^^^^^^^^^^^^
Explanation
This lint is mostly historical, and not particularly useful. Box<T>
used to be built into the language, and the only way to do heap
allocation. Today's Rust can call into other allocators, etc.
elided-lifetimes-in-paths
The elided_lifetimes_in_paths
lint detects the use of hidden
lifetime parameters.
Example
#![allow(unused)] #![deny(elided_lifetimes_in_paths)] fn main() { struct Foo<'a> { x: &'a u32 } fn foo(x: &Foo) { } }
This will produce:
error: hidden lifetime parameters in types are deprecated
--> lint_example.rs:7:12
|
7 | fn foo(x: &Foo) {
| ^^^ expected lifetime parameter
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(elided_lifetimes_in_paths)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^
help: indicate the anonymous lifetime
|
7 | fn foo(x: &Foo<'_>) {
| ++++
Explanation
Elided lifetime parameters can make it difficult to see at a glance
that borrowing is occurring. This lint ensures that lifetime
parameters are always explicitly stated, even if it is the '_
placeholder lifetime.
This lint is "allow" by default because it has some known issues, and may require a significant transition for old code.
explicit-outlives-requirements
The explicit_outlives_requirements
lint detects unnecessary
lifetime bounds that can be inferred.
Example
#![allow(unused)] fn main() { #![allow(unused)] #![deny(explicit_outlives_requirements)] struct SharedRef<'a, T> where T: 'a, { data: &'a T, } }
This will produce:
error: outlives requirements can be inferred
--> lint_example.rs:5:24
|
5 | struct SharedRef<'a, T>
| ________________________^
6 | | where
7 | | T: 'a,
| |__________^ help: remove this bound
|
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![deny(explicit_outlives_requirements)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
If a struct
contains a reference, such as &'a T
, the compiler
requires that T
outlives the lifetime 'a
. This historically
required writing an explicit lifetime bound to indicate this
requirement. However, this can be overly explicit, causing clutter and
unnecessary complexity. The language was changed to automatically
infer the bound if it is not specified. Specifically, if the struct
contains a reference, directly or indirectly, to T
with lifetime
'x
, then it will infer that T: 'x
is a requirement.
This lint is "allow" by default because it can be noisy for existing code that already had these requirements. This is a stylistic choice, as it is still valid to explicitly state the bound. It also has some false positives that can cause confusion.
See RFC 2093 for more details.
ffi-unwind-calls
The ffi_unwind_calls
lint detects calls to foreign functions or function pointers with
C-unwind
or other FFI-unwind ABIs.
Example
#![feature(ffi_unwind_calls)]
#![feature(c_unwind)]
mod impl {
#[no_mangle]
pub fn "C-unwind" fn foo() {}
}
extern "C-unwind" {
fn foo();
}
fn bar() {
unsafe { foo(); }
let ptr: unsafe extern "C-unwind" fn() = foo;
unsafe { ptr(); }
}
{{produces}}
Explanation
For crates containing such calls, if they are compiled with -C panic=unwind
then the
produced library cannot be linked with crates compiled with -C panic=abort
. For crates
that desire this ability it is therefore necessary to avoid such calls.
fuzzy-provenance-casts
The fuzzy_provenance_casts
lint detects an as
cast between an integer
and a pointer.
Example
#![feature(strict_provenance)] #![warn(fuzzy_provenance_casts)] fn main() { let _dangling = 16_usize as *const u8; }
This will produce:
warning: strict provenance disallows casting integer `usize` to pointer `*const u8`
--> lint_example.rs:5:21
|
5 | let _dangling = 16_usize as *const u8;
| ^^^^^^^^^^^^^^^^^^^^^
|
= help: if you can't comply with strict provenance and don't have a pointer with the correct provenance you can use `std::ptr::from_exposed_addr()` instead
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![warn(fuzzy_provenance_casts)]
| ^^^^^^^^^^^^^^^^^^^^^^
help: use `.with_addr()` to adjust a valid pointer in the same allocation, to this address
|
5 | let _dangling = (...).with_addr(16_usize);
| ++++++++++++++++ ~
Explanation
This lint is part of the strict provenance effort, see issue #95228.
Casting an integer to a pointer is considered bad style, as a pointer
contains, besides the address also a provenance, indicating what
memory the pointer is allowed to read/write. Casting an integer, which
doesn't have provenance, to a pointer requires the compiler to assign
(guess) provenance. The compiler assigns "all exposed valid" (see the
docs of ptr::from_exposed_addr
for more information about this
"exposing"). This penalizes the optimiser and is not well suited for
dynamic analysis/dynamic program verification (e.g. Miri or CHERI
platforms).
It is much better to use ptr::with_addr
instead to specify the
provenance you want. If using this function is not possible because the
code relies on exposed provenance then there is as an escape hatch
ptr::from_exposed_addr
.
keyword-idents
The keyword_idents
lint detects edition keywords being used as an
identifier.
Example
#![allow(unused)] #![deny(keyword_idents)] fn main() { // edition 2015 fn dyn() {} }
This will produce:
error: `dyn` is a keyword in the 2018 edition
--> lint_example.rs:4:4
|
4 | fn dyn() {}
| ^^^ help: you can use a raw identifier to stay compatible: `r#dyn`
|
= warning: this is accepted in the current edition (Rust 2015) but is a hard error in Rust 2018!
= note: for more information, see issue #49716 <https://github.com/rust-lang/rust/issues/49716>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(keyword_idents)]
| ^^^^^^^^^^^^^^
Explanation
Rust editions allow the language to evolve without breaking backwards compatibility. This lint catches code that uses new keywords that are added to the language that are used as identifiers (such as a variable name, function name, etc.). If you switch the compiler to a new edition without updating the code, then it will fail to compile if you are using a new keyword as an identifier.
You can manually change the identifiers to a non-keyword, or use a
raw identifier, for example r#dyn
, to transition to a new edition.
This lint solves the problem automatically. It is "allow" by default
because the code is perfectly valid in older editions. The cargo fix
tool with the --edition
flag will switch this lint to "warn"
and automatically apply the suggested fix from the compiler (which is
to use a raw identifier). This provides a completely automated way to
update old code for a new edition.
let-underscore-drop
The let_underscore_drop
lint checks for statements which don't bind
an expression which has a non-trivial Drop implementation to anything,
causing the expression to be dropped immediately instead of at end of
scope.
Example
struct SomeStruct;
impl Drop for SomeStruct {
fn drop(&mut self) {
println!("Dropping SomeStruct");
}
}
fn main() {
#[warn(let_underscore_drop)]
// SomeStuct is dropped immediately instead of at end of scope,
// so "Dropping SomeStruct" is printed before "end of main".
// The order of prints would be reversed if SomeStruct was bound to
// a name (such as "_foo").
let _ = SomeStruct;
println!("end of main");
}
{{produces}}
Explanation
Statements which assign an expression to an underscore causes the
expression to immediately drop instead of extending the expression's
lifetime to the end of the scope. This is usually unintended,
especially for types like MutexGuard
, which are typically used to
lock a mutex for the duration of an entire scope.
If you want to extend the expression's lifetime to the end of the scope,
assign an underscore-prefixed name (such as _foo
) to the expression.
If you do actually want to drop the expression immediately, then
calling std::mem::drop
on the expression is clearer and helps convey
intent.
lossy-provenance-casts
The lossy_provenance_casts
lint detects an as
cast between a pointer
and an integer.
Example
#![feature(strict_provenance)] #![warn(lossy_provenance_casts)] fn main() { let x: u8 = 37; let _addr: usize = &x as *const u8 as usize; }
This will produce:
warning: under strict provenance it is considered bad style to cast pointer `*const u8` to integer `usize`
--> lint_example.rs:6:24
|
6 | let _addr: usize = &x as *const u8 as usize;
| ^^^^^^^^^^^^^^^^^^^^^^^^
|
= help: if you can't comply with strict provenance and need to expose the pointer provenance you can use `.expose_addr()` instead
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![warn(lossy_provenance_casts)]
| ^^^^^^^^^^^^^^^^^^^^^^
help: use `.addr()` to obtain the address of a pointer
|
6 | let _addr: usize = (&x as *const u8).addr();
| + ~~~~~~~~
Explanation
This lint is part of the strict provenance effort, see issue #95228. Casting a pointer to an integer is a lossy operation, because beyond just an address a pointer may be associated with a particular provenance. This information is used by the optimiser and for dynamic analysis/dynamic program verification (e.g. Miri or CHERI platforms).
Since this cast is lossy, it is considered good style to use the
ptr::addr
method instead, which has a similar effect, but doesn't
"expose" the pointer provenance. This improves optimisation potential.
See the docs of ptr::addr
and ptr::expose_addr
for more information
about exposing pointer provenance.
If your code can't comply with strict provenance and needs to expose
the provenance, then there is ptr::expose_addr
as an escape hatch,
which preserves the behaviour of as usize
casts while being explicit
about the semantics.
macro-use-extern-crate
The macro_use_extern_crate
lint detects the use of the
macro_use
attribute.
Example
#![deny(macro_use_extern_crate)]
#[macro_use]
extern crate serde_json;
fn main() {
let _ = json!{{}};
}
This will produce:
error: deprecated `#[macro_use]` attribute used to import macros should be replaced at use sites with a `use` item to import the macro instead
--> src/main.rs:3:1
|
3 | #[macro_use]
| ^^^^^^^^^^^^
|
note: the lint level is defined here
--> src/main.rs:1:9
|
1 | #![deny(macro_use_extern_crate)]
| ^^^^^^^^^^^^^^^^^^^^^^
Explanation
The macro_use
attribute on an extern crate
item causes
macros in that external crate to be brought into the prelude of the
crate, making the macros in scope everywhere. As part of the efforts
to simplify handling of dependencies in the 2018 edition, the use of
extern crate
is being phased out. To bring macros from extern crates
into scope, it is recommended to use a use
import.
This lint is "allow" by default because this is a stylistic choice that has not been settled, see issue #52043 for more information.
meta-variable-misuse
The meta_variable_misuse
lint detects possible meta-variable misuse
in macro definitions.
Example
#![deny(meta_variable_misuse)] macro_rules! foo { () => {}; ($( $i:ident = $($j:ident),+ );*) => { $( $( $i = $k; )+ )* }; } fn main() { foo!(); }
This will produce:
error: unknown macro variable `k`
--> lint_example.rs:5:55
|
5 | ($( $i:ident = $($j:ident),+ );*) => { $( $( $i = $k; )+ )* };
| ^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(meta_variable_misuse)]
| ^^^^^^^^^^^^^^^^^^^^
Explanation
There are quite a few different ways a macro_rules
macro can be
improperly defined. Many of these errors were previously only detected
when the macro was expanded or not at all. This lint is an attempt to
catch some of these problems when the macro is defined.
This lint is "allow" by default because it may have false positives and other issues. See issue #61053 for more details.
missing-abi
The missing_abi
lint detects cases where the ABI is omitted from
extern declarations.
Example
#![allow(unused)] #![deny(missing_abi)] fn main() { extern fn foo() {} }
This will produce:
error: extern declarations without an explicit ABI are deprecated
--> lint_example.rs:4:1
|
4 | extern fn foo() {}
| ^^^^^^^^^^^^^^^ ABI should be specified here
|
= help: the default ABI is C
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(missing_abi)]
| ^^^^^^^^^^^
Explanation
Historically, Rust implicitly selected C as the ABI for extern
declarations. We expect to add new ABIs, like C-unwind
, in the future,
though this has not yet happened, and especially with their addition
seeing the ABI easily will make code review easier.
missing-copy-implementations
The missing_copy_implementations
lint detects potentially-forgotten
implementations of Copy
.
Example
#![deny(missing_copy_implementations)] pub struct Foo { pub field: i32 } fn main() {}
This will produce:
error: type could implement `Copy`; consider adding `impl Copy`
--> lint_example.rs:2:1
|
2 | / pub struct Foo {
3 | | pub field: i32
4 | | }
| |_^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(missing_copy_implementations)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
Historically (before 1.0), types were automatically marked as Copy
if possible. This was changed so that it required an explicit opt-in
by implementing the Copy
trait. As part of this change, a lint was
added to alert if a copyable type was not marked Copy
.
This lint is "allow" by default because this code isn't bad; it is
common to write newtypes like this specifically so that a Copy
type
is no longer Copy
. Copy
types can result in unintended copies of
large data which can impact performance.
missing-debug-implementations
The missing_debug_implementations
lint detects missing
implementations of fmt::Debug
.
Example
#![deny(missing_debug_implementations)] pub struct Foo; fn main() {}
This will produce:
error: type does not implement `Debug`; consider adding `#[derive(Debug)]` or a manual implementation
--> lint_example.rs:2:1
|
2 | pub struct Foo;
| ^^^^^^^^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(missing_debug_implementations)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
Having a Debug
implementation on all types can assist with
debugging, as it provides a convenient way to format and display a
value. Using the #[derive(Debug)]
attribute will automatically
generate a typical implementation, or a custom implementation can be
added by manually implementing the Debug
trait.
This lint is "allow" by default because adding Debug
to all types can
have a negative impact on compile time and code size. It also requires
boilerplate to be added to every type, which can be an impediment.
missing-docs
The missing_docs
lint detects missing documentation for public items.
Example
#![allow(unused)] #![deny(missing_docs)] fn main() { pub fn foo() {} }
This will produce:
error: missing documentation for the crate
--> lint_example.rs:1:1
|
1 | / #![deny(missing_docs)]
2 | | fn main() {
3 | | pub fn foo() {}
4 | | }
| |_^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(missing_docs)]
| ^^^^^^^^^^^^
Explanation
This lint is intended to ensure that a library is well-documented. Items without documentation can be difficult for users to understand how to use properly.
This lint is "allow" by default because it can be noisy, and not all projects may want to enforce everything to be documented.
must-not-suspend
The must_not_suspend
lint guards against values that shouldn't be held across suspend points
(.await
)
Example
#![allow(unused)] #![feature(must_not_suspend)] #![warn(must_not_suspend)] fn main() { #[must_not_suspend] struct SyncThing {} async fn yield_now() {} pub async fn uhoh() { let guard = SyncThing {}; yield_now().await; } }
This will produce:
warning: `SyncThing` held across a suspend point, but should not be
--> lint_example.rs:11:9
|
11 | let guard = SyncThing {};
| ^^^^^
12 | yield_now().await;
| ------ the value is held across this suspend point
|
help: consider using a block (`{ ... }`) to shrink the value's scope, ending before the suspend point
--> lint_example.rs:11:9
|
11 | let guard = SyncThing {};
| ^^^^^
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![warn(must_not_suspend)]
| ^^^^^^^^^^^^^^^^
Explanation
The must_not_suspend
lint detects values that are marked with the #[must_not_suspend]
attribute being held across suspend points. A "suspend" point is usually a .await
in an async
function.
This attribute can be used to mark values that are semantically incorrect across suspends
(like certain types of timers), values that have async alternatives, and values that
regularly cause problems with the Send
-ness of async fn's returned futures (like
MutexGuard
's)
non-ascii-idents
The non_ascii_idents
lint detects non-ASCII identifiers.
Example
#![allow(unused)] #![deny(non_ascii_idents)] fn main() { let föö = 1; }
This will produce:
error: identifier contains non-ASCII characters
--> lint_example.rs:4:9
|
4 | let föö = 1;
| ^^^
|
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![deny(non_ascii_idents)]
| ^^^^^^^^^^^^^^^^
Explanation
This lint allows projects that wish to retain the limit of only using ASCII characters to switch this lint to "forbid" (for example to ease collaboration or for security reasons). See RFC 2457 for more details.
non-exhaustive-omitted-patterns
The non_exhaustive_omitted_patterns
lint detects when a wildcard (_
or ..
) in a
pattern for a #[non_exhaustive]
struct or enum is reachable.
Example
// crate A
#[non_exhaustive]
pub enum Bar {
A,
B, // added variant in non breaking change
}
// in crate B
#![feature(non_exhaustive_omitted_patterns_lint)]
match Bar::A {
Bar::A => {},
#[warn(non_exhaustive_omitted_patterns)]
_ => {},
}
This will produce:
warning: reachable patterns not covered of non exhaustive enum
--> $DIR/reachable-patterns.rs:70:9
|
LL | _ => {}
| ^ pattern `B` not covered
|
note: the lint level is defined here
--> $DIR/reachable-patterns.rs:69:16
|
LL | #[warn(non_exhaustive_omitted_patterns)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
= help: ensure that all possible cases are being handled by adding the suggested match arms
= note: the matched value is of type `Bar` and the `non_exhaustive_omitted_patterns` attribute was found
Explanation
Structs and enums tagged with #[non_exhaustive]
force the user to add a
(potentially redundant) wildcard when pattern-matching, to allow for future
addition of fields or variants. The non_exhaustive_omitted_patterns
lint
detects when such a wildcard happens to actually catch some fields/variants.
In other words, when the match without the wildcard would not be exhaustive.
This lets the user be informed if new fields/variants were added.
noop-method-call
The noop_method_call
lint detects specific calls to noop methods
such as a calling <&T as Clone>::clone
where T: !Clone
.
Example
#![allow(unused)] fn main() { #![allow(unused)] #![warn(noop_method_call)] struct Foo; let foo = &Foo; let clone: &Foo = foo.clone(); }
This will produce:
warning: call to `.clone()` on a reference in this situation does nothing
--> lint_example.rs:6:22
|
6 | let clone: &Foo = foo.clone();
| ^^^^^^^^ unnecessary method call
|
= note: the type `&Foo` which `clone` is being called on is the same as the type returned from `clone`, so the method call does not do anything and can be removed
note: the lint level is defined here
--> lint_example.rs:2:9
|
2 | #![warn(noop_method_call)]
| ^^^^^^^^^^^^^^^^
Explanation
Some method calls are noops meaning that they do nothing. Usually such methods
are the result of blanket implementations that happen to create some method invocations
that end up not doing anything. For instance, Clone
is implemented on all &T
, but
calling clone
on a &T
where T
does not implement clone, actually doesn't do anything
as references are copy. This lint detects these calls and warns the user about them.
pointer-structural-match
The pointer_structural_match
lint detects pointers used in patterns whose behaviour
cannot be relied upon across compiler versions and optimization levels.
Example
#![deny(pointer_structural_match)] fn foo(a: usize, b: usize) -> usize { a + b } const FOO: fn(usize, usize) -> usize = foo; fn main() { match FOO { FOO => {}, _ => {}, } }
This will produce:
error: function pointers and unsized pointers in patterns behave unpredictably and should not be relied upon. See https://github.com/rust-lang/rust/issues/70861 for details.
--> lint_example.rs:6:9
|
6 | FOO => {},
| ^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #62411 <https://github.com/rust-lang/rust/issues/70861>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(pointer_structural_match)]
| ^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
Previous versions of Rust allowed function pointers and wide raw pointers in patterns. While these work in many cases as expected by users, it is possible that due to optimizations pointers are "not equal to themselves" or pointers to different functions compare as equal during runtime. This is because LLVM optimizations can deduplicate functions if their bodies are the same, thus also making pointers to these functions point to the same location. Additionally functions may get duplicated if they are instantiated in different crates and not deduplicated again via LTO.
rust-2021-incompatible-closure-captures
The rust_2021_incompatible_closure_captures
lint detects variables that aren't completely
captured in Rust 2021, such that the Drop
order of their fields may differ between
Rust 2018 and 2021.
It can also detect when a variable implements a trait like Send
, but one of its fields does not,
and the field is captured by a closure and used with the assumption that said field implements
the same trait as the root variable.
Example of drop reorder
#![deny(rust_2021_incompatible_closure_captures)] #![allow(unused)] struct FancyInteger(i32); impl Drop for FancyInteger { fn drop(&mut self) { println!("Just dropped {}", self.0); } } struct Point { x: FancyInteger, y: FancyInteger } fn main() { let p = Point { x: FancyInteger(10), y: FancyInteger(20) }; let c = || { let x = p.x; }; c(); // ... More code ... }
This will produce:
error: changes to closure capture in Rust 2021 will affect drop order
--> lint_example.rs:17:11
|
17 | let c = || {
| ^^
18 | let x = p.x;
| --- in Rust 2018, this closure captures all of `p`, but in Rust 2021, it will only capture `p.x`
...
24 | }
| - in Rust 2018, `p` is dropped here, but in Rust 2021, only `p.x` will be dropped here as part of the closure
|
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/disjoint-capture-in-closures.html>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(rust_2021_incompatible_closure_captures)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
help: add a dummy let to cause `p` to be fully captured
|
17 ~ let c = || {
18 + let _ = &p;
|
Explanation
In the above example, p.y
will be dropped at the end of f
instead of
with c
in Rust 2021.
Example of auto-trait
#![deny(rust_2021_incompatible_closure_captures)] use std::thread; struct Pointer(*mut i32); unsafe impl Send for Pointer {} fn main() { let mut f = 10; let fptr = Pointer(&mut f as *mut i32); thread::spawn(move || unsafe { *fptr.0 = 20; }); }
This will produce:
error: changes to closure capture in Rust 2021 will affect which traits the closure implements
--> lint_example.rs:10:19
|
10 | thread::spawn(move || unsafe {
| ^^^^^^^ in Rust 2018, this closure implements `Send` as `fptr` implements `Send`, but in Rust 2021, this closure will no longer implement `Send` because `fptr` is not fully captured and `fptr.0` does not implement `Send`
11 | *fptr.0 = 20;
| ------- in Rust 2018, this closure captures all of `fptr`, but in Rust 2021, it will only capture `fptr.0`
|
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/disjoint-capture-in-closures.html>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(rust_2021_incompatible_closure_captures)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
help: add a dummy let to cause `fptr` to be fully captured
|
10 ~ thread::spawn(move || { let _ = &fptr; unsafe {
11 | *fptr.0 = 20;
12 ~ } });
|
Explanation
In the above example, only fptr.0
is captured in Rust 2021.
The field is of type *mut i32
, which doesn't implement Send
,
making the code invalid as the field cannot be sent between threads safely.
rust-2021-incompatible-or-patterns
The rust_2021_incompatible_or_patterns
lint detects usage of old versions of or-patterns.
Example
#![deny(rust_2021_incompatible_or_patterns)] macro_rules! match_any { ( $expr:expr , $( $( $pat:pat )|+ => $expr_arm:expr ),+ ) => { match $expr { $( $( $pat => $expr_arm, )+ )+ } }; } fn main() { let result: Result<i64, i32> = Err(42); let int: i64 = match_any!(result, Ok(i) | Err(i) => i.into()); assert_eq!(int, 42); }
This will produce:
error: the meaning of the `pat` fragment specifier is changing in Rust 2021, which may affect this macro
--> lint_example.rs:4:26
|
4 | ( $expr:expr , $( $( $pat:pat )|+ => $expr_arm:expr ),+ ) => {
| ^^^^^^^^ help: use pat_param to preserve semantics: `$pat:pat_param`
|
= warning: this is accepted in the current edition (Rust 2018) but is a hard error in Rust 2021!
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/or-patterns-macro-rules.html>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(rust_2021_incompatible_or_patterns)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
In Rust 2021, the pat
matcher will match additional patterns, which include the |
character.
rust-2021-prefixes-incompatible-syntax
The rust_2021_prefixes_incompatible_syntax
lint detects identifiers that will be parsed as a
prefix instead in Rust 2021.
Example
#![allow(unused)] #![deny(rust_2021_prefixes_incompatible_syntax)] fn main() { macro_rules! m { (z $x:expr) => (); } m!(z"hey"); }
This will produce:
error: prefix `z` is unknown
--> lint_example.rs:8:4
|
8 | m!(z"hey");
| ^ unknown prefix
|
= warning: this is accepted in the current edition (Rust 2018) but is a hard error in Rust 2021!
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/reserving-syntax.html>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(rust_2021_prefixes_incompatible_syntax)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
help: insert whitespace here to avoid this being parsed as a prefix in Rust 2021
|
8 | m!(z "hey");
| +
Explanation
In Rust 2015 and 2018, z"hey"
is two tokens: the identifier z
followed by the string literal "hey"
. In Rust 2021, the z
is
considered a prefix for "hey"
.
This lint suggests to add whitespace between the z
and "hey"
tokens
to keep them separated in Rust 2021.
rust-2021-prelude-collisions
The rust_2021_prelude_collisions
lint detects the usage of trait methods which are ambiguous
with traits added to the prelude in future editions.
Example
#![deny(rust_2021_prelude_collisions)] trait Foo { fn try_into(self) -> Result<String, !>; } impl Foo for &str { fn try_into(self) -> Result<String, !> { Ok(String::from(self)) } } fn main() { let x: String = "3".try_into().unwrap(); // ^^^^^^^^ // This call to try_into matches both Foo:try_into and TryInto::try_into as // `TryInto` has been added to the Rust prelude in 2021 edition. println!("{x}"); }
This will produce:
error: trait method `try_into` will become ambiguous in Rust 2021
--> lint_example.rs:14:21
|
14 | let x: String = "3".try_into().unwrap();
| ^^^^^^^^^^^^^^ help: disambiguate the associated function: `Foo::try_into(&*"3")`
|
= warning: this is accepted in the current edition (Rust 2018) but is a hard error in Rust 2021!
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/prelude.html>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(rust_2021_prelude_collisions)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
In Rust 2021, one of the important introductions is the prelude changes, which add
TryFrom
, TryInto
, and FromIterator
into the standard library's prelude. Since this
results in an ambiguity as to which method/function to call when an existing try_into
method is called via dot-call syntax or a try_from
/from_iter
associated function
is called directly on a type.
single-use-lifetimes
The single_use_lifetimes
lint detects lifetimes that are only used
once.
Example
#![allow(unused)] #![deny(single_use_lifetimes)] fn main() { fn foo<'a>(x: &'a u32) {} }
This will produce:
error: lifetime parameter `'a` only used once
--> lint_example.rs:4:8
|
4 | fn foo<'a>(x: &'a u32) {}
| ^^ -- ...is used only here
| |
| this lifetime...
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(single_use_lifetimes)]
| ^^^^^^^^^^^^^^^^^^^^
help: elide the single-use lifetime
|
4 - fn foo<'a>(x: &'a u32) {}
4 + fn foo(x: &u32) {}
|
Explanation
Specifying an explicit lifetime like 'a
in a function or impl
should only be used to link together two things. Otherwise, you should
just use '_
to indicate that the lifetime is not linked to anything,
or elide the lifetime altogether if possible.
This lint is "allow" by default because it was introduced at a time
when '_
and elided lifetimes were first being introduced, and this
lint would be too noisy. Also, there are some known false positives
that it produces. See RFC 2115 for historical context, and issue
#44752 for more details.
trivial-casts
The trivial_casts
lint detects trivial casts which could be replaced
with coercion, which may require type ascription or a temporary
variable.
Example
#![allow(unused)] #![deny(trivial_casts)] fn main() { let x: &u32 = &42; let y = x as *const u32; }
This will produce:
error: trivial cast: `&u32` as `*const u32`
--> lint_example.rs:4:9
|
4 | let y = x as *const u32;
| ^^^^^^^^^^^^^^^
|
= help: cast can be replaced by coercion; this might require a temporary variable
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(trivial_casts)]
| ^^^^^^^^^^^^^
Explanation
A trivial cast is a cast e as T
where e
has type U
and U
is a
subtype of T
. This type of cast is usually unnecessary, as it can be
usually be inferred.
This lint is "allow" by default because there are situations, such as with FFI interfaces or complex type aliases, where it triggers incorrectly, or in situations where it will be more difficult to clearly express the intent. It may be possible that this will become a warning in the future, possibly with type ascription providing a convenient way to work around the current issues. See RFC 401 for historical context.
trivial-numeric-casts
The trivial_numeric_casts
lint detects trivial numeric casts of types
which could be removed.
Example
#![allow(unused)] #![deny(trivial_numeric_casts)] fn main() { let x = 42_i32 as i32; }
This will produce:
error: trivial numeric cast: `i32` as `i32`
--> lint_example.rs:3:9
|
3 | let x = 42_i32 as i32;
| ^^^^^^^^^^^^^
|
= help: cast can be replaced by coercion; this might require a temporary variable
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(trivial_numeric_casts)]
| ^^^^^^^^^^^^^^^^^^^^^
Explanation
A trivial numeric cast is a cast of a numeric type to the same numeric type. This type of cast is usually unnecessary.
This lint is "allow" by default because there are situations, such as with FFI interfaces or complex type aliases, where it triggers incorrectly, or in situations where it will be more difficult to clearly express the intent. It may be possible that this will become a warning in the future, possibly with type ascription providing a convenient way to work around the current issues. See RFC 401 for historical context.
unreachable-pub
The unreachable_pub
lint triggers for pub
items not reachable from
the crate root.
Example
#![allow(unused)] #![deny(unreachable_pub)] fn main() { mod foo { pub mod bar { } } }
This will produce:
error: unreachable `pub` item
--> lint_example.rs:4:5
|
4 | pub mod bar {
| ---^^^^^^^^
| |
| help: consider restricting its visibility: `pub(crate)`
|
= help: or consider exporting it for use by other crates
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unreachable_pub)]
| ^^^^^^^^^^^^^^^
Explanation
A bare pub
visibility may be misleading if the item is not actually
publicly exported from the crate. The pub(crate)
visibility is
recommended to be used instead, which more clearly expresses the intent
that the item is only visible within its own crate.
This lint is "allow" by default because it will trigger for a large amount existing Rust code, and has some false-positives. Eventually it is desired for this to become warn-by-default.
unsafe-code
The unsafe_code
lint catches usage of unsafe
code.
Example
#![deny(unsafe_code)] fn main() { unsafe { } }
This will produce:
error: usage of an `unsafe` block
--> lint_example.rs:3:5
|
3 | / unsafe {
4 | |
5 | | }
| |_____^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unsafe_code)]
| ^^^^^^^^^^^
Explanation
This lint is intended to restrict the usage of unsafe
, which can be
difficult to use correctly.
unsafe-op-in-unsafe-fn
The unsafe_op_in_unsafe_fn
lint detects unsafe operations in unsafe
functions without an explicit unsafe block.
Example
#![deny(unsafe_op_in_unsafe_fn)] unsafe fn foo() {} unsafe fn bar() { foo(); } fn main() {}
This will produce:
error: call to unsafe function is unsafe and requires unsafe block (error E0133)
--> lint_example.rs:6:5
|
6 | foo();
| ^^^^^ call to unsafe function
|
= note: consult the function's documentation for information on how to avoid undefined behavior
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unsafe_op_in_unsafe_fn)]
| ^^^^^^^^^^^^^^^^^^^^^^
Explanation
Currently, an unsafe fn
allows any unsafe operation within its
body. However, this can increase the surface area of code that needs
to be scrutinized for proper behavior. The unsafe
block provides a
convenient way to make it clear exactly which parts of the code are
performing unsafe operations. In the future, it is desired to change
it so that unsafe operations cannot be performed in an unsafe fn
without an unsafe
block.
The fix to this is to wrap the unsafe code in an unsafe
block.
This lint is "allow" by default since this will affect a large amount of existing code, and the exact plan for increasing the severity is still being considered. See RFC #2585 and issue #71668 for more details.
unstable-features
The unstable_features
is deprecated and should no longer be used.
unused-crate-dependencies
The unused_crate_dependencies
lint detects crate dependencies that
are never used.
Example
#![deny(unused_crate_dependencies)]
This will produce:
error: external crate `regex` unused in `lint_example`: remove the dependency or add `use regex as _;`
|
note: the lint level is defined here
--> src/lib.rs:1:9
|
1 | #![deny(unused_crate_dependencies)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
After removing the code that uses a dependency, this usually also
requires removing the dependency from the build configuration.
However, sometimes that step can be missed, which leads to time wasted
building dependencies that are no longer used. This lint can be
enabled to detect dependencies that are never used (more specifically,
any dependency passed with the --extern
command-line flag that is
never referenced via use
, extern crate
, or in any path).
This lint is "allow" by default because it can provide false positives depending on how the build system is configured. For example, when using Cargo, a "package" consists of multiple crates (such as a library and a binary), but the dependencies are defined for the package as a whole. If there is a dependency that is only used in the binary, but not the library, then the lint will be incorrectly issued in the library.
unused-extern-crates
The unused_extern_crates
lint guards against extern crate
items
that are never used.
Example
#![allow(unused)] #![deny(unused_extern_crates)] fn main() { extern crate proc_macro; }
This will produce:
error: unused extern crate
--> lint_example.rs:3:1
|
3 | extern crate proc_macro;
| ^^^^^^^^^^^^^^^^^^^^^^^^ help: remove it
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unused_extern_crates)]
| ^^^^^^^^^^^^^^^^^^^^
Explanation
extern crate
items that are unused have no effect and should be
removed. Note that there are some cases where specifying an extern crate
is desired for the side effect of ensuring the given crate is
linked, even though it is not otherwise directly referenced. The lint
can be silenced by aliasing the crate to an underscore, such as
extern crate foo as _
. Also note that it is no longer idiomatic to
use extern crate
in the 2018 edition, as extern crates are now
automatically added in scope.
This lint is "allow" by default because it can be noisy, and produce
false-positives. If a dependency is being removed from a project, it
is recommended to remove it from the build configuration (such as
Cargo.toml
) to ensure stale build entries aren't left behind.
unused-import-braces
The unused_import_braces
lint catches unnecessary braces around an
imported item.
Example
#![deny(unused_import_braces)] use test::{A}; pub mod test { pub struct A; } fn main() {}
This will produce:
error: braces around A is unnecessary
--> lint_example.rs:2:1
|
2 | use test::{A};
| ^^^^^^^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unused_import_braces)]
| ^^^^^^^^^^^^^^^^^^^^
Explanation
If there is only a single item, then remove the braces (use test::A;
for example).
This lint is "allow" by default because it is only enforcing a stylistic choice.
unused-lifetimes
The unused_lifetimes
lint detects lifetime parameters that are never
used.
Example
#![allow(unused)] fn main() { #[deny(unused_lifetimes)] pub fn foo<'a>() {} }
This will produce:
error: lifetime parameter `'a` never used
--> lint_example.rs:4:12
|
4 | pub fn foo<'a>() {}
| -^^- help: elide the unused lifetime
|
note: the lint level is defined here
--> lint_example.rs:2:8
|
2 | #[deny(unused_lifetimes)]
| ^^^^^^^^^^^^^^^^
Explanation
Unused lifetime parameters may signal a mistake or unfinished code. Consider removing the parameter.
unused-macro-rules
The unused_macro_rules
lint detects macro rules that were not used.
Note that the lint is distinct from the unused_macros
lint, which
fires if the entire macro is never called, while this lint fires for
single unused rules of the macro that is otherwise used.
unused_macro_rules
fires only if unused_macros
wouldn't fire.
Example
#[warn(unused_macro_rules)] macro_rules! unused_empty { (hello) => { println!("Hello, world!") }; // This rule is unused () => { println!("empty") }; // This rule is used } fn main() { unused_empty!(hello); }
This will produce:
warning: 2nd rule of macro `unused_empty` is never used
--> lint_example.rs:4:5
|
4 | () => { println!("empty") }; // This rule is used
| ^^
|
note: the lint level is defined here
--> lint_example.rs:1:8
|
1 | #[warn(unused_macro_rules)]
| ^^^^^^^^^^^^^^^^^^
Explanation
Unused macro rules may signal a mistake or unfinished code. Furthermore, they slow down compilation. Right now, silencing the warning is not supported on a single rule level, so you have to add an allow to the entire macro definition.
If you intended to export the macro to make it
available outside of the crate, use the macro_export
attribute.
unused-qualifications
The unused_qualifications
lint detects unnecessarily qualified
names.
Example
#![deny(unused_qualifications)] mod foo { pub fn bar() {} } fn main() { use foo::bar; foo::bar(); }
This will produce:
error: unnecessary qualification
--> lint_example.rs:8:5
|
8 | foo::bar();
| ^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unused_qualifications)]
| ^^^^^^^^^^^^^^^^^^^^^
Explanation
If an item from another module is already brought into scope, then
there is no need to qualify it in this case. You can call bar()
directly, without the foo::
.
This lint is "allow" by default because it is somewhat pedantic, and doesn't indicate an actual problem, but rather a stylistic choice, and can be noisy when refactoring or moving around code.
unused-results
The unused_results
lint checks for the unused result of an
expression in a statement.
Example
#![deny(unused_results)] fn foo<T>() -> T { panic!() } fn main() { foo::<usize>(); }
This will produce:
error: unused result of type `usize`
--> lint_example.rs:5:5
|
5 | foo::<usize>();
| ^^^^^^^^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(unused_results)]
| ^^^^^^^^^^^^^^
Explanation
Ignoring the return value of a function may indicate a mistake. In
cases were it is almost certain that the result should be used, it is
recommended to annotate the function with the must_use
attribute.
Failure to use such a return value will trigger the unused_must_use
lint which is warn-by-default. The unused_results
lint is
essentially the same, but triggers for all return values.
This lint is "allow" by default because it can be noisy, and may not be
an actual problem. For example, calling the remove
method of a Vec
or HashMap
returns the previous value, which you may not care about.
Using this lint would require explicitly ignoring or discarding such
values.
unused-tuple-struct-fields
The unused_tuple_struct_fields
lint detects fields of tuple structs
that are never read.
Example
#[warn(unused_tuple_struct_fields)]
struct S(i32, i32, i32);
let s = S(1, 2, 3);
let _ = (s.0, s.2);
{{produces}}
Explanation
Tuple struct fields that are never read anywhere may indicate a mistake or unfinished code. To silence this warning, consider removing the unused field(s) or, to preserve the numbering of the remaining fields, change the unused field(s) to have unit type.
variant-size-differences
The variant_size_differences
lint detects enums with widely varying
variant sizes.
Example
#![allow(unused)] #![deny(variant_size_differences)] fn main() { enum En { V0(u8), VBig([u8; 1024]), } }
This will produce:
error: enum variant is more than three times larger (1024 bytes) than the next largest
--> lint_example.rs:5:5
|
5 | VBig([u8; 1024]),
| ^^^^^^^^^^^^^^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(variant_size_differences)]
| ^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
It can be a mistake to add a variant to an enum that is much larger than the other variants, bloating the overall size required for all variants. This can impact performance and memory usage. This is triggered if one variant is more than 3 times larger than the second-largest variant.
Consider placing the large variant's contents on the heap (for example
via Box
) to keep the overall size of the enum itself down.
This lint is "allow" by default because it can be noisy, and may not be an actual problem. Decisions about this should be guided with profiling and benchmarking.
Warn-by-default Lints
These lints are all set to the 'warn' level by default.
anonymous_parameters
array_into_iter
asm_sub_register
bad_asm_style
bare_trait_objects
bindings_with_variant_name
break_with_label_and_loop
clashing_extern_declarations
coherence_leak_check
confusable_idents
const_evaluatable_unchecked
const_item_mutation
dead_code
deprecated
deprecated_where_clause_location
deref_into_dyn_supertrait
deref_nullptr
drop_bounds
duplicate_macro_attributes
dyn_drop
ellipsis_inclusive_range_patterns
exported_private_dependencies
for_loops_over_fallibles
forbidden_lint_groups
function_item_references
illegal_floating_point_literal_pattern
improper_ctypes
improper_ctypes_definitions
incomplete_features
indirect_structural_match
inline_no_sanitize
invalid_doc_attributes
invalid_value
irrefutable_let_patterns
large_assignments
late_bound_lifetime_arguments
legacy_derive_helpers
mixed_script_confusables
named_arguments_used_positionally
no_mangle_generic_items
non_camel_case_types
non_fmt_panics
non_shorthand_field_patterns
non_snake_case
non_upper_case_globals
nontrivial_structural_match
opaque_hidden_inferred_bound
overlapping_range_endpoints
path_statements
private_in_public
redundant_semicolons
renamed_and_removed_lints
repr_transparent_external_private_fields
semicolon_in_expressions_from_macros
special_module_name
stable_features
suspicious_auto_trait_impls
temporary_cstring_as_ptr
trivial_bounds
type_alias_bounds
tyvar_behind_raw_pointer
uncommon_codepoints
unconditional_recursion
undefined_naked_function_abi
unexpected_cfgs
unfulfilled_lint_expectations
uninhabited_static
unknown_lints
unnameable_test_items
unreachable_code
unreachable_patterns
unstable_name_collisions
unstable_syntax_pre_expansion
unsupported_calling_conventions
unused_allocation
unused_assignments
unused_attributes
unused_braces
unused_comparisons
unused_doc_comments
unused_features
unused_imports
unused_labels
unused_macros
unused_must_use
unused_mut
unused_parens
unused_unsafe
unused_variables
warnings
where_clauses_object_safety
while_true
anonymous-parameters
The anonymous_parameters
lint detects anonymous parameters in trait
definitions.
Example
#![deny(anonymous_parameters)] // edition 2015 pub trait Foo { fn foo(usize); } fn main() {}
This will produce:
error: anonymous parameters are deprecated and will be removed in the next edition
--> lint_example.rs:4:12
|
4 | fn foo(usize);
| ^^^^^ help: try naming the parameter or explicitly ignoring it: `_: usize`
|
= warning: this is accepted in the current edition (Rust 2015) but is a hard error in Rust 2018!
= note: for more information, see issue #41686 <https://github.com/rust-lang/rust/issues/41686>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(anonymous_parameters)]
| ^^^^^^^^^^^^^^^^^^^^
Explanation
This syntax is mostly a historical accident, and can be worked around
quite easily by adding an _
pattern or a descriptive identifier:
#![allow(unused)] fn main() { trait Foo { fn foo(_: usize); } }
This syntax is now a hard error in the 2018 edition. In the 2015
edition, this lint is "warn" by default. This lint
enables the cargo fix
tool with the --edition
flag to
automatically transition old code from the 2015 edition to 2018. The
tool will run this lint and automatically apply the
suggested fix from the compiler (which is to add _
to each
parameter). This provides a completely automated way to update old
code for a new edition. See issue #41686 for more details.
array-into-iter
The array_into_iter
lint detects calling into_iter
on arrays.
Example
#![allow(unused)] fn main() { #![allow(unused)] [1, 2, 3].into_iter().for_each(|n| { *n; }); }
This will produce:
warning: this method call resolves to `<&[T; N] as IntoIterator>::into_iter` (due to backwards compatibility), but will resolve to <[T; N] as IntoIterator>::into_iter in Rust 2021
--> lint_example.rs:3:11
|
3 | [1, 2, 3].into_iter().for_each(|n| { *n; });
| ^^^^^^^^^
|
= warning: this changes meaning in Rust 2021
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/IntoIterator-for-arrays.html>
= note: `#[warn(array_into_iter)]` on by default
help: use `.iter()` instead of `.into_iter()` to avoid ambiguity
|
3 | [1, 2, 3].iter().for_each(|n| { *n; });
| ~~~~
help: or use `IntoIterator::into_iter(..)` instead of `.into_iter()` to explicitly iterate by value
|
3 | IntoIterator::into_iter([1, 2, 3]).for_each(|n| { *n; });
| ++++++++++++++++++++++++ ~
Explanation
Since Rust 1.53, arrays implement IntoIterator
. However, to avoid
breakage, array.into_iter()
in Rust 2015 and 2018 code will still
behave as (&array).into_iter()
, returning an iterator over
references, just like in Rust 1.52 and earlier.
This only applies to the method call syntax array.into_iter()
, not to
any other syntax such as for _ in array
or IntoIterator::into_iter(array)
.
asm-sub-register
The asm_sub_register
lint detects using only a subset of a register
for inline asm inputs.
Example
#[cfg(target_arch="x86_64")]
use std::arch::asm;
fn main() {
#[cfg(target_arch="x86_64")]
unsafe {
asm!("mov {0}, {0}", in(reg) 0i16);
}
}
This will produce:
warning: formatting may not be suitable for sub-register argument
--> src/main.rs:7:19
|
7 | asm!("mov {0}, {0}", in(reg) 0i16);
| ^^^ ^^^ ---- for this argument
|
= note: `#[warn(asm_sub_register)]` on by default
= help: use the `x` modifier to have the register formatted as `ax`
= help: or use the `r` modifier to keep the default formatting of `rax`
Explanation
Registers on some architectures can use different names to refer to a subset of the register. By default, the compiler will use the name for the full register size. To explicitly use a subset of the register, you can override the default by using a modifier on the template string operand to specify when subregister to use. This lint is issued if you pass in a value with a smaller data type than the default register size, to alert you of possibly using the incorrect width. To fix this, add the suggested modifier to the template, or cast the value to the correct size.
See register template modifiers in the reference for more details.
bad-asm-style
The bad_asm_style
lint detects the use of the .intel_syntax
and
.att_syntax
directives.
Example
#[cfg(target_arch="x86_64")]
use std::arch::asm;
fn main() {
#[cfg(target_arch="x86_64")]
unsafe {
asm!(
".att_syntax",
"movq %{0}, %{0}", in(reg) 0usize
);
}
}
This will produce:
warning: avoid using `.att_syntax`, prefer using `options(att_syntax)` instead
--> src/main.rs:8:14
|
8 | ".att_syntax",
| ^^^^^^^^^^^
|
= note: `#[warn(bad_asm_style)]` on by default
Explanation
On x86, asm!
uses the intel assembly syntax by default. While this
can be switched using assembler directives like .att_syntax
, using the
att_syntax
option is recommended instead because it will also properly
prefix register placeholders with %
as required by AT&T syntax.
bare-trait-objects
The bare_trait_objects
lint suggests using dyn Trait
for trait
objects.
Example
#![allow(unused)] fn main() { trait Trait { } fn takes_trait_object(_: Box<Trait>) { } }
This will produce:
warning: trait objects without an explicit `dyn` are deprecated
--> lint_example.rs:4:30
|
4 | fn takes_trait_object(_: Box<Trait>) {
| ^^^^^
|
= warning: this is accepted in the current edition (Rust 2018) but is a hard error in Rust 2021!
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/warnings-promoted-to-error.html>
= note: `#[warn(bare_trait_objects)]` on by default
help: use `dyn`
|
4 | fn takes_trait_object(_: Box<dyn Trait>) {
| +++
Explanation
Without the dyn
indicator, it can be ambiguous or confusing when
reading code as to whether or not you are looking at a trait object.
The dyn
keyword makes it explicit, and adds a symmetry to contrast
with impl Trait
.
bindings-with-variant-name
The bindings_with_variant_name
lint detects pattern bindings with
the same name as one of the matched variants.
Example
#![allow(unused)] fn main() { pub enum Enum { Foo, Bar, } pub fn foo(x: Enum) { match x { Foo => {} Bar => {} } } }
This will produce:
warning[E0170]: pattern binding `Foo` is named the same as one of the variants of the type `Enum`
--> lint_example.rs:9:9
|
9 | Foo => {}
| ^^^ help: to match on the variant, qualify the path: `Enum::Foo`
|
= note: `#[warn(bindings_with_variant_name)]` on by default
Explanation
It is usually a mistake to specify an enum variant name as an
identifier pattern. In the example above, the match
arms are
specifying a variable name to bind the value of x
to. The second arm
is ignored because the first one matches all values. The likely
intent is that the arm was intended to match on the enum variant.
Two possible solutions are:
- Specify the enum variant using a path pattern, such as
Enum::Foo
. - Bring the enum variants into local scope, such as adding
use Enum::*;
to the beginning of thefoo
function in the example above.
break-with-label-and-loop
The break_with_label_and_loop
lint detects labeled break
expressions with
an unlabeled loop as their value expression.
Example
#![allow(unused)] fn main() { 'label: loop { break 'label loop { break 42; }; }; }
This will produce:
warning: this labeled break expression is easy to confuse with an unlabeled break with a labeled value expression
--> lint_example.rs:3:5
|
3 | break 'label loop { break 42; };
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(break_with_label_and_loop)]` on by default
help: wrap this expression in parentheses
|
3 | break 'label (loop { break 42; });
| + +
Explanation
In Rust, loops can have a label, and break
expressions can refer to that label to
break out of specific loops (and not necessarily the innermost one). break
expressions
can also carry a value expression, which can be another loop. A labeled break
with an
unlabeled loop as its value expression is easy to confuse with an unlabeled break with
a labeled loop and is thus discouraged (but allowed for compatibility); use parentheses
around the loop expression to silence this warning. Unlabeled break
expressions with
labeled loops yield a hard error, which can also be silenced by wrapping the expression
in parentheses.
clashing-extern-declarations
The clashing_extern_declarations
lint detects when an extern fn
has been declared with the same name but different types.
Example
#![allow(unused)] fn main() { mod m { extern "C" { fn foo(); } } extern "C" { fn foo(_: u32); } }
This will produce:
warning: `foo` redeclared with a different signature
--> lint_example.rs:9:5
|
4 | fn foo();
| --------- `foo` previously declared here
...
9 | fn foo(_: u32);
| ^^^^^^^^^^^^^^^ this signature doesn't match the previous declaration
|
= note: expected `unsafe extern "C" fn()`
found `unsafe extern "C" fn(u32)`
= note: `#[warn(clashing_extern_declarations)]` on by default
Explanation
Because two symbols of the same name cannot be resolved to two
different functions at link time, and one function cannot possibly
have two types, a clashing extern declaration is almost certainly a
mistake. Check to make sure that the extern
definitions are correct
and equivalent, and possibly consider unifying them in one location.
This lint does not run between crates because a project may have
dependencies which both rely on the same extern function, but declare
it in a different (but valid) way. For example, they may both declare
an opaque type for one or more of the arguments (which would end up
distinct types), or use types that are valid conversions in the
language the extern fn
is defined in. In these cases, the compiler
can't say that the clashing declaration is incorrect.
coherence-leak-check
The coherence_leak_check
lint detects conflicting implementations of
a trait that are only distinguished by the old leak-check code.
Example
#![allow(unused)] fn main() { trait SomeTrait { } impl SomeTrait for for<'a> fn(&'a u8) { } impl<'a> SomeTrait for fn(&'a u8) { } }
This will produce:
warning: conflicting implementations of trait `main::SomeTrait` for type `for<'a> fn(&'a u8)`
--> lint_example.rs:4:1
|
3 | impl SomeTrait for for<'a> fn(&'a u8) { }
| ------------------------------------- first implementation here
4 | impl<'a> SomeTrait for fn(&'a u8) { }
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ conflicting implementation for `for<'a> fn(&'a u8)`
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #56105 <https://github.com/rust-lang/rust/issues/56105>
= note: this behavior recently changed as a result of a bug fix; see rust-lang/rust#56105 for details
= note: `#[warn(coherence_leak_check)]` on by default
Explanation
In the past, the compiler would accept trait implementations for identical functions that differed only in where the lifetime binder appeared. Due to a change in the borrow checker implementation to fix several bugs, this is no longer allowed. However, since this affects existing code, this is a future-incompatible lint to transition this to a hard error in the future.
Code relying on this pattern should introduce "newtypes",
like struct Foo(for<'a> fn(&'a u8))
.
See issue #56105 for more details.
confusable-idents
The confusable_idents
lint detects visually confusable pairs between
identifiers.
Example
#![allow(unused)] fn main() { // Latin Capital Letter E With Caron pub const Ě: i32 = 1; // Latin Capital Letter E With Breve pub const Ĕ: i32 = 2; }
This will produce:
warning: identifier pair considered confusable between `Ě` and `Ĕ`
--> lint_example.rs:5:11
|
3 | pub const Ě: i32 = 1;
| - this is where the previous identifier occurred
4 | // Latin Capital Letter E With Breve
5 | pub const Ĕ: i32 = 2;
| ^
|
= note: `#[warn(confusable_idents)]` on by default
Explanation
This lint warns when different identifiers may appear visually similar, which can cause confusion.
The confusable detection algorithm is based on Unicode® Technical
Standard #39 Unicode Security Mechanisms Section 4 Confusable
Detection. For every distinct identifier X execute
the function skeleton(X)
. If there exist two distinct identifiers X
and Y in the same crate where skeleton(X) = skeleton(Y)
report it.
The compiler uses the same mechanism to check if an identifier is too
similar to a keyword.
Note that the set of confusable characters may change over time. Beware that if you "forbid" this lint that existing code may fail in the future.
const-evaluatable-unchecked
The const_evaluatable_unchecked
lint detects a generic constant used
in a type.
Example
#![allow(unused)] fn main() { const fn foo<T>() -> usize { if std::mem::size_of::<*mut T>() < 8 { // size of *mut T does not depend on T 4 } else { 8 } } fn test<T>() { let _ = [0; foo::<T>()]; } }
This will produce:
warning: cannot use constants which depend on generic parameters in types
--> lint_example.rs:11:17
|
11 | let _ = [0; foo::<T>()];
| ^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #76200 <https://github.com/rust-lang/rust/issues/76200>
= note: `#[warn(const_evaluatable_unchecked)]` on by default
Explanation
In the 1.43 release, some uses of generic parameters in array repeat expressions were accidentally allowed. This is a future-incompatible lint to transition this to a hard error in the future. See issue #76200 for a more detailed description and possible fixes.
const-item-mutation
The const_item_mutation
lint detects attempts to mutate a const
item.
Example
const FOO: [i32; 1] = [0]; fn main() { FOO[0] = 1; // This will print "[0]". println!("{:?}", FOO); }
This will produce:
warning: attempting to modify a `const` item
--> lint_example.rs:4:5
|
4 | FOO[0] = 1;
| ^^^^^^^^^^
|
= note: each usage of a `const` item creates a new temporary; the original `const` item will not be modified
note: `const` item defined here
--> lint_example.rs:1:1
|
1 | const FOO: [i32; 1] = [0];
| ^^^^^^^^^^^^^^^^^^^
= note: `#[warn(const_item_mutation)]` on by default
Explanation
Trying to directly mutate a const
item is almost always a mistake.
What is happening in the example above is that a temporary copy of the
const
is mutated, but the original const
is not. Each time you
refer to the const
by name (such as FOO
in the example above), a
separate copy of the value is inlined at that location.
This lint checks for writing directly to a field (FOO.field = some_value
) or array entry (FOO[0] = val
), or taking a mutable
reference to the const item (&mut FOO
), including through an
autoderef (FOO.some_mut_self_method()
).
There are various alternatives depending on what you are trying to accomplish:
- First, always reconsider using mutable globals, as they can be difficult to use correctly, and can make the code more difficult to use or understand.
- If you are trying to perform a one-time initialization of a global:
- If the value can be computed at compile-time, consider using const-compatible values (see Constant Evaluation).
- For more complex single-initialization cases, consider using a
third-party crate, such as
lazy_static
oronce_cell
. - If you are using the nightly channel, consider the new
lazy
module in the standard library.
- If you truly need a mutable global, consider using a
static
, which has a variety of options:- Simple data types can be directly defined and mutated with an
atomic
type. - More complex types can be placed in a synchronization primitive
like a
Mutex
, which can be initialized with one of the options listed above. - A mutable
static
is a low-level primitive, requiring unsafe. Typically This should be avoided in preference of something higher-level like one of the above.
- Simple data types can be directly defined and mutated with an
dead-code
The dead_code
lint detects unused, unexported items.
Example
#![allow(unused)] fn main() { fn foo() {} }
This will produce:
warning: function `foo` is never used
--> lint_example.rs:2:4
|
2 | fn foo() {}
| ^^^
|
= note: `#[warn(dead_code)]` on by default
Explanation
Dead code may signal a mistake or unfinished code. To silence the
warning for individual items, prefix the name with an underscore such
as _foo
. If it was intended to expose the item outside of the crate,
consider adding a visibility modifier like pub
. Otherwise consider
removing the unused code.
deprecated
The deprecated
lint detects use of deprecated items.
Example
#![allow(unused)] fn main() { #[deprecated] fn foo() {} fn bar() { foo(); } }
This will produce:
warning: use of deprecated function `main::foo`
--> lint_example.rs:6:5
|
6 | foo();
| ^^^
|
= note: `#[warn(deprecated)]` on by default
Explanation
Items may be marked "deprecated" with the deprecated
attribute to
indicate that they should no longer be used. Usually the attribute
should include a note on what to use instead, or check the
documentation.
deprecated-where-clause-location
The deprecated_where_clause_location
lint detects when a where clause in front of the equals
in an associated type.
Example
#![allow(unused)] fn main() { trait Trait { type Assoc<'a> where Self: 'a; } impl Trait for () { type Assoc<'a> where Self: 'a = (); } }
This will produce:
warning: where clause not allowed here
--> lint_example.rs:7:18
|
7 | type Assoc<'a> where Self: 'a = ();
| ^^^^^^^^^^^^^^
|
= note: see issue #89122 <https://github.com/rust-lang/rust/issues/89122> for more information
= note: `#[warn(deprecated_where_clause_location)]` on by default
help: move it to the end of the type declaration
|
7 - type Assoc<'a> where Self: 'a = ();
7 + type Assoc<'a> = () where Self: 'a;
|
Explanation
The preferred location for where clauses on associated types in impls is after the type. However, for most of generic associated types development, it was only accepted before the equals. To provide a transition period and further evaluate this change, both are currently accepted. At some point in the future, this may be disallowed at an edition boundary; but, that is undecided currently.
deref-into-dyn-supertrait
The deref_into_dyn_supertrait
lint is output whenever there is a use of the
Deref
implementation with a dyn SuperTrait
type as Output
.
These implementations will become shadowed when the trait_upcasting
feature is stabilized.
The deref
functions will no longer be called implicitly, so there might be behavior change.
Example
#![allow(unused)] #![deny(deref_into_dyn_supertrait)] #![allow(dead_code)] fn main() { use core::ops::Deref; trait A {} trait B: A {} impl<'a> Deref for dyn 'a + B { type Target = dyn A; fn deref(&self) -> &Self::Target { todo!() } } fn take_a(_: &dyn A) { } fn take_b(b: &dyn B) { take_a(b); } }
This will produce:
error: `dyn B` implements `Deref` with supertrait `(dyn A + 'static)` as output
--> lint_example.rs:19:12
|
19 | take_a(b);
| ^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #89460 <https://github.com/rust-lang/rust/issues/89460>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(deref_into_dyn_supertrait)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
The dyn upcasting coercion feature adds new coercion rules, taking priority over certain other coercion rules, which will cause some behavior change.
deref-nullptr
The deref_nullptr
lint detects when an null pointer is dereferenced,
which causes undefined behavior.
Example
#![allow(unused)] fn main() { #![allow(unused)] use std::ptr; unsafe { let x = &*ptr::null::<i32>(); let x = ptr::addr_of!(*ptr::null::<i32>()); let x = *(0 as *const i32); } }
This will produce:
warning: dereferencing a null pointer
--> lint_example.rs:5:14
|
5 | let x = &*ptr::null::<i32>();
| ^^^^^^^^^^^^^^^^^^^ this code causes undefined behavior when executed
|
= note: `#[warn(deref_nullptr)]` on by default
Explanation
Dereferencing a null pointer causes undefined behavior even as a place expression,
like &*(0 as *const i32)
or addr_of!(*(0 as *const i32))
.
drop-bounds
The drop_bounds
lint checks for generics with std::ops::Drop
as
bounds.
Example
#![allow(unused)] fn main() { fn foo<T: Drop>() {} }
This will produce:
warning: bounds on `T: Drop` are most likely incorrect, consider instead using `std::mem::needs_drop` to detect whether a type can be trivially dropped
--> lint_example.rs:2:11
|
2 | fn foo<T: Drop>() {}
| ^^^^
|
= note: `#[warn(drop_bounds)]` on by default
Explanation
A generic trait bound of the form T: Drop
is most likely misleading
and not what the programmer intended (they probably should have used
std::mem::needs_drop
instead).
Drop
bounds do not actually indicate whether a type can be trivially
dropped or not, because a composite type containing Drop
types does
not necessarily implement Drop
itself. Naïvely, one might be tempted
to write an implementation that assumes that a type can be trivially
dropped while also supplying a specialization for T: Drop
that
actually calls the destructor. However, this breaks down e.g. when T
is String
, which does not implement Drop
itself but contains a
Vec
, which does implement Drop
, so assuming T
can be trivially
dropped would lead to a memory leak here.
Furthermore, the Drop
trait only contains one method, Drop::drop
,
which may not be called explicitly in user code (E0040
), so there is
really no use case for using Drop
in trait bounds, save perhaps for
some obscure corner cases, which can use #[allow(drop_bounds)]
.
duplicate-macro-attributes
The duplicate_macro_attributes
lint detects when a #[test]
-like built-in macro
attribute is duplicated on an item. This lint may trigger on bench
, cfg_eval
, test
and test_case
.
Example
#[test]
#[test]
fn foo() {}
This will produce:
warning: duplicated attribute
--> src/lib.rs:2:1
|
2 | #[test]
| ^^^^^^^
|
= note: `#[warn(duplicate_macro_attributes)]` on by default
Explanation
A duplicated attribute may erroneously originate from a copy-paste and the effect of it being duplicated may not be obvious or desirable.
For instance, doubling the #[test]
attributes registers the test to be run twice with no
change to its environment.
dyn-drop
The dyn_drop
lint checks for trait objects with std::ops::Drop
.
Example
#![allow(unused)] fn main() { fn foo(_x: Box<dyn Drop>) {} }
This will produce:
warning: types that do not implement `Drop` can still have drop glue, consider instead using `std::mem::needs_drop` to detect whether a type is trivially dropped
--> lint_example.rs:2:20
|
2 | fn foo(_x: Box<dyn Drop>) {}
| ^^^^
|
= note: `#[warn(dyn_drop)]` on by default
Explanation
A trait object bound of the form dyn Drop
is most likely misleading
and not what the programmer intended.
Drop
bounds do not actually indicate whether a type can be trivially
dropped or not, because a composite type containing Drop
types does
not necessarily implement Drop
itself. Naïvely, one might be tempted
to write a deferred drop system, to pull cleaning up memory out of a
latency-sensitive code path, using dyn Drop
trait objects. However,
this breaks down e.g. when T
is String
, which does not implement
Drop
, but should probably be accepted.
To write a trait object bound that accepts anything, use a placeholder trait with a blanket implementation.
#![allow(unused)] fn main() { trait Placeholder {} impl<T> Placeholder for T {} fn foo(_x: Box<dyn Placeholder>) {} }
ellipsis-inclusive-range-patterns
The ellipsis_inclusive_range_patterns
lint detects the ...
range
pattern, which is deprecated.
Example
#![allow(unused)] fn main() { let x = 123; match x { 0...100 => {} _ => {} } }
This will produce:
warning: `...` range patterns are deprecated
--> lint_example.rs:4:6
|
4 | 0...100 => {}
| ^^^ help: use `..=` for an inclusive range
|
= warning: this is accepted in the current edition (Rust 2018) but is a hard error in Rust 2021!
= note: for more information, see <https://doc.rust-lang.org/nightly/edition-guide/rust-2021/warnings-promoted-to-error.html>
= note: `#[warn(ellipsis_inclusive_range_patterns)]` on by default
Explanation
The ...
range pattern syntax was changed to ..=
to avoid potential
confusion with the ..
range expression. Use the new form instead.
exported-private-dependencies
The exported_private_dependencies
lint detects private dependencies
that are exposed in a public interface.
Example
pub fn foo() -> Option<some_private_dependency::Thing> {
None
}
This will produce:
warning: type `bar::Thing` from private dependency 'bar' in public interface
--> src/lib.rs:3:1
|
3 | pub fn foo() -> Option<bar::Thing> {
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(exported_private_dependencies)]` on by default
Explanation
Dependencies can be marked as "private" to indicate that they are not exposed in the public interface of a crate. This can be used by Cargo to independently resolve those dependencies because it can assume it does not need to unify them with other packages using that same dependency. This lint is an indication of a violation of that contract.
To fix this, avoid exposing the dependency in your public interface. Or, switch the dependency to a public dependency.
Note that support for this is only available on the nightly channel. See RFC 1977 for more details, as well as the Cargo documentation.
for-loops-over-fallibles
The for_loops_over_fallibles
lint checks for for
loops over Option
or Result
values.
Example
#![allow(unused)] fn main() { let opt = Some(1); for x in opt { /* ... */} }
This will produce:
warning: for loop over an `Option`. This is more readably written as an `if let` statement
--> lint_example.rs:3:10
|
3 | for x in opt { /* ... */}
| ^^^
|
= note: `#[warn(for_loops_over_fallibles)]` on by default
help: to check pattern in a loop use `while let`
|
3 | while let Some(x) = opt { /* ... */}
| ~~~~~~~~~~~~~~~ ~~~
help: consider using `if let` to clear intent
|
3 | if let Some(x) = opt { /* ... */}
| ~~~~~~~~~~~~ ~~~
Explanation
Both Option
and Result
implement IntoIterator
trait, which allows using them in a for
loop.
for
loop over Option
or Result
will iterate either 0 (if the value is None
/Err(_)
)
or 1 time (if the value is Some(_)
/Ok(_)
). This is not very useful and is more clearly expressed
via if let
.
for
loop can also be accidentally written with the intention to call a function multiple times,
while the function returns Some(_)
, in these cases while let
loop should be used instead.
The "intended" use of IntoIterator
implementations for Option
and Result
is passing them to
generic code that expects something implementing IntoIterator
. For example using .chain(option)
to optionally add a value to an iterator.
forbidden-lint-groups
The forbidden_lint_groups
lint detects violations of
forbid
applied to a lint group. Due to a bug in the compiler,
these used to be overlooked entirely. They now generate a warning.
Example
#![forbid(warnings)] #![deny(bad_style)] fn main() {}
This will produce:
warning: deny(bad_style) incompatible with previous forbid
--> lint_example.rs:2:9
|
1 | #![forbid(warnings)]
| -------- `forbid` level set here
2 | #![deny(bad_style)]
| ^^^^^^^^^ overruled by previous forbid
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #81670 <https://github.com/rust-lang/rust/issues/81670>
= note: `#[warn(forbidden_lint_groups)]` on by default
Recommended fix
If your crate is using #![forbid(warnings)]
,
we recommend that you change to #![deny(warnings)]
.
Explanation
Due to a compiler bug, applying forbid
to lint groups
previously had no effect. The bug is now fixed but instead of
enforcing forbid
we issue this future-compatibility warning
to avoid breaking existing crates.
function-item-references
The function_item_references
lint detects function references that are
formatted with fmt::Pointer
or transmuted.
Example
fn foo() { } fn main() { println!("{:p}", &foo); }
This will produce:
warning: taking a reference to a function item does not give a function pointer
--> lint_example.rs:4:22
|
4 | println!("{:p}", &foo);
| ^^^^ help: cast `foo` to obtain a function pointer: `foo as fn()`
|
= note: `#[warn(function_item_references)]` on by default
Explanation
Taking a reference to a function may be mistaken as a way to obtain a
pointer to that function. This can give unexpected results when
formatting the reference as a pointer or transmuting it. This lint is
issued when function references are formatted as pointers, passed as
arguments bound by fmt::Pointer
or transmuted.
illegal-floating-point-literal-pattern
The illegal_floating_point_literal_pattern
lint detects
floating-point literals used in patterns.
Example
#![allow(unused)] fn main() { let x = 42.0; match x { 5.0 => {} _ => {} } }
This will produce:
warning: floating-point types cannot be used in patterns
--> lint_example.rs:5:5
|
5 | 5.0 => {}
| ^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #41620 <https://github.com/rust-lang/rust/issues/41620>
= note: `#[warn(illegal_floating_point_literal_pattern)]` on by default
Explanation
Previous versions of the compiler accepted floating-point literals in patterns, but it was later determined this was a mistake. The semantics of comparing floating-point values may not be clear in a pattern when contrasted with "structural equality". Typically you can work around this by using a match guard, such as:
#![allow(unused)] fn main() { let x = 42.0; match x { y if y == 5.0 => {} _ => {} } }
This is a future-incompatible lint to transition this to a hard error in the future. See issue #41620 for more details.
improper-ctypes
The improper_ctypes
lint detects incorrect use of types in foreign
modules.
Example
#![allow(unused)] fn main() { extern "C" { static STATIC: String; } }
This will produce:
warning: `extern` block uses type `String`, which is not FFI-safe
--> lint_example.rs:3:20
|
3 | static STATIC: String;
| ^^^^^^ not FFI-safe
|
= help: consider adding a `#[repr(C)]` or `#[repr(transparent)]` attribute to this struct
= note: this struct has unspecified layout
= note: `#[warn(improper_ctypes)]` on by default
Explanation
The compiler has several checks to verify that types used in extern
blocks are safe and follow certain rules to ensure proper
compatibility with the foreign interfaces. This lint is issued when it
detects a probable mistake in a definition. The lint usually should
provide a description of the issue, along with possibly a hint on how
to resolve it.
improper-ctypes-definitions
The improper_ctypes_definitions
lint detects incorrect use of
extern
function definitions.
Example
#![allow(unused)] fn main() { #![allow(unused)] pub extern "C" fn str_type(p: &str) { } }
This will produce:
warning: `extern` fn uses type `str`, which is not FFI-safe
--> lint_example.rs:3:31
|
3 | pub extern "C" fn str_type(p: &str) { }
| ^^^^ not FFI-safe
|
= help: consider using `*const u8` and a length instead
= note: string slices have no C equivalent
= note: `#[warn(improper_ctypes_definitions)]` on by default
Explanation
There are many parameter and return types that may be specified in an
extern
function that are not compatible with the given ABI. This
lint is an alert that these types should not be used. The lint usually
should provide a description of the issue, along with possibly a hint
on how to resolve it.
incomplete-features
The incomplete_features
lint detects unstable features enabled with
the feature
attribute that may function improperly in some or all
cases.
Example
#![allow(unused)] #![feature(generic_const_exprs)] fn main() { }
This will produce:
warning: the feature `generic_const_exprs` is incomplete and may not be safe to use and/or cause compiler crashes
--> lint_example.rs:1:12
|
1 | #![feature(generic_const_exprs)]
| ^^^^^^^^^^^^^^^^^^^
|
= note: see issue #76560 <https://github.com/rust-lang/rust/issues/76560> for more information
= note: `#[warn(incomplete_features)]` on by default
Explanation
Although it is encouraged for people to experiment with unstable features, some of them are known to be incomplete or faulty. This lint is a signal that the feature has not yet been finished, and you may experience problems with it.
indirect-structural-match
The indirect_structural_match
lint detects a const
in a pattern
that manually implements PartialEq
and Eq
.
Example
#![deny(indirect_structural_match)] struct NoDerive(i32); impl PartialEq for NoDerive { fn eq(&self, _: &Self) -> bool { false } } impl Eq for NoDerive { } #[derive(PartialEq, Eq)] struct WrapParam<T>(T); const WRAP_INDIRECT_PARAM: & &WrapParam<NoDerive> = & &WrapParam(NoDerive(0)); fn main() { match WRAP_INDIRECT_PARAM { WRAP_INDIRECT_PARAM => { } _ => { } } }
This will produce:
error: to use a constant of type `NoDerive` in a pattern, `NoDerive` must be annotated with `#[derive(PartialEq, Eq)]`
--> lint_example.rs:11:9
|
11 | WRAP_INDIRECT_PARAM => { }
| ^^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #62411 <https://github.com/rust-lang/rust/issues/62411>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(indirect_structural_match)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
The compiler unintentionally accepted this form in the past. This is a future-incompatible lint to transition this to a hard error in the future. See issue #62411 for a complete description of the problem, and some possible solutions.
inline-no-sanitize
The inline_no_sanitize
lint detects incompatible use of
#[inline(always)]
and #[no_sanitize(...)]
.
Example
#![feature(no_sanitize)] #[inline(always)] #[no_sanitize(address)] fn x() {} fn main() { x() }
This will produce:
warning: `no_sanitize` will have no effect after inlining
--> lint_example.rs:4:1
|
4 | #[no_sanitize(address)]
| ^^^^^^^^^^^^^^^^^^^^^^^
|
note: inlining requested here
--> lint_example.rs:3:1
|
3 | #[inline(always)]
| ^^^^^^^^^^^^^^^^^
= note: `#[warn(inline_no_sanitize)]` on by default
Explanation
The use of the #[inline(always)]
attribute prevents the
the #[no_sanitize(...)]
attribute from working.
Consider temporarily removing inline
attribute.
invalid-doc-attributes
The invalid_doc_attributes
lint detects when the #[doc(...)]
is
misused.
Example
#![allow(unused)] #![deny(warnings)] fn main() { pub mod submodule { #![doc(test(no_crate_inject))] } }
This will produce:
error: this attribute can only be applied at the crate level
--> lint_example.rs:5:12
|
5 | #![doc(test(no_crate_inject))]
| ^^^^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #82730 <https://github.com/rust-lang/rust/issues/82730>
= note: read <https://doc.rust-lang.org/nightly/rustdoc/the-doc-attribute.html#at-the-crate-level> for more information
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(warnings)]
| ^^^^^^^^
= note: `#[deny(invalid_doc_attributes)]` implied by `#[deny(warnings)]`
Explanation
Previously, there were very like checks being performed on #[doc(..)]
unlike the other attributes. It'll now catch all the issues that it
silently ignored previously.
invalid-value
The invalid_value
lint detects creating a value that is not valid,
such as a null reference.
Example
#![allow(unused)] fn main() { #![allow(unused)] unsafe { let x: &'static i32 = std::mem::zeroed(); } }
This will produce:
warning: the type `&i32` does not permit zero-initialization
--> lint_example.rs:4:27
|
4 | let x: &'static i32 = std::mem::zeroed();
| ^^^^^^^^^^^^^^^^^^
| |
| this code causes undefined behavior when executed
| help: use `MaybeUninit<T>` instead, and only call `assume_init` after initialization is done
|
= note: references must be non-null
= note: `#[warn(invalid_value)]` on by default
Explanation
In some situations the compiler can detect that the code is creating an invalid value, which should be avoided.
In particular, this lint will check for improper use of
mem::zeroed
, mem::uninitialized
, mem::transmute
, and
MaybeUninit::assume_init
that can cause undefined behavior. The
lint should provide extra information to indicate what the problem is
and a possible solution.
irrefutable-let-patterns
The irrefutable_let_patterns
lint detects irrefutable patterns
in if let
s, while let
s, and if let
guards.
Example
#![allow(unused)] fn main() { if let _ = 123 { println!("always runs!"); } }
This will produce:
warning: irrefutable `if let` pattern
--> lint_example.rs:2:4
|
2 | if let _ = 123 {
| ^^^^^^^^^^^
|
= note: this pattern will always match, so the `if let` is useless
= help: consider replacing the `if let` with a `let`
= note: `#[warn(irrefutable_let_patterns)]` on by default
Explanation
There usually isn't a reason to have an irrefutable pattern in an
if let
or while let
statement, because the pattern will always match
successfully. A let
or loop
statement will suffice. However,
when generating code with a macro, forbidding irrefutable patterns
would require awkward workarounds in situations where the macro
doesn't know if the pattern is refutable or not. This lint allows
macros to accept this form, while alerting for a possibly incorrect
use in normal code.
See RFC 2086 for more details.
large-assignments
The large_assignments
lint detects when objects of large
types are being moved around.
Example
let x = [0; 50000];
let y = x;
produces:
warning: moving a large value
--> $DIR/move-large.rs:1:3
let y = x;
- Copied large value here
Explanation
When using a large type in a plain assignment or in a function argument, idiomatic code can be inefficient. Ideally appropriate optimizations would resolve this, but such optimizations are only done in a best-effort manner. This lint will trigger on all sites of large moves and thus allow the user to resolve them in code.
late-bound-lifetime-arguments
The late_bound_lifetime_arguments
lint detects generic lifetime
arguments in path segments with late bound lifetime parameters.
Example
struct S; impl S { fn late<'a, 'b>(self, _: &'a u8, _: &'b u8) {} } fn main() { S.late::<'static>(&0, &0); }
This will produce:
warning: cannot specify lifetime arguments explicitly if late bound lifetime parameters are present
--> lint_example.rs:8:14
|
4 | fn late<'a, 'b>(self, _: &'a u8, _: &'b u8) {}
| -- the late bound lifetime parameter is introduced here
...
8 | S.late::<'static>(&0, &0);
| ^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #42868 <https://github.com/rust-lang/rust/issues/42868>
= note: `#[warn(late_bound_lifetime_arguments)]` on by default
Explanation
It is not clear how to provide arguments for early-bound lifetime parameters if they are intermixed with late-bound parameters in the same list. For now, providing any explicit arguments will trigger this lint if late-bound parameters are present, so in the future a solution can be adopted without hitting backward compatibility issues. This is a future-incompatible lint to transition this to a hard error in the future. See issue #42868 for more details, along with a description of the difference between early and late-bound parameters.
legacy-derive-helpers
The legacy_derive_helpers
lint detects derive helper attributes
that are used before they are introduced.
Example
#[serde(rename_all = "camelCase")]
#[derive(Deserialize)]
struct S { /* fields */ }
produces:
warning: derive helper attribute is used before it is introduced
--> $DIR/legacy-derive-helpers.rs:1:3
|
1 | #[serde(rename_all = "camelCase")]
| ^^^^^
...
2 | #[derive(Deserialize)]
| ----------- the attribute is introduced here
Explanation
Attributes like this work for historical reasons, but attribute expansion works in
left-to-right order in general, so, to resolve #[serde]
, compiler has to try to "look
into the future" at not yet expanded part of the item , but such attempts are not always
reliable.
To fix the warning place the helper attribute after its corresponding derive.
#[derive(Deserialize)]
#[serde(rename_all = "camelCase")]
struct S { /* fields */ }
mixed-script-confusables
The mixed_script_confusables
lint detects visually confusable
characters in identifiers between different scripts.
Example
#![allow(unused)] fn main() { // The Japanese katakana character エ can be confused with the Han character 工. const エ: &'static str = "アイウ"; }
This will produce:
warning: the usage of Script Group `Japanese, Katakana` in this crate consists solely of mixed script confusables
--> lint_example.rs:3:7
|
3 | const エ: &'static str = "アイウ";
| ^^
|
= note: the usage includes 'エ' (U+30A8)
= note: please recheck to make sure their usages are indeed what you want
= note: `#[warn(mixed_script_confusables)]` on by default
Explanation
This lint warns when characters between different scripts may appear visually similar, which can cause confusion.
If the crate contains other identifiers in the same script that have
non-confusable characters, then this lint will not be issued. For
example, if the example given above has another identifier with
katakana characters (such as let カタカナ = 123;
), then this indicates
that you are intentionally using katakana, and it will not warn about
it.
Note that the set of confusable characters may change over time. Beware that if you "forbid" this lint that existing code may fail in the future.
named-arguments-used-positionally
The named_arguments_used_positionally
lint detects cases where named arguments are only
used positionally in format strings. This usage is valid but potentially very confusing.
Example
#![deny(named_arguments_used_positionally)] fn main() { let _x = 5; println!("{}", _x = 1); // Prints 1, will trigger lint println!("{}", _x); // Prints 5, no lint emitted println!("{_x}", _x = _x); // Prints 5, no lint emitted }
This will produce:
error: named argument `_x` is not used by name
--> lint_example.rs:4:20
|
4 | println!("{}", _x = 1); // Prints 1, will trigger lint
| -- ^^ this named argument is referred to by position in formatting string
| |
| this formatting argument uses named argument `_x` by position
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(named_arguments_used_positionally)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
help: use the named argument by name to avoid ambiguity
|
4 | println!("{_x}", _x = 1); // Prints 1, will trigger lint
| ++
Explanation
Rust formatting strings can refer to named arguments by their position, but this usage is potentially confusing. In particular, readers can incorrectly assume that the declaration of named arguments is an assignment (which would produce the unit type). For backwards compatibility, this is not a hard error.
no-mangle-generic-items
The no_mangle_generic_items
lint detects generic items that must be
mangled.
Example
#![allow(unused)] fn main() { #[no_mangle] fn foo<T>(t: T) { } }
This will produce:
warning: functions generic over types or consts must be mangled
--> lint_example.rs:3:1
|
2 | #[no_mangle]
| ------------ help: remove this attribute
3 | / fn foo<T>(t: T) {
4 | |
5 | | }
| |_^
|
= note: `#[warn(no_mangle_generic_items)]` on by default
Explanation
A function with generics must have its symbol mangled to accommodate
the generic parameter. The no_mangle
attribute has no effect in
this situation, and should be removed.
non-camel-case-types
The non_camel_case_types
lint detects types, variants, traits and
type parameters that don't have camel case names.
Example
#![allow(unused)] fn main() { struct my_struct; }
This will produce:
warning: type `my_struct` should have an upper camel case name
--> lint_example.rs:2:8
|
2 | struct my_struct;
| ^^^^^^^^^ help: convert the identifier to upper camel case: `MyStruct`
|
= note: `#[warn(non_camel_case_types)]` on by default
Explanation
The preferred style for these identifiers is to use "camel case", such
as MyStruct
, where the first letter should not be lowercase, and
should not use underscores between letters. Underscores are allowed at
the beginning and end of the identifier, as well as between
non-letters (such as X86_64
).
non-fmt-panics
The non_fmt_panics
lint detects panic!(..)
invocations where the first
argument is not a formatting string.
Example
#![allow(unused)] fn main() { panic!("{}"); panic!(123); }
This will produce:
warning: panic message contains an unused formatting placeholder
--> lint_example.rs:2:9
|
2 | panic!("{}");
| ^^
|
= note: this message is not used as a format string when given without arguments, but will be in Rust 2021
= note: `#[warn(non_fmt_panics)]` on by default
help: add the missing argument
|
2 | panic!("{}", ...);
| +++++
help: or add a "{}" format string to use the message literally
|
2 | panic!("{}", "{}");
| +++++
Explanation
In Rust 2018 and earlier, panic!(x)
directly uses x
as the message.
That means that panic!("{}")
panics with the message "{}"
instead
of using it as a formatting string, and panic!(123)
will panic with
an i32
as message.
Rust 2021 always interprets the first argument as format string.
non-shorthand-field-patterns
The non_shorthand_field_patterns
lint detects using Struct { x: x }
instead of Struct { x }
in a pattern.
Example
struct Point { x: i32, y: i32, } fn main() { let p = Point { x: 5, y: 5, }; match p { Point { x: x, y: y } => (), } }
This will produce:
warning: the `x:` in this pattern is redundant
--> lint_example.rs:14:17
|
14 | Point { x: x, y: y } => (),
| ^^^^ help: use shorthand field pattern: `x`
|
= note: `#[warn(non_shorthand_field_patterns)]` on by default
Explanation
The preferred style is to avoid the repetition of specifying both the field name and the binding name if both identifiers are the same.
non-snake-case
The non_snake_case
lint detects variables, methods, functions,
lifetime parameters and modules that don't have snake case names.
Example
#![allow(unused)] fn main() { let MY_VALUE = 5; }
This will produce:
warning: variable `MY_VALUE` should have a snake case name
--> lint_example.rs:2:5
|
2 | let MY_VALUE = 5;
| ^^^^^^^^ help: convert the identifier to snake case: `my_value`
|
= note: `#[warn(non_snake_case)]` on by default
Explanation
The preferred style for these identifiers is to use "snake case",
where all the characters are in lowercase, with words separated with a
single underscore, such as my_value
.
non-upper-case-globals
The non_upper_case_globals
lint detects static items that don't have
uppercase identifiers.
Example
#![allow(unused)] fn main() { static max_points: i32 = 5; }
This will produce:
warning: static variable `max_points` should have an upper case name
--> lint_example.rs:2:8
|
2 | static max_points: i32 = 5;
| ^^^^^^^^^^ help: convert the identifier to upper case: `MAX_POINTS`
|
= note: `#[warn(non_upper_case_globals)]` on by default
Explanation
The preferred style is for static item names to use all uppercase
letters such as MAX_POINTS
.
nontrivial-structural-match
The nontrivial_structural_match
lint detects constants that are used in patterns,
whose type is not structural-match and whose initializer body actually uses values
that are not structural-match. So Option<NotStructuralMatch>
is ok if the constant
is just None
.
Example
#![deny(nontrivial_structural_match)] #[derive(Copy, Clone, Debug)] struct NoDerive(u32); impl PartialEq for NoDerive { fn eq(&self, _: &Self) -> bool { false } } impl Eq for NoDerive { } fn main() { const INDEX: Option<NoDerive> = [None, Some(NoDerive(10))][0]; match None { Some(_) => panic!("whoops"), INDEX => dbg!(INDEX), }; }
This will produce:
error: to use a constant of type `NoDerive` in a pattern, the constant's initializer must be trivial or `NoDerive` must be annotated with `#[derive(PartialEq, Eq)]`
--> lint_example.rs:9:47
|
9 | match None { Some(_) => panic!("whoops"), INDEX => dbg!(INDEX), };
| ^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #73448 <https://github.com/rust-lang/rust/issues/73448>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(nontrivial_structural_match)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
Previous versions of Rust accepted constants in patterns, even if those constants' types
did not have PartialEq
derived. Thus the compiler falls back to runtime execution of
PartialEq
, which can report that two constants are not equal even if they are
bit-equivalent.
opaque-hidden-inferred-bound
The opaque_hidden_inferred_bound
lint detects cases in which nested
impl Trait
in associated type bounds are not written generally enough
to satisfy the bounds of the associated type.
Explanation
This functionality was removed in #97346, but then rolled back in #99860 because it caused regressions.
We plan on reintroducing this as a hard error, but in the mean time, this lint serves to warn and suggest fixes for any use-cases which rely on this behavior.
Example
trait Trait {
type Assoc: Send;
}
struct Struct;
impl Trait for Struct {
type Assoc = i32;
}
fn test() -> impl Trait<Assoc = impl Sized> {
Struct
}
{{produces}}
In this example, test
declares that the associated type Assoc
for
impl Trait
is impl Sized
, which does not satisfy the Send
bound
on the associated type.
Although the hidden type, i32
does satisfy this bound, we do not
consider the return type to be well-formed with this lint. It can be
fixed by changing impl Sized
into impl Sized + Send
.
overlapping-range-endpoints
The overlapping_range_endpoints
lint detects match
arms that have range patterns that
overlap on their endpoints.
Example
#![allow(unused)] fn main() { let x = 123u8; match x { 0..=100 => { println!("small"); } 100..=255 => { println!("large"); } } }
This will produce:
warning: multiple patterns overlap on their endpoints
--> lint_example.rs:5:5
|
4 | 0..=100 => { println!("small"); }
| ------- this range overlaps on `100_u8`...
5 | 100..=255 => { println!("large"); }
| ^^^^^^^^^ ... with this range
|
= note: you likely meant to write mutually exclusive ranges
= note: `#[warn(overlapping_range_endpoints)]` on by default
Explanation
It is likely a mistake to have range patterns in a match expression that overlap in this
way. Check that the beginning and end values are what you expect, and keep in mind that
with ..=
the left and right bounds are inclusive.
path-statements
The path_statements
lint detects path statements with no effect.
Example
#![allow(unused)] fn main() { let x = 42; x; }
This will produce:
warning: path statement with no effect
--> lint_example.rs:4:1
|
4 | x;
| ^^
|
= note: `#[warn(path_statements)]` on by default
Explanation
It is usually a mistake to have a statement that has no effect.
private-in-public
The private_in_public
lint detects private items in public
interfaces not caught by the old implementation.
Example
#![allow(unused)] struct SemiPriv; mod m1 { struct Priv; impl super::SemiPriv { pub fn f(_: Priv) {} } } fn main() {}
This will produce:
warning: private type `Priv` in public interface (error E0446)
--> lint_example.rs:7:9
|
7 | pub fn f(_: Priv) {}
| ^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #34537 <https://github.com/rust-lang/rust/issues/34537>
= note: `#[warn(private_in_public)]` on by default
Explanation
The visibility rules are intended to prevent exposing private items in public interfaces. This is a future-incompatible lint to transition this to a hard error in the future. See issue #34537 for more details.
redundant-semicolons
The redundant_semicolons
lint detects unnecessary trailing
semicolons.
Example
#![allow(unused)] fn main() { let _ = 123;; }
This will produce:
warning: unnecessary trailing semicolon
--> lint_example.rs:2:13
|
2 | let _ = 123;;
| ^ help: remove this semicolon
|
= note: `#[warn(redundant_semicolons)]` on by default
Explanation
Extra semicolons are not needed, and may be removed to avoid confusion and visual clutter.
renamed-and-removed-lints
The renamed_and_removed_lints
lint detects lints that have been
renamed or removed.
Example
#![allow(unused)] #![deny(raw_pointer_derive)] fn main() { }
This will produce:
warning: lint `raw_pointer_derive` has been removed: using derive with raw pointers is ok
--> lint_example.rs:1:9
|
1 | #![deny(raw_pointer_derive)]
| ^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(renamed_and_removed_lints)]` on by default
Explanation
To fix this, either remove the lint or use the new name. This can help avoid confusion about lints that are no longer valid, and help maintain consistency for renamed lints.
repr-transparent-external-private-fields
The repr_transparent_external_private_fields
lint
detects types marked #[repr(transparent)]
that (transitively)
contain an external ZST type marked #[non_exhaustive]
or containing
private fields
Example
#![deny(repr_transparent_external_private_fields)]
use foo::NonExhaustiveZst;
#[repr(transparent)]
struct Bar(u32, ([u32; 0], NonExhaustiveZst));
This will produce:
error: zero-sized fields in repr(transparent) cannot contain external non-exhaustive types
--> src/main.rs:5:28
|
5 | struct Bar(u32, ([u32; 0], NonExhaustiveZst));
| ^^^^^^^^^^^^^^^^
|
note: the lint level is defined here
--> src/main.rs:1:9
|
1 | #![deny(repr_transparent_external_private_fields)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #78586 <https://github.com/rust-lang/rust/issues/78586>
= note: this struct contains `NonExhaustiveZst`, which is marked with `#[non_exhaustive]`, and makes it not a breaking change to become non-zero-sized in the future.
Explanation
Previous, Rust accepted fields that contain external private zero-sized types, even though it should not be a breaking change to add a non-zero-sized field to that private type.
This is a future-incompatible lint to transition this to a hard error in the future. See issue #78586 for more details.
semicolon-in-expressions-from-macros
The semicolon_in_expressions_from_macros
lint detects trailing semicolons
in macro bodies when the macro is invoked in expression position.
This was previous accepted, but is being phased out.
Example
#![deny(semicolon_in_expressions_from_macros)] macro_rules! foo { () => { true; } } fn main() { let val = match true { true => false, _ => foo!() }; }
This will produce:
error: trailing semicolon in macro used in expression position
--> lint_example.rs:3:17
|
3 | () => { true; }
| ^
...
9 | _ => foo!()
| ------ in this macro invocation
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #79813 <https://github.com/rust-lang/rust/issues/79813>
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(semicolon_in_expressions_from_macros)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
= note: this error originates in the macro `foo` (in Nightly builds, run with -Z macro-backtrace for more info)
Explanation
Previous, Rust ignored trailing semicolon in a macro body when a macro was invoked in expression position. However, this makes the treatment of semicolons in the language inconsistent, and could lead to unexpected runtime behavior in some circumstances (e.g. if the macro author expects a value to be dropped).
This is a future-incompatible lint to transition this to a hard error in the future. See issue #79813 for more details.
special-module-name
The special_module_name
lint detects module
declarations for files that have a special meaning.
Example
mod lib; fn main() { lib::run(); }
This will produce:
warning: found module declaration for lib.rs
--> lint_example.rs:1:1
|
1 | mod lib;
| ^^^^^^^^
|
= note: lib.rs is the root of this crate's library target
= help: to refer to it from other targets, use the library's name as the path
= note: `#[warn(special_module_name)]` on by default
Explanation
Cargo recognizes lib.rs
and main.rs
as the root of a
library or binary crate, so declaring them as modules
will lead to miscompilation of the crate unless configured
explicitly.
To access a library from a binary target within the same crate,
use your_crate_name::
as the path instead of lib::
:
// bar/src/lib.rs fn run() { // ... } // bar/src/main.rs fn main() { bar::run(); }
Binary targets cannot be used as libraries and so declaring one as a module is not allowed.
stable-features
The stable_features
lint detects a feature
attribute that
has since been made stable.
Example
#![feature(test_accepted_feature)] fn main() {}
This will produce:
warning: the feature `test_accepted_feature` has been stable since 1.0.0 and no longer requires an attribute to enable
--> lint_example.rs:1:12
|
1 | #![feature(test_accepted_feature)]
| ^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(stable_features)]` on by default
Explanation
When a feature is stabilized, it is no longer necessary to include a
#![feature]
attribute for it. To fix, simply remove the
#![feature]
attribute.
suspicious-auto-trait-impls
The suspicious_auto_trait_impls
lint checks for potentially incorrect
implementations of auto traits.
Example
#![allow(unused)] fn main() { struct Foo<T>(T); unsafe impl<T> Send for Foo<*const T> {} }
This will produce:
warning: cross-crate traits with a default impl, like `Send`, should not be specialized
--> lint_example.rs:4:1
|
4 | unsafe impl<T> Send for Foo<*const T> {}
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= warning: this will change its meaning in a future release!
= note: for more information, see issue #93367 <https://github.com/rust-lang/rust/issues/93367>
= note: `*const T` is not a generic parameter
note: try using the same sequence of generic parameters as the struct definition
--> lint_example.rs:2:1
|
2 | struct Foo<T>(T);
| ^^^^^^^^^^^^^
= note: `#[warn(suspicious_auto_trait_impls)]` on by default
Explanation
A type can implement auto traits, e.g. Send
, Sync
and Unpin
,
in two different ways: either by writing an explicit impl or if
all fields of the type implement that auto trait.
The compiler disables the automatic implementation if an explicit one exists for given type constructor. The exact rules governing this are currently unsound, quite subtle, and will be modified in the future. This change will cause the automatic implementation to be disabled in more cases, potentially breaking some code.
temporary-cstring-as-ptr
The temporary_cstring_as_ptr
lint detects getting the inner pointer of
a temporary CString
.
Example
#![allow(unused)] fn main() { #![allow(unused)] use std::ffi::CString; let c_str = CString::new("foo").unwrap().as_ptr(); }
This will produce:
warning: getting the inner pointer of a temporary `CString`
--> lint_example.rs:4:42
|
4 | let c_str = CString::new("foo").unwrap().as_ptr();
| ---------------------------- ^^^^^^ this pointer will be invalid
| |
| this `CString` is deallocated at the end of the statement, bind it to a variable to extend its lifetime
|
= note: pointers do not have a lifetime; when calling `as_ptr` the `CString` will be deallocated at the end of the statement because nothing is referencing it as far as the type system is concerned
= help: for more information, see https://doc.rust-lang.org/reference/destructors.html
= note: `#[warn(temporary_cstring_as_ptr)]` on by default
Explanation
The inner pointer of a CString
lives only as long as the CString
it
points to. Getting the inner pointer of a temporary CString
allows the CString
to be dropped at the end of the statement, as it is not being referenced as far as the typesystem
is concerned. This means outside of the statement the pointer will point to freed memory, which
causes undefined behavior if the pointer is later dereferenced.
trivial-bounds
The trivial_bounds
lint detects trait bounds that don't depend on
any type parameters.
Example
#![allow(unused)] #![feature(trivial_bounds)] fn main() { pub struct A where i32: Copy; }
This will produce:
warning: trait bound i32: Copy does not depend on any type or lifetime parameters
--> lint_example.rs:3:25
|
3 | pub struct A where i32: Copy;
| ^^^^
|
= note: `#[warn(trivial_bounds)]` on by default
Explanation
Usually you would not write a trait bound that you know is always
true, or never true. However, when using macros, the macro may not
know whether or not the constraint would hold or not at the time when
generating the code. Currently, the compiler does not alert you if the
constraint is always true, and generates an error if it is never true.
The trivial_bounds
feature changes this to be a warning in both
cases, giving macros more freedom and flexibility to generate code,
while still providing a signal when writing non-macro code that
something is amiss.
See RFC 2056 for more details. This feature is currently only available on the nightly channel, see tracking issue #48214.
type-alias-bounds
The type_alias_bounds
lint detects bounds in type aliases.
Example
#![allow(unused)] fn main() { type SendVec<T: Send> = Vec<T>; }
This will produce:
warning: bounds on generic parameters are not enforced in type aliases
--> lint_example.rs:2:17
|
2 | type SendVec<T: Send> = Vec<T>;
| ^^^^
|
= note: `#[warn(type_alias_bounds)]` on by default
help: the bound will not be checked when the type alias is used, and should be removed
|
2 - type SendVec<T: Send> = Vec<T>;
2 + type SendVec<T> = Vec<T>;
|
Explanation
The trait bounds in a type alias are currently ignored, and should not be included to avoid confusion. This was previously allowed unintentionally; this may become a hard error in the future.
tyvar-behind-raw-pointer
The tyvar_behind_raw_pointer
lint detects raw pointer to an
inference variable.
Example
#![allow(unused)] fn main() { // edition 2015 let data = std::ptr::null(); let _ = &data as *const *const (); if data.is_null() {} }
This will produce:
warning: type annotations needed
--> lint_example.rs:6:9
|
6 | if data.is_null() {}
| ^^^^^^^
|
= warning: this is accepted in the current edition (Rust 2015) but is a hard error in Rust 2018!
= note: for more information, see issue #46906 <https://github.com/rust-lang/rust/issues/46906>
= note: `#[warn(tyvar_behind_raw_pointer)]` on by default
Explanation
This kind of inference was previously allowed, but with the future arrival of arbitrary self types, this can introduce ambiguity. To resolve this, use an explicit type instead of relying on type inference.
This is a future-incompatible lint to transition this to a hard error in the 2018 edition. See issue #46906 for more details. This is currently a hard-error on the 2018 edition, and is "warn" by default in the 2015 edition.
uncommon-codepoints
The uncommon_codepoints
lint detects uncommon Unicode codepoints in
identifiers.
Example
#![allow(unused)] fn main() { #![allow(unused)] const µ: f64 = 0.000001; }
This will produce:
warning: identifier contains uncommon Unicode codepoints
--> lint_example.rs:3:7
|
3 | const µ: f64 = 0.000001;
| ^
|
= note: `#[warn(uncommon_codepoints)]` on by default
Explanation
This lint warns about using characters which are not commonly used, and may cause visual confusion.
This lint is triggered by identifiers that contain a codepoint that is not part of the set of "Allowed" codepoints as described by Unicode® Technical Standard #39 Unicode Security Mechanisms Section 3.1 General Security Profile for Identifiers.
Note that the set of uncommon codepoints may change over time. Beware that if you "forbid" this lint that existing code may fail in the future.
unconditional-recursion
The unconditional_recursion
lint detects functions that cannot
return without calling themselves.
Example
#![allow(unused)] fn main() { fn foo() { foo(); } }
This will produce:
warning: function cannot return without recursing
--> lint_example.rs:2:1
|
2 | fn foo() {
| ^^^^^^^^ cannot return without recursing
3 | foo();
| ----- recursive call site
|
= help: a `loop` may express intention better if this is on purpose
= note: `#[warn(unconditional_recursion)]` on by default
Explanation
It is usually a mistake to have a recursive call that does not have
some condition to cause it to terminate. If you really intend to have
an infinite loop, using a loop
expression is recommended.
undefined-naked-function-abi
The undefined_naked_function_abi
lint detects naked function definitions that
either do not specify an ABI or specify the Rust ABI.
Example
#![allow(unused)] #![feature(asm_experimental_arch, naked_functions)] fn main() { use std::arch::asm; #[naked] pub fn default_abi() -> u32 { unsafe { asm!("", options(noreturn)); } } #[naked] pub extern "Rust" fn rust_abi() -> u32 { unsafe { asm!("", options(noreturn)); } } }
This will produce:
warning: Rust ABI is unsupported in naked functions
--> lint_example.rs:7:1
|
7 | pub fn default_abi() -> u32 {
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(undefined_naked_function_abi)]` on by default
Explanation
The Rust ABI is currently undefined. Therefore, naked functions should specify a non-Rust ABI.
unexpected-cfgs
The unexpected_cfgs
lint detects unexpected conditional compilation conditions.
Example
rustc --check-cfg 'names()'
#[cfg(widnows)]
fn foo() {}
This will produce:
warning: unknown condition name used
--> lint_example.rs:1:7
|
1 | #[cfg(widnows)]
| ^^^^^^^
|
= note: `#[warn(unexpected_cfgs)]` on by default
Explanation
This lint is only active when a --check-cfg='names(...)'
option has been passed
to the compiler and triggers whenever an unknown condition name or value is used.
The known condition include names or values passed in --check-cfg
, --cfg
, and some
well-knows names and values built into the compiler.
unfulfilled-lint-expectations
The unfulfilled_lint_expectations
lint detects lint trigger expectations
that have not been fulfilled.
Example
#![allow(unused)] #![feature(lint_reasons)] fn main() { #[expect(unused_variables)] let x = 10; println!("{}", x); }
This will produce:
warning: this lint expectation is unfulfilled
--> lint_example.rs:4:10
|
4 | #[expect(unused_variables)]
| ^^^^^^^^^^^^^^^^
|
= note: `#[warn(unfulfilled_lint_expectations)]` on by default
Explanation
It was expected that the marked code would emit a lint. This expectation has not been fulfilled.
The expect
attribute can be removed if this is intended behavior otherwise
it should be investigated why the expected lint is no longer issued.
In rare cases, the expectation might be emitted at a different location than
shown in the shown code snippet. In most cases, the #[expect]
attribute
works when added to the outer scope. A few lints can only be expected
on a crate level.
Part of RFC 2383. The progress is being tracked in #54503
uninhabited-static
The uninhabited_static
lint detects uninhabited statics.
Example
#![allow(unused)] fn main() { enum Void {} extern { static EXTERN: Void; } }
This will produce:
warning: static of uninhabited type
--> lint_example.rs:4:5
|
4 | static EXTERN: Void;
| ^^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #74840 <https://github.com/rust-lang/rust/issues/74840>
= note: uninhabited statics cannot be initialized, and any access would be an immediate error
= note: `#[warn(uninhabited_static)]` on by default
Explanation
Statics with an uninhabited type can never be initialized, so they are impossible to define.
However, this can be side-stepped with an extern static
, leading to problems later in the
compiler which assumes that there are no initialized uninhabited places (such as locals or
statics). This was accidentally allowed, but is being phased out.
unknown-lints
The unknown_lints
lint detects unrecognized lint attributes.
Example
#![allow(unused)] #![allow(not_a_real_lint)] fn main() { }
This will produce:
warning: unknown lint: `not_a_real_lint`
--> lint_example.rs:1:10
|
1 | #![allow(not_a_real_lint)]
| ^^^^^^^^^^^^^^^
|
= note: `#[warn(unknown_lints)]` on by default
Explanation
It is usually a mistake to specify a lint that does not exist. Check the spelling, and check the lint listing for the correct name. Also consider if you are using an old version of the compiler, and the lint is only available in a newer version.
unnameable-test-items
The unnameable_test_items
lint detects #[test]
functions
that are not able to be run by the test harness because they are in a
position where they are not nameable.
Example
fn main() { #[test] fn foo() { // This test will not fail because it does not run. assert_eq!(1, 2); } }
This will produce:
warning: cannot test inner items
--> lint_example.rs:2:5
|
2 | #[test]
| ^^^^^^^
|
= note: `#[warn(unnameable_test_items)]` on by default
= note: this warning originates in the attribute macro `test` (in Nightly builds, run with -Z macro-backtrace for more info)
Explanation
In order for the test harness to run a test, the test function must be located in a position where it can be accessed from the crate root. This generally means it must be defined in a module, and not anywhere else such as inside another function. The compiler previously allowed this without an error, so a lint was added as an alert that a test is not being used. Whether or not this should be allowed has not yet been decided, see RFC 2471 and issue #36629.
unreachable-code
The unreachable_code
lint detects unreachable code paths.
Example
#![allow(unused)] fn main() { panic!("we never go past here!"); let x = 5; }
This will produce:
warning: unreachable statement
--> lint_example.rs:4:1
|
2 | panic!("we never go past here!");
| -------------------------------- any code following this expression is unreachable
3 |
4 | let x = 5;
| ^^^^^^^^^^ unreachable statement
|
= note: `#[warn(unreachable_code)]` on by default
Explanation
Unreachable code may signal a mistake or unfinished code. If the code is no longer in use, consider removing it.
unreachable-patterns
The unreachable_patterns
lint detects unreachable patterns.
Example
#![allow(unused)] fn main() { let x = 5; match x { y => (), 5 => (), } }
This will produce:
warning: unreachable pattern
--> lint_example.rs:5:5
|
4 | y => (),
| - matches any value
5 | 5 => (),
| ^ unreachable pattern
|
= note: `#[warn(unreachable_patterns)]` on by default
Explanation
This usually indicates a mistake in how the patterns are specified or
ordered. In this example, the y
pattern will always match, so the
five is impossible to reach. Remember, match arms match in order, you
probably wanted to put the 5
case above the y
case.
unstable-name-collisions
The unstable_name_collisions
lint detects that you have used a name
that the standard library plans to add in the future.
Example
#![allow(unused)] fn main() { trait MyIterator : Iterator { // is_sorted is an unstable method that already exists on the Iterator trait fn is_sorted(self) -> bool where Self: Sized {true} } impl<T: ?Sized> MyIterator for T where T: Iterator { } let x = vec![1, 2, 3]; let _ = x.iter().is_sorted(); }
This will produce:
warning: an associated function with this name may be added to the standard library in the future
--> lint_example.rs:10:18
|
10 | let _ = x.iter().is_sorted();
| ^^^^^^^^^
|
= warning: once this associated item is added to the standard library, the ambiguity may cause an error or change in behavior!
= note: for more information, see issue #48919 <https://github.com/rust-lang/rust/issues/48919>
= help: call with fully qualified syntax `MyIterator::is_sorted(...)` to keep using the current method
= help: add `#![feature(is_sorted)]` to the crate attributes to enable `is_sorted`
= note: `#[warn(unstable_name_collisions)]` on by default
Explanation
When new methods are added to traits in the standard library, they are
usually added in an "unstable" form which is only available on the
nightly channel with a feature
attribute. If there is any
pre-existing code which extends a trait to have a method with the same
name, then the names will collide. In the future, when the method is
stabilized, this will cause an error due to the ambiguity. This lint
is an early-warning to let you know that there may be a collision in
the future. This can be avoided by adding type annotations to
disambiguate which trait method you intend to call, such as
MyIterator::is_sorted(my_iter)
or renaming or removing the method.
unstable-syntax-pre-expansion
The unstable_syntax_pre_expansion
lint detects the use of unstable
syntax that is discarded during attribute expansion.
Example
#![allow(unused)] fn main() { #[cfg(FALSE)] macro foo() {} }
This will produce:
warning: `macro` is experimental
--> lint_example.rs:3:1
|
3 | macro foo() {}
| ^^^^^^^^^^^^^^
|
= note: see issue #39412 <https://github.com/rust-lang/rust/issues/39412> for more information
= help: add `#![feature(decl_macro)]` to the crate attributes to enable
= warning: unstable syntax can change at any point in the future, causing a hard error!
= note: for more information, see issue #65860 <https://github.com/rust-lang/rust/issues/65860>
Explanation
The input to active attributes such as #[cfg]
or procedural macro
attributes is required to be valid syntax. Previously, the compiler only
gated the use of unstable syntax features after resolving #[cfg]
gates
and expanding procedural macros.
To avoid relying on unstable syntax, move the use of unstable syntax into a position where the compiler does not parse the syntax, such as a functionlike macro.
#![allow(unused)] fn main() { #![deny(unstable_syntax_pre_expansion)] macro_rules! identity { ( $($tokens:tt)* ) => { $($tokens)* } } #[cfg(FALSE)] identity! { macro foo() {} } }
This is a future-incompatible lint to transition this to a hard error in the future. See issue #65860 for more details.
unsupported-calling-conventions
The unsupported_calling_conventions
lint is output whenever there is a use of the
stdcall
, fastcall
, thiscall
, vectorcall
calling conventions (or their unwind
variants) on targets that cannot meaningfully be supported for the requested target.
For example stdcall
does not make much sense for a x86_64 or, more apparently, powerpc
code, because this calling convention was never specified for those targets.
Historically MSVC toolchains have fallen back to the regular C calling convention for targets other than x86, but Rust doesn't really see a similar need to introduce a similar hack across many more targets.
Example
extern "stdcall" fn stdcall() {}
This will produce:
warning: use of calling convention not supported on this target
--> $DIR/unsupported.rs:39:1
|
LL | extern "stdcall" fn stdcall() {}
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(unsupported_calling_conventions)]` on by default
= warning: this was previously accepted by the compiler but is being phased out;
it will become a hard error in a future release!
= note: for more information, see issue ...
Explanation
On most of the targets the behaviour of stdcall
and similar calling conventions is not
defined at all, but was previously accepted due to a bug in the implementation of the
compiler.
unused-allocation
The unused_allocation
lint detects unnecessary allocations that can
be eliminated.
Example
#![feature(box_syntax)] fn main() { let a = (box [1, 2, 3]).len(); }
This will produce:
warning: unnecessary allocation, use `&` instead
--> lint_example.rs:3:13
|
3 | let a = (box [1, 2, 3]).len();
| ^^^^^^^^^^^^^^^
|
= note: `#[warn(unused_allocation)]` on by default
Explanation
When a box
expression is immediately coerced to a reference, then
the allocation is unnecessary, and a reference (using &
or &mut
)
should be used instead to avoid the allocation.
unused-assignments
The unused_assignments
lint detects assignments that will never be read.
Example
#![allow(unused)] fn main() { let mut x = 5; x = 6; }
This will produce:
warning: value assigned to `x` is never read
--> lint_example.rs:3:1
|
3 | x = 6;
| ^
|
= help: maybe it is overwritten before being read?
= note: `#[warn(unused_assignments)]` on by default
Explanation
Unused assignments may signal a mistake or unfinished code. If the
variable is never used after being assigned, then the assignment can
be removed. Variables with an underscore prefix such as _x
will not
trigger this lint.
unused-attributes
The unused_attributes
lint detects attributes that were not used by
the compiler.
Example
#![allow(unused)] #![ignore] fn main() { }
This will produce:
warning: `#[ignore]` only has an effect on functions
--> lint_example.rs:1:1
|
1 | #![ignore]
| ^^^^^^^^^^
|
= note: `#[warn(unused_attributes)]` on by default
Explanation
Unused attributes may indicate the attribute is placed in the wrong
position. Consider removing it, or placing it in the correct position.
Also consider if you intended to use an inner attribute (with a !
such as #![allow(unused)]
) which applies to the item the attribute
is within, or an outer attribute (without a !
such as
#[allow(unused)]
) which applies to the item following the
attribute.
unused-braces
The unused_braces
lint detects unnecessary braces around an
expression.
Example
#![allow(unused)] fn main() { if { true } { // ... } }
This will produce:
warning: unnecessary braces around `if` condition
--> lint_example.rs:2:4
|
2 | if { true } {
| ^^ ^^
|
= note: `#[warn(unused_braces)]` on by default
help: remove these braces
|
2 - if { true } {
2 + if true {
|
Explanation
The braces are not needed, and should be removed. This is the preferred style for writing these expressions.
unused-comparisons
The unused_comparisons
lint detects comparisons made useless by
limits of the types involved.
Example
#![allow(unused)] fn main() { fn foo(x: u8) { x >= 0; } }
This will produce:
warning: comparison is useless due to type limits
--> lint_example.rs:3:5
|
3 | x >= 0;
| ^^^^^^
|
= note: `#[warn(unused_comparisons)]` on by default
Explanation
A useless comparison may indicate a mistake, and should be fixed or removed.
unused-doc-comments
The unused_doc_comments
lint detects doc comments that aren't used
by rustdoc
.
Example
#![allow(unused)] fn main() { /// docs for x let x = 12; }
This will produce:
warning: unused doc comment
--> lint_example.rs:2:1
|
2 | /// docs for x
| ^^^^^^^^^^^^^^
3 | let x = 12;
| ----------- rustdoc does not generate documentation for statements
|
= help: use `//` for a plain comment
= note: `#[warn(unused_doc_comments)]` on by default
Explanation
rustdoc
does not use doc comments in all positions, and so the doc
comment will be ignored. Try changing it to a normal comment with //
to avoid the warning.
unused-features
The unused_features
lint detects unused or unknown features found in
crate-level feature
attributes.
Note: This lint is currently not functional, see issue #44232 for more details.
unused-imports
The unused_imports
lint detects imports that are never used.
Example
#![allow(unused)] fn main() { use std::collections::HashMap; }
This will produce:
warning: unused import: `std::collections::HashMap`
--> lint_example.rs:2:5
|
2 | use std::collections::HashMap;
| ^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[warn(unused_imports)]` on by default
Explanation
Unused imports may signal a mistake or unfinished code, and clutter
the code, and should be removed. If you intended to re-export the item
to make it available outside of the module, add a visibility modifier
like pub
.
unused-labels
The unused_labels
lint detects labels that are never used.
Example
#![allow(unused)] fn main() { 'unused_label: loop {} }
This will produce:
warning: unused label
--> lint_example.rs:2:1
|
2 | 'unused_label: loop {}
| ^^^^^^^^^^^^^
|
= note: `#[warn(unused_labels)]` on by default
Explanation
Unused labels may signal a mistake or unfinished code. To silence the
warning for the individual label, prefix it with an underscore such as
'_my_label:
.
unused-macros
The unused_macros
lint detects macros that were not used.
Note that this lint is distinct from the unused_macro_rules
lint,
which checks for single rules that never match of an otherwise used
macro, and thus never expand.
Example
macro_rules! unused { () => {}; } fn main() { }
This will produce:
warning: unused macro definition: `unused`
--> lint_example.rs:1:14
|
1 | macro_rules! unused {
| ^^^^^^
|
= note: `#[warn(unused_macros)]` on by default
Explanation
Unused macros may signal a mistake or unfinished code. To silence the
warning for the individual macro, prefix the name with an underscore
such as _my_macro
. If you intended to export the macro to make it
available outside of the crate, use the macro_export
attribute.
unused-must-use
The unused_must_use
lint detects unused result of a type flagged as
#[must_use]
.
Example
fn returns_result() -> Result<(), ()> { Ok(()) } fn main() { returns_result(); }
This will produce:
warning: unused `Result` that must be used
--> lint_example.rs:6:5
|
6 | returns_result();
| ^^^^^^^^^^^^^^^^^
|
= note: this `Result` may be an `Err` variant, which should be handled
= note: `#[warn(unused_must_use)]` on by default
Explanation
The #[must_use]
attribute is an indicator that it is a mistake to
ignore the value. See the reference for more details.
unused-mut
The unused_mut
lint detects mut variables which don't need to be
mutable.
Example
#![allow(unused)] fn main() { let mut x = 5; }
This will produce:
warning: variable does not need to be mutable
--> lint_example.rs:2:5
|
2 | let mut x = 5;
| ----^
| |
| help: remove this `mut`
|
= note: `#[warn(unused_mut)]` on by default
Explanation
The preferred style is to only mark variables as mut
if it is
required.
unused-parens
The unused_parens
lint detects if
, match
, while
and return
with parentheses; they do not need them.
Examples
#![allow(unused)] fn main() { if(true) {} }
This will produce:
warning: unnecessary parentheses around `if` condition
--> lint_example.rs:2:3
|
2 | if(true) {}
| ^ ^
|
= note: `#[warn(unused_parens)]` on by default
help: remove these parentheses
|
2 - if(true) {}
2 + if true {}
|
Explanation
The parentheses are not needed, and should be removed. This is the preferred style for writing these expressions.
unused-unsafe
The unused_unsafe
lint detects unnecessary use of an unsafe
block.
Example
#![allow(unused)] fn main() { unsafe {} }
This will produce:
warning: unnecessary `unsafe` block
--> lint_example.rs:2:1
|
2 | unsafe {}
| ^^^^^^ unnecessary `unsafe` block
|
= note: `#[warn(unused_unsafe)]` on by default
Explanation
If nothing within the block requires unsafe
, then remove the
unsafe
marker because it is not required and may cause confusion.
unused-variables
The unused_variables
lint detects variables which are not used in
any way.
Example
#![allow(unused)] fn main() { let x = 5; }
This will produce:
warning: unused variable: `x`
--> lint_example.rs:2:5
|
2 | let x = 5;
| ^ help: if this is intentional, prefix it with an underscore: `_x`
|
= note: `#[warn(unused_variables)]` on by default
Explanation
Unused variables may signal a mistake or unfinished code. To silence
the warning for the individual variable, prefix it with an underscore
such as _x
.
warnings
The warnings
lint allows you to change the level of other
lints which produce warnings.
Example
#![allow(unused)] #![deny(warnings)] fn main() { fn foo() {} }
This will produce:
error: function `foo` is never used
--> lint_example.rs:3:4
|
3 | fn foo() {}
| ^^^
|
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(warnings)]
| ^^^^^^^^
= note: `#[deny(dead_code)]` implied by `#[deny(warnings)]`
Explanation
The warnings
lint is a bit special; by changing its level, you
change every other warning that would produce a warning to whatever
value you'd like. As such, you won't ever trigger this lint in your
code directly.
where-clauses-object-safety
The where_clauses_object_safety
lint detects for object safety of
where clauses.
Example
trait Trait {} trait X { fn foo(&self) where Self: Trait; } impl X for () { fn foo(&self) {} } impl Trait for dyn X {} // Segfault at opt-level 0, SIGILL otherwise. pub fn main() { <dyn X as X>::foo(&()); }
This will produce:
warning: the trait `X` cannot be made into an object
--> lint_example.rs:3:14
|
3 | trait X { fn foo(&self) where Self: Trait; }
| ^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #51443 <https://github.com/rust-lang/rust/issues/51443>
note: for a trait to be "object safe" it needs to allow building a vtable to allow the call to be resolvable dynamically; for more information visit <https://doc.rust-lang.org/reference/items/traits.html#object-safety>
--> lint_example.rs:3:14
|
3 | trait X { fn foo(&self) where Self: Trait; }
| - ^^^ ...because method `foo` references the `Self` type in its `where` clause
| |
| this trait cannot be made into an object...
= help: consider moving `foo` to another trait
= note: `#[warn(where_clauses_object_safety)]` on by default
Explanation
The compiler previously allowed these object-unsafe bounds, which was incorrect. This is a future-incompatible lint to transition this to a hard error in the future. See issue #51443 for more details.
while-true
The while_true
lint detects while true { }
.
Example
#![allow(unused)] fn main() { while true { } }
This will produce:
warning: denote infinite loops with `loop { ... }`
--> lint_example.rs:2:1
|
2 | while true {
| ^^^^^^^^^^ help: use `loop`
|
= note: `#[warn(while_true)]` on by default
Explanation
while true
should be replaced with loop
. A loop
expression is
the preferred way to write an infinite loop because it more directly
expresses the intent of the loop.
Deny-by-default Lints
These lints are all set to the 'deny' level by default.
ambiguous_associated_items
arithmetic_overflow
cenum_impl_drop_cast
conflicting_repr_hints
deprecated_cfg_attr_crate_type_name
enum_intrinsics_non_enums
ill_formed_attribute_input
incomplete_include
ineffective_unstable_trait_impl
invalid_atomic_ordering
invalid_type_param_default
let_underscore_lock
macro_expanded_macro_exports_accessed_by_absolute_paths
missing_fragment_specifier
mutable_transmutes
named_asm_labels
no_mangle_const_items
order_dependent_trait_objects
overflowing_literals
patterns_in_fns_without_body
proc_macro_back_compat
pub_use_of_private_extern_crate
soft_unstable
test_unstable_lint
text_direction_codepoint_in_comment
text_direction_codepoint_in_literal
unaligned_references
unconditional_panic
unknown_crate_types
useless_deprecated
ambiguous-associated-items
The ambiguous_associated_items
lint detects ambiguity between
associated items and enum variants.
Example
#![allow(unused)] fn main() { enum E { V } trait Tr { type V; fn foo() -> Self::V; } impl Tr for E { type V = u8; // `Self::V` is ambiguous because it may refer to the associated type or // the enum variant. fn foo() -> Self::V { 0 } } }
This will produce:
error: ambiguous associated item
--> lint_example.rs:15:17
|
15 | fn foo() -> Self::V { 0 }
| ^^^^^^^ help: use fully-qualified syntax: `<E as Tr>::V`
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #57644 <https://github.com/rust-lang/rust/issues/57644>
note: `V` could refer to the variant defined here
--> lint_example.rs:3:5
|
3 | V
| ^
note: `V` could also refer to the associated type defined here
--> lint_example.rs:7:5
|
7 | type V;
| ^^^^^^
= note: `#[deny(ambiguous_associated_items)]` on by default
Explanation
Previous versions of Rust did not allow accessing enum variants through type aliases. When this ability was added (see RFC 2338), this introduced some situations where it can be ambiguous what a type was referring to.
To fix this ambiguity, you should use a qualified path to explicitly
state which type to use. For example, in the above example the
function can be written as fn f() -> <Self as Tr>::V { 0 }
to
specifically refer to the associated type.
This is a future-incompatible lint to transition this to a hard error in the future. See issue #57644 for more details.
arithmetic-overflow
The arithmetic_overflow
lint detects that an arithmetic operation
will overflow.
Example
#![allow(unused)] fn main() { 1_i32 << 32; }
This will produce:
error: this arithmetic operation will overflow
--> lint_example.rs:2:1
|
2 | 1_i32 << 32;
| ^^^^^^^^^^^ attempt to shift left by `32_i32`, which would overflow
|
= note: `#[deny(arithmetic_overflow)]` on by default
Explanation
It is very likely a mistake to perform an arithmetic operation that overflows its value. If the compiler is able to detect these kinds of overflows at compile-time, it will trigger this lint. Consider adjusting the expression to avoid overflow, or use a data type that will not overflow.
cenum-impl-drop-cast
The cenum_impl_drop_cast
lint detects an as
cast of a field-less
enum
that implements Drop
.
Example
# #![allow(unused)]
enum E {
A,
}
impl Drop for E {
fn drop(&mut self) {
println!("Drop");
}
}
fn main() {
let e = E::A;
let i = e as u32;
}
{{produces}}
Explanation
Casting a field-less enum
that does not implement Copy
to an
integer moves the value without calling drop
. This can result in
surprising behavior if it was expected that drop
should be called.
Calling drop
automatically would be inconsistent with other move
operations. Since neither behavior is clear or consistent, it was
decided that a cast of this nature will no longer be allowed.
This is a future-incompatible lint to transition this to a hard error in the future. See issue #73333 for more details.
conflicting-repr-hints
The conflicting_repr_hints
lint detects repr
attributes with
conflicting hints.
Example
#![allow(unused)] fn main() { #[repr(u32, u64)] enum Foo { Variant1, } }
This will produce:
error[E0566]: conflicting representation hints
--> lint_example.rs:2:8
|
2 | #[repr(u32, u64)]
| ^^^ ^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #68585 <https://github.com/rust-lang/rust/issues/68585>
= note: `#[deny(conflicting_repr_hints)]` on by default
Explanation
The compiler incorrectly accepted these conflicting representations in the past. This is a future-incompatible lint to transition this to a hard error in the future. See issue #68585 for more details.
To correct the issue, remove one of the conflicting hints.
deprecated-cfg-attr-crate-type-name
The deprecated_cfg_attr_crate_type_name
lint detects uses of the
#![cfg_attr(..., crate_type = "...")]
and
#![cfg_attr(..., crate_name = "...")]
attributes to conditionally
specify the crate type and name in the source code.
Example
#![allow(unused)] #![cfg_attr(debug_assertions, crate_type = "lib")] fn main() { }
This will produce:
error: `crate_type` within an `#![cfg_attr] attribute is deprecated`
--> lint_example.rs:1:31
|
1 | #![cfg_attr(debug_assertions, crate_type = "lib")]
| ^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #91632 <https://github.com/rust-lang/rust/issues/91632>
= note: `#[deny(deprecated_cfg_attr_crate_type_name)]` on by default
Explanation
The #![crate_type]
and #![crate_name]
attributes require a hack in
the compiler to be able to change the used crate type and crate name
after macros have been expanded. Neither attribute works in combination
with Cargo as it explicitly passes --crate-type
and --crate-name
on
the commandline. These values must match the value used in the source
code to prevent an error.
To fix the warning use --crate-type
on the commandline when running
rustc instead of #![cfg_attr(..., crate_type = "...")]
and
--crate-name
instead of #![cfg_attr(..., crate_name = "...")]
.
enum-intrinsics-non-enums
The enum_intrinsics_non_enums
lint detects calls to
intrinsic functions that require an enum (core::mem::discriminant
,
core::mem::variant_count
), but are called with a non-enum type.
Example
#![allow(unused)] #![deny(enum_intrinsics_non_enums)] fn main() { core::mem::discriminant::<i32>(&123); }
This will produce:
error: the return value of `mem::discriminant` is unspecified when called with a non-enum type
--> lint_example.rs:3:1
|
3 | core::mem::discriminant::<i32>(&123);
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
note: the argument to `discriminant` should be a reference to an enum, but it was passed a reference to a `i32`, which is not an enum.
--> lint_example.rs:3:32
|
3 | core::mem::discriminant::<i32>(&123);
| ^^^^
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(enum_intrinsics_non_enums)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^
Explanation
In order to accept any enum, the mem::discriminant
and
mem::variant_count
functions are generic over a type T
.
This makes it technically possible for T
to be a non-enum,
in which case the return value is unspecified.
This lint prevents such incorrect usage of these functions.
ill-formed-attribute-input
The ill_formed_attribute_input
lint detects ill-formed attribute
inputs that were previously accepted and used in practice.
Example
#![allow(unused)] fn main() { #[inline = "this is not valid"] fn foo() {} }
This will produce:
error: attribute must be of the form `#[inline]` or `#[inline(always|never)]`
--> lint_example.rs:2:1
|
2 | #[inline = "this is not valid"]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #57571 <https://github.com/rust-lang/rust/issues/57571>
= note: `#[deny(ill_formed_attribute_input)]` on by default
Explanation
Previously, inputs for many built-in attributes weren't validated and nonsensical attribute inputs were accepted. After validation was added, it was determined that some existing projects made use of these invalid forms. This is a future-incompatible lint to transition this to a hard error in the future. See issue #57571 for more details.
Check the attribute reference for details on the valid inputs for attributes.
incomplete-include
The incomplete_include
lint detects the use of the include!
macro with a file that contains more than one expression.
Example
fn main() {
include!("foo.txt");
}
where the file foo.txt
contains:
println!("hi!");
produces:
error: include macro expected single expression in source
--> foo.txt:1:14
|
1 | println!("1");
| ^
|
= note: `#[deny(incomplete_include)]` on by default
Explanation
The include!
macro is currently only intended to be used to
include a single expression or multiple items. Historically it
would ignore any contents after the first expression, but that can be
confusing. In the example above, the println!
expression ends just
before the semicolon, making the semicolon "extra" information that is
ignored. Perhaps even more surprising, if the included file had
multiple print statements, the subsequent ones would be ignored!
One workaround is to place the contents in braces to create a block expression. Also consider alternatives, like using functions to encapsulate the expressions, or use proc-macros.
This is a lint instead of a hard error because existing projects were
found to hit this error. To be cautious, it is a lint for now. The
future semantics of the include!
macro are also uncertain, see
issue #35560.
ineffective-unstable-trait-impl
The ineffective_unstable_trait_impl
lint detects #[unstable]
attributes which are not used.
Example
#![allow(unused)] #![feature(staged_api)] fn main() { #[derive(Clone)] #[stable(feature = "x", since = "1")] struct S {} #[unstable(feature = "y", issue = "none")] impl Copy for S {} }
This will produce:
error: an `#[unstable]` annotation here has no effect
--> lint_example.rs:8:1
|
8 | #[unstable(feature = "y", issue = "none")]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: see issue #55436 <https://github.com/rust-lang/rust/issues/55436> for more information
= note: `#[deny(ineffective_unstable_trait_impl)]` on by default
Explanation
staged_api
does not currently support using a stability attribute on impl
blocks.
impl
s are always stable if both the type and trait are stable, and always unstable otherwise.
invalid-atomic-ordering
The invalid_atomic_ordering
lint detects passing an Ordering
to an atomic operation that does not support that ordering.
Example
#![allow(unused)] fn main() { use core::sync::atomic::{AtomicU8, Ordering}; let atom = AtomicU8::new(0); let value = atom.load(Ordering::Release); let _ = value; }
This will produce:
error: atomic loads cannot have `Release` or `AcqRel` ordering
--> lint_example.rs:4:23
|
4 | let value = atom.load(Ordering::Release);
| ^^^^^^^^^^^^^^^^^
|
= help: consider using ordering modes `Acquire`, `SeqCst` or `Relaxed`
= note: `#[deny(invalid_atomic_ordering)]` on by default
Explanation
Some atomic operations are only supported for a subset of the
atomic::Ordering
variants. Passing an unsupported variant will cause
an unconditional panic at runtime, which is detected by this lint.
This lint will trigger in the following cases: (where AtomicType
is an
atomic type from core::sync::atomic
, such as AtomicBool
,
AtomicPtr
, AtomicUsize
, or any of the other integer atomics).
-
Passing
Ordering::Acquire
orOrdering::AcqRel
toAtomicType::store
. -
Passing
Ordering::Release
orOrdering::AcqRel
toAtomicType::load
. -
Passing
Ordering::Relaxed
tocore::sync::atomic::fence
orcore::sync::atomic::compiler_fence
. -
Passing
Ordering::Release
orOrdering::AcqRel
as the failure ordering for any ofAtomicType::compare_exchange
,AtomicType::compare_exchange_weak
, orAtomicType::fetch_update
.
invalid-type-param-default
The invalid_type_param_default
lint detects type parameter defaults
erroneously allowed in an invalid location.
Example
#![allow(unused)] fn main() { fn foo<T=i32>(t: T) {} }
This will produce:
error: defaults for type parameters are only allowed in `struct`, `enum`, `type`, or `trait` definitions
--> lint_example.rs:2:8
|
2 | fn foo<T=i32>(t: T) {}
| ^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #36887 <https://github.com/rust-lang/rust/issues/36887>
= note: `#[deny(invalid_type_param_default)]` on by default
Explanation
Default type parameters were only intended to be allowed in certain situations, but historically the compiler allowed them everywhere. This is a future-incompatible lint to transition this to a hard error in the future. See issue #36887 for more details.
let-underscore-lock
The let_underscore_lock
lint checks for statements which don't bind
a mutex to anything, causing the lock to be released immediately instead
of at end of scope, which is typically incorrect.
Example
use std::sync::{Arc, Mutex};
use std::thread;
let data = Arc::new(Mutex::new(0));
thread::spawn(move || {
// The lock is immediately released instead of at the end of the
// scope, which is probably not intended.
let _ = data.lock().unwrap();
println!("doing some work");
let mut lock = data.lock().unwrap();
*lock += 1;
});
{{produces}}
Explanation
Statements which assign an expression to an underscore causes the
expression to immediately drop instead of extending the expression's
lifetime to the end of the scope. This is usually unintended,
especially for types like MutexGuard
, which are typically used to
lock a mutex for the duration of an entire scope.
If you want to extend the expression's lifetime to the end of the scope,
assign an underscore-prefixed name (such as _foo
) to the expression.
If you do actually want to drop the expression immediately, then
calling std::mem::drop
on the expression is clearer and helps convey
intent.
macro-expanded-macro-exports-accessed-by-absolute-paths
The macro_expanded_macro_exports_accessed_by_absolute_paths
lint
detects macro-expanded macro_export
macros from the current crate
that cannot be referred to by absolute paths.
Example
macro_rules! define_exported { () => { #[macro_export] macro_rules! exported { () => {}; } }; } define_exported!(); fn main() { crate::exported!(); }
This will produce:
error: macro-expanded `macro_export` macros from the current crate cannot be referred to by absolute paths
--> lint_example.rs:13:5
|
13 | crate::exported!();
| ^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #52234 <https://github.com/rust-lang/rust/issues/52234>
note: the macro is defined here
--> lint_example.rs:4:9
|
4 | / macro_rules! exported {
5 | | () => {};
6 | | }
| |_________^
...
10 | define_exported!();
| ------------------ in this macro invocation
= note: `#[deny(macro_expanded_macro_exports_accessed_by_absolute_paths)]` on by default
= note: this error originates in the macro `define_exported` (in Nightly builds, run with -Z macro-backtrace for more info)
Explanation
The intent is that all macros marked with the #[macro_export]
attribute are made available in the root of the crate. However, when a
macro_rules!
definition is generated by another macro, the macro
expansion is unable to uphold this rule. This is a
future-incompatible lint to transition this to a hard error in the
future. See issue #53495 for more details.
missing-fragment-specifier
The missing_fragment_specifier
lint is issued when an unused pattern in a
macro_rules!
macro definition has a meta-variable (e.g. $e
) that is not
followed by a fragment specifier (e.g. :expr
).
This warning can always be fixed by removing the unused pattern in the
macro_rules!
macro definition.
Example
macro_rules! foo { () => {}; ($name) => { }; } fn main() { foo!(); }
This will produce:
error: missing fragment specifier
--> lint_example.rs:3:5
|
3 | ($name) => { };
| ^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #40107 <https://github.com/rust-lang/rust/issues/40107>
= note: `#[deny(missing_fragment_specifier)]` on by default
Explanation
To fix this, remove the unused pattern from the macro_rules!
macro definition:
macro_rules! foo { () => {}; } fn main() { foo!(); }
mutable-transmutes
The mutable_transmutes
lint catches transmuting from &T
to &mut T
because it is undefined behavior.
Example
#![allow(unused)] fn main() { unsafe { let y = std::mem::transmute::<&i32, &mut i32>(&5); } }
This will produce:
error: transmuting &T to &mut T is undefined behavior, even if the reference is unused, consider instead using an UnsafeCell
--> lint_example.rs:3:13
|
3 | let y = std::mem::transmute::<&i32, &mut i32>(&5);
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
= note: `#[deny(mutable_transmutes)]` on by default
Explanation
Certain assumptions are made about aliasing of data, and this transmute
violates those assumptions. Consider using UnsafeCell
instead.
named-asm-labels
The named_asm_labels
lint detects the use of named labels in the
inline asm!
macro.
Example
#![feature(asm_experimental_arch)] use std::arch::asm; fn main() { unsafe { asm!("foo: bar"); } }
This will produce:
error: avoid using named labels in inline assembly
--> lint_example.rs:6:15
|
6 | asm!("foo: bar");
| ^^^
|
= help: only local labels of the form `<number>:` should be used in inline asm
= note: see the asm section of Rust By Example <https://doc.rust-lang.org/nightly/rust-by-example/unsafe/asm.html#labels> for more information
= note: `#[deny(named_asm_labels)]` on by default
Explanation
LLVM is allowed to duplicate inline assembly blocks for any reason, for example when it is in a function that gets inlined. Because of this, GNU assembler local labels must be used instead of labels with a name. Using named labels might cause assembler or linker errors.
See the explanation in Rust By Example for more details.
no-mangle-const-items
The no_mangle_const_items
lint detects any const
items with the
no_mangle
attribute.
Example
#![allow(unused)] fn main() { #[no_mangle] const FOO: i32 = 5; }
This will produce:
error: const items should never be `#[no_mangle]`
--> lint_example.rs:3:1
|
3 | const FOO: i32 = 5;
| -----^^^^^^^^^^^^^^
| |
| help: try a static value: `pub static`
|
= note: `#[deny(no_mangle_const_items)]` on by default
Explanation
Constants do not have their symbols exported, and therefore, this
probably means you meant to use a static
, not a const
.
order-dependent-trait-objects
The order_dependent_trait_objects
lint detects a trait coherency
violation that would allow creating two trait impls for the same
dynamic trait object involving marker traits.
Example
#![allow(unused)] fn main() { pub trait Trait {} impl Trait for dyn Send + Sync { } impl Trait for dyn Sync + Send { } }
This will produce:
error: conflicting implementations of trait `main::Trait` for type `(dyn std::marker::Send + std::marker::Sync + 'static)`: (E0119)
--> lint_example.rs:5:1
|
4 | impl Trait for dyn Send + Sync { }
| ------------------------------ first implementation here
5 | impl Trait for dyn Sync + Send { }
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ conflicting implementation for `(dyn std::marker::Send + std::marker::Sync + 'static)`
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #56484 <https://github.com/rust-lang/rust/issues/56484>
= note: `#[deny(order_dependent_trait_objects)]` on by default
Explanation
A previous bug caused the compiler to interpret traits with different
orders (such as Send + Sync
and Sync + Send
) as distinct types
when they were intended to be treated the same. This allowed code to
define separate trait implementations when there should be a coherence
error. This is a future-incompatible lint to transition this to a
hard error in the future. See issue #56484 for more details.
overflowing-literals
The overflowing_literals
lint detects literal out of range for its
type.
Example
#![allow(unused)] fn main() { let x: u8 = 1000; }
This will produce:
error: literal out of range for `u8`
--> lint_example.rs:2:13
|
2 | let x: u8 = 1000;
| ^^^^
|
= note: the literal `1000` does not fit into the type `u8` whose range is `0..=255`
= note: `#[deny(overflowing_literals)]` on by default
Explanation
It is usually a mistake to use a literal that overflows the type where it is used. Either use a literal that is within range, or change the type to be within the range of the literal.
patterns-in-fns-without-body
The patterns_in_fns_without_body
lint detects mut
identifier
patterns as a parameter in functions without a body.
Example
#![allow(unused)] fn main() { trait Trait { fn foo(mut arg: u8); } }
This will produce:
error: patterns aren't allowed in functions without bodies
--> lint_example.rs:3:12
|
3 | fn foo(mut arg: u8);
| ^^^^^^^ help: remove `mut` from the parameter: `arg`
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #35203 <https://github.com/rust-lang/rust/issues/35203>
= note: `#[deny(patterns_in_fns_without_body)]` on by default
Explanation
To fix this, remove mut
from the parameter in the trait definition;
it can be used in the implementation. That is, the following is OK:
#![allow(unused)] fn main() { trait Trait { fn foo(arg: u8); // Removed `mut` here } impl Trait for i32 { fn foo(mut arg: u8) { // `mut` here is OK } } }
Trait definitions can define functions without a body to specify a
function that implementors must define. The parameter names in the
body-less functions are only allowed to be _
or an identifier for
documentation purposes (only the type is relevant). Previous versions
of the compiler erroneously allowed identifier patterns with the
mut
keyword, but this was not intended to be allowed. This is a
future-incompatible lint to transition this to a hard error in the
future. See issue #35203 for more details.
proc-macro-back-compat
The proc_macro_back_compat
lint detects uses of old versions of certain
proc-macro crates, which have hardcoded workarounds in the compiler.
Example
use time_macros_impl::impl_macros;
struct Foo;
impl_macros!(Foo);
This will produce:
warning: using an old version of `time-macros-impl`
::: $DIR/group-compat-hack.rs:27:5
|
LL | impl_macros!(Foo);
| ------------------ in this macro invocation
|
= note: `#[warn(proc_macro_back_compat)]` on by default
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #83125 <https://github.com/rust-lang/rust/issues/83125>
= note: the `time-macros-impl` crate will stop compiling in futures version of Rust. Please update to the latest version of the `time` crate to avoid breakage
= note: this warning originates in a macro (in Nightly builds, run with -Z macro-backtrace for more info)
Explanation
Eventually, the backwards-compatibility hacks present in the compiler will be removed, causing older versions of certain crates to stop compiling. This is a future-incompatible lint to ease the transition to an error. See issue #83125 for more details.
pub-use-of-private-extern-crate
The pub_use_of_private_extern_crate
lint detects a specific
situation of re-exporting a private extern crate
.
Example
#![allow(unused)] fn main() { extern crate core; pub use core as reexported_core; }
This will produce:
error: extern crate `core` is private, and cannot be re-exported (error E0365), consider declaring with `pub`
--> lint_example.rs:3:9
|
3 | pub use core as reexported_core;
| ^^^^^^^^^^^^^^^^^^^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #34537 <https://github.com/rust-lang/rust/issues/34537>
= note: `#[deny(pub_use_of_private_extern_crate)]` on by default
Explanation
A public use
declaration should not be used to publicly re-export a
private extern crate
. pub extern crate
should be used instead.
This was historically allowed, but is not the intended behavior according to the visibility rules. This is a future-incompatible lint to transition this to a hard error in the future. See issue #34537 for more details.
soft-unstable
The soft_unstable
lint detects unstable features that were
unintentionally allowed on stable.
Example
#![allow(unused)] fn main() { #[cfg(test)] extern crate test; #[bench] fn name(b: &mut test::Bencher) { b.iter(|| 123) } }
This will produce:
error: use of unstable library feature 'test': `bench` is a part of custom test frameworks which are unstable
--> lint_example.rs:5:3
|
5 | #[bench]
| ^^^^^
|
= warning: this was previously accepted by the compiler but is being phased out; it will become a hard error in a future release!
= note: for more information, see issue #64266 <https://github.com/rust-lang/rust/issues/64266>
= note: `#[deny(soft_unstable)]` on by default
Explanation
The bench
attribute was accidentally allowed to be specified on
the stable release channel. Turning this to a hard error would have
broken some projects. This lint allows those projects to continue to
build correctly when --cap-lints
is used, but otherwise signal an
error that #[bench]
should not be used on the stable channel. This
is a future-incompatible lint to transition this to a hard error in
the future. See issue #64266 for more details.
test-unstable-lint
The test_unstable_lint
lint tests unstable lints and is perma-unstable.
Example
#![allow(test_unstable_lint)]
{{produces}}
Explanation
In order to test the behavior of unstable lints, a permanently-unstable lint is required. This lint can be used to trigger warnings and errors from the compiler related to unstable lints.
text-direction-codepoint-in-comment
The text_direction_codepoint_in_comment
lint detects Unicode codepoints in comments that
change the visual representation of text on screen in a way that does not correspond to
their on memory representation.
Example
#![deny(text_direction_codepoint_in_comment)] fn main() { println!("{:?}"); // ''); }
This will produce:
error: unicode codepoint changing visible direction of text present in comment
--> lint_example.rs:3:23
|
3 | println!("{:?}"); // '');
| ^^^^-^^
| | |
| | '\u{202e}'
| this comment contains an invisible unicode text flow control codepoint
|
= note: these kind of unicode codepoints change the way text flows on applications that support them, but can cause confusion because they change the order of characters on the screen
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(text_direction_codepoint_in_comment)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
= help: if their presence wasn't intentional, you can remove them
Explanation
Unicode allows changing the visual flow of text on screen in order to support scripts that are written right-to-left, but a specially crafted comment can make code that will be compiled appear to be part of a comment, depending on the software used to read the code. To avoid potential problems or confusion, such as in CVE-2021-42574, by default we deny their use.
text-direction-codepoint-in-literal
The text_direction_codepoint_in_literal
lint detects Unicode codepoints that change the
visual representation of text on screen in a way that does not correspond to their on
memory representation.
Explanation
The unicode characters \u{202A}
, \u{202B}
, \u{202D}
, \u{202E}
, \u{2066}
,
\u{2067}
, \u{2068}
, \u{202C}
and \u{2069}
make the flow of text on screen change
its direction on software that supports these codepoints. This makes the text "abc" display
as "cba" on screen. By leveraging software that supports these, people can write specially
crafted literals that make the surrounding code seem like it's performing one action, when
in reality it is performing another. Because of this, we proactively lint against their
presence to avoid surprises.
Example
#![deny(text_direction_codepoint_in_literal)] fn main() { println!("{:?}", ''); }
This will produce:
error: unicode codepoint changing visible direction of text present in literal
--> lint_example.rs:3:22
|
3 | println!("{:?}", '');
| ^-
| ||
| |'\u{202e}'
| this literal contains an invisible unicode text flow control codepoint
|
= note: these kind of unicode codepoints change the way text flows on applications that support them, but can cause confusion because they change the order of characters on the screen
note: the lint level is defined here
--> lint_example.rs:1:9
|
1 | #![deny(text_direction_codepoint_in_literal)]
| ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
= help: if their presence wasn't intentional, you can remove them
help: if you want to keep them but make them visible in your source code, you can escape them
|
3 | println!("{:?}", '\u{202e}');
| ~~~~~~~~
unaligned-references
The unaligned_references
lint detects unaligned references to fields
of packed structs.
Example
#[repr(packed)]
pub struct Foo {
field1: u64,
field2: u8,
}
fn main() {
unsafe {
let foo = Foo { field1: 0, field2: 0 };
let _ = &foo.field1;
println!("{}", foo.field1); // An implicit `&` is added here, triggering the lint.
}
}
{{produces}}
Explanation
Creating a reference to an insufficiently aligned packed field is undefined behavior and
should be disallowed. Using an unsafe
block does not change anything about this. Instead,
the code should do a copy of the data in the packed field or use raw pointers and unaligned
accesses. See issue #82523 for more information.
unconditional-panic
The unconditional_panic
lint detects an operation that will cause a
panic at runtime.
Example
#![allow(unused)] fn main() { #![allow(unused)] let x = 1 / 0; }
This will produce:
error: this operation will panic at runtime
--> lint_example.rs:3:9
|
3 | let x = 1 / 0;
| ^^^^^ attempt to divide `1_i32` by zero
|
= note: `#[deny(unconditional_panic)]` on by default
Explanation
This lint detects code that is very likely incorrect because it will
always panic, such as division by zero and out-of-bounds array
accesses. Consider adjusting your code if this is a bug, or using the
panic!
or unreachable!
macro instead in case the panic is intended.
unknown-crate-types
The unknown_crate_types
lint detects an unknown crate type found in
a crate_type
attribute.
Example
#![crate_type="lol"] fn main() {}
This will produce:
error: invalid `crate_type` value
--> lint_example.rs:1:15
|
1 | #![crate_type="lol"]
| ^^^^^
|
= note: `#[deny(unknown_crate_types)]` on by default
Explanation
An unknown value give to the crate_type
attribute is almost
certainly a mistake.
useless-deprecated
The useless_deprecated
lint detects deprecation attributes with no effect.
Example
#![allow(unused)] fn main() { struct X; #[deprecated = "message"] impl Default for X { fn default() -> Self { X } } }
This will produce:
error: this `#[deprecated]` annotation has no effect
--> lint_example.rs:4:1
|
4 | #[deprecated = "message"]
| ^^^^^^^^^^^^^^^^^^^^^^^^^ help: remove the unnecessary deprecation attribute
|
= note: `#[deny(useless_deprecated)]` on by default
Explanation
Deprecation attributes have no effect on trait implementations.
JSON Output
This chapter documents the JSON structures emitted by rustc
. JSON may be
enabled with the --error-format=json
flag. Additional
options may be specified with the --json
flag which can
change which messages are generated, and the format of the messages.
JSON messages are emitted one per line to stderr.
If parsing the output with Rust, the
cargo_metadata
crate provides
some support for parsing the messages.
When parsing, care should be taken to be forwards-compatible with future changes
to the format. Optional values may be null
. New fields may be added. Enumerated
fields like "level" or "suggestion_applicability" may add new values.
Diagnostics
Diagnostic messages provide errors or possible concerns generated during
compilation. rustc
provides detailed information about where the diagnostic
originates, along with hints and suggestions.
Diagnostics are arranged in a parent/child relationship where the parent diagnostic value is the core of the diagnostic, and the attached children provide additional context, help, and information.
Diagnostics have the following format:
{
/* The primary message. */
"message": "unused variable: `x`",
/* The diagnostic code.
Some messages may set this value to null.
*/
"code": {
/* A unique string identifying which diagnostic triggered. */
"code": "unused_variables",
/* An optional string explaining more detail about the diagnostic code. */
"explanation": null
},
/* The severity of the diagnostic.
Values may be:
- "error": A fatal error that prevents compilation.
- "warning": A possible error or concern.
- "note": Additional information or context about the diagnostic.
- "help": A suggestion on how to resolve the diagnostic.
- "failure-note": A note attached to the message for further information.
- "error: internal compiler error": Indicates a bug within the compiler.
*/
"level": "warning",
/* An array of source code locations to point out specific details about
where the diagnostic originates from. This may be empty, for example
for some global messages, or child messages attached to a parent.
Character offsets are offsets of Unicode Scalar Values.
*/
"spans": [
{
/* The file where the span is located.
Note that this path may not exist. For example, if the path
points to the standard library, and the rust src is not
available in the sysroot, then it may point to a non-existent
file. Beware that this may also point to the source of an
external crate.
*/
"file_name": "lib.rs",
/* The byte offset where the span starts (0-based, inclusive). */
"byte_start": 21,
/* The byte offset where the span ends (0-based, exclusive). */
"byte_end": 22,
/* The first line number of the span (1-based, inclusive). */
"line_start": 2,
/* The last line number of the span (1-based, inclusive). */
"line_end": 2,
/* The first character offset of the line_start (1-based, inclusive). */
"column_start": 9,
/* The last character offset of the line_end (1-based, exclusive). */
"column_end": 10,
/* Whether or not this is the "primary" span.
This indicates that this span is the focal point of the
diagnostic.
There are rare cases where multiple spans may be marked as
primary. For example, "immutable borrow occurs here" and
"mutable borrow ends here" can be two separate primary spans.
The top (parent) message should always have at least one
primary span, unless it has zero spans. Child messages may have
zero or more primary spans.
*/
"is_primary": true,
/* An array of objects showing the original source code for this
span. This shows the entire lines of text where the span is
located. A span across multiple lines will have a separate
value for each line.
*/
"text": [
{
/* The entire line of the original source code. */
"text": " let x = 123;",
/* The first character offset of the line of
where the span covers this line (1-based, inclusive). */
"highlight_start": 9,
/* The last character offset of the line of
where the span covers this line (1-based, exclusive). */
"highlight_end": 10
}
],
/* An optional message to display at this span location.
This is typically null for primary spans.
*/
"label": null,
/* An optional string of a suggested replacement for this span to
solve the issue. Tools may try to replace the contents of the
span with this text.
*/
"suggested_replacement": null,
/* An optional string that indicates the confidence of the
"suggested_replacement". Tools may use this value to determine
whether or not suggestions should be automatically applied.
Possible values may be:
- "MachineApplicable": The suggestion is definitely what the
user intended. This suggestion should be automatically
applied.
- "MaybeIncorrect": The suggestion may be what the user
intended, but it is uncertain. The suggestion should result
in valid Rust code if it is applied.
- "HasPlaceholders": The suggestion contains placeholders like
`(...)`. The suggestion cannot be applied automatically
because it will not result in valid Rust code. The user will
need to fill in the placeholders.
- "Unspecified": The applicability of the suggestion is unknown.
*/
"suggestion_applicability": null,
/* An optional object indicating the expansion of a macro within
this span.
If a message occurs within a macro invocation, this object will
provide details of where within the macro expansion the message
is located.
*/
"expansion": {
/* The span of the macro invocation.
Uses the same span definition as the "spans" array.
*/
"span": {/*...*/}
/* Name of the macro, such as "foo!" or "#[derive(Eq)]". */
"macro_decl_name": "some_macro!",
/* Optional span where the relevant part of the macro is
defined. */
"def_site_span": {/*...*/},
}
}
],
/* Array of attached diagnostic messages.
This is an array of objects using the same format as the parent
message. Children are not nested (children do not themselves
contain "children" definitions).
*/
"children": [
{
"message": "`#[warn(unused_variables)]` on by default",
"code": null,
"level": "note",
"spans": [],
"children": [],
"rendered": null
},
{
"message": "if this is intentional, prefix it with an underscore",
"code": null,
"level": "help",
"spans": [
{
"file_name": "lib.rs",
"byte_start": 21,
"byte_end": 22,
"line_start": 2,
"line_end": 2,
"column_start": 9,
"column_end": 10,
"is_primary": true,
"text": [
{
"text": " let x = 123;",
"highlight_start": 9,
"highlight_end": 10
}
],
"label": null,
"suggested_replacement": "_x",
"suggestion_applicability": "MachineApplicable",
"expansion": null
}
],
"children": [],
"rendered": null
}
],
/* Optional string of the rendered version of the diagnostic as displayed
by rustc. Note that this may be influenced by the `--json` flag.
*/
"rendered": "warning: unused variable: `x`\n --> lib.rs:2:9\n |\n2 | let x = 123;\n | ^ help: if this is intentional, prefix it with an underscore: `_x`\n |\n = note: `#[warn(unused_variables)]` on by default\n\n"
}
Artifact notifications
Artifact notifications are emitted when the --json=artifacts
flag is used. They indicate that a file artifact has been saved
to disk. More information about emit kinds may be found in the --emit
flag documentation.
{
/* The filename that was generated. */
"artifact": "libfoo.rlib",
/* The kind of artifact that was generated. Possible values:
- "link": The generated crate as specified by the crate-type.
- "dep-info": The `.d` file with dependency information in a Makefile-like syntax.
- "metadata": The Rust `.rmeta` file containing metadata about the crate.
- "save-analysis": A JSON file emitted by the `-Zsave-analysis` feature.
*/
"emit": "link"
}
Future-incompatible reports
If the --json=future-incompat
flag is used, then a separate
JSON structure will be emitted if the crate may stop compiling in the future.
This contains diagnostic information about the particular warnings that may be
turned into a hard error in the future. This will include the diagnostic
information, even if the diagnostics have been suppressed (such as with an
#[allow]
attribute or the --cap-lints
option).
{
/* An array of objects describing a warning that will become a hard error
in the future.
*/
"future_incompat_report":
[
{
/* A diagnostic structure as defined in
https://doc.rust-lang.org/rustc/json.html#diagnostics
*/
"diagnostic": {...},
}
]
}
Tests
rustc
has a built-in facility for building and running tests for a crate.
More information about writing and running tests may be found in the Testing
Chapter of the Rust Programming Language book.
Tests are written as free functions with the #[test]
attribute. For example:
#![allow(unused)] fn main() { #[test] fn it_works() { assert_eq!(2 + 2, 4); } }
Tests "pass" if they return without an error. They "fail" if they panic, or
return a type such as Result
that implements the Termination
trait
with a non-zero value.
By passing the --test
option to rustc
, the compiler will build the crate
in a special mode to construct an executable that will run the tests in the
crate. The --test
flag will make the following changes:
- The crate will be built as a
bin
crate type, forcing it to be an executable. - Links the executable with
libtest
, the test harness that is part of the standard library, which handles running the tests. - Synthesizes a
main
function which will process command-line arguments and run the tests. This newmain
function will replace any existingmain
function as the entry point of the executable, though the existingmain
will still be compiled. - Enables the
test
cfg option, which allows your code to use conditional compilation to detect if it is being built as a test. - Enables building of functions annotated with the
test
andbench
attributes, which will be run by the test harness.
After the executable is created, you can run it to execute the tests and
receive a report on what passes and fails. If you are using Cargo to manage
your project, it has a built-in cargo test
command which handles all of
this automatically. An example of the output looks like this:
running 4 tests
test it_works ... ok
test check_valid_args ... ok
test invalid_characters ... ok
test walks_the_dog ... ok
test result: ok. 4 passed; 0 failed; 0 ignored; 0 measured; 0 filtered out; finished in 0.00s
Note: Tests must be built with the
unwind
panic strategy. This is because all tests run in the same process, and they are intended to catch panics, which is not possible with theabort
strategy. See the unstable-Z panic-abort-tests
option for experimental support of theabort
strategy by spawning tests in separate processes.
Test attributes
Tests are indicated using attributes on free functions. The following attributes are used for testing, see the linked documentation for more details:
#[test]
— Indicates a function is a test to be run.#[bench]
— Indicates a function is a benchmark to be run. Benchmarks are currently unstable and only available in the nightly channel, see the unstable docs for more details.#[should_panic]
— Indicates that the test function will only pass if the function panics.#[ignore]
— Indicates that the test function will be compiled, but not run by default. See the--ignored
and--include-ignored
options to run these tests.
CLI arguments
The libtest harness has several command-line arguments to control its behavior.
Note: When running with
cargo test
, the libtest CLI arguments must be passed after the--
argument to differentiate between flags for Cargo and those for the harness. For example:cargo test -- --nocapture
Filters
Positional arguments (those without a -
prefix) are treated as filters which
will only run tests whose name matches one of those strings. The filter will
match any substring found in the full path of the test function. For example,
if the test function it_works
is located in the module
utils::paths::tests
, then any of the filters works
, path
, utils::
, or
utils::paths::tests::it_works
will match that test.
See Selection options for more options to control which tests are run.
Action options
The following options perform different actions other than running tests.
--list
Prints a list of all tests and benchmarks. Does not run any of the tests. Filters can be used to list only matching tests.
-h
, --help
Displays usage information and command-line options.
Selection options
The following options change how tests are selected.
--test
This is the default mode where all tests will be run as well as running all
benchmarks with only a single iteration (to ensure the benchmark works,
without taking the time to actually perform benchmarking). This can be
combined with the --bench
flag to run both tests and perform full
benchmarking.
--bench
This runs in a mode where tests are ignored, and only runs benchmarks. This
can be combined with --test
to run both benchmarks and tests.
--exact
This forces filters to match the full path of the test exactly.
For example, if the test it_works
is in the module utils::paths::tests
,
then only the string utils::paths::tests::it_works
will match that test.
--skip
FILTER
Skips any tests whose name contains the given FILTER string. This flag may be passed multiple times.
--ignored
Runs only tests that are marked with the ignore
attribute.
--include-ignored
Runs both ignored and non-ignored tests.
--exclude-should-panic
Excludes tests marked with the should_panic
attribute.
⚠️ 🚧 This option is unstable, and requires the -Z unstable-options
flag. See tracking issue
#82348 for more information.
Execution options
The following options affect how tests are executed.
--test-threads
NUM_THREADS
Sets the number of threads to use for running tests in parallel. By default,
uses the amount of concurrency available on the hardware as indicated by
available_parallelism
.
This can also be specified with the RUST_TEST_THREADS
environment variable.
--force-run-in-process
Forces the tests to run in a single process when using the abort
panic
strategy.
⚠️ 🚧 This only works with the unstable -Z panic-abort-tests
option, and
requires the -Z unstable-options
flag. See tracking issue
#67650 for more information.
--ensure-time
⚠️ 🚧 This option is unstable, and requires the -Z unstable-options
flag. See tracking issue
#64888 and the unstable
docs for more information.
--shuffle
Runs the tests in random order, as opposed to the default alphabetical order.
This may also be specified by setting the RUST_TEST_SHUFFLE
environment
variable to anything but 0
.
The random number generator seed that is output can be passed to
--shuffle-seed
to run the tests in the same order
again.
Note that --shuffle
does not affect whether the tests are run in parallel. To
run the tests in random order sequentially, use --shuffle --test-threads 1
.
⚠️ 🚧 This option is unstable, and requires the -Z unstable-options
flag. See tracking issue
#89583 for more information.
--shuffle-seed
SEED
Like --shuffle
, but seeds the random number generator with
SEED. Thus, calling the test harness with --shuffle-seed
SEED twice runs
the tests in the same order both times.
SEED is any 64-bit unsigned integer, for example, one produced by
--shuffle
.
This can also be specified with the RUST_TEST_SHUFFLE_SEED
environment
variable.
⚠️ 🚧 This option is unstable, and requires the -Z unstable-options
flag. See tracking issue
#89583 for more information.
Output options
The following options affect the output behavior.
-q
, --quiet
Displays one character per test instead of one line per test. This is an alias
for --format=terse
.
--nocapture
Does not capture the stdout and stderr of the test, and allows tests to print to the console. Usually the output is captured, and only displayed if the test fails.
This may also be specified by setting the RUST_TEST_NOCAPTURE
environment
variable to anything but 0
.
--show-output
Displays the stdout and stderr of successful tests after all tests have run.
Contrast this with --nocapture
which allows tests to print
while they are running, which can cause interleaved output if there are
multiple tests running in parallel, --show-output
ensures the output is
contiguous, but requires waiting for all tests to finish.
--color
COLOR
Control when colored terminal output is used. Valid options:
auto
: Colorize if stdout is a tty and--nocapture
is not used. This is the default.always
: Always colorize the output.never
: Never colorize the output.
--format
FORMAT
Controls the format of the output. Valid options:
pretty
: This is the default format, with one line per test.terse
: Displays only a single character per test.--quiet
is an alias for this option.json
: Emits JSON objects, one per line. ⚠️ 🚧 This option is unstable, and requires the-Z unstable-options
flag. See tracking issue #49359 for more information.
--logfile
PATH
Writes the results of the tests to the given file.
--report-time
⚠️ 🚧 This option is unstable, and requires the -Z unstable-options
flag. See tracking issue
#64888 and the unstable
docs for more information.
Unstable options
Some CLI options are added in an "unstable" state, where they are intended for
experimentation and testing to determine if the option works correctly, has
the right design, and is useful. The option may not work correctly, break, or
change at any time. To signal that you acknowledge that you are using an
unstable option, they require passing the -Z unstable-options
command-line
flag.
Benchmarks
The libtest harness supports running benchmarks for functions annotated with
the #[bench]
attribute. Benchmarks are currently unstable, and only
available on the nightly channel. More information may be found in the
unstable book.
Custom test frameworks
Experimental support for using custom test harnesses is available on the nightly channel. See tracking issue #50297 and the custom_test_frameworks documentation for more information.
Platform Support
Support for different platforms ("targets") are organized into three tiers, each with a different set of guarantees. For more information on the policies for targets at each tier, see the Target Tier Policy.
Targets are identified by their "target triple" which is the string to inform the compiler what kind of output should be produced.
Tier 1 with Host Tools
Tier 1 targets can be thought of as "guaranteed to work". The Rust project builds official binary releases for each tier 1 target, and automated testing ensures that each tier 1 target builds and passes tests after each change.
Tier 1 targets with host tools additionally support running tools like rustc
and cargo
natively on the target, and automated testing ensures that tests
pass for the host tools as well. This allows the target to be used as a
development platform, not just a compilation target. For the full requirements,
see Tier 1 with Host Tools in
the Target Tier Policy.
All tier 1 targets with host tools support the full standard library.
target | notes |
---|---|
aarch64-unknown-linux-gnu | ARM64 Linux (kernel 4.1, glibc 2.17+) 1 |
i686-pc-windows-gnu | 32-bit MinGW (Windows 7+) 2 |
i686-pc-windows-msvc | 32-bit MSVC (Windows 7+) 2 |
i686-unknown-linux-gnu | 32-bit Linux (kernel 3.2+, glibc 2.17+) |
x86_64-apple-darwin | 64-bit macOS (10.7+, Lion+) |
x86_64-pc-windows-gnu | 64-bit MinGW (Windows 7+) 2 |
x86_64-pc-windows-msvc | 64-bit MSVC (Windows 7+) 2 |
x86_64-unknown-linux-gnu | 64-bit Linux (kernel 3.2+, glibc 2.17+) |
Stack probes support is missing on
aarch64-unknown-linux-gnu
, but it's planned to be implemented in the near
future. The implementation is tracked on issue #77071.
Only Windows 10 currently undergoes automated testing. Earlier versions of Windows rely on testing and support from the community.
Tier 1
Tier 1 targets can be thought of as "guaranteed to work". The Rust project builds official binary releases for each tier 1 target, and automated testing ensures that each tier 1 target builds and passes tests after each change. For the full requirements, see Tier 1 target policy in the Target Tier Policy.
At this time, all Tier 1 targets are Tier 1 with Host Tools.
Tier 2 with Host Tools
Tier 2 targets can be thought of as "guaranteed to build". The Rust project builds official binary releases for each tier 2 target, and automated builds ensure that each tier 2 target builds after each change. Automated tests are not always run so it's not guaranteed to produce a working build, but tier 2 targets often work to quite a good degree and patches are always welcome!
Tier 2 targets with host tools additionally support running tools like rustc
and cargo
natively on the target, and automated builds ensure that the host
tools build as well. This allows the target to be used as a development
platform, not just a compilation target. For the full requirements, see Tier 2
with Host Tools in the Target
Tier Policy.
All tier 2 targets with host tools support the full standard library.
NOTE: The rust-docs
component is not usually built for tier 2 targets,
so Rustup may install the documentation for a similar tier 1 target instead.
target | notes |
---|---|
aarch64-apple-darwin | ARM64 macOS (11.0+, Big Sur+) |
aarch64-pc-windows-msvc | ARM64 Windows MSVC |
aarch64-unknown-linux-musl | ARM64 Linux with MUSL |
arm-unknown-linux-gnueabi | ARMv6 Linux (kernel 3.2, glibc 2.17) |
arm-unknown-linux-gnueabihf | ARMv6 Linux, hardfloat (kernel 3.2, glibc 2.17) |
armv7-unknown-linux-gnueabihf | ARMv7 Linux, hardfloat (kernel 3.2, glibc 2.17) |
mips-unknown-linux-gnu | MIPS Linux (kernel 4.4, glibc 2.23) |
mips64-unknown-linux-gnuabi64 | MIPS64 Linux, n64 ABI (kernel 4.4, glibc 2.23) |
mips64el-unknown-linux-gnuabi64 | MIPS64 (LE) Linux, n64 ABI (kernel 4.4, glibc 2.23) |
mipsel-unknown-linux-gnu | MIPS (LE) Linux (kernel 4.4, glibc 2.23) |
powerpc-unknown-linux-gnu | PowerPC Linux (kernel 3.2, glibc 2.17) |
powerpc64-unknown-linux-gnu | PPC64 Linux (kernel 3.2, glibc 2.17) |
powerpc64le-unknown-linux-gnu | PPC64LE Linux (kernel 3.10, glibc 2.17) |
riscv64gc-unknown-linux-gnu | RISC-V Linux (kernel 4.20, glibc 2.29) |
s390x-unknown-linux-gnu | S390x Linux (kernel 3.2, glibc 2.17) |
x86_64-unknown-freebsd | 64-bit FreeBSD |
x86_64-unknown-illumos | illumos |
x86_64-unknown-linux-musl | 64-bit Linux with MUSL |
x86_64-unknown-netbsd | NetBSD/amd64 |
Tier 2
Tier 2 targets can be thought of as "guaranteed to build". The Rust project builds official binary releases for each tier 2 target, and automated builds ensure that each tier 2 target builds after each change. Automated tests are not always run so it's not guaranteed to produce a working build, but tier 2 targets often work to quite a good degree and patches are always welcome! For the full requirements, see Tier 2 target policy in the Target Tier Policy.
The std
column in the table below has the following meanings:
- ✓ indicates the full standard library is available.
- * indicates the target only supports
no_std
development.
NOTE: The rust-docs
component is not usually built for tier 2 targets,
so Rustup may install the documentation for a similar tier 1 target instead.
target | std | notes |
---|---|---|
aarch64-apple-ios | ✓ | ARM64 iOS |
aarch64-apple-ios-sim | ✓ | Apple iOS Simulator on ARM64 |
aarch64-fuchsia | ✓ | ARM64 Fuchsia |
aarch64-linux-android | ✓ | ARM64 Android |
aarch64-unknown-none-softfloat | * | Bare ARM64, softfloat |
aarch64-unknown-none | * | Bare ARM64, hardfloat |
arm-linux-androideabi | ✓ | ARMv7 Android |
arm-unknown-linux-musleabi | ✓ | ARMv6 Linux with MUSL |
arm-unknown-linux-musleabihf | ✓ | ARMv6 Linux with MUSL, hardfloat |
armebv7r-none-eabi | * | Bare ARMv7-R, Big Endian |
armebv7r-none-eabihf | * | Bare ARMv7-R, Big Endian, hardfloat |
armv5te-unknown-linux-gnueabi | ✓ | ARMv5TE Linux (kernel 4.4, glibc 2.23) |
armv5te-unknown-linux-musleabi | ✓ | ARMv5TE Linux with MUSL |
armv7-linux-androideabi | ✓ | ARMv7a Android |
armv7-unknown-linux-gnueabi | ✓ | ARMv7 Linux (kernel 4.15, glibc 2.27) |
armv7-unknown-linux-musleabi | ✓ | ARMv7 Linux with MUSL |
armv7-unknown-linux-musleabihf | ✓ | ARMv7 Linux with MUSL, hardfloat |
armv7a-none-eabi | * | Bare ARMv7-A |
armv7r-none-eabi | * | Bare ARMv7-R |
armv7r-none-eabihf | * | Bare ARMv7-R, hardfloat |
asmjs-unknown-emscripten | ✓ | asm.js via Emscripten |
i586-pc-windows-msvc | * | 32-bit Windows w/o SSE |
i586-unknown-linux-gnu | ✓ | 32-bit Linux w/o SSE (kernel 3.2, glibc 2.17) |
i586-unknown-linux-musl | ✓ | 32-bit Linux w/o SSE, MUSL |
i686-linux-android | ✓ | 32-bit x86 Android |
i686-unknown-freebsd | ✓ | 32-bit FreeBSD |
i686-unknown-linux-musl | ✓ | 32-bit Linux with MUSL |
mips-unknown-linux-musl | ✓ | MIPS Linux with MUSL |
mips64-unknown-linux-muslabi64 | ✓ | MIPS64 Linux, n64 ABI, MUSL |
mips64el-unknown-linux-muslabi64 | ✓ | MIPS64 (LE) Linux, n64 ABI, MUSL |
mipsel-unknown-linux-musl | ✓ | MIPS (LE) Linux with MUSL |
nvptx64-nvidia-cuda | * | --emit=asm generates PTX code that runs on NVIDIA GPUs |
riscv32i-unknown-none-elf | * | Bare RISC-V (RV32I ISA) |
riscv32imac-unknown-none-elf | * | Bare RISC-V (RV32IMAC ISA) |
riscv32imc-unknown-none-elf | * | Bare RISC-V (RV32IMC ISA) |
riscv64gc-unknown-none-elf | * | Bare RISC-V (RV64IMAFDC ISA) |
riscv64imac-unknown-none-elf | * | Bare RISC-V (RV64IMAC ISA) |
sparc64-unknown-linux-gnu | ✓ | SPARC Linux (kernel 4.4, glibc 2.23) |
sparcv9-sun-solaris | ✓ | SPARC Solaris 10/11, illumos |
thumbv6m-none-eabi | * | Bare Cortex-M0, M0+, M1 |
thumbv7em-none-eabi | * | Bare Cortex-M4, M7 |
thumbv7em-none-eabihf | * | Bare Cortex-M4F, M7F, FPU, hardfloat |
thumbv7m-none-eabi | * | Bare Cortex-M3 |
thumbv7neon-linux-androideabi | ✓ | Thumb2-mode ARMv7a Android with NEON |
thumbv7neon-unknown-linux-gnueabihf | ✓ | Thumb2-mode ARMv7a Linux with NEON (kernel 4.4, glibc 2.23) |
thumbv8m.base-none-eabi | * | ARMv8-M Baseline |
thumbv8m.main-none-eabi | * | ARMv8-M Mainline |
thumbv8m.main-none-eabihf | * | ARMv8-M Mainline, hardfloat |
wasm32-unknown-emscripten | ✓ | WebAssembly via Emscripten |
wasm32-unknown-unknown | ✓ | WebAssembly |
wasm32-wasi | ✓ | WebAssembly with WASI |
x86_64-apple-ios | ✓ | 64-bit x86 iOS |
x86_64-fortanix-unknown-sgx | ✓ | Fortanix ABI for 64-bit Intel SGX |
x86_64-fuchsia | ✓ | 64-bit Fuchsia |
x86_64-linux-android | ✓ | 64-bit x86 Android |
x86_64-pc-solaris | ✓ | 64-bit Solaris 10/11, illumos |
x86_64-unknown-linux-gnux32 | ✓ | 64-bit Linux (x32 ABI) (kernel 4.15, glibc 2.27) |
x86_64-unknown-none | * | Freestanding/bare-metal x86_64, softfloat |
x86_64-unknown-redox | ✓ | Redox OS |
Tier 3
Tier 3 targets are those which the Rust codebase has support for, but which the Rust project does not build or test automatically, so they may or may not work. Official builds are not available. For the full requirements, see Tier 3 target policy in the Target Tier Policy.
The std
column in the table below has the following meanings:
- ✓ indicates the full standard library is available.
- * indicates the target only supports
no_std
development. - ? indicates the standard library support is unknown or a work-in-progress.
The host
column indicates whether the codebase includes support for building
host tools.
target | std | host | notes |
---|---|---|---|
aarch64-apple-ios-macabi | ? | Apple Catalyst on ARM64 | |
aarch64-apple-tvos | * | ARM64 tvOS | |
aarch64-apple-watchos-sim | ✓ | ARM64 Apple WatchOS Simulator | |
aarch64-kmc-solid_asp3 | ✓ | ARM64 SOLID with TOPPERS/ASP3 | |
aarch64-nintendo-switch-freestanding | * | ARM64 Nintendo Switch, Horizon | |
aarch64-pc-windows-gnullvm | ✓ | ✓ | |
aarch64-unknown-freebsd | ✓ | ✓ | ARM64 FreeBSD |
aarch64-unknown-hermit | ✓ | ARM64 HermitCore | |
aarch64-unknown-uefi | * | ARM64 UEFI | |
aarch64-unknown-linux-gnu_ilp32 | ✓ | ✓ | ARM64 Linux (ILP32 ABI) |
aarch64-unknown-netbsd | ✓ | ✓ | |
aarch64-unknown-openbsd | ✓ | ✓ | ARM64 OpenBSD |
aarch64-unknown-redox | ? | ARM64 Redox OS | |
aarch64-uwp-windows-msvc | ? | ||
aarch64-wrs-vxworks | ? | ||
aarch64_be-unknown-linux-gnu_ilp32 | ✓ | ✓ | ARM64 Linux (big-endian, ILP32 ABI) |
aarch64_be-unknown-linux-gnu | ✓ | ✓ | ARM64 Linux (big-endian) |
arm64_32-apple-watchos | ✓ | ARM Apple WatchOS 64-bit with 32-bit pointers | |
armeb-unknown-linux-gnueabi | ✓ | ? | ARM BE8 the default ARM big-endian architecture since ARMv6. |
armv4t-none-eabi | * | ARMv4T A32 | |
armv4t-unknown-linux-gnueabi | ? | ||
armv5te-none-eabi | * | ARMv5TE A32 | |
armv5te-unknown-linux-uclibceabi | ? | ARMv5TE Linux with uClibc | |
armv6-unknown-freebsd | ✓ | ✓ | ARMv6 FreeBSD |
armv6-unknown-netbsd-eabihf | ? | ||
armv6k-nintendo-3ds | ? | ARMv6K Nintendo 3DS, Horizon (Requires devkitARM toolchain) | |
armv7-apple-ios | ✓ | ARMv7 iOS, Cortex-a8 | |
armv7-unknown-linux-uclibceabi | ✓ | ✓ | ARMv7 Linux with uClibc, softfloat |
armv7-unknown-linux-uclibceabihf | ✓ | ? | ARMv7 Linux with uClibc, hardfloat |
armv7-unknown-freebsd | ✓ | ✓ | ARMv7 FreeBSD |
armv7-unknown-netbsd-eabihf | ✓ | ✓ | |
armv7-wrs-vxworks-eabihf | ? | ||
armv7a-kmc-solid_asp3-eabi | ✓ | ARM SOLID with TOPPERS/ASP3 | |
armv7a-kmc-solid_asp3-eabihf | ✓ | ARM SOLID with TOPPERS/ASP3, hardfloat | |
armv7a-none-eabihf | * | ARM Cortex-A, hardfloat | |
armv7k-apple-watchos | ✓ | ARM Apple WatchOS | |
armv7s-apple-ios | ✓ | ||
avr-unknown-gnu-atmega328 | * | AVR. Requires -Z build-std=core | |
bpfeb-unknown-none | * | BPF (big endian) | |
bpfel-unknown-none | * | BPF (little endian) | |
hexagon-unknown-linux-musl | ? | ||
i386-apple-ios | ✓ | 32-bit x86 iOS | |
i686-apple-darwin | ✓ | ✓ | 32-bit macOS (10.7+, Lion+) |
i686-pc-windows-msvc | * | 32-bit Windows XP support | |
i686-unknown-haiku | ✓ | ✓ | 32-bit Haiku |
i686-unknown-netbsd | ✓ | ✓ | NetBSD/i386 with SSE2 |
i686-unknown-openbsd | ✓ | ✓ | 32-bit OpenBSD |
i686-unknown-uefi | * | 32-bit UEFI | |
i686-uwp-windows-gnu | ? | ||
i686-uwp-windows-msvc | ? | ||
i686-wrs-vxworks | ? | ||
m68k-unknown-linux-gnu | ? | Motorola 680x0 Linux | |
mips-unknown-linux-uclibc | ✓ | MIPS Linux with uClibc | |
mips64-openwrt-linux-musl | ? | MIPS64 for OpenWrt Linux MUSL | |
mipsel-sony-psp | * | MIPS (LE) Sony PlayStation Portable (PSP) | |
mipsel-sony-psx | * | MIPS (LE) Sony PlayStation 1 (PSX) | |
mipsel-unknown-linux-uclibc | ✓ | MIPS (LE) Linux with uClibc | |
mipsel-unknown-none | * | Bare MIPS (LE) softfloat | |
mipsisa32r6-unknown-linux-gnu | ? | ||
mipsisa32r6el-unknown-linux-gnu | ? | ||
mipsisa64r6-unknown-linux-gnuabi64 | ? | ||
mipsisa64r6el-unknown-linux-gnuabi64 | ? | ||
msp430-none-elf | * | 16-bit MSP430 microcontrollers | |
powerpc-unknown-linux-gnuspe | ✓ | PowerPC SPE Linux | |
powerpc-unknown-linux-musl | ? | ||
powerpc-unknown-netbsd | ✓ | ✓ | |
powerpc-unknown-openbsd | ? | ||
powerpc-wrs-vxworks-spe | ? | ||
powerpc-wrs-vxworks | ? | ||
powerpc64-unknown-freebsd | ✓ | ✓ | PPC64 FreeBSD (ELFv1 and ELFv2) |
powerpc64le-unknown-freebsd | PPC64LE FreeBSD | ||
powerpc-unknown-freebsd | PowerPC FreeBSD | ||
powerpc64-unknown-linux-musl | ? | ||
powerpc64-wrs-vxworks | ? | ||
powerpc64le-unknown-linux-musl | ? | ||
powerpc64-unknown-openbsd | ✓ | ✓ | OpenBSD/powerpc64 |
riscv32gc-unknown-linux-gnu | RISC-V Linux (kernel 5.4, glibc 2.33) | ||
riscv32gc-unknown-linux-musl | RISC-V Linux (kernel 5.4, musl + RISCV32 support patches) | ||
riscv32im-unknown-none-elf | * | Bare RISC-V (RV32IM ISA) | |
riscv32imac-unknown-xous-elf | ? | RISC-V Xous (RV32IMAC ISA) | |
riscv32imc-esp-espidf | ✓ | RISC-V ESP-IDF | |
riscv64gc-unknown-freebsd | RISC-V FreeBSD | ||
riscv64gc-unknown-linux-musl | RISC-V Linux (kernel 4.20, musl 1.2.0) | ||
riscv64gc-unknown-openbsd | ✓ | ✓ | OpenBSD/riscv64 |
s390x-unknown-linux-musl | S390x Linux (kernel 3.2, MUSL) | ||
sparc-unknown-linux-gnu | ✓ | 32-bit SPARC Linux | |
sparc64-unknown-netbsd | ✓ | ✓ | NetBSD/sparc64 |
sparc64-unknown-openbsd | ✓ | ✓ | OpenBSD/sparc64 |
thumbv4t-none-eabi | * | ARMv4T T32 | |
thumbv5te-none-eabi | * | ARMv5TE T32 | |
thumbv7a-pc-windows-msvc | ? | ||
thumbv7a-uwp-windows-msvc | ✓ | ||
thumbv7neon-unknown-linux-musleabihf | ? | Thumb2-mode ARMv7a Linux with NEON, MUSL | |
wasm64-unknown-unknown | ? | WebAssembly | |
x86_64-apple-ios-macabi | ✓ | Apple Catalyst on x86_64 | |
x86_64-apple-tvos | * | x86 64-bit tvOS | |
x86_64-apple-watchos-sim | ✓ | x86 64-bit Apple WatchOS simulator | |
x86_64-pc-windows-gnullvm | ✓ | ✓ | |
x86_64-pc-windows-msvc | * | 64-bit Windows XP support | |
x86_64-sun-solaris | ? | Deprecated target for 64-bit Solaris 10/11, illumos | |
x86_64-unknown-dragonfly | ✓ | ✓ | 64-bit DragonFlyBSD |
x86_64-unknown-haiku | ✓ | ✓ | 64-bit Haiku |
x86_64-unknown-hermit | ✓ | HermitCore | |
x86_64-unknown-l4re-uclibc | ? | ||
x86_64-unknown-none-linuxkernel | * | Linux kernel modules | |
x86_64-unknown-openbsd | ✓ | ✓ | 64-bit OpenBSD |
x86_64-unknown-uefi | * | 64-bit UEFI | |
x86_64-uwp-windows-gnu | ✓ | ||
x86_64-uwp-windows-msvc | ✓ | ||
x86_64-wrs-vxworks | ? |
Target Tier Policy
Table of Contents
General
Rust provides three tiers of target support:
- Rust provides no guarantees about tier 3 targets; they exist in the codebase, but may or may not build.
- Rust's continuous integration checks that tier 2 targets will always build, but they may or may not pass tests.
- Rust's continuous integration checks that tier 1 targets will always build and pass tests.
Adding a new tier 3 target imposes minimal requirements; we focus primarily on avoiding disruption to other ongoing Rust development.
Tier 2 and tier 1 targets place work on Rust project developers as a whole, to avoid breaking the target. The broader Rust community may also feel more inclined to support higher-tier targets in their crates (though they are not obligated to do so). Thus, these tiers require commensurate and ongoing efforts from the maintainers of the target, to demonstrate value and to minimize any disruptions to ongoing Rust development.
This policy defines the requirements for accepting a proposed target at a given level of support.
Each tier builds on all the requirements from the previous tier, unless
overridden by a stronger requirement. Targets at tier 2 and tier 1 may also
provide host tools (such as rustc
and cargo
); each of those tiers
includes a set of supplementary requirements that must be met if supplying host
tools for the target. A target at tier 2 or tier 1 is not required to supply
host tools, but if it does, it must meet the corresponding additional
requirements for host tools.
The policy for each tier also documents the Rust governance teams that must approve the addition of any target at that tier. Those teams are responsible for reviewing and evaluating the target, based on these requirements and their own judgment. Those teams may apply additional requirements, including subjective requirements, such as to deal with issues not foreseen by this policy. (Such requirements may subsequently motivate additions to this policy.)
While these criteria attempt to document the policy, that policy still involves human judgment. Targets must fulfill the spirit of the requirements as well, as determined by the judgment of the approving teams. Reviewers and team members evaluating targets and target-specific patches should always use their own best judgment regarding the quality of work, and the suitability of a target for the Rust project. Neither this policy nor any decisions made regarding targets shall create any binding agreement or estoppel by any party.
Before filing an issue or pull request (PR) to introduce or promote a target, the target should already meet the corresponding tier requirements. This does not preclude an existing target's maintainers using issues (on the Rust repository or otherwise) to track requirements that have not yet been met, as appropriate; however, before officially proposing the introduction or promotion of a target, it should meet all of the necessary requirements. A target proposal must quote the corresponding requirements verbatim and respond to them as part of explaining how the target meets those requirements. (For the requirements that simply state that the target or the target developers must not do something, it suffices to acknowledge the requirement.)
For a list of all supported targets and their corresponding tiers ("tier 3", "tier 2", "tier 2 with host tools", "tier 1", or "tier 1 with host tools"), see platform support.
Several parts of this policy require providing target-specific documentation. Such documentation should typically appear in a subdirectory of the platform-support section of this rustc manual, with a link from the target's entry in platform support. Use TEMPLATE.md as a base, and see other documentation in that directory for examples.
Note that a target must have already received approval for the next lower tier, and spent a reasonable amount of time at that tier, before making a proposal for promotion to the next higher tier; this is true even if a target meets the requirements for several tiers at once. This policy leaves the precise interpretation of "reasonable amount of time" up to the approving teams; those teams may scale the amount of time required based on their confidence in the target and its demonstrated track record at its current tier. At a minimum, multiple stable releases of Rust should typically occur between promotions of a target.
The availability or tier of a target in stable Rust is not a hard stability guarantee about the future availability or tier of that target. Higher-level target tiers are an increasing commitment to the support of a target, and we will take that commitment and potential disruptions into account when evaluating the potential demotion or removal of a target that has been part of a stable release. The promotion or demotion of a target will not generally affect existing stable releases, only current development and future releases.
In this policy, the words "must" and "must not" specify absolute requirements that a target must meet to qualify for a tier. The words "should" and "should not" specify requirements that apply in almost all cases, but for which the approving teams may grant an exception for good reason. The word "may" indicates something entirely optional, and does not indicate guidance or recommendations. This language is based on IETF RFC 2119.
Adding a new target
New targets typically start as Tier 3 and then can be promoted later.
To propose addition of a new target, open a pull request on rust-lang/rust
:
- Copy the Tier 3 target policy to the description and fill it out, see example.
- Add a new description for the target in
src/doc/rustc/src/platform-support
using the template. - Add the target to the SUMMARY.md (allows wildcards) and platform-support.md (must name all targets verbatim). Link to the created description page.
- Ensure the pull request is assigned to a member of the Rust compiler team by commenting:
r? compiler-team
Tier 3 target policy
At this tier, the Rust project provides no official support for a target, so we place minimal requirements on the introduction of targets.
A proposed new tier 3 target must be reviewed and approved by a member of the compiler team based on these requirements. The reviewer may choose to gauge broader compiler team consensus via a Major Change Proposal (MCP).
A proposed target or target-specific patch that substantially changes code shared with other targets (not just target-specific code) must be reviewed and approved by the appropriate team for that shared code before acceptance.
- A tier 3 target must have a designated developer or developers (the "target maintainers") on record to be CCed when issues arise regarding the target. (The mechanism to track and CC such developers may evolve over time.)
- Targets must use naming consistent with any existing targets; for instance, a
target for the same CPU or OS as an existing Rust target should use the same
name for that CPU or OS. Targets should normally use the same names and
naming conventions as used elsewhere in the broader ecosystem beyond Rust
(such as in other toolchains), unless they have a very good reason to
diverge. Changing the name of a target can be highly disruptive, especially
once the target reaches a higher tier, so getting the name right is important
even for a tier 3 target.
- Target names should not introduce undue confusion or ambiguity unless absolutely necessary to maintain ecosystem compatibility. For example, if the name of the target makes people extremely likely to form incorrect beliefs about what it targets, the name should be changed or augmented to disambiguate it.
- Tier 3 targets may have unusual requirements to build or use, but must not
create legal issues or impose onerous legal terms for the Rust project or for
Rust developers or users.
- The target must not introduce license incompatibilities.
- Anything added to the Rust repository must be under the standard Rust
license (
MIT OR Apache-2.0
). - The target must not cause the Rust tools or libraries built for any other
host (even when supporting cross-compilation to the target) to depend
on any new dependency less permissive than the Rust licensing policy. This
applies whether the dependency is a Rust crate that would require adding
new license exceptions (as specified by the
tidy
tool in the rust-lang/rust repository), or whether the dependency is a native library or binary. In other words, the introduction of the target must not cause a user installing or running a version of Rust or the Rust tools to be subject to any new license requirements. - Compiling, linking, and emitting functional binaries, libraries, or other
code for the target (whether hosted on the target itself or cross-compiling
from another target) must not depend on proprietary (non-FOSS) libraries.
Host tools built for the target itself may depend on the ordinary runtime
libraries supplied by the platform and commonly used by other applications
built for the target, but those libraries must not be required for code
generation for the target; cross-compilation to the target must not require
such libraries at all. For instance,
rustc
built for the target may depend on a common proprietary C runtime library or console output library, but must not depend on a proprietary code generation library or code optimization library. Rust's license permits such combinations, but the Rust project has no interest in maintaining such combinations within the scope of Rust itself, even at tier 3. - "onerous" here is an intentionally subjective term. At a minimum, "onerous" legal/licensing terms include but are not limited to: non-disclosure requirements, non-compete requirements, contributor license agreements (CLAs) or equivalent, "non-commercial"/"research-only"/etc terms, requirements conditional on the employer or employment of any particular Rust developers, revocable terms, any requirements that create liability for the Rust project or its developers or users, or any requirements that adversely affect the livelihood or prospects of the Rust project or its developers or users.
- Neither this policy nor any decisions made regarding targets shall create any
binding agreement or estoppel by any party. If any member of an approving
Rust team serves as one of the maintainers of a target, or has any legal or
employment requirement (explicit or implicit) that might affect their
decisions regarding a target, they must recuse themselves from any approval
decisions regarding the target's tier status, though they may otherwise
participate in discussions.
- This requirement does not prevent part or all of this policy from being cited in an explicit contract or work agreement (e.g. to implement or maintain support for a target). This requirement exists to ensure that a developer or team responsible for reviewing and approving a target does not face any legal threats or obligations that would prevent them from freely exercising their judgment in such approval, even if such judgment involves subjective matters or goes beyond the letter of these requirements.
- Tier 3 targets should attempt to implement as much of the standard libraries
as possible and appropriate (
core
for most targets,alloc
for targets that can support dynamic memory allocation,std
for targets with an operating system or equivalent layer of system-provided functionality), but may leave some code unimplemented (either unavailable or stubbed out as appropriate), whether because the target makes it impossible to implement or challenging to implement. The authors of pull requests are not obligated to avoid calling any portions of the standard library on the basis of a tier 3 target not implementing those portions. - The target must provide documentation for the Rust community explaining how to build for the target, using cross-compilation if possible. If the target supports running binaries, or running tests (even if they do not pass), the documentation must explain how to run such binaries or tests for the target, using emulation if possible or dedicated hardware if necessary.
- Tier 3 targets must not impose burden on the authors of pull requests, or
other developers in the community, to maintain the target. In particular,
do not post comments (automated or manual) on a PR that derail or suggest a
block on the PR based on a tier 3 target. Do not send automated messages or
notifications (via any medium, including via
@
) to a PR author or others involved with a PR regarding a tier 3 target, unless they have opted into such messages.- Backlinks such as those generated by the issue/PR tracker when linking to an issue or PR are not considered a violation of this policy, within reason. However, such messages (even on a separate repository) must not generate notifications to anyone involved with a PR who has not requested such notifications.
- Patches adding or updating tier 3 targets must not break any existing tier 2
or tier 1 target, and must not knowingly break another tier 3 target without
approval of either the compiler team or the maintainers of the other tier 3
target.
- In particular, this may come up when working on closely related targets, such as variations of the same architecture with different features. Avoid introducing unconditional uses of features that another variation of the target may not have; use conditional compilation or runtime detection, as appropriate, to let each target run code supported by that target.
If a tier 3 target stops meeting these requirements, or the target maintainers no longer have interest or time, or the target shows no signs of activity and has not built for some time, or removing the target would improve the quality of the Rust codebase, we may post a PR to remove it; any such PR will be CCed to the target maintainers (and potentially other people who have previously worked on the target), to check potential interest in improving the situation.
Tier 2 target policy
At this tier, the Rust project guarantees that a target builds, and will reject patches that fail to build on a target. Thus, we place requirements that ensure the target will not block forward progress of the Rust project.
A proposed new tier 2 target must be reviewed and approved by the compiler team based on these requirements. Such review and approval may occur via a Major Change Proposal (MCP).
In addition, the infrastructure team must approve the integration of the target into Continuous Integration (CI), and the tier 2 CI-related requirements. This review and approval may take place in a PR adding the target to CI, or simply by an infrastructure team member reporting the outcome of a team discussion.
- A tier 2 target must have value to people other than its maintainers. (It may still be a niche target, but it must not be exclusively useful for an inherently closed group.)
- A tier 2 target must have a designated team of developers (the "target
maintainers") available to consult on target-specific build-breaking issues,
or if necessary to develop target-specific language or library implementation
details. This team must have at least 2 developers.
- The target maintainers should not only fix target-specific issues, but should use any such issue as an opportunity to educate the Rust community about portability to their target, and enhance documentation of the target.
- The target must not place undue burden on Rust developers not specifically concerned with that target. Rust developers are expected to not gratuitously break a tier 2 target, but are not expected to become experts in every tier 2 target, and are not expected to provide target-specific implementations for every tier 2 target.
- The target must provide documentation for the Rust community explaining how to build for the target using cross-compilation, and explaining how to run tests for the target. If at all possible, this documentation should show how to run Rust programs and tests for the target using emulation, to allow anyone to do so. If the target cannot be feasibly emulated, the documentation should explain how to obtain and work with physical hardware, cloud systems, or equivalent.
- The target must document its baseline expectations for the features or versions of CPUs, operating systems, libraries, runtime environments, and similar.
- If introducing a new tier 2 or higher target that is identical to an existing
Rust target except for the baseline expectations for the features or versions
of CPUs, operating systems, libraries, runtime environments, and similar,
then the proposed target must document to the satisfaction of the approving
teams why the specific difference in baseline expectations provides
sufficient value to justify a separate target.
- Note that in some cases, based on the usage of existing targets within the
Rust community, Rust developers or a target's maintainers may wish to
modify the baseline expectations of a target, or split an existing target
into multiple targets with different baseline expectations. A proposal to
do so will be treated similarly to the analogous promotion, demotion, or
removal of a target, according to this policy, with the same team approvals
required.
- For instance, if an OS version has become obsolete and unsupported, a target for that OS may raise its baseline expectations for OS version (treated as though removing a target corresponding to the older versions), or a target for that OS may split out support for older OS versions into a lower-tier target (treated as though demoting a target corresponding to the older versions, and requiring justification for a new target at a lower tier for the older OS versions).
- Note that in some cases, based on the usage of existing targets within the
Rust community, Rust developers or a target's maintainers may wish to
modify the baseline expectations of a target, or split an existing target
into multiple targets with different baseline expectations. A proposal to
do so will be treated similarly to the analogous promotion, demotion, or
removal of a target, according to this policy, with the same team approvals
required.
- Tier 2 targets must not leave any significant portions of
core
or the standard library unimplemented or stubbed out, unless they cannot possibly be supported on the target.- The right approach to handling a missing feature from a target may depend on whether the target seems likely to develop the feature in the future. In some cases, a target may be co-developed along with Rust support, and Rust may gain new features on the target as that target gains the capabilities to support those features.
- As an exception, a target identical to an existing tier 1 target except for
lower baseline expectations for the OS, CPU, or similar, may propose to
qualify as tier 2 (but not higher) without support for
std
if the target will primarily be used inno_std
applications, to reduce the support burden for the standard library. In this case, evaluation of the proposed target's value will take this limitation into account.
- The code generation backend for the target should not have deficiencies that
invalidate Rust safety properties, as evaluated by the Rust compiler team.
(This requirement does not apply to arbitrary security enhancements or
mitigations provided by code generation backends, only to those properties
needed to ensure safe Rust code cannot cause undefined behavior or other
unsoundness.) If this requirement does not hold, the target must clearly and
prominently document any such limitations as part of the target's entry in
the target tier list, and ideally also via a failing test in the testsuite.
The Rust compiler team must be satisfied with the balance between these
limitations and the difficulty of implementing the necessary features.
- For example, if Rust relies on a specific code generation feature to ensure that safe code cannot overflow the stack, the code generation for the target should support that feature.
- If the Rust compiler introduces new safety properties (such as via new capabilities of a compiler backend), the Rust compiler team will determine if they consider those new safety properties a best-effort improvement for specific targets, or a required property for all Rust targets. In the latter case, the compiler team may require the maintainers of existing targets to either implement and confirm support for the property or update the target tier list with documentation of the missing property.
- If the target supports C code, and the target has an interoperable calling
convention for C code, the Rust target must support that C calling convention
for the platform via
extern "C"
. The C calling convention does not need to be the default Rust calling convention for the target, however. - The target must build reliably in CI, for all components that Rust's CI considers mandatory.
- The approving teams may additionally require that a subset of tests pass in
CI, such as enough to build a functional "hello world" program,
./x.py test --no-run
, or equivalent "smoke tests". In particular, this requirement may apply if the target builds host tools, or if the tests in question provide substantial value via early detection of critical problems. - Building the target in CI must not take substantially longer than the current slowest target in CI, and should not substantially raise the maintenance burden of the CI infrastructure. This requirement is subjective, to be evaluated by the infrastructure team, and will take the community importance of the target into account.
- Tier 2 targets should, if at all possible, support cross-compiling. Tier 2 targets should not require using the target as the host for builds, even if the target supports host tools.
- In addition to the legal requirements for all targets (specified in the tier
3 requirements), because a tier 2 target typically involves the Rust project
building and supplying various compiled binaries, incorporating the target
and redistributing any resulting compiled binaries (e.g. built libraries,
host tools if any) must not impose any onerous license requirements on any
members of the Rust project, including infrastructure team members and those
operating CI systems. This is a subjective requirement, to be evaluated by
the approving teams.
- As an exception to this, if the target's primary purpose is to build components for a Free and Open Source Software (FOSS) project licensed under "copyleft" terms (terms which require licensing other code under compatible FOSS terms), such as kernel modules or plugins, then the standard libraries for the target may potentially be subject to copyleft terms, as long as such terms are satisfied by Rust's existing practices of providing full corresponding source code. Note that anything added to the Rust repository itself must still use Rust's standard license terms.
- Tier 2 targets must not impose burden on the authors of pull requests, or
other developers in the community, to ensure that tests pass for the target.
In particular, do not post comments (automated or manual) on a PR that derail
or suggest a block on the PR based on tests failing for the target. Do not
send automated messages or notifications (via any medium, including via
@
) to a PR author or others involved with a PR regarding the PR breaking tests on a tier 2 target, unless they have opted into such messages.- Backlinks such as those generated by the issue/PR tracker when linking to an issue or PR are not considered a violation of this policy, within reason. However, such messages (even on a separate repository) must not generate notifications to anyone involved with a PR who has not requested such notifications.
- The target maintainers should regularly run the testsuite for the target, and should fix any test failures in a reasonably timely fashion.
- All requirements for tier 3 apply.
A tier 2 target may be demoted or removed if it no longer meets these requirements. Any proposal for demotion or removal will be CCed to the target maintainers, and will be communicated widely to the Rust community before being dropped from a stable release. (The amount of time between such communication and the next stable release may depend on the nature and severity of the failed requirement, the timing of its discovery, whether the target has been part of a stable release yet, and whether the demotion or removal can be a planned and scheduled action.)
In some circumstances, especially if the target maintainers do not respond in a
timely fashion, Rust teams may land pull requests that temporarily disable some
targets in the nightly compiler, in order to implement a feature not yet
supported by those targets. (As an example, this happened when introducing the
128-bit types u128
and i128
.) Such a pull request will include notification
and coordination with the maintainers of such targets, and will ideally happen
towards the beginning of a new development cycle to give maintainers time to
update their targets. The maintainers of such targets will then be expected to
implement the corresponding target-specific support in order to re-enable the
target. If the maintainers of such targets cannot provide such support in time
for the next stable release, this may result in demoting or removing the
targets.
Tier 2 with host tools
Some tier 2 targets may additionally have binaries built to run on them as a
host (such as rustc
and cargo
). This allows the target to be used as a
development platform, not just a compilation target.
A proposed new tier 2 target with host tools must be reviewed and approved by the compiler team based on these requirements. Such review and approval may occur via a Major Change Proposal (MCP).
In addition, the infrastructure team must approve the integration of the target's host tools into Continuous Integration (CI), and the CI-related requirements for host tools. This review and approval may take place in a PR adding the target's host tools to CI, or simply by an infrastructure team member reporting the outcome of a team discussion.
- Depending on the target, its capabilities, its performance, and the
likelihood of use for any given tool, the host tools provided for a tier 2
target may include only
rustc
andcargo
, or may include additional tools such asclippy
andrustfmt
. - Approval of host tools will take into account the additional time required to build the host tools, and the substantial additional storage required for the host tools.
- The host tools must have direct value to people other than the target's
maintainers. (It may still be a niche target, but the host tools must not be
exclusively useful for an inherently closed group.) This requirement will be
evaluated independently from the corresponding tier 2 requirement.
- The requirement to provide "direct value" means that it does not suffice to argue that having host tools will help the target's maintainers more easily provide the target to others. The tools themselves must provide value to others.
- There must be a reasonable expectation that the host tools will be used, for purposes other than to prove that they can be used.
- The host tools must build and run reliably in CI (for all components that Rust's CI considers mandatory), though they may or may not pass tests.
- Building host tools for the target must not take substantially longer than building host tools for other targets, and should not substantially raise the maintenance burden of the CI infrastructure.
- The host tools must provide a substantively similar experience as on other
targets, subject to reasonable target limitations.
- Adding a substantively different interface to an existing tool, or a
target-specific interface to the functionality of an existing tool,
requires design and implementation approval (e.g. RFC/MCP) from the
appropriate approving teams for that tool.
- Such an interface should have a design that could potentially work for other targets with similar properties.
- This should happen separately from the review and approval of the target, to simplify the target review and approval processes, and to simplify the review and approval processes for the proposed new interface.
- By way of example, a target that runs within a sandbox may need to modify the handling of files, tool invocation, and similar to meet the expectations and conventions of the sandbox, but must not introduce a separate "sandboxed compilation" interface separate from the CLI interface without going through the normal approval process for such an interface. Such an interface should take into account potential other targets with similar sandboxes.
- Adding a substantively different interface to an existing tool, or a
target-specific interface to the functionality of an existing tool,
requires design and implementation approval (e.g. RFC/MCP) from the
appropriate approving teams for that tool.
- If the host tools for the platform would normally be expected to be signed or
equivalent (e.g. if running unsigned binaries or similar involves a
"developer mode" or an additional prompt), it must be possible for the Rust
project's automated builds to apply the appropriate signature process,
without any manual intervention by either Rust developers, target
maintainers, or a third party. This process must meet the approval of the
infrastructure team.
- This process may require one-time or semi-regular manual steps by the infrastructure team, such as registration or renewal of a signing key. Any such manual process must meet the approval of the infrastructure team.
- This process may require the execution of a legal agreement with the signature provider. Such a legal agreement may be revocable, and may potentially require a nominal fee, but must not be otherwise onerous. Any such legal agreement must meet the approval of the infrastructure team. (The infrastructure team is not expected or required to sign binding legal agreements on behalf of the Rust project; this review and approval exists to ensure no terms are onerous or cause problems for infrastructure, especially if such terms may impose requirements or obligations on people who have access to target-specific infrastructure.)
- Changes to this process, or to any legal agreements involved, may cause a target to stop meeting this requirement.
- This process involved must be available under substantially similar non-onerous terms to the general public. Making it available exclusively to the Rust project does not suffice.
- This requirement exists to ensure that Rust builds, including nightly builds, can meet the necessary requirements to allow users to smoothly run the host tools.
- Providing host tools does not exempt a target from requirements to support cross-compilation if at all possible.
- All requirements for tier 2 apply.
A target may be promoted directly from tier 3 to tier 2 with host tools if it meets all the necessary requirements, but doing so may introduce substantial additional complexity. If in doubt, the target should qualify for tier 2 without host tools first.
Tier 1 target policy
At this tier, the Rust project guarantees that a target builds and passes all tests, and will reject patches that fail to build or pass the testsuite on a target. We hold tier 1 targets to our highest standard of requirements.
A proposed new tier 1 target must be reviewed and approved by the compiler team based on these requirements. In addition, the release team must approve the viability and value of supporting the target. For a tier 1 target, this will typically take place via a full RFC proposing the target, to be jointly reviewed and approved by the compiler team and release team.
In addition, the infrastructure team must approve the integration of the target into Continuous Integration (CI), and the tier 1 CI-related requirements. This review and approval may take place in a PR adding the target to CI, by an infrastructure team member reporting the outcome of a team discussion, or by including the infrastructure team in the RFC proposing the target.
- Tier 1 targets must have substantial, widespread interest within the developer community, and must serve the ongoing needs of multiple production users of Rust across multiple organizations or projects. These requirements are subjective, and determined by consensus of the approving teams. A tier 1 target may be demoted or removed if it becomes obsolete or no longer meets this requirement.
- The target maintainer team must include at least 3 developers.
- The target must build and pass tests reliably in CI, for all components that
Rust's CI considers mandatory.
- The target must not disable an excessive number of tests or pieces of tests in the testsuite in order to do so. This is a subjective requirement.
- If the target does not have host tools support, or if the target has low performance, the infrastructure team may choose to have CI cross-compile the testsuite from another platform, and then run the compiled tests either natively or via accurate emulation. However, the approving teams may take such performance considerations into account when determining the viability of the target or of its host tools.
- The target must provide as much of the Rust standard library as is feasible
and appropriate to provide. For instance, if the target can support dynamic
memory allocation, it must provide an implementation of
alloc
and the associated data structures. - Building the target and running the testsuite for the target must not take
substantially longer than other targets, and should not substantially raise
the maintenance burden of the CI infrastructure.
- In particular, if building the target takes a reasonable amount of time, but the target cannot run the testsuite in a timely fashion due to low performance of either native code or accurate emulation, that alone may prevent the target from qualifying as tier 1.
- If running the testsuite requires additional infrastructure (such as physical
systems running the target), the target maintainers must arrange to provide
such resources to the Rust project, to the satisfaction and approval of the
Rust infrastructure team.
- Such resources may be provided via cloud systems, via emulation, or via physical hardware.
- If the target requires the use of emulation to meet any of the tier requirements, the approving teams for those requirements must have high confidence in the accuracy of the emulation, such that discrepancies between emulation and native operation that affect test results will constitute a high-priority bug in either the emulation or the implementation of the target.
- If it is not possible to run the target via emulation, these resources must additionally be sufficient for the Rust infrastructure team to make them available for access by Rust team members, for the purposes of development and testing. (Note that the responsibility for doing target-specific development to keep the target well maintained remains with the target maintainers. This requirement ensures that it is possible for other Rust developers to test the target, but does not obligate other Rust developers to make target-specific fixes.)
- Resources provided for CI and similar infrastructure must be available for continuous exclusive use by the Rust project. Resources provided for access by Rust team members for development and testing must be available on an exclusive basis when in use, but need not be available on a continuous basis when not in use.
- Tier 1 targets must not have a hard requirement for signed, verified, or
otherwise "approved" binaries. Developers must be able to build, run, and
test binaries for the target on systems they control, or provide such
binaries for others to run. (Doing so may require enabling some appropriate
"developer mode" on such systems, but must not require the payment of any
additional fee or other consideration, or agreement to any onerous legal
agreements.)
- The Rust project may decide to supply appropriately signed binaries if doing so provides a smoother experience for developers using the target, and a tier 2 target with host tools already requires providing appropriate mechanisms that enable our infrastructure to provide such signed binaries. However, this additional tier 1 requirement ensures that Rust developers can develop and test Rust software for the target (including Rust itself), and that development or testing for the target is not limited.
- All requirements for tier 2 apply.
A tier 1 target may be demoted if it no longer meets these requirements but still meets the requirements for a lower tier. Any proposal for demotion of a tier 1 target requires a full RFC process, with approval by the compiler and release teams. Any such proposal will be communicated widely to the Rust community, both when initially proposed and before being dropped from a stable release. A tier 1 target is highly unlikely to be directly removed without first being demoted to tier 2 or tier 3. (The amount of time between such communication and the next stable release may depend on the nature and severity of the failed requirement, the timing of its discovery, whether the target has been part of a stable release yet, and whether the demotion or removal can be a planned and scheduled action.)
Raising the baseline expectations of a tier 1 target (such as the minimum CPU features or OS version required) requires the approval of the compiler and release teams, and should be widely communicated as well, but does not necessarily require a full RFC.
Tier 1 with host tools
Some tier 1 targets may additionally have binaries built to run on them as a
host (such as rustc
and cargo
). This allows the target to be used as a
development platform, not just a compilation target.
A proposed new tier 1 target with host tools must be reviewed and approved by the compiler team based on these requirements. In addition, the release team must approve the viability and value of supporting host tools for the target. For a tier 1 target, this will typically take place via a full RFC proposing the target, to be jointly reviewed and approved by the compiler team and release team.
In addition, the infrastructure team must approve the integration of the target's host tools into Continuous Integration (CI), and the CI-related requirements for host tools. This review and approval may take place in a PR adding the target's host tools to CI, by an infrastructure team member reporting the outcome of a team discussion, or by including the infrastructure team in the RFC proposing the target.
- Tier 1 targets with host tools should typically include all of the additional
tools such as
clippy
andrustfmt
, unless there is a target-specific reason why a tool cannot possibly make sense for the target.- Unlike with tier 2, for tier 1 we will not exclude specific tools on the sole basis of them being less likely to be used; rather, we'll take that into account when considering whether the target should be at tier 1 with host tools. In general, on any tier 1 target with host tools, people should be able to expect to find and install all the same components that they would for any other tier 1 target with host tools.
- Approval of host tools will take into account the additional time required to build the host tools, and the substantial additional storage required for the host tools.
- Host tools for the target must have substantial, widespread interest within the developer community, and must serve the ongoing needs of multiple production users of Rust across multiple organizations or projects. These requirements are subjective, and determined by consensus of the approving teams. This requirement will be evaluated independently from the corresponding tier 1 requirement; it is possible for a target to have sufficient interest for cross-compilation, but not have sufficient interest for native compilation. The host tools may be dropped if they no longer meet this requirement, even if the target otherwise qualifies as tier 1.
- The host tools must build, run, and pass tests reliably in CI, for all
components that Rust's CI considers mandatory.
- The target must not disable an excessive number of tests or pieces of tests in the testsuite in order to do so. This is a subjective requirement.
- Building the host tools and running the testsuite for the host tools must not
take substantially longer than other targets, and should not substantially raise
the maintenance burden of the CI infrastructure.
- In particular, if building the target's host tools takes a reasonable amount of time, but the target cannot run the testsuite in a timely fashion due to low performance of either native code or accurate emulation, that alone may prevent the target from qualifying as tier 1 with host tools.
- Providing host tools does not exempt a target from requirements to support cross-compilation if at all possible.
- All requirements for tier 2 targets with host tools apply.
- All requirements for tier 1 apply.
A target seeking promotion to tier 1 with host tools should typically either be tier 2 with host tools or tier 1 without host tools, to reduce the number of requirements to simultaneously review and approve.
In addition to the general process for demoting a tier 1 target, a tier 1 target with host tools may be demoted (including having its host tools dropped, or being demoted to tier 2 with host tools) if it no longer meets these requirements but still meets the requirements for a lower tier. Any proposal for demotion of a tier 1 target (with or without host tools) requires a full RFC process, with approval by the compiler and release teams. Any such proposal will be communicated widely to the Rust community, both when initially proposed and before being dropped from a stable release.
target-name-here
Tier: 3
One-sentence description of the target (e.g. CPU, OS)
Target maintainers
- Some Person,
email@example.org
, https://github.com/...
Requirements
Does the target support host tools, or only cross-compilation? Does the target support std, or alloc (either with a default allocator, or if the user supplies an allocator)?
Document the expectations of binaries built for the target. Do they assume specific minimum features beyond the baseline of the CPU/environment/etc? What version of the OS or environment do they expect?
Are there notable #[target_feature(...)]
or -C target-feature=
values that
programs may wish to use?
What calling convention does extern "C"
use on the target?
What format do binaries use by default? ELF, PE, something else?
Building the target
If Rust doesn't build the target by default, how can users build it? Can users
just add it to the target
list in config.toml
?
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for
this target, you will either need to build Rust with the target enabled (see
"Building the target" above), or build your own copy of core
by using
build-std
or similar.
Testing
Does the target support running binaries, or do binaries have varying expectations that prevent having a standard way to run them? If users can run binaries, can they do so in some common emulator, or do they need native hardware? Does the target support running the Rust testsuite?
Cross-compilation toolchains and C code
Does the target support C code? If so, what toolchain target should users use to build compatible C code? (This may match the target triple, or it may be a toolchain for a different target triple, potentially with specific options or caveats.)
aarch64-apple-ios-sim
Tier: 2
Apple iOS Simulator on ARM64.
Designated Developers
Requirements
This target is cross-compiled. To build this target Xcode 12 or higher on macOS is required.
Building
The target can be built by enabling it for a rustc
build:
[build]
build-stage = 1
target = ["aarch64-apple-ios-sim"]
Cross-compilation
This target can be cross-compiled from x86_64
or aarch64
macOS hosts.
Other hosts are not supported for cross-compilation, but might work when also providing the required Xcode SDK.
Testing
Currently there is no support to run the rustc test suite for this target.
Building Rust programs
Note: Building for this target requires the corresponding iOS SDK, as provided by Xcode 12+.
From Rust Nightly 1.56.0 (2021-08-03) on the artifacts are shipped pre-compiled:
rustup target add aarch64-apple-ios-sim --toolchain nightly
Rust programs can be built for that target:
rustc --target aarch64-apple-ios-sim your-code.rs
There is no easy way to run simple programs in the iOS simulator. Static library builds can be embedded into iOS applications.
*-apple-watchos
- arm64_32-apple-watchos
- armv7k-apple-watchos
- aarch64-apple-watchos-sim
- x86_64-apple-watchos-sim
Tier: 3
Apple WatchOS targets:
- Apple WatchOS on Arm 64_32
- Apple WatchOS on Arm v7k
- Apple WatchOS Simulator on arm64
- Apple WatchOS Simulator on x86_64
Target maintainers
Requirements
These targets are cross-compiled. To build these targets Xcode 12 or higher on macOS is required.
Building the target
The targets can be built by enabling them for a rustc
build, for example:
[build]
build-stage = 1
target = ["aarch64-apple-watchos-sim"]
Building Rust programs
Note: Building for this target requires the corresponding WatchOS SDK, as provided by Xcode 12+.
Rust programs can be built for these targets, if rustc
has been built with support for them, for example:
rustc --target aarch64-apple-watchos-sim your-code.rs
Testing
There is no support for running the Rust testsuite on WatchOS or the simulators.
There is no easy way to run simple programs on WatchOS or the WatchOS simulators. Static library builds can be embedded into WatchOS applications.
Cross-compilation toolchains and C code
This target can be cross-compiled from x86_64 or aarch64 macOS hosts.
Other hosts are not supported for cross-compilation, but might work when also providing the required Xcode SDK.
aarch64-nintendo-switch-freestanding
Tier: 3
Nintendo Switch with pure-Rust toolchain.
Designated Developers
Requirements
This target is cross-compiled. It has no special requirements for the host.
Building
The target can be built by enabling it for a rustc
build:
[build]
build-stage = 1
target = ["aarch64-nintendo-switch-freestanding"]
Cross-compilation
This target can be cross-compiled from any host.
Testing
Currently there is no support to run the rustc test suite for this target.
Building Rust programs
If rustc
has support for that target and the library artifacts are available,
then Rust programs can be built for that target:
rustc --target aarch64-nintendo-switch-freestanding your-code.rs
To generate binaries in the NRO format that can be easily run on-device, you can use cargo-nx:
cargo nx --triple=aarch64-nintendo-switch-freestanding
armeb-unknown-linux-gnueabi
Tier: 3
Target for cross-compiling Linux user-mode applications targeting the ARM BE8 architecture.
Overview
BE8 architecture retains the same little-endian ordered code-stream used by conventional little endian ARM systems, however the data accesses are in big-endian. BE8 is used primarily in high-performance networking applications where the ability to read packets in their native "Network Byte Order" is important (many network protocols transmit data in big-endian byte order for their wire formats).
History
BE8 architecture is the default big-endian architecture for ARM since ARMv6. It's predecessor, used for ARMv4 and ARMv5 devices was BE32. On ARMv6 architecture, endianness can be configured via system registers. However, BE32 was withdrawn for ARMv7 onwards.
Target Maintainers
Requirements
The target is cross-compiled. This target supports std
in the normal way (indeed only nominal changes are required from the standard ARM configuration).
Target definition
The target definition can be seen here. In particular, it should be noted that the features
specify that this target is built for the ARMv8 core. Though this can likely be modified as required.
Building the target
Because it is Tier 3, rust does not yet ship pre-compiled artifacts for this target.
Therefore, you can build Rust with support for the target by adding it to the target list in config.toml, a sample configuration is shown below. It is expected that the user already have a working GNU compiler toolchain and update the paths accordingly.
[llvm]
download-ci-llvm = false
skip-rebuild = true
optimize = true
ninja = true
targets = "ARM;X86"
clang = false
[build]
target = ["x86_64-unknown-linux-gnu", "armeb-unknown-linux-gnueabi"]
docs = false
docs-minification = false
compiler-docs = false
[install]
prefix = "/home/user/x-tools/rust/"
[rust]
debug-logging=true
backtrace = true
incremental = true
[target.x86_64-unknown-linux-gnu]
[dist]
[target.armeb-unknown-linux-gnueabi]
cc = "/home/user/x-tools/armeb-unknown-linux-gnueabi/bin/armeb-unknown-linux-gnueabi-gcc"
cxx = "/home/user/x-tools/armeb-unknown-linux-gnueabi/bin/armeb-unknown-linux-gnueabi-g++"
ar = "/home/user/x-tools/armeb-unknown-linux-gnueabi/bin/armeb-unknown-linux-gnueabi-ar"
ranlib = "/home/user/x-tools/armeb-unknown-linux-gnueabi/bin/armeb-unknown-linux-gnueabi-ranlib"
linker = "/home/user/x-tools/armeb-unknown-linux-gnueabi/bin/armeb-unknown-linux-gnueabi-gcc"
llvm-config = "/home/user/x-tools/clang/bin/llvm-config"
llvm-filecheck = "/home/user/x-tools/clang/bin/FileCheck"
Building Rust programs
The following .cargo/config
is needed inside any project directory to build for the BE8 target:
[build]
target = "armeb-unknown-linux-gnueabi"
[target.armeb-unknown-linux-gnueabi]
linker = "armeb-unknown-linux-gnueabi-gcc"
Note that it is expected that the user has a suitable linker from the GNU toolchain.
armv4t-none-eabi
Tier 3
Bare-metal target for any cpu in the ARMv4T architecture family, supporting
ARM/Thumb code interworking (aka a32
/t32
), with ARM code as the default code
generation.
In particular this supports the Gameboy Advance (GBA), but there's nothing GBA specific with this target, so any ARMv4T device should work fine.
Target Maintainers
Requirements
The target is cross-compiled, and uses static linking.
The linker that comes with rustc cannot link for this platform (the platform is
too old). You will need the arm-none-eabi-ld
linker from a GNU Binutils
targeting ARM. This can be obtained for Windows/Mac/Linux from the ARM
Developer Website, or possibly from your OS's package manager.
This target doesn't provide a linker script, you'll need to bring your own
according to the specific device you want to target. Pass
-Clink-arg=-Tyour_script.ld
as a rustc argument to make the linker use
your_script.ld
during linking.
Building Rust Programs
Because it is Tier 3, rust does not yet ship pre-compiled artifacts for this target.
Just use the build-std
nightly cargo feature to build the core
library. You
can pass this as a command line argument to cargo, or your .cargo/config.toml
file might include the following lines:
[unstable]
build-std = ["core"]
Most of core
should work as expected, with the following notes:
- the target is "soft float", so
f32
andf64
operations are emulated in software. - integer division is also emulated in software.
- the target is old enough that it doesn't have atomic instructions.
Rust programs are output as ELF files.
For running on hardware, you'll generally need to extract the "raw" program code
out of the ELF and into a file of its own. The objcopy
program provided as
part of the GNU Binutils can do this:
arm-none-eabi-objcopy --output-target binary [in_file] [out_file]
Testing
This is a cross-compiled target that you will need to emulate during testing.
Because this is a device-agnostic target, and the exact emulator that you'll need depends on the specific device you want to run your code on.
For example, when programming for the Gameboy Advance, the
mgba-test-runner program could be used to make a
normal set of rust tests be run within the mgba
emulator.
armv5te-none-eabi
Tier: 3
Bare-metal target for any cpu in the ARMv5TE architecture family, supporting
ARM/Thumb code interworking (aka a32
/t32
), with a32
code as the default code
generation.
The thumbv5te-none-eabi
target is the same as this one, but the instruction set defaults to t32
.
Target Maintainers
Requirements
The target is cross-compiled, and uses static linking.
By default, the lld
linker included with Rust will be used.
However, you may want to use the arm-none-eabi-ld
linker instead. This can be obtained for Windows/Mac/Linux from the ARM
Developer Website, or possibly from your OS's package manager. To use it, add the following to your .cargo/config.toml
:
[target.armv5te-none-eabi]
linker = "arm-none-eabi-ld"
This target doesn't provide a linker script, you'll need to bring your own
according to the specific device you want to target. Pass
-Clink-arg=-Tyour_script.ld
as a rustc argument to make the linker use
your_script.ld
during linking.
Building Rust Programs
Because it is Tier 3, rust does not yet ship pre-compiled artifacts for this target.
Just use the build-std
nightly cargo feature to build the core
library. You
can pass this as a command line argument to cargo, or your .cargo/config.toml
file might include the following lines:
[unstable]
build-std = ["core"]
Most of core
should work as expected, with the following notes:
- the target is "soft float", so
f32
andf64
operations are emulated in software. - integer division is also emulated in software.
- the target is old enough that it doesn't have atomic instructions.
alloc
is also supported, as long as you provide your own global allocator.
Rust programs are output as ELF files.
Testing
This is a cross-compiled target that you will need to emulate during testing.
Because this is a device-agnostic target, and the exact emulator that you'll need depends on the specific device you want to run your code on.
For example, when programming for the DS, you can use one of the several available DS emulators, such as melonDS.
armv6k-nintendo-3ds
Tier: 3
The Nintendo 3DS platform, which has an ARMv6K processor, and its associated
operating system (horizon
).
Rust support for this target is not affiliated with Nintendo, and is not derived from nor used with any official Nintendo SDK.
Target maintainers
Requirements
This target is cross-compiled. Dynamic linking is not supported.
#![no_std]
crates can be built using build-std
to build core
and optionally
alloc
, and either panic_abort
or panic_unwind
.
std
is partially supported, but mostly works. Some APIs are unimplemented
and will simply return an error, such as std::process
. An allocator is provided
by default.
In order to support some APIs, binaries must be linked against libc
written
for the target, using a linker for the target. These are provided by the
devkitARM toolchain. See
Cross-compilation toolchains and C code
for more details.
Additionally, some helper crates provide implementations of some libc
functions
use by std
that may otherwise be missing. These, or an alternate implementation
of the relevant functions, are required to use std
:
pthread-3ds
provides pthread APIs forstd::thread
.linker-fix-3ds
fulfills some other missing libc APIs.
Binaries built for this target should be compatible with all variants of the 3DS (and 2DS) hardware and firmware, but testing is limited and some versions may not work correctly.
This target generates binaries in the ELF format.
Building the target
You can build Rust with support for the target by adding it to the target
list in config.toml
and providing paths to the devkitARM toolchain.
[build]
build-stage = 1
target = ["armv6k-nintendo-3ds"]
[target.armv6k-nintendo-3ds]
cc = "/opt/devkitpro/devkitARM/bin/arm-none-eabi-gcc"
cxx = "/opt/devkitpro/devkitARM/bin/arm-none-eabi-g++"
ar = "/opt/devkitpro/devkitARM/bin/arm-none-eabi-ar"
ranlib = "/opt/devkitpro/devkitARM/bin/arm-none-eabi-ranlib"
linker = "/opt/devkitpro/devkitARM/bin/arm-none-eabi-gcc"
Also, to build compiler_builtins
for the target, export these flags before
building the Rust toolchain:
export CFLAGS_armv6k_nintendo_3ds="-mfloat-abi=hard -mtune=mpcore -mtp=soft -march=armv6k"
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target.
The recommended way to build binaries is by using the
cargo-3ds tool, which uses build-std
and provides commands that work like the usual cargo run
, cargo build
, etc.
You can also build Rust with the target enabled (see Building the target above).
As mentioned in Requirements, programs that use std
must link
against both the devkitARM toolchain and libraries providing the libc
APIs used
in std
. There is a general-purpose utility crate for working with nonstandard
APIs provided by the OS: ctru-rs
.
Add it to Cargo.toml to use it in your program:
[dependencies]
ctru-rs = { git = "https://github.com/Meziu/ctru-rs.git" }
Using this library's init()
function ensures the symbols needed to link
against std
are present (as mentioned in Requirements
above), as well as providing a runtime suitable for std
:
fn main() {
ctru::init();
}
Testing
Binaries built for this target can be run in an emulator (most commonly
Citra), or sent to a device through
the use of a tool like devkitARM's 3dslink
. They may also simply be copied
to an SD card to be inserted in the device.
The cargo-3ds
tool mentioned in Building Rust programs
supports the use of 3dslink
with cargo 3ds run
. The default Rust test runner
is not supported, but
custom test frameworks
can be used with cargo 3ds test
to run unit tests on a device.
The Rust test suite for library/std
is not yet supported.
Cross-compilation toolchains and C code
C code can be built for this target using the
devkitARM toolchain.
This toolchain provides arm-none-eabi-gcc
as the linker used to link Rust
programs as well.
The toolchain also provides a libc
implementation, which is required by std
for many of its APIs, and a helper library libctru
which is used by several
of the helper crates listed in Requirements.
This toolchain does not, however, include all of the APIs expected by std
,
and the remaining APIs are implemented by pthread-3ds
and linker-fix-3ds
.
armv7-unknown-linux-uclibceabi
Tier: 3
This target supports ARMv7 softfloat CPUs and uses the uclibc-ng standard library. This is a common configuration on many consumer routers (e.g., Netgear R7000, Asus RT-AC68U).
Target maintainers
Requirements
This target is cross compiled, and requires a cross toolchain.
This target supports host tools and std.
Building the target
You will need to download or build a 'C'
cross toolchain that targets ARMv7 softfloat and that uses the uclibc-ng standard library. If your target hardware is something like a router or an embedded device, keep in mind that manufacturer supplied SDKs for this class of CPU could be outdated and potentially unsuitable for bootstrapping rust.
Here is a sample toolchain that is built using buildroot. It uses modern toolchain components, older thus universal kernel headers (2.6.36.4), and is used for a project called Tomatoware. This toolchain is patched so that its sysroot is located at /mmc (e.g., /mmc/bin, /mmc/lib, /mmc/include). This is useful in scenarios where the root filesystem is read-only but you are able attach external storage loaded with user applications. Tomatoware is an example of this that even allows you to run various compilers and developer tools natively on the target device.
Utilizing the Tomatoware toolchain this target can be built for cross compilation and native compilation (host tools) with project
rust-bootstrap-armv7-unknown-linux-uclibceabi.
Here is a sample config if using your own toolchain.
[build]
build-stage = 2
target = ["armv7-unknown-linux-uclibceabi"]
[target.armv7-unknown-linux-uclibceabi]
cc = "/path/to/arm-unknown-linux-uclibcgnueabi-gcc"
cxx = "/path/to/arm-unknown-linux-uclibcgnueabi-g++"
ar = "path/to/arm-unknown-linux-uclibcgnueabi-ar"
ranlib = "path/to/arm-unknown-linux-uclibcgnueabi-ranlib"
linker = "/path/to/arm-unknown-linux-uclibcgnueabi-gcc"
Building Rust programs
The following assumes you are using the Tomatoware toolchain and environment. Adapt if you are using your own toolchain.
Native compilation
Since this target supports host tools, you can natively build rust applications directly on your target device. This can be convenient because it removes the complexities of cross compiling and you can immediately test and deploy your binaries. One downside is that compiling on your ARMv7 CPU will probably be much slower than cross compilation on your x86 machine.
To setup native compilation:
- Download Tomatoware to your device using the latest nightly release found here.
- Extract
tar zxvf arm-soft-mmc.tgz -C /mmc
- Add
/mmc/bin:/mmc:sbin/
to your PATH, orsource /mmc/etc/profile
apt update && apt install rust
If you bootstrap rust on your own using the project above, it will create a .deb file that you then can install with
dpkg -i rust_1.xx.x-x_arm.deb
After completing these steps you can use rust normally in a native environment.
Cross Compilation
To cross compile, you'll need to:
-
Build the rust cross toochain using rust-bootstrap-armv7-unknown-linux-uclibceabi or your own built toolchain.
-
Link your built toolchain with
rustup toolchain link stage2 \ ${HOME}/rust-bootstrap-armv7-unknown-linux-uclibceabi/src/rust/rust/build/x86_64-unknown-linux-gnu/stage2
-
Build with:
CC_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-gcc \ CXX_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-g++ \ AR_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-ar \ CFLAGS_armv7_unknown_linux_uclibceabi="-march=armv7-a -mtune=cortex-a9" \ CXXFLAGS_armv7_unknown_linux_uclibceabi="-march=armv7-a -mtune=cortex-a9" \ CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABI_LINKER=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-gcc \ CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABI_RUSTFLAGS='-Clink-arg=-s -Clink-arg=-Wl,--dynamic-linker=/mmc/lib/ld-uClibc.so.1 -Clink-arg=-Wl,-rpath,/mmc/lib' \ cargo +stage2 \ build \ --target armv7-unknown-linux-uclibceabi \ --release
-
Copy the binary to your target device and run.
We specify CC
, CXX
, AR
, CFLAGS
, and CXXFLAGS
environment variables because sometimes a project or a subproject requires the use of your 'C'
cross toolchain. Since Tomatoware has a modified sysroot we also pass via RUSTFLAGS the location of the dynamic-linker and rpath.
Test with QEMU
To test a cross-compiled binary on your build system follow the instructions for Cross Compilation
, install qemu-arm-static
, and run with the following.
CC_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-gcc \
CXX_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-g++ \
AR_armv7_unknown_linux_uclibceabi=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-ar \
CFLAGS_armv7_unknown_linux_uclibceabi="-march=armv7-a -mtune=cortex-a9" \
CXXFLAGS_armv7_unknown_linux_uclibceabi="-march=armv7-a -mtune=cortex-a9" \
CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABI_LINKER=/opt/tomatoware/arm-soft-mmc/bin/arm-linux-gcc \
CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABI_RUNNER="qemu-arm-static -L /opt/tomatoware/arm-soft-mmc/arm-tomatoware-linux-uclibcgnueabi/sysroot/" \
cargo +stage2 \
run \
--target armv7-unknown-linux-uclibceabi \
--release
Run in a chroot
It's also possible to build in a chroot environment. This is a convenient way to work without needing to access the target hardware.
To build the chroot:
sudo debootstrap --arch armel bullseye $HOME/debian
sudo chroot $HOME/debian/ /bin/bash
mount proc /proc -t proc
mount -t sysfs /sys sys/
export PATH=/mmc/bin:/mmc/sbin:$PATH
From here you can setup your environment (e.g., add user, install wget).
- Download Tomatoware to the chroot environment using the latest nightly release found here.
- Extract
tar zxvf arm-soft-mmc.tgz -C /mmc
- Add
/mmc/bin:/mmc:sbin/
to your PATH, orsource /mmc/etc/profile
sudo /mmc/bin/apt update && sudo /mmc/bin/apt install rust
After completing these steps you can use rust normally in a chroot environment.
Remember when using sudo
the root user's PATH could differ from your user's PATH.
armv7-unknown-linux-uclibceabihf
Tier: 3
This tier supports the ARMv7 processor running a Linux kernel and uClibc-ng standard library. It provides full support for rust and the rust standard library.
Designated Developers
Requirements
This target is cross compiled, and requires a cross toolchain. You can find suitable pre-built toolchains at bootlin or build one yourself via buildroot.
Building
Get a C toolchain
Compiling rust for this target has been tested on x86_64
linux hosts. Other host types have not been tested, but may work, if you can find a suitable cross compilation toolchain for them.
If you don't already have a suitable toolchain, download one here, and unpack it into a directory.
Configure rust
The target can be built by enabling it for a rustc
build, by placing the following in config.toml
:
[build]
target = ["armv7-unknown-linux-uclibceabihf"]
stage = 2
[target.armv7-unknown-linux-uclibceabihf]
# ADJUST THIS PATH TO POINT AT YOUR TOOLCHAIN
cc = "/TOOLCHAIN_PATH/bin/arm-buildroot-linux-uclibcgnueabihf-gcc"
Build
# in rust dir
./x.py build --stage 2
Building and Running Rust Programs
To test cross-compiled binaries on a x86_64
system, you can use the qemu-arm
userspace emulation program. This avoids having a full emulated ARM system by doing dynamic binary translation and dynamic system call translation. It lets you run ARM programs directly on your x86_64
kernel. It's very convenient!
To use:
- Install
qemu-arm
according to your distro. - Link your built toolchain via:
rustup toolchain link stage2 ${RUST}/build/x86_64-unknown-linux-gnu/stage2
- Create a test program
cargo new hello_world
cd hello_world
- Build and run
CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABIHF_RUNNER="qemu-arm -L ${TOOLCHAIN}/arm-buildroot-linux-uclibcgnueabihf/sysroot/" \
CARGO_TARGET_ARMV7_UNKNOWN_LINUX_UCLIBCEABIHF_LINKER=${TOOLCHAIN}/bin/arm-buildroot-linux-uclibcgnueabihf-gcc \
cargo +stage2 run --target armv7-unknown-linux-uclibceabihf
*-linux-android and *-linux-androideabi
Tier: 2
Android is a mobile operating system built on top of the Linux kernel.
Target maintainers
- Chris Wailes (@chriswailes)
- Matthew Maurer (@maurer)
- Martin Geisler (@mgeisler)
Requirements
This target is cross-compiled from a host environment. Development may be done from the source tree or using the Android NDK.
Android targets support std. Generated binaries use the ELF file format.
NDK/API Update Policy
Rust will support the most recent Long Term Support (LTS) Android Native Development Kit (NDK). By default Rust will support all API levels supported by the NDK, but a higher minimum API level may be required if deemed necessary.
Building the target
To build Rust binaries for Android you'll need a copy of the most recent LTS edition of the Android NDK. Supported Android targets are:
- aarch64-linux-android
- arm-linux-androideabi
- armv7-linux-androideabi
- i686-linux-android
- thumbv7neon-linux-androideabi
- x86_64-linux-android
A list of all supported targets can be found here
aarch64-fuchsia
and x86_64-fuchsia
Tier: 2
Fuchsia is a modern open source operating system that's simple, secure, updatable, and performant.
Target maintainers
The Fuchsia team:
- Tyler Mandry (@tmandry)
- Dan Johnson (@computerdruid)
- David Koloski (@djkoloski)
- Andrew Pollack (@andrewpollack)
- Joseph Ryan (@P1n3appl3)
As the team evolves over time, the specific members listed here may differ from
the members reported by the API. The API should be considered to be
authoritative if this occurs. Instead of pinging individual members, use
@rustbot ping fuchsia
to contact the team on GitHub.
Table of contents
- Requirements
- Walkthrough structure
- Compiling a Rust binary targeting Fuchsia
- Creating a Fuchsia package
- Publishing a Fuchsia package
- Running a Fuchsia component on an emulator
.gitignore
extensions- Testing
- Debugging
Requirements
This target is cross-compiled from a host environment. You will need a recent copy of the Fuchsia SDK, which provides the tools, libraries, and binaries required to build and link programs for Fuchsia.
Development may also be done from the source tree.
Fuchsia targets support std
and follow the sysv64
calling convention on
x86_64. Fuchsia binaries use the ELF file format.
Walkthrough structure
This walkthrough will cover:
- Compiling a Rust binary targeting Fuchsia.
- Building a Fuchsia package.
- Publishing and running a Fuchsia package to a Fuchsia emulator.
For the purposes of this walkthrough, we will only target x86_64-fuchsia
.
Compiling a Rust binary targeting Fuchsia
Today, there are two main ways to build a Rust binary targeting Fuchsia using the Fuchsia SDK:
- Allow rustup to handle the installation of Fuchsia targets for you.
- Build a toolchain locally that can target Fuchsia.
Targeting Fuchsia with rustup and cargo
The easiest way to build a Rust binary targeting Fuchsia is by allowing rustup to handle the installation of Fuchsia targets for you. This can be done by issuing the following commands:
rustup target add x86_64-fuchsia
rustup target add aarch64-fuchsia
After installing our Fuchsia targets, we can now compile a Rust binary that targets Fuchsia.
To create our Rust project, we can issue a standard cargo
command as follows:
From base working directory
cargo new hello_fuchsia
The rest of this walkthrough will take place from hello_fuchsia
, so we can
change into that directory now:
cd hello_fuchsia
Note: From this point onwards, all commands will be issued from the hello_fuchsia/
directory, and all hello_fuchsia/
prefixes will be removed from references for sake of brevity.
We can edit our src/main.rs
to include a test as follows:
src/main.rs
fn main() { println!("Hello Fuchsia!"); } #[test] fn it_works() { assert_eq!(2 + 2, 4); }
In addition to the standard workspace created, we will want to create a
.cargo/config.toml
file to link necessary libraries
during compilation:
.cargo/config.toml
[target.x86_64-fuchsia]
rustflags = [
"-Lnative=<SDK_PATH>/arch/x64/lib",
"-Lnative=<SDK_PATH>/arch/x64/sysroot/lib"
]
Note: Make sure to fill out <SDK_PATH>
with the path to the downloaded Fuchsia SDK.
These options configure the following:
-Lnative=${SDK_PATH}/arch/${ARCH}/lib
: Link against Fuchsia libraries from the SDK-Lnative=${SDK_PATH}/arch/${ARCH}/sysroot/lib
: Link against Fuchsia sysroot libraries from the SDK
In total, our new project will look like:
Current directory structure
hello_fuchsia/
┣━ src/
┃ ┗━ main.rs
┣━ Cargo.toml
┗━ .cargo/
┗━ config.toml
Finally, we can build our rust binary as:
cargo build --target x86_64-fuchsia
Now we have a Rust binary at target/x86_64-fuchsia/debug/hello_fuchsia
,
targeting our desired Fuchsia target.
Current directory structure
hello_fuchsia/
┣━ src/
┃ ┗━ main.rs
┣━ target/
┃ ┗━ x86_64-fuchsia/
┃ ┗━ debug/
┃ ┗━ hello_fuchsia
┣━ Cargo.toml
┗━ .cargo/
┗━ config.toml
Targeting Fuchsia with a compiler built from source
An alternative to the first workflow is to target Fuchsia by using
rustc
built from source.
Before building Rust for Fuchsia, you'll need a clang toolchain that supports Fuchsia as well. A recent version (14+) of clang should be sufficient to compile Rust for Fuchsia.
x86-64 and AArch64 Fuchsia targets can be enabled using the following configuration.
In config.toml
, add:
[build]
target = ["<host_platform>", "aarch64-fuchsia", "x86_64-fuchsia"]
Additionally, the following environment variables must be configured (for
example, using a script like config-env.sh
):
# Configure this environment variable to be the path to the downloaded SDK
export SDK_PATH="<SDK path goes here>"
export CFLAGS_aarch64_fuchsia="--target=aarch64-fuchsia --sysroot=${SDK_PATH}/arch/arm64/sysroot -I${SDK_PATH}/pkg/fdio/include"
export CXXFLAGS_aarch64_fuchsia="--target=aarch64-fuchsia --sysroot=${SDK_PATH}/arch/arm64/sysroot -I${SDK_PATH}/pkg/fdio/include"
export LDFLAGS_aarch64_fuchsia="--target=aarch64-fuchsia --sysroot=${SDK_PATH}/arch/arm64/sysroot -L${SDK_PATH}/arch/arm64/lib"
export CARGO_TARGET_AARCH64_FUCHSIA_RUSTFLAGS="-C link-arg=--sysroot=${SDK_PATH}/arch/arm64/sysroot -Lnative=${SDK_PATH}/arch/arm64/sysroot/lib -Lnative=${SDK_PATH}/arch/arm64/lib"
export CFLAGS_x86_64_fuchsia="--target=x86_64-fuchsia --sysroot=${SDK_PATH}/arch/x64/sysroot -I${SDK_PATH}/pkg/fdio/include"
export CXXFLAGS_x86_64_fuchsia="--target=x86_64-fuchsia --sysroot=${SDK_PATH}/arch/x64/sysroot -I${SDK_PATH}/pkg/fdio/include"
export LDFLAGS_x86_64_fuchsia="--target=x86_64-fuchsia --sysroot=${SDK_PATH}/arch/x64/sysroot -L${SDK_PATH}/arch/x64/lib"
export CARGO_TARGET_X86_64_FUCHSIA_RUSTFLAGS="-C link-arg=--sysroot=${SDK_PATH}/arch/x64/sysroot -Lnative=${SDK_PATH}/arch/x64/sysroot/lib -Lnative=${SDK_PATH}/arch/x64/lib"
These can be run together in a shell environment by executing
(source config-env.sh && ./x.py install)
.
Once rustc
is installed, we can create a new working directory to work from,
hello_fuchsia
along with hello_fuchsia/src
:
mkdir hello_fuchsia
cd hello_fuchsia
mkdir src
Note: From this point onwards, all commands will be issued from the hello_fuchsia/
directory, and all hello_fuchsia/
prefixes will be removed from references for sake of brevity.
There, we can create a new file named src/hello_fuchsia.rs
:
src/hello_fuchsia.rs
fn main() { println!("Hello Fuchsia!"); } #[test] fn it_works() { assert_eq!(2 + 2, 4); }
Current directory structure
hello_fuchsia/
┗━ src/
┗━ hello_fuchsia.rs
Using your freshly installed rustc
, you can compile a binary for Fuchsia using
the following options:
--target x86_64-fuchsia
/--target aarch64-fuchsia
: Targets the Fuchsia platform of your choice-Lnative ${SDK_PATH}/arch/${ARCH}/lib
: Link against Fuchsia libraries from the SDK-Lnative ${SDK_PATH}/arch/${ARCH}/sysroot/lib
: Link against Fuchsia sysroot libraries from the SDK
Putting it all together:
# Configure these for the Fuchsia target of your choice
TARGET_ARCH="<x86_64-fuchsia|aarch64-fuchsia>"
ARCH="<x64|aarch64>"
rustc \
--target ${TARGET_ARCH} \
-Lnative=${SDK_PATH}/arch/${ARCH}/lib \
-Lnative=${SDK_PATH}/arch/${ARCH}/sysroot/lib \
--out-dir bin src/hello_fuchsia.rs
Current directory structure
hello_fuchsia/
┣━ src/
┃ ┗━ hello_fuchsia.rs
┗━ bin/
┗━ hello_fuchsia
Creating a Fuchsia package
Before moving on, double check your directory structure:
Current directory structure
hello_fuchsia/
┣━ src/ (if using rustc)
┃ ┗━ hello_fuchsia.rs ...
┣━ bin/ ...
┃ ┗━ hello_fuchsia ...
┣━ src/ (if using cargo)
┃ ┗━ main.rs ...
┗━ target/ ...
┗━ x86_64-fuchsia/ ...
┗━ debug/ ...
┗━ hello_fuchsia ...
With our Rust binary built, we can move to creating a Fuchsia package. On Fuchsia, a package is the unit of distribution for software. We'll need to create a new package directory where we will place files like our finished binary and any data it may need.
To start, make the pkg
, and pkg/meta
directories:
mkdir pkg
mkdir pkg/meta
Current directory structure
hello_fuchsia/
┗━ pkg/
┗━ meta/
Now, create the following files inside:
pkg/meta/package
{
"name": "hello_fuchsia",
"version": "0"
}
The package
file describes our package's name and version number. Every
package must contain one.
pkg/hello_fuchsia.manifest
if using cargo
bin/hello_fuchsia=target/x86_64-fuchsia/debug/hello_fuchsia
lib/ld.so.1=<SDK_PATH>/arch/x64/sysroot/dist/lib/ld.so.1
lib/libfdio.so=<SDK_PATH>/arch/x64/dist/libfdio.so
meta/package=pkg/meta/package
meta/hello_fuchsia.cm=pkg/meta/hello_fuchsia.cm
pkg/hello_fuchsia.manifest
if using rustc
bin/hello_fuchsia=bin/hello_fuchsia
lib/ld.so.1=<SDK_PATH>/arch/x64/sysroot/dist/lib/ld.so.1
lib/libfdio.so=<SDK_PATH>/arch/x64/dist/libfdio.so
meta/package=pkg/meta/package
meta/hello_fuchsia.cm=pkg/meta/hello_fuchsia.cm
Note: Relative manifest paths are resolved starting from the working directory
of pm
. Make sure to fill out <SDK_PATH>
with the path to the downloaded
SDK.
The .manifest
file will be used to describe the contents of the package by
relating their location when installed to their location on the file system. The
bin/hello_fuchsia=
entry will be different depending on how your Rust binary
was built, so choose accordingly.
Current directory structure
hello_fuchsia/
┗━ pkg/
┣━ meta/
┃ ┗━ package
┗━ hello_fuchsia.manifest
Creating a Fuchsia component
On Fuchsia, components require a component manifest written in Fuchsia's markup language called CML. The Fuchsia devsite contains an overview of CML and a reference for the file format. Here's a basic one that can run our single binary:
pkg/hello_fuchsia.cml
{
include: [ "syslog/client.shard.cml" ],
program: {
runner: "elf",
binary: "bin/hello_fuchsia",
},
}
Current directory structure
hello_fuchsia/
┗━ pkg/
┣━ meta/
┃ ┗━ package
┣━ hello_fuchsia.manifest
┗━ hello_fuchsia.cml
Now we can compile that CML into a component manifest:
${SDK_PATH}/tools/${ARCH}/cmc compile \
pkg/hello_fuchsia.cml \
--includepath ${SDK_PATH}/pkg \
-o pkg/meta/hello_fuchsia.cm
Note: --includepath
tells the compiler where to look for include
s from our CML.
In our case, we're only using syslog/client.shard.cml
.
Current directory structure
hello_fuchsia/
┗━ pkg/
┣━ meta/
┃ ┣━ package
┃ ┗━ hello_fuchsia.cm
┣━ hello_fuchsia.manifest
┗━ hello_fuchsia.cml
Building a Fuchsia package
Next, we'll build a package manifest as defined by our manifest:
${SDK_PATH}/tools/${ARCH}/pm \
-api-level $(${SDK_PATH}/tools/${ARCH}/ffx version -v | grep "api-level" | head -1 | awk -F ' ' '{print $2}') \
-o pkg/hello_fuchsia_manifest \
-m pkg/hello_fuchsia.manifest \
build \
-output-package-manifest pkg/hello_fuchsia_package_manifest
This will produce pkg/hello_fuchsia_manifest/
which is a package manifest we can
publish directly to a repository.
Current directory structure
hello_fuchsia/
┗━ pkg/
┣━ meta/
┃ ┣━ package
┃ ┗━ hello_fuchsia.cm
┣━ hello_fuchsia_manifest/
┃ ┗━ ...
┣━ hello_fuchsia.manifest
┣━ hello_fuchsia.cml
┗━ hello_fuchsia_package_manifest
We are now ready to publish the package.
Publishing a Fuchsia package
With our package and component manifests setup, we can now publish our package. The first step will be to create a Fuchsia package repository to publish to.
Creating a Fuchsia package repository
We can set up our repository with:
${SDK_PATH}/tools/${ARCH}/pm newrepo \
-repo pkg/repo
Current directory structure
hello_fuchsia/
┗━ pkg/
┣━ meta/
┃ ┣━ package
┃ ┗━ hello_fuchsia.cm
┣━ hello_fuchsia_manifest/
┃ ┗━ ...
┣━ repo/
┃ ┗━ ...
┣━ hello_fuchsia.manifest
┣━ hello_fuchsia.cml
┗━ hello_fuchsia_package_manifest
Publishing Fuchsia package to repository
We can publish our new package to that repository with:
${SDK_PATH}/tools/${ARCH}/pm publish \
-repo pkg/repo \
-lp -f <(echo "pkg/hello_fuchsia_package_manifest")
Then we can add the repository to ffx
's package server as hello-fuchsia
using:
${SDK_PATH}/tools/${ARCH}/ffx repository add-from-pm \
pkg/repo \
-r hello-fuchsia
Running a Fuchsia component on an emulator
At this point, we are ready to run our Fuchsia component. For reference, our final directory structure will look like:
Final directory structure
hello_fuchsia/
┣━ src/ (if using rustc)
┃ ┗━ hello_fuchsia.rs ...
┣━ bin/ ...
┃ ┗━ hello_fuchsia ...
┣━ src/ (if using cargo)
┃ ┗━ main.rs ...
┣━ target/ ...
┃ ┗━ x86_64-fuchsia/ ...
┃ ┗━ debug/ ...
┃ ┗━ hello_fuchsia ...
┗━ pkg/
┣━ meta/
┃ ┣━ package
┃ ┗━ hello_fuchsia.cm
┣━ hello_fuchsia_manifest/
┃ ┗━ ...
┣━ repo/
┃ ┗━ ...
┣━ hello_fuchsia.manifest
┣━ hello_fuchsia.cml
┗━ hello_fuchsia_package_manifest
Starting the Fuchsia emulator
Start a Fuchsia emulator in a new terminal using:
${SDK_PATH}/tools/${ARCH}/ffx product-bundle get workstation_eng.qemu-${ARCH}
${SDK_PATH}/tools/${ARCH}/ffx emu start workstation_eng.qemu-${ARCH} --headless
Watching emulator logs
Once the emulator is running, open a separate terminal to watch the emulator logs:
In separate terminal
${SDK_PATH}/tools/${ARCH}/ffx log \
--since now
Serving a Fuchsia package
Now, start a package repository server to serve our package to the emulator:
${SDK_PATH}/tools/${ARCH}/ffx repository server start
Once the repository server is up and running, register it with the target Fuchsia system running in the emulator:
${SDK_PATH}/tools/${ARCH}/ffx target repository register \
--repository hello-fuchsia
Running a Fuchsia component
Finally, run the component:
${SDK_PATH}/tools/${ARCH}/ffx component run \
/core/ffx-laboratory:hello_fuchsia \
fuchsia-pkg://hello-fuchsia/hello_fuchsia_manifest#meta/hello_fuchsia.cm
On reruns of the component, the --recreate
argument may also need to be
passed.
${SDK_PATH}/tools/${ARCH}/ffx component run \
--recreate \
/core/ffx-laboratory:hello_fuchsia \
fuchsia-pkg://hello-fuchsia/hello_fuchsia_manifest#meta/hello_fuchsia.cm
.gitignore
extensions
Optionally, we can create/extend our .gitignore
file to ignore files and
directories that are not helpful to track:
pkg/repo
pkg/meta/hello_fuchsia.cm
pkg/hello_fuchsia_manifest
pkg/hello_fuchsia_package_manifest
Testing
Running unit tests
Tests can be run in the same way as a regular binary.
-
If using
cargo
, you can simply passtest --no-run
to thecargo
invocation and then repackage and rerun the Fuchsia package. From our previous example, this would look likecargo test --target x86_64-fuchsia --no-run
, and moving the executable binary path found from the lineExecutable unittests src/main.rs (target/x86_64-fuchsia/debug/deps/hello_fuchsia-<HASH>)
intopkg/hello_fuchsia.manifest
. -
If using the compiled
rustc
, you can simply pass--test
to therustc
invocation and then repackage and rerun the Fuchsia package.
The test harness will run the applicable unit tests.
Often when testing, you may want to pass additional command line arguments to your binary. Additional arguments can be set in the component manifest:
pkg/hello_fuchsia.cml
{
include: [ "syslog/client.shard.cml" ],
program: {
runner: "elf",
binary: "bin/hello_fuchsia",
args: ["it_works"],
},
}
This will pass the argument it_works
to the binary, filtering the tests to
only those tests that match the pattern. There are many more configuration
options available in CML including environment variables. More documentation is
available on the Fuchsia devsite.
Running the compiler test suite
Running the Rust test suite on Fuchsia is not currently supported, but work is underway to enable it.
Debugging
zxdb
Debugging components running on a Fuchsia emulator can be done using the
console-mode debugger: zxdb. We will demonstrate attaching necessary symbol
paths to debug our hello-fuchsia
component.
Attaching zxdb
In a separate terminal, issue the following command from our hello_fuchsia
directory to launch zxdb
:
In separate terminal
${SDK_PATH}/tools/${ARCH}/ffx debug connect -- \
--symbol-path target/x86_64-fuchsia/debug
--symbol-path
gets required symbol paths, which are necessary for stepping through your program.
The "displaying source code in zxdb
" section describes how you can
display Rust and/or Fuchsia source code in your debugging session.
Using zxdb
Once launched, you will be presented with the window:
Connecting (use "disconnect" to cancel)...
Connected successfully.
👉 To get started, try "status" or "help".
[zxdb]
To attach to our program, we can run:
[zxdb] attach hello_fuchsia
Expected output
Waiting for process matching "hello_fuchsia".
Type "filter" to see the current filters.
Next, we can create a breakpoint at main using "b main":
[zxdb] b main
Expected output
Created Breakpoint 1 @ main
Finally, we can re-run the "hello_fuchsia" component from our original terminal:
${SDK_PATH}/tools/${ARCH}/ffx component run \
--recreate \
fuchsia-pkg://hello-fuchsia/hello_fuchsia_manifest#meta/hello_fuchsia.cm
Once our component is running, our zxdb
window will stop execution
in our main as desired:
Expected output
Breakpoint 1 now matching 1 addrs for main
🛑 on bp 1 hello_fuchsia::main() • main.rs:2
1 fn main() {
▶ 2 println!("Hello Fuchsia!");
3 }
4
[zxdb]
zxdb
has similar commands to other debuggers like gdb.
To list the available commands, run "help" in the
zxdb
window or visit the zxdb documentation.
[zxdb] help
Expected output
Help!
Type "help <command>" for command-specific help.
Other help topics (see "help <topic>")
...
Displaying source code in zxdb
By default, the debugger will not be able to display
source code while debugging. For our user code, we displayed
source code by pointing our debugger to our debug binary via
the --symbol-path
arg. To display library source code in
the debugger, you must provide paths to the source using
--build-dir
. For example, to display the Rust and Fuchsia
source code:
${SDK_PATH}/tools/${ARCH}/ffx debug connect -- \
--symbol-path target/x86_64-fuchsia/debug \
--build-dir ${RUST_SRC_PATH}/rust \
--build-dir ${FUCHSIA_SRC_PATH}/fuchsia/out/default
--build-dir
links against source code paths, which are not strictly necessary for debugging, but is a nice-to-have for displaying source code inzxdb
.
Linking to a Fuchsia checkout can help with debugging Fuchsia libraries, such as fdio.
*-kmc-solid_*
Tier: 3
SOLID embedded development platform by Kyoto Microcomputer Co., Ltd.
The target names follow this format: $ARCH-kmc-solid_$KERNEL-$ABI
, where $ARCH
specifies the target processor architecture, $KERNEL
the base kernel, and $ABI
the target ABI (optional). The following targets are currently defined:
Target name | target_arch | target_vendor | target_os |
---|---|---|---|
aarch64-kmc-solid_asp3 | aarch64 | kmc | solid_asp3 |
armv7a-kmc-solid_asp3-eabi | arm | kmc | solid_asp3 |
armv7a-kmc-solid_asp3-eabihf | arm | kmc | solid_asp3 |
Designated Developers
Requirements
This target is cross-compiled. A platform-provided C compiler toolchain is required, though it can be substituted by GNU Arm Embedded Toolchain for the purpose of building Rust and functional binaries.
Building
The target can be built by enabling it for a rustc
build.
[build]
target = ["aarch64-kmc-solid_asp3"]
Make sure aarch64-kmc-elf-gcc
is included in $PATH
. Alternatively, you can use GNU Arm Embedded Toolchain by adding the following to config.toml
:
[target.aarch64-kmc-solid_asp3]
cc = "arm-none-eabi-gcc"
Cross-compilation
This target can be cross-compiled from any hosts.
Testing
Currently there is no support to run the rustc test suite for this target.
Building Rust programs
Building executables is not supported yet.
If rustc
has support for that target and the library artifacts are available, then Rust static libraries can be built for that target:
$ rustc --target aarch64-kmc-solid_asp3 your-code.rs --crate-type staticlib
$ ls libyour_code.a
On Rust Nightly it's possible to build without the target artifacts available:
cargo build -Z build-std --target aarch64-kmc-solid_asp3
m68k-unknown-linux-gnu
Tier: 3
Motorola 680x0 Linux
Designated Developers
Requirements
This target requires a Linux/m68k build environment for cross-compilation which is available on Debian and Debian-based systems, openSUSE and other distributions.
On Debian, it should be sufficient to install a g++ cross-compiler for the m68k architecture which will automatically pull in additional dependencies such as the glibc cross development package:
# apt install g++-m68k-linux-gnu
Binaries can be run using QEMU user emulation. On Debian-based systems, it should be
sufficient to install the package qemu-user-static
to be able to run simple static
binaries:
# apt install qemu-user-static
To run more complex programs, it will be necessary to set up a Debian/m68k chroot with
the help of the command debootstrap
:
# apt install debootstrap debian-ports-archive-keyring
# debootstrap --keyring=/usr/share/keyrings/debian-ports-archive-keyring.gpg --arch=m68k unstable debian-68k http://ftp.ports.debian.org/debian-ports
This chroot can then seamlessly entered using the normal chroot
command thanks to
QEMU user emulation:
# chroot /path/to/debian-68k
To get started with native builds, which are currently untested, a native Debian/m68k system can be installed either on real hardware such as 68k-based Commodore Amiga or Atari systems or emulated environments such as QEMU version 4.2 or newer or ARAnyM.
ISO images for installation are provided by the Debian Ports team and can be obtained from the Debian CD image server available at:
https://cdimage.debian.org/cdimage/ports/current
Documentation for Debian/m68k is available on the Debian Wiki at:
Support is available either through the debian-68k
mailing list:
https://lists.debian.org/debian-68k/
or the #debian-68k
IRC channel on OFTC network.
Building
The codegen for this target should be built by default. However, core and std are currently missing but are being worked on and should become available in the near future.
Cross-compilation
This target can be cross-compiled from a standard Debian or Debian-based, openSUSE or any other distribution which has a basic m68k cross-toolchain available.
Testing
Currently there is no support to run the rustc test suite for this target.
Building Rust programs
Rust programs can be built for that target:
rustc --target m68k-unknown-linux-gnu your-code.rs
Very simple programs can be run using the qemu-m68k-static
program:
$ qemu-m68k-static your-code
For more complex applications, a chroot or native (emulated) Debian/m68k system are required for testing.
mips64-openwrt-linux-musl
Tier: 3
Target maintainers
- Donald Hoskins
grommish@gmail.com
, https://github.com/Itus-Shield
Requirements
This target is cross-compiled. There is no support for std
. There is no
default allocator, but it's possible to use alloc
by supplying an allocator.
By default, Rust code generated for this target uses -msoft-float
and is
dynamically linked.
This target generated binaries in the ELF format.
Building the target
This target is built exclusively within the OpenWrt
build system via
the rust-lang
HOST package
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for this target, you will either need to build Rust with the target enabled (see "Building the target" above).
Testing
As mips64-openwrt-linux-musl
supports a variety of different environments and does
not support std
, this target does not support running the Rust testsuite at this
time.
mipsel-sony-psx
Tier: 3
Sony PlayStation 1 (psx)
Designated Developer
Requirements
This target is cross-compiled. It has no special requirements for the host.
Building
The target can be built by enabling it for a rustc
build:
[build]
build-stage = 1
target = ["mipsel-sony-psx"]
Cross-compilation
This target can be cross-compiled from any host.
Testing
Currently there is no support to run the rustc test suite for this target.
Building Rust programs
Since it is Tier 3, rust doesn't ship pre-compiled artifacts for this target.
Just use the build-std
nightly cargo feature to build the core
and alloc
libraries:
cargo build -Zbuild-std=core,alloc --target mipsel-sony-psx
The command above generates an ELF. To generate binaries in the PSEXE format that emulators run, you can use cargo-psx:
cargo psx build
or use -Clink-arg=--oformat=binary
to produce a flat binary.
nvptx64-nvidia-cuda
Tier: 2
This is the target meant for deploying code for Nvidia® accelerators based on their CUDA platform.
Target maintainers
- Riccardo D'Ambrosio, https://github.com/RDambrosio016
- Kjetil Kjeka, https://github.com/kjetilkjeka
riscv32imac-unknown-xous-elf
Tier: 3
Xous microkernel, message-based operating system that powers devices such as Precursor and Betrusted. The operating system is written entirely in Rust, so no additional software is required to compile programs for Xous.
Target maintainers
Requirements
Building the target itself requires a RISC-V compiler that is supported by cc-rs
. For example, you can use the prebuilt xPack toolchain.
Cross-compiling programs does not require any additional software beyond the toolchain. Prebuilt versions of the toolchain are available from Betrusted.
Building the target
The target can be built by enabling it for a rustc
build.
[build]
target = ["riscv32imac-unknown-xous-elf"]
Make sure your C compiler is included in $PATH
, then add it to the config.toml
:
[target.riscv32imac-unknown-xous-elf]
cc = "riscv-none-elf-gcc"
ar = "riscv-none-elf-ar"
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for this target, you will need to do one of the following:
- Build Rust with the target enabled (see "Building the target" above)
- Build your own copy of
core
by usingbuild-std
or similar - Download a prebuilt toolchain from Betrusted
Cross-compilation
This target can be cross-compiled from any host.
Testing
Currently there is no support to run the rustc test suite for this target.
*-pc-windows-gnullvm
Tier: 3
Windows targets similar to *-pc-windows-gnu
but using UCRT as the runtime and various LLVM tools/libraries instead of GCC/Binutils.
Target triples available so far:
aarch64-pc-windows-gnullvm
x86_64-pc-windows-gnullvm
Target maintainers
Requirements
The easiest way to obtain these targets is cross-compilation but native build from x86_64-pc-windows-gnu
is possible with few hacks which I don't recommend.
Std support is expected to be on pair with *-pc-windows-gnu
.
Binaries for this target should be at least on pair with *-pc-windows-gnu
in terms of requirements and functionality.
Those targets follow Windows calling convention for extern "C"
.
Like with any other Windows target created binaries are in PE format.
Building the target
For cross-compilation I recommend using llvm-mingw toolchain, one change that seems necessary beside configuring cross compilers is disabling experimental m86k
target. Otherwise LLVM build fails with multiple definition ...
errors.
Native bootstrapping builds require rather fragile hacks until host artifacts are available so I won't describe them here.
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for
this target, you will either need to build Rust with the target enabled (see
"Building the target" above), or build your own copy of core
by using
build-std
or similar.
Testing
Created binaries work fine on Windows or Wine using native hardware. Testing AArch64 on x86_64 is problematic though and requires spending some time with QEMU. Once these targets bootstrap themselves on native hardware they should pass Rust testsuite.
Cross-compilation toolchains and C code
Compatible C code can be built with Clang's aarch64-pc-windows-gnu
and x86_64-pc-windows-gnu
targets as long as LLVM based C toolchains are used.
Those include:
*-unknown-openbsd
Tier: 3
OpenBSD multi-platform 4.4BSD-based UNIX-like operating system.
The target names follow this format: $ARCH-unknown-openbsd
, where $ARCH
specifies the target processor architecture. The following targets are currently defined:
Target name | C++ library | OpenBSD Platform |
---|---|---|
aarch64-unknown-openbsd | libc++ | 64-bit ARM systems |
i686-unknown-openbsd | libc++ | Standard PC and clones based on the Intel i386 architecture and compatible processors |
powerpc64-unknown-openbsd | libc++ | IBM POWER-based PowerNV systems |
riscv64gc-unknown-openbsd | libc++ | 64-bit RISC-V systems |
sparc64-unknown-openbsd | estdc++ | Sun UltraSPARC and Fujitsu SPARC64 systems |
x86_64-unknown-openbsd | libc++ | AMD64-based systems |
Note that all OS versions are major even if using X.Y notation (6.8
and 6.9
are different major versions) and could be binary incompatibles (with breaking changes).
Designated Developers
Fallback to ports@openbsd.org, OpenBSD third parties public mailing-list (with openbsd developers readers)
Requirements
These targets are natively compiled and could be cross-compiled. C compiler toolchain is required for the purpose of building Rust and functional binaries.
Building
The target can be built by enabling it for a rustc
build.
[build]
target = ["$ARCH-unknown-openbsd"]
[target.$ARCH-unknown-openbsd]
cc = "$ARCH-openbsd-cc"
Cross-compilation
These targets can be cross-compiled, but LLVM might not build out-of-box.
Testing
The Rust testsuite could be run natively.
Building Rust programs
Rust does not yet ship pre-compiled artifacts for these targets.
*-unknown-uefi
Tier: 3
Unified Extensible Firmware Interface (UEFI) targets for application, driver, and core UEFI binaries.
Available targets:
aarch64-unknown-uefi
i686-unknown-uefi
x86_64-unknown-uefi
Target maintainers
- David Rheinsberg (@dvdhrm)
- Nicholas Bishop (@nicholasbishop)
Requirements
All UEFI targets can be used as no-std
environments via cross-compilation.
Support for std
is missing, but actively worked on. alloc
is supported if
an allocator is provided by the user. No host tools are supported.
The UEFI environment resembles the environment for Microsoft Windows, with some
minor differences. Therefore, cross-compiling for UEFI works with the same
tools as cross-compiling for Windows. The target binaries are PE32+ encoded,
the calling convention is different for each architecture, but matches what
Windows uses (if the architecture is supported by Windows). The special
efiapi
Rust calling-convention chooses the right ABI for the target platform
(extern "C"
is incorrect on Intel targets at least). The specification has an
elaborate section on the different supported calling-conventions, if more
details are desired.
MMX, SSE, and other FP-units are disabled by default, to allow for compilation of core UEFI code that runs before they are set up. This can be overridden for individual compilations via rustc command-line flags. Not all firmwares correctly configure those units, though, so careful inspection is required.
As native to PE32+, binaries are position-dependent, but can be relocated at runtime if their desired location is unavailable. The code must be statically linked. Dynamic linking is not supported. Code is shared via UEFI interfaces, rather than dynamic linking. Additionally, UEFI forbids running code on anything but the boot CPU/thread, nor is interrupt-usage allowed (apart from the timer interrupt). Device drivers are required to use polling methods.
UEFI uses a single address-space to run all code in. Multiple applications can be loaded simultaneously and are dispatched via cooperative multitasking on a single stack.
By default, the UEFI targets use the link
-flavor of the LLVM linker lld
to
link binaries into the final PE32+ file suffixed with *.efi
. The PE subsystem
is set to EFI_APPLICATION
, but can be modified by passing /subsystem:<...>
to the linker. Similarly, the entry-point is to to efi_main
but can be
changed via /entry:<...>
. The panic-strategy is set to abort
,
The UEFI specification is available online for free: UEFI Specification Directory
Building rust for UEFI targets
Rust can be built for the UEFI targets by enabling them in the rustc
build
configuration. Note that you can only build the standard libraries. The
compiler and host tools currently cannot be compiled for UEFI targets. A sample
configuration would be:
[build]
build-stage = 1
target = ["x86_64-unknown-uefi"]
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for
this target, you will either need to build Rust with the target enabled (see
"Building rust for UEFI targets" above), or build your own copy of core
by
using build-std
, cargo-buildx
, or similar.
A native build with the unstable build-std
-feature can be achieved via:
cargo +nightly build \
-Zbuild-std=core,compiler_builtins \
-Zbuild-std-features=compiler-builtins-mem \
--target x86_64-unknown-uefi
Alternatively, you can install cargo-xbuild
via
cargo install --force cargo-xbuild
and build for the UEFI targets via:
cargo \
+nightly \
xbuild \
--target x86_64-unknown-uefi
Testing
UEFI applications can be copied into the ESP on any UEFI system and executed via the firmware boot menu. The qemu suite allows emulating UEFI systems and executing UEFI applications as well. See its documentation for details.
The uefi-run rust tool is a simple
wrapper around qemu
that can spawn UEFI applications in qemu. You can install
it via cargo install uefi-run
and execute qemu applications as
uefi-run ./application.efi
.
Cross-compilation toolchains and C code
There are 3 common ways to compile native C code for UEFI targets:
- Use the official SDK by Intel: Tianocore/EDK2. This supports a multitude of platforms, comes with the full specification transposed into C, lots of examples and build-system integrations. This is also the only officially supported platform by Intel, and is used by many major firmware implementations. Any code compiled via the SDK is compatible to rust binaries compiled for the UEFI targets. You can link them directly into your rust binaries, or call into each other via UEFI protocols.
- Use the GNU-EFI suite. This approach is used by many UEFI applications in the Linux/OSS ecosystem. The GCC compiler is used to compile ELF binaries, and linked with a pre-loader that converts the ELF binary to PE32+ at runtime. You can combine such binaries with the rust UEFI targets only via UEFI protocols. Linking both into the same executable will fail, since one is an ELF executable, and one a PE32+. If linking to GNU-EFI executables is desired, you must compile your rust code natively for the same GNU target as GNU-EFI and use their pre-loader. This requires careful consideration about which calling-convention to use when calling into native UEFI protocols, or calling into linked GNU-EFI code (similar to how these differences need to be accounted for when writing GNU-EFI C code).
- Use native Windows targets. This means compiling your C code for the Windows platform as if it was the UEFI platform. This works for static libraries, but needs adjustments when linking into an UEFI executable. You can, however, link such static libraries seamlessly into rust code compiled for UEFI targets. Be wary of any includes that are not specifically suitable for UEFI targets (especially the C standard library includes are not always compatible). Freestanding compilations are recommended to avoid incompatibilites.
Ecosystem
The rust language has a long history of supporting UEFI targets. Many crates have been developed to provide access to UEFI protocols and make UEFI programming more ergonomic in rust. The following list is a short overview (in alphabetical ordering):
- efi: Ergonomic Rust bindings for writing UEFI applications. Provides rustified access to UEFI protocols, implements allocators and a safe environment to write UEFI applications.
- r-efi: UEFI Reference Specification Protocol Constants and Definitions. A pure transpose of the UEFI specification into rust. This provides the raw definitions from the specification, without any extended helpers or rustification. It serves as baseline to implement any more elaborate rust UEFI layers.
- uefi-rs: Safe and easy-to-use wrapper for building UEFI apps. An elaborate library providing safe abstractions for UEFI protocols and features. It implements allocators and provides an execution environment to UEFI applications written in rust.
- uefi-run: Run UEFI applications. A small wrapper around qemu to spawn
UEFI applications in an emulated
x86_64
machine.
Example: Freestanding
The following code is a valid UEFI application returning immediately upon execution with an exit code of 0. A panic handler is provided. This is executed by rust on panic. For simplicity, we simply end up in an infinite loop.
Note that as of rust-1.31.0, all features used here are stabilized. No unstable
features are required, nor do we rely on nightly compilers. However, if you do
not compile rustc for the UEFI targets, you need a nightly compiler to support
the -Z build-std
flag.
This example can be compiled as binary crate via cargo
:
cargo +nightly build \
-Zbuild-std=core,compiler_builtins \
-Zbuild-std-features=compiler-builtins-mem \
--target x86_64-unknown-uefi
#![no_main]
#![no_std]
#[panic_handler]
fn panic_handler(_info: &core::panic::PanicInfo) -> ! {
loop {}
}
#[export_name = "efi_main"]
pub extern "C" fn main(_h: *mut core::ffi::c_void, _st: *mut core::ffi::c_void) -> usize {
0
}
Example: Hello World
This is an example UEFI application that prints "Hello World!", then waits for
key input before it exits. It serves as base example how to write UEFI
applications without any helper modules other than the standalone UEFI protocol
definitions provided by the r-efi
crate.
This extends the "Freestanding" example and builds upon its setup. See there for instruction how to compile this as binary crate.
Note that UEFI uses UTF-16 strings. Since rust literals are UTF-8, we have to
use an open-coded, zero-terminated, UTF-16 array as argument to
output_string()
. Similarly to the panic handler, real applications should
rather use UTF-16 modules.
#![no_main]
#![no_std]
use r_efi::efi;
#[panic_handler]
fn panic_handler(_info: &core::panic::PanicInfo) -> ! {
loop {}
}
#[export_name = "efi_main"]
pub extern "C" fn main(_h: efi::Handle, st: *mut efi::SystemTable) -> efi::Status {
let s = [
0x0048u16, 0x0065u16, 0x006cu16, 0x006cu16, 0x006fu16, // "Hello"
0x0020u16, // " "
0x0057u16, 0x006fu16, 0x0072u16, 0x006cu16, 0x0064u16, // "World"
0x0021u16, // "!"
0x000au16, // "\n"
0x0000u16, // NUL
];
// Print "Hello World!".
let r =
unsafe { ((*(*st).con_out).output_string)((*st).con_out, s.as_ptr() as *mut efi::Char16) };
if r.is_error() {
return r;
}
// Wait for key input, by waiting on the `wait_for_key` event hook.
let r = unsafe {
let mut x: usize = 0;
((*(*st).boot_services).wait_for_event)(1, &mut (*(*st).con_in).wait_for_key, &mut x)
};
if r.is_error() {
return r;
}
efi::Status::SUCCESS
}
wasm64-unknown-unknown
Tier: 3
WebAssembly target which uses 64-bit memories, relying on the memory64 WebAssembly proposal.
Target maintainers
- Alex Crichton, https://github.com/alexcrichton
Requirements
This target is cross-compiled. The target supports std
in the same manner as
the wasm32-unknown-unknown
target which is to say that it comes with the
standard library but many I/O functions such as std::fs
and std::net
will
simply return error. Additionally I/O operations like println!
don't actually
do anything and the prints aren't routed anywhere. This is the same as the
wasm32-unknown-unknown
target. This target comes by default with an allocator,
currently dlmalloc which is ported to rust.
The difference of this target with wasm32-unknown-unknown
is that it's
compiled for 64-bit memories instead of 32-bit memories. This means that usize
is 8-bytes large as well as pointers. The tradeoff, though, is that the maximum
memory size is now the full 64-bit address space instead of the 4GB as limited
by the 32-bit address space for wasm32-unknown-unknown
.
This target is not a stable target. The memory64 WebAssembly proposal is still
in-progress and not standardized. This means that there are not many engines
which implement the memory64
feature and if they do they're likely behind a
flag, for example:
- Nodejs -
--experimental-wasm-memory64
- Wasmtime -
--wasm-features memory64
Also note that at this time the wasm64-unknown-unknown
target assumes the
presence of other merged wasm proposals such as (with their LLVM feature flags):
- Bulk memory -
+bulk-memory
- Mutable imported globals -
+mutable-globals
- Sign-extending operations -
+sign-ext
- Non-trapping fp-to-int operations -
+nontrapping-fptoint
The wasm64-unknown-unknown
target intends to match the default Clang targets
for its "C"
ABI, which is likely to be the same as Clang's
wasm32-unknown-unknown
largely.
Note: due to the relatively early-days nature of this target when working with this target you may encounter LLVM bugs. If an assertion hit or a bug is found it's recommended to open an issue either with rust-lang/rust or ideally with LLVM itself.
This target does not support panic=unwind
at this time.
Building the target
You can build Rust with support for the target by adding it to the target
list in config.toml
, and the target also requires lld
to be built to work.
[build]
target = ["wasm64-unknown-unknown"]
[rust]
lld = true
Building Rust programs
Rust does not yet ship pre-compiled artifacts for this target. To compile for
this target, you will either need to build Rust with the target enabled (see
"Building the target" above), or build your own copy of std
by using
build-std
or similar.
Note that the following cfg
directives are set for wasm64-unknown-unknown
:
cfg(target_arch = "wasm64")
cfg(target_family = "wasm")
Testing
Currently testing is not well supported for wasm64-unknown-unknown
and the
Rust project doesn't run any tests for this target. Testing support sort of
works but without println!
it's not the most exciting tests to run.
Cross-compilation toolchains and C code
Compiling Rust code with C code for wasm64-unknown-unknown
is theoretically
possible, but there are no known toolchains to do this at this time. At the time
of this writing there is no known "libc" for wasm that works with
wasm64-unknown-unknown
, which means that mixing C & Rust with this target
effectively cannot be done.
x86_64-fortanix-unknown-sgx
Tier: 2
Secure enclaves using Intel Software Guard Extensions (SGX) based on the ABI defined by Fortanix for the Enclave Development Platform (EDP).
Target maintainers
The EDP team at Fortanix.
- Jethro Beekman @jethrogb
- Raoul Strackx @raoulstrackx
- Mohsen Zohrevandi @mzohreva
Requirements
The target supports std
with a default allocator. Only cross compilation is
supported.
Binaries support all CPUs that include Intel SGX. Only 64-bit mode is supported.
Not all std
features are supported, see Using Rust's
std for details.
The extern "C"
calling convention is the System V AMD64 ABI.
The supported ABI is the fortanix-sgx-abi.
The compiler output is ELF, but the native format for the platform is the SGX stream (SGXS) format. A converter like ftxsgx-elf2sgxs is needed.
Programs in SGXS format adhering to the Fortanix SGX ABI can be run with any compatible runner, such as ftxsgx-runner.
See the EDP installation guide for recommendations on how to setup a development and runtime environment.
Building the target
As a tier 2 target, the target is built by the Rust project.
You can configure rustbuild like so:
[build]
build-stage = 1
target = ["x86_64-fortanix-unknown-sgx"]
Building Rust programs
Standard build flows using cargo
or rustc
should work.
Testing
The Rust test suite as well as custom unit and integration tests will run on hardware that has Intel SGX enabled if a cargo runner is configured correctly, see the requirements section.
Cross-compilation toolchains and C code
C code is not generally supported, as there is no libc. C code compiled for x86-64 in freestanding mode using the System V AMD64 ABI may work. The rs-libc crate contains a subset of libc that's known to work with this target.
x86_64-unknown-none
Tier: 2
Freestanding/bare-metal x86-64 binaries in ELF format: firmware, kernels, etc.
Target maintainers
- Harald Hoyer
harald@profian.com
, https://github.com/haraldh - Mike Leany, https://github.com/mikeleany
Requirements
This target is cross-compiled. There is no support for std
. There is no
default allocator, but it's possible to use alloc
by supplying an allocator.
By default, Rust code generated for this target does not use any vector or
floating-point registers (e.g. SSE, AVX). This allows the generated code to run
in environments, such as kernels, which may need to avoid the use of such
registers or which may have special considerations about the use of such
registers (e.g. saving and restoring them to avoid breaking userspace code
using the same registers). You can change code generation to use additional CPU
features via the -C target-feature=
codegen options to rustc, or via the
#[target_feature]
mechanism within Rust code.
By default, code generated with this target should run on any x86_64
hardware; enabling additional target features may raise this baseline.
Code generated with this target will use the kernel
code model by default.
You can change this using the -C code-model=
option to rustc.
On x86_64-unknown-none
, extern "C"
uses the standard System V calling
convention, without red zones.
This target generates binaries in the ELF format. Any alternate formats or special considerations for binary layout will require linker options or linker scripts.
Building the target
You can build Rust with support for the target by adding it to the target
list in config.toml
:
[build]
build-stage = 1
target = ["x86_64-unknown-none"]
Building Rust programs
Starting with Rust 1.62, precompiled artifacts are provided via rustup
:
# install cross-compile toolchain
rustup target add x86_64-unknown-none
# target flag may be used with any cargo or rustc command
cargo build --target x86_64-unknown-none
Testing
As x86_64-unknown-none
supports a variety of different environments and does
not support std
, this target does not support running the Rust test suite.
Cross-compilation toolchains and C code
If you want to compile C code along with Rust (such as for Rust crates with C
dependencies), you will need an appropriate x86_64
toolchain.
Rust may be able to use an x86_64-linux-gnu-
toolchain with appropriate
standalone flags to build for this toolchain (depending on the assumptions of
that toolchain, see below), or you may wish to use a separate
x86_64-unknown-none
(or x86_64-elf-
) toolchain.
On some x86_64
hosts that use ELF binaries, you may be able to use the host
C toolchain, if it does not introduce assumptions about the host environment
that don't match the expectations of a standalone environment. Otherwise, you
may need a separate toolchain for standalone/freestanding development, just as
when cross-compiling from a non-x86_64
platform.
Targets
rustc
is a cross-compiler by default. This means that you can use any compiler to build for any
architecture. The list of targets are the possible architectures that you can build for.
To see all the options that you can set with a target, see the docs here.
To compile to a particular target, use the --target
flag:
$ rustc src/main.rs --target=wasm32-unknown-unknown
Target Features
x86
, and ARMv8
are two popular CPU architectures. Their instruction sets form a common baseline across most CPUs. However, some CPUs extend these with custom instruction sets, e.g. vector (AVX
), bitwise manipulation (BMI
) or cryptographic (AES
).
Developers, who know on which CPUs their compiled code is going to run can choose to add (or remove) CPU specific instruction sets via the -C target-feature=val
flag.
Please note, that this flag is generally considered as unsafe. More details can be found in this section.
Built-in Targets
rustc
ships with the ability to compile to many targets automatically, we
call these "built-in" targets, and they generally correspond to targets that
the team is supporting directly. To see the list of built-in targets, you can
run rustc --print target-list
.
Typically, a target needs a compiled copy of the Rust standard library to work. If using rustup, then check out the documentation on Cross-compilation on how to download a pre-built standard library built by the official Rust distributions. Most targets will need a system linker, and possibly other things.
Custom Targets
If you'd like to build for a target that is not yet supported by rustc
, you can use a
"custom target specification" to define a target. These target specification files
are JSON. To see the JSON for the host target, you can run:
rustc +nightly -Z unstable-options --print target-spec-json
To see it for a different target, add the --target
flag:
rustc +nightly -Z unstable-options --target=wasm32-unknown-unknown --print target-spec-json
To use a custom target, see the (unstable) build-std
feature of cargo
.
Known Issues
This section informs you about known "gotchas". Keep in mind, that this section is (and always will be) incomplete. For suggestions and amendments, feel free to contribute to this guide.
Target Features
Most target-feature problems arise, when mixing code that have the target-feature enabled with code that have it disabled. If you want to avoid undefined behavior, it is recommended to build all code (including the standard library and imported crates) with a common set of target-features.
By default, compiling your code with the -C target-feature
flag will not recompile the entire standard library and/or imported crates with matching target features. Therefore, target features are generally considered as unsafe. Using #[target_feature]
on individual functions makes the function unsafe.
Examples:
Target-Feature | Issue | Seen on | Description | Details |
---|---|---|---|---|
+soft-float and -sse | Segfaults and ABI mismatches | x86 and x86-64 | The x86 and x86_64 architecture uses SSE registers (aka xmm ) for floating point operations. Using software emulated floats ("soft-floats") disables usage of xmm registers, but parts of Rust's core libraries (e.g. std::f32 or std::f64 ) are compiled without soft-floats and expect parameters to be passed in xmm registers. This leads to ABI mismatches. Attempting to compile with disabled SSE causes the same error, too. | #63466 |
Profile-guided Optimization
rustc
supports doing profile-guided optimization (PGO).
This chapter describes what PGO is, what it is good for, and how it can be used.
What Is Profiled-Guided Optimization?
The basic concept of PGO is to collect data about the typical execution of a program (e.g. which branches it is likely to take) and then use this data to inform optimizations such as inlining, machine-code layout, register allocation, etc.
There are different ways of collecting data about a program's execution.
One is to run the program inside a profiler (such as perf
) and another
is to create an instrumented binary, that is, a binary that has data
collection built into it, and run that.
The latter usually provides more accurate data and it is also what is
supported by rustc
.
Usage
Generating a PGO-optimized program involves following a workflow with four steps:
- Compile the program with instrumentation enabled
(e.g.
rustc -Cprofile-generate=/tmp/pgo-data main.rs
) - Run the instrumented program (e.g.
./main
) which generates adefault_<id>.profraw
file - Convert the
.profraw
file into a.profdata
file using LLVM'sllvm-profdata
tool - Compile the program again, this time making use of the profiling data
(for example
rustc -Cprofile-use=merged.profdata main.rs
)
An instrumented program will create one or more .profraw
files, one for each
instrumented binary. E.g. an instrumented executable that loads two instrumented
dynamic libraries at runtime will generate three .profraw
files. Running an
instrumented binary multiple times, on the other hand, will re-use the
respective .profraw
files, updating them in place.
These .profraw
files have to be post-processed before they can be fed back
into the compiler. This is done by the llvm-profdata
tool. This tool
is most easily installed via
rustup component add llvm-tools-preview
Note that installing the llvm-tools-preview
component won't add
llvm-profdata
to the PATH
. Rather, the tool can be found in:
~/.rustup/toolchains/<toolchain>/lib/rustlib/<target-triple>/bin/
Alternatively, an llvm-profdata
coming with a recent LLVM or Clang
version usually works too.
The llvm-profdata
tool merges multiple .profraw
files into a single
.profdata
file that can then be fed back into the compiler via
-Cprofile-use
:
# STEP 1: Compile the binary with instrumentation
rustc -Cprofile-generate=/tmp/pgo-data -O ./main.rs
# STEP 2: Run the binary a few times, maybe with common sets of args.
# Each run will create or update `.profraw` files in /tmp/pgo-data
./main mydata1.csv
./main mydata2.csv
./main mydata3.csv
# STEP 3: Merge and post-process all the `.profraw` files in /tmp/pgo-data
llvm-profdata merge -o ./merged.profdata /tmp/pgo-data
# STEP 4: Use the merged `.profdata` file during optimization. All `rustc`
# flags have to be the same.
rustc -Cprofile-use=./merged.profdata -O ./main.rs
A Complete Cargo Workflow
Using this feature with Cargo works very similar to using it with rustc
directly. Again, we generate an instrumented binary, run it to produce data,
merge the data, and feed it back into the compiler. Some things of note:
-
We use the
RUSTFLAGS
environment variable in order to pass the PGO compiler flags to the compilation of all crates in the program. -
We pass the
--target
flag to Cargo, which prevents theRUSTFLAGS
arguments to be passed to Cargo build scripts. We don't want the build scripts to generate a bunch of.profraw
files. -
We pass
--release
to Cargo because that's where PGO makes the most sense. In theory, PGO can also be done on debug builds but there is little reason to do so. -
It is recommended to use absolute paths for the argument of
-Cprofile-generate
and-Cprofile-use
. Cargo can invokerustc
with varying working directories, meaning thatrustc
will not be able to find the supplied.profdata
file. With absolute paths this is not an issue. -
It is good practice to make sure that there is no left-over profiling data from previous compilation sessions. Just deleting the directory is a simple way of doing so (see
STEP 0
below).
This is what the entire workflow looks like:
# STEP 0: Make sure there is no left-over profiling data from previous runs
rm -rf /tmp/pgo-data
# STEP 1: Build the instrumented binaries
RUSTFLAGS="-Cprofile-generate=/tmp/pgo-data" \
cargo build --release --target=x86_64-unknown-linux-gnu
# STEP 2: Run the instrumented binaries with some typical data
./target/x86_64-unknown-linux-gnu/release/myprogram mydata1.csv
./target/x86_64-unknown-linux-gnu/release/myprogram mydata2.csv
./target/x86_64-unknown-linux-gnu/release/myprogram mydata3.csv
# STEP 3: Merge the `.profraw` files into a `.profdata` file
llvm-profdata merge -o /tmp/pgo-data/merged.profdata /tmp/pgo-data
# STEP 4: Use the `.profdata` file for guiding optimizations
RUSTFLAGS="-Cprofile-use=/tmp/pgo-data/merged.profdata" \
cargo build --release --target=x86_64-unknown-linux-gnu
Troubleshooting
-
It is recommended to pass
-Cllvm-args=-pgo-warn-missing-function
during the-Cprofile-use
phase. LLVM by default does not warn if it cannot find profiling data for a given function. Enabling this warning will make it easier to spot errors in your setup. -
There is a known issue in Cargo prior to version 1.39 that will prevent PGO from working correctly. Be sure to use Cargo 1.39 or newer when doing PGO.
Further Reading
rustc
's PGO support relies entirely on LLVM's implementation of the feature
and is equivalent to what Clang offers via the -fprofile-generate
/
-fprofile-use
flags. The Profile Guided Optimization section
in Clang's documentation is therefore an interesting read for anyone who wants
to use PGO with Rust.
Instrumentation-based Code Coverage
Introduction
The Rust compiler includes two code coverage implementations:
- A GCC-compatible, gcov-based coverage implementation, enabled with
-Z profile
, which derives coverage data based on DebugInfo. - A source-based code coverage implementation, enabled with
-C instrument-coverage
, which uses LLVM's native, efficient coverage instrumentation to generate very precise coverage data.
This document describes how to enable and use the LLVM instrumentation-based coverage, via the -C instrument-coverage
compiler flag.
How it works
When -C instrument-coverage
is enabled, the Rust compiler enhances rust-based libraries and binaries by:
- Automatically injecting calls to an LLVM intrinsic (
llvm.instrprof.increment
), at functions and branches in compiled code, to increment counters when conditional sections of code are executed. - Embedding additional information in the data section of each library and binary (using the LLVM Code Coverage Mapping Format Version 5, if compiling with LLVM 12, or Version 6, if compiling with LLVM 13 or higher), to define the code regions (start and end positions in the source code) being counted.
When running a coverage-instrumented program, the counter values are written to a profraw
file at program termination. LLVM bundles tools that read the counter results, combine those results with the coverage map (embedded in the program binary), and generate coverage reports in multiple formats.
Note:
-C instrument-coverage
also automatically enables-C symbol-mangling-version=v0
(tracking issue #60705). Thev0
symbol mangler is strongly recommended. Thev0
demangler can be overridden by explicitly adding-Z unstable-options -C symbol-mangling-version=legacy
.
Enable coverage profiling in the Rust compiler
Rust's source-based code coverage requires the Rust "profiler runtime". Without it, compiling with -C instrument-coverage
generates an error that the profiler runtime is missing.
The Rust nightly
distribution channel includes the profiler runtime, by default.
Important: If you are building the Rust compiler from the source distribution, the profiler runtime is not enabled in the default
config.toml.example
. Edit yourconfig.toml
file and ensure theprofiler
feature is set it totrue
(either under the[build]
section, or under the settings for an individual[target.<triple>]
):# Build the profiler runtime (required when compiling with options that depend # on this runtime, such as `-C profile-generate` or `-C instrument-coverage`). profiler = true
Building the demangler
LLVM coverage reporting tools generate results that can include function names and other symbol references, and the raw coverage results report symbols using the compiler's "mangled" version of the symbol names, which can be difficult to interpret. To work around this issue, LLVM coverage tools also support a user-specified symbol name demangler.
One option for a Rust demangler is rustfilt
, which can be installed with:
cargo install rustfilt
Another option, if you are building from the Rust compiler source distribution, is to use the rust-demangler
tool included in the Rust source distribution, which can be built with:
$ ./x.py build rust-demangler
Compiling with coverage enabled
Set the -C instrument-coverage
compiler flag in order to enable LLVM source-based code coverage profiling.
The default option generates coverage for all functions, including unused (never called) functions and generics. The compiler flag supports an optional value to tailor this behavior. (See -C instrument-coverage=<options>
, below.)
With cargo
, you can instrument your program binary and dependencies at the same time.
For example (if your project's Cargo.toml builds a binary by default):
$ cd your-project
$ cargo clean
$ RUSTFLAGS="-C instrument-coverage" cargo build
If cargo
is not configured to use your profiler
-enabled version of rustc
, set the path explicitly via the RUSTC
environment variable. Here is another example, using a stage1
build of rustc
to compile an example
binary (from the json5format
crate):
$ RUSTC=$HOME/rust/build/x86_64-unknown-linux-gnu/stage1/bin/rustc \
RUSTFLAGS="-C instrument-coverage" \
cargo build --example formatjson5
Note: that some compiler options, combined with
-C instrument-coverage
, can produce LLVM IR and/or linked binaries that are incompatible with LLVM coverage maps. For example, coverage requires references to actual functions in LLVM IR. If any covered function is optimized out, the coverage tools may not be able to process the coverage results. If you need to pass additional options, with coverage enabled, test them early, to confirm you will get the coverage results you expect.
Running the instrumented binary to generate raw coverage profiling data
In the previous example, cargo
generated the coverage-instrumented binary formatjson5
:
$ echo "{some: 'thing'}" | target/debug/examples/formatjson5 -
{
some: "thing",
}
After running this program, a new file named like default_11699812450447639123_0_20944
should be in the current working directory.
A new, unique file name will be generated each time the program is run to avoid overwriting previous data.
$ echo "{some: 'thing'}" | target/debug/examples/formatjson5 -
...
$ ls default_*.profraw
default_11699812450447639123_0_20944.profraw
You can also set a specific file name or path for the generated .profraw
files by using the environment variable LLVM_PROFILE_FILE
:
$ echo "{some: 'thing'}" \
| LLVM_PROFILE_FILE="formatjson5.profraw" target/debug/examples/formatjson5 -
...
$ ls formatjson5.profraw
formatjson5.profraw
If LLVM_PROFILE_FILE
contains a path to a non-existent directory, the missing directory structure will be created. Additionally, the following special pattern strings are rewritten:
%p
- The process ID.%h
- The hostname of the machine running the program.%t
- The value of the TMPDIR environment variable.%Nm
- the instrumented binary’s signature: The runtime creates a pool of N raw profiles, used for on-line profile merging. The runtime takes care of selecting a raw profile from the pool, locking it, and updating it before the program exits.N
must be between1
and9
, and defaults to1
if omitted (with simply%m
).%c
- Does not add anything to the filename, but enables a mode (on some platforms, including Darwin) in which profile counter updates are continuously synced to a file. This means that if the instrumented program crashes, or is killed by a signal, perfect coverage information can still be recovered.
In the first example above, the value 11699812450447639123_0
in the generated filename is the instrumented binary's signature,
which replaced the %m
pattern and the value 20944
is the process ID of the binary being executed.
Installing LLVM coverage tools
LLVM's supplies two tools—llvm-profdata
and llvm-cov
—that process coverage data and generate reports. There are several ways to find and/or install these tools, but note that the coverage mapping data generated by the Rust compiler requires LLVM version 12 or higher, and processing the raw data may require exactly the LLVM version used by the compiler. (llvm-cov --version
typically shows the tool's LLVM version number, and rustc --verbose --version
shows the version of LLVM used by the Rust compiler.)
- You can install compatible versions of these tools via the
rustup
componentllvm-tools-preview
. This component is the recommended path, though the specific tools available and their interface is not currently subject to Rust's usual stability guarantees. In this case, you may also findcargo-binutils
useful as a wrapper around these tools. - You can install a compatible version of LLVM tools from your operating system distribution, or from your distribution of LLVM.
- If you are building the Rust compiler from source, you can optionally use the bundled LLVM tools, built from source. Those tool binaries can typically be found in your build platform directory at something like:
rust/build/x86_64-unknown-linux-gnu/llvm/bin/llvm-*
.
The examples in this document show how to use the llvm tools directly.
Creating coverage reports
Raw profiles have to be indexed before they can be used to generate coverage reports. This is done using llvm-profdata merge
, which can combine multiple raw profiles and index them at the same time:
$ llvm-profdata merge -sparse formatjson5.profraw -o formatjson5.profdata
Finally, the .profdata
file is used, in combination with the coverage map (from the program binary) to generate coverage reports using llvm-cov report
, for a coverage summaries; and llvm-cov show
, to see detailed coverage of lines and regions (character ranges) overlaid on the original source code.
These commands have several display and filtering options. For example:
$ llvm-cov show -Xdemangler=rustfilt target/debug/examples/formatjson5 \
-instr-profile=formatjson5.profdata \
-show-line-counts-or-regions \
-show-instantiations \
-name=add_quoted_string
Some of the more notable options in this example include:
--Xdemangler=rustfilt
- the command name or path used to demangle Rust symbols (rustfilt
in the example, but this could also be a path to therust-demangler
tool)target/debug/examples/formatjson5
- the instrumented binary (from which to extract the coverage map)--instr-profile=<path-to-file>.profdata
- the location of the.profdata
file created byllvm-profdata merge
(from the.profraw
file generated by the instrumented binary)--name=<exact-function-name>
- to show coverage for a specific function (or, consider using another filter option, such as--name-regex=<pattern>
)
Note: Coverage can also be disabled on an individual function by annotating the function with the
no_coverage
attribute (which requires the feature flag#![feature(no_coverage)]
).
Interpreting reports
There are four statistics tracked in a coverage summary:
- Function coverage is the percentage of functions that have been executed at least once. A function is considered to be executed if any of its instantiations are executed.
- Instantiation coverage is the percentage of function instantiations that have been executed at least once. Generic functions and functions generated from macros are two kinds of functions that may have multiple instantiations.
- Line coverage is the percentage of code lines that have been executed at least once. Only executable lines within function bodies are considered to be code lines.
- Region coverage is the percentage of code regions that have been executed at least once. A code region may span multiple lines: for example, in a large function body with no control flow. In other cases, a single line can contain multiple code regions:
return x || (y && z)
has countable code regions forx
(which may resolve the expression, ifx
istrue
),|| (y && z)
(executed only ifx
wasfalse
), andreturn
(executed in either situation).
Of these four statistics, function coverage is usually the least granular while region coverage is the most granular. The project-wide totals for each statistic are listed in the summary.
Test coverage
A typical use case for coverage analysis is test coverage. Rust's source-based coverage tools can both measure your tests' code coverage as percentage, and pinpoint functions and branches not tested.
The following example (using the json5format
crate, for demonstration purposes) show how to generate and analyze coverage results for all tests in a crate.
Since cargo test
both builds and runs the tests, we set the additional RUSTFLAGS
, to add the -C instrument-coverage
flag.
$ RUSTFLAGS="-C instrument-coverage" \
cargo test --tests
Make note of the test binary file paths, displayed after the word "Running
" in the test output:
...
Compiling json5format v0.1.3 ($HOME/json5format)
Finished test [unoptimized + debuginfo] target(s) in 14.60s
Running target/debug/deps/json5format-fececd4653271682
running 25 tests
...
test result: ok. 25 passed; 0 failed; 0 ignored; 0 measured; 0 filtered out
Running target/debug/deps/lib-30768f9c53506dc5
running 31 tests
...
test result: ok. 31 passed; 0 failed; 0 ignored; 0 measured; 0 filtered out
You should have one or more .profraw
files now, one for each test binary. Run the profdata
tool to merge them:
$ llvm-profdata merge -sparse default_*.profraw -o json5format.profdata
Then run the cov
tool, with the profdata
file and all test binaries:
$ llvm-cov report \
--use-color --ignore-filename-regex='/.cargo/registry' \
--instr-profile=json5format.profdata \
--object target/debug/deps/lib-30768f9c53506dc5 \
--object target/debug/deps/json5format-fececd4653271682
$ llvm-cov show \
--use-color --ignore-filename-regex='/.cargo/registry' \
--instr-profile=json5format.profdata \
--object target/debug/deps/lib-30768f9c53506dc5 \
--object target/debug/deps/json5format-fececd4653271682 \
--show-instantiations --show-line-counts-or-regions \
--Xdemangler=rustfilt | less -R
Note: If overriding the default
profraw
file name via theLLVM_PROFILE_FILE
environment variable, it's highly recommended to use the%m
and%p
special pattern strings to generate unique file names in the case of more than a single test binary being executed.
Note: The command line option
--ignore-filename-regex=/.cargo/registry
, which excludes the sources for dependencies from the coverage results._
Tips for listing the binaries automatically
For bash
users, one suggested way to automatically complete the cov
command with the list of binaries is with a command like:
$ llvm-cov report \
$( \
for file in \
$( \
RUSTFLAGS="-C instrument-coverage" \
cargo test --tests --no-run --message-format=json \
| jq -r "select(.profile.test == true) | .filenames[]" \
| grep -v dSYM - \
); \
do \
printf "%s %s " -object $file; \
done \
) \
--instr-profile=json5format.profdata --summary-only # and/or other options
Adding --no-run --message-format=json
to the same cargo test
command used to run
the tests (including the same environment variables and flags) generates output in a JSON
format that jq
can easily query.
The printf
command takes this list and generates the --object <binary>
arguments
for each listed test binary.
Including doc tests
The previous examples run cargo test
with --tests
, which excludes doc tests.1
To include doc tests in the coverage results, drop the --tests
flag, and apply the
-C instrument-coverage
flag, and some doc-test-specific options in the
RUSTDOCFLAGS
environment variable. (The llvm-profdata
command does not change.)
$ RUSTFLAGS="-C instrument-coverage" \
RUSTDOCFLAGS="-C instrument-coverage -Z unstable-options --persist-doctests target/debug/doctestbins" \
cargo test
$ llvm-profdata merge -sparse default_*.profraw -o json5format.profdata
The -Z unstable-options --persist-doctests
flag is required, to save the test binaries
(with their coverage maps) for llvm-cov
.
$ llvm-cov report \
$( \
for file in \
$( \
RUSTFLAGS="-C instrument-coverage" \
RUSTDOCFLAGS="-C instrument-coverage -Z unstable-options --persist-doctests target/debug/doctestbins" \
cargo test --no-run --message-format=json \
| jq -r "select(.profile.test == true) | .filenames[]" \
| grep -v dSYM - \
) \
target/debug/doctestbins/*/rust_out; \
do \
[[ -x $file ]] && printf "%s %s " -object $file; \
done \
) \
--instr-profile=json5format.profdata --summary-only # and/or other options
Note: The differences in this
llvm-cov
invocation, compared with the version without doc tests, include:
- The
cargo test ... --no-run
command is updated with the same environment variables and flags used to build the tests, including the doc tests. - The file glob pattern
target/debug/doctestbins/*/rust_out
adds therust_out
binaries generated for doc tests (note, however, that somerust_out
files may not be executable binaries). [[ -x $file ]] &&
filters the files passed on to theprintf
, to include only executable binaries.
There is ongoing work to resolve a known issue
[(#79417)](https://github.com/rust-lang/rust/issues/79417) that doc test coverage
generates incorrect source line numbers in `llvm-cov show` results.
-C instrument-coverage=<options>
-C instrument-coverage=all
: Instrument all functions, including unused functions and unused generics. (This is the same as-C instrument-coverage
, with no value.)-C instrument-coverage=off
: Do not instrument any functions. (This is the same as simply not including the-C instrument-coverage
option.)-Zunstable-options -C instrument-coverage=except-unused-generics
: Instrument all functions except unused generics.-Zunstable-options -C instrument-coverage=except-unused-functions
: Instrument only used (called) functions and instantiated generic functions.
Other references
Rust's implementation and workflow for source-based code coverage is based on the same library and tools used to implement source-based code coverage in Clang. (This document is partially based on the Clang guide.)
Linker-plugin-based LTO
The -C linker-plugin-lto
flag allows for deferring the LTO optimization
to the actual linking step, which in turn allows for performing
interprocedural optimizations across programming language boundaries if
all the object files being linked were created by LLVM based toolchains.
The prime example here would be linking Rust code together with
Clang-compiled C/C++ code.
Usage
There are two main cases how linker plugin based LTO can be used:
- compiling a Rust
staticlib
that is used as a C ABI dependency - compiling a Rust binary where
rustc
invokes the linker
In both cases the Rust code has to be compiled with -C linker-plugin-lto
and
the C/C++ code with -flto
or -flto=thin
so that object files are emitted
as LLVM bitcode.
Rust staticlib
as dependency in C/C++ program
In this case the Rust compiler just has to make sure that the object files in
the staticlib
are in the right format. For linking, a linker with the
LLVM plugin must be used (e.g. LLD).
Using rustc
directly:
# Compile the Rust staticlib
rustc --crate-type=staticlib -Clinker-plugin-lto -Copt-level=2 ./lib.rs
# Compile the C code with `-flto=thin`
clang -c -O2 -flto=thin -o cmain.o ./cmain.c
# Link everything, making sure that we use an appropriate linker
clang -flto=thin -fuse-ld=lld -L . -l"name-of-your-rust-lib" -o main -O2 ./cmain.o
Using cargo
:
# Compile the Rust staticlib
RUSTFLAGS="-Clinker-plugin-lto" cargo build --release
# Compile the C code with `-flto=thin`
clang -c -O2 -flto=thin -o cmain.o ./cmain.c
# Link everything, making sure that we use an appropriate linker
clang -flto=thin -fuse-ld=lld -L . -l"name-of-your-rust-lib" -o main -O2 ./cmain.o
C/C++ code as a dependency in Rust
In this case the linker will be invoked by rustc
. We again have to make sure
that an appropriate linker is used.
Using rustc
directly:
# Compile C code with `-flto`
clang ./clib.c -flto=thin -c -o ./clib.o -O2
# Create a static library from the C code
ar crus ./libxyz.a ./clib.o
# Invoke `rustc` with the additional arguments
rustc -Clinker-plugin-lto -L. -Copt-level=2 -Clinker=clang -Clink-arg=-fuse-ld=lld ./main.rs
Using cargo
directly:
# Compile C code with `-flto`
clang ./clib.c -flto=thin -c -o ./clib.o -O2
# Create a static library from the C code
ar crus ./libxyz.a ./clib.o
# Set the linking arguments via RUSTFLAGS
RUSTFLAGS="-Clinker-plugin-lto -Clinker=clang -Clink-arg=-fuse-ld=lld" cargo build --release
Explicitly specifying the linker plugin to be used by rustc
If one wants to use a linker other than LLD, the LLVM linker plugin has to be
specified explicitly. Otherwise the linker cannot read the object files. The
path to the plugin is passed as an argument to the -Clinker-plugin-lto
option:
rustc -Clinker-plugin-lto="/path/to/LLVMgold.so" -L. -Copt-level=2 ./main.rs
Usage with clang-cl and x86_64-pc-windows-msvc
Cross language LTO can be used with the x86_64-pc-windows-msvc target, but this requires using the clang-cl compiler instead of the MSVC cl.exe included with Visual Studio Build Tools, and linking with lld-link. Both clang-cl and lld-link can be downloaded from LLVM's download page. Note that most crates in the ecosystem are likely to assume you are using cl.exe if using this target and that some things, like for example vcpkg, don't work very well with clang-cl.
You will want to make sure your rust major LLVM version matches your installed LLVM tooling version, otherwise it is likely you will get linker errors:
rustc -V --verbose
clang-cl --version
If you are compiling any proc-macros, you will get this error:
error: Linker plugin based LTO is not supported together with `-C prefer-dynamic` when
targeting Windows-like targets
This is fixed if you explicitly set the target, for example
cargo build --target x86_64-pc-windows-msvc
Without an explicit --target the flags will be passed to all compiler invocations (including build
scripts and proc macros), see cargo docs on rustflags
If you have dependencies using the cc
crate, you will need to set these
environment variables:
set CC=clang-cl
set CXX=clang-cl
set CFLAGS=/clang:-flto=thin /clang:-fuse-ld=lld-link
set CXXFLAGS=/clang:-flto=thin /clang:-fuse-ld=lld-link
REM Needed because msvc's lib.exe crashes on LLVM LTO .obj files
set AR=llvm-lib
If you are specifying lld-link as your linker by setting linker = "lld-link.exe"
in your cargo config,
you may run into issues with some crates that compile code with separate cargo invocations. You should be
able to get around this problem by setting -Clinker=lld-link
in RUSTFLAGS
Toolchain Compatibility
In order for this kind of LTO to work, the LLVM linker plugin must be able to
handle the LLVM bitcode produced by both rustc
and clang
.
Best results are achieved by using a rustc
and clang
that are based on the
exact same version of LLVM. One can use rustc -vV
in order to view the LLVM
used by a given rustc
version. Note that the version number given
here is only an approximation as Rust sometimes uses unstable revisions of
LLVM. However, the approximation is usually reliable.
The following table shows known good combinations of toolchain versions.
Rust Version | Clang Version |
---|---|
Rust 1.34 | Clang 8 |
Rust 1.35 | Clang 8 |
Rust 1.36 | Clang 8 |
Rust 1.37 | Clang 8 |
Rust 1.38 | Clang 9 |
Rust 1.39 | Clang 9 |
Rust 1.40 | Clang 9 |
Rust 1.41 | Clang 9 |
Rust 1.42 | Clang 9 |
Rust 1.43 | Clang 9 |
Rust 1.44 | Clang 9 |
Rust 1.45 | Clang 10 |
Rust 1.46 | Clang 10 |
Rust 1.47 | Clang 11 |
Rust 1.48 | Clang 11 |
Rust 1.49 | Clang 11 |
Rust 1.50 | Clang 11 |
Rust 1.51 | Clang 11 |
Rust 1.52 | Clang 12 |
Rust 1.53 | Clang 12 |
Rust 1.54 | Clang 12 |
Rust 1.55 | Clang 12 |
Rust 1.56 | Clang 13 |
Rust 1.57 | Clang 13 |
Rust 1.58 | Clang 13 |
Rust 1.59 | Clang 13 |
Rust 1.60 | Clang 14 |
Note that the compatibility policy for this feature might change in the future.
Exploit Mitigations
This chapter documents the exploit mitigations supported by the Rust compiler, and is by no means an extensive survey of the Rust programming language’s security features.
This chapter is for software engineers working with the Rust programming language, and assumes prior knowledge of the Rust programming language and its toolchain.
Introduction
The Rust programming language provides memory[1] and thread[2] safety guarantees via its ownership[3], references and borrowing[4], and slice types[5] features. However, Unsafe Rust[6] introduces unsafe blocks, unsafe functions and methods, unsafe traits, and new types that are not subject to the borrowing rules.
Parts of the Rust standard library are implemented as safe abstractions over unsafe code (and historically have been vulnerable to memory corruption[7]). Furthermore, the Rust code and documentation encourage creating safe abstractions over unsafe code. This can cause a false sense of security if unsafe code is not properly reviewed and tested.
Unsafe Rust introduces features that do not provide the same memory and thread safety guarantees. This causes programs or libraries to be susceptible to memory corruption (CWE-119)[8] and concurrency issues (CWE-557)[9]. Modern C and C++ compilers provide exploit mitigations to increase the difficulty to exploit vulnerabilities resulting from these issues. Therefore, the Rust compiler must also support these exploit mitigations in order to mitigate vulnerabilities resulting from the use of Unsafe Rust. This chapter documents these exploit mitigations and how they apply to Rust.
This chapter does not discuss the effectiveness of these exploit mitigations as they vary greatly depending on several factors besides their design and implementation, but rather describe what they do, so their effectiveness can be understood within a given context.
Exploit mitigations
This section documents the exploit mitigations applicable to the Rust compiler when building programs for the Linux operating system on the AMD64 architecture and equivalent.1
The Rust Programming Language currently has no specification. The Rust compiler (i.e., rustc) is the language reference implementation. All references to “the Rust compiler” in this chapter refer to the language reference implementation.
Table I
Summary of exploit mitigations supported by the Rust compiler when building
programs for the Linux operating system on the AMD64 architecture and
equivalent.
Exploit mitigation | Supported and enabled by default | Since |
Position-independent executable | Yes | 0.12.0 (2014-10-09) |
Integer overflow checks | Yes (enabled when debug assertions are enabled, and disabled when debug assertions are disabled) | 1.1.0 (2015-06-25) |
Non-executable memory regions | Yes | 1.8.0 (2016-04-14) |
Stack clashing protection | Yes | 1.20.0 (2017-08-31) |
Read-only relocations and immediate binding | Yes | 1.21.0 (2017-10-12) |
Heap corruption protection | Yes | 1.32.0 (2019-01-17) (via operating system default or specified allocator) |
Stack smashing protection | No | |
Forward-edge control flow protection | Yes | Nightly |
Backward-edge control flow protection (e.g., shadow and safe stack) | No |
1. See https://github.com/rust-lang/rust/tree/master/compiler/rustc_target/src/spec for a list of targets and their default options. ↩
Position-independent executable
Position-independent executable increases the difficulty of the use of code reuse exploitation techniques, such as return-oriented programming (ROP) and variants, by generating position-independent code for the executable, and instructing the dynamic linker to load it similarly to a shared object at a random load address, thus also benefiting from address-space layout randomization (ASLR). This is also referred to as “full ASLR”.
The Rust compiler supports position-independent executable, and enables it by default since version 0.12.0 (2014-10-09)[10]–[13].
$ readelf -h target/release/hello-rust | grep Type:
Type: DYN (Shared object file)
Fig. 1. Checking if an executable is a position-independent executable.
An executable with an object type of ET_DYN
(i.e., shared object) and not
ET_EXEC
(i.e., executable) is a position-independent executable (see Fig.
1).
Integer overflow checks
Integer overflow checks protects programs from undefined and unintended behavior (which may cause vulnerabilities) by checking for results of signed and unsigned integer computations that cannot be represented in their type, resulting in an overflow or wraparound.
The Rust compiler supports integer overflow checks, and enables it when debug assertions are enabled since version 1.1.0 (2015-06-25)[14]–[20].
fn main() {
let u: u8 = 255;
println!("u: {}", u + 1);
}
Fig. 2. hello-rust-integer program.
$ cargo run
Compiling hello-rust-integer v0.1.0 (/home/rcvalle/hello-rust-integer)
Finished dev [unoptimized + debuginfo] target(s) in 0.23s
Running `target/debug/hello-rust-integer`
thread 'main' panicked at 'attempt to add with overflow', src/main.rs:3:23
note: run with `RUST_BACKTRACE=1` environment variable to display a backtrace.
Fig. 3. Build and execution of hello-rust-integer with debug assertions enabled.
$ cargo run --release
Compiling hello-rust-integer v0.1.0 (/home/rcvalle/hello-rust-integer)
Finished release [optimized] target(s) in 0.23s
Running `target/release/hello-rust-integer`
u: 0
Fig. 4. Build and execution of hello-rust-integer with debug assertions disabled.
Integer overflow checks are enabled when debug assertions are enabled (see
Fig. 3), and disabled when debug assertions are disabled (see Fig. 4). To
enable integer overflow checks independently, use the option to control
integer overflow checks, scoped attributes, or explicit checking methods
such as checked_add
2.
It is recommended that explicit wrapping methods such as wrapping_add
be
used when wrapping semantics are intended, and that explicit checking and
wrapping methods always be used when using Unsafe Rust.
2. See https://doc.rust-lang.org/std/primitive.u32.html for more information on the checked, overflowing, saturating, and wrapping methods (using u32 as an example). ↩
Non-executable memory regions
Non-executable memory regions increase the difficulty of exploitation by limiting the memory regions that can be used to execute arbitrary code. Most modern processors provide support for the operating system to mark memory regions as non executable, but it was previously emulated by software, such as in grsecurity/PaX's PAGEEXEC and SEGMEXEC, on processors that did not provide support for it. This is also known as “No Execute (NX) Bit”, “Execute Disable (XD) Bit”, “Execute Never (XN) Bit”, and others.
The Rust compiler supports non-executable memory regions, and enables it by default since its initial release, version 0.1 (2012-01-20)[21], [22], but has regressed since then[23]–[25], and enforced by default since version 1.8.0 (2016-04-14)[25].
$ readelf -l target/release/hello-rust | grep -A 1 GNU_STACK
GNU_STACK 0x0000000000000000 0x0000000000000000 0x0000000000000000
0x0000000000000000 0x0000000000000000 RW 0x10
Fig. 5. Checking if non-executable memory regions are enabled for a given binary.
The presence of an element of type PT_GNU_STACK
in the program header
table with the PF_X
(i.e., executable) flag unset indicates non-executable
memory regions3 are enabled for a given binary (see Fig. 5).
Conversely, the presence of an element of type PT_GNU_STACK
in the program
header table with the PF_X
flag set or the absence of an element of type
PT_GNU_STACK
in the program header table indicates non-executable memory
regions are not enabled for a given binary.
3. See the Appendix section for more information on why it affects other memory regions besides the stack. ↩
Stack clashing protection
Stack clashing protection protects the stack from overlapping with another memory region—allowing arbitrary data in both to be overwritten using each other—by reading from the stack pages as the stack grows to cause a page fault when attempting to read from the guard page/region. This is also referred to as “stack probes” or “stack probing”.
The Rust compiler supports stack clashing protection via stack probing, and enables it by default since version 1.20.0 (2017-08-31)[26]–[29].
Fig. 6. IDA Pro listing cross references to __rust_probestack
in
hello-rust.
fn hello() { println!("Hello, world!"); } fn main() { let _: [u64; 1024] = [0; 1024]; hello(); }
Fig 7. Modified hello-rust.
Fig. 8. IDA Pro listing cross references to __rust_probestack
in modified
hello-rust.
To check if stack clashing protection is enabled for a given binary, search
for cross references to __rust_probestack
. The __rust_probestack
is
called in the prologue of functions whose stack size is larger than a page
size (see Fig. 6), and can be forced for illustration purposes by modifying
the hello-rust example as seen in Fig. 7 and Fig. 8.
Read-only relocations and immediate binding
Read-only relocations protect segments containing relocations and
relocation information (i.e., .init_array
, .fini_array
, .dynamic
, and
.got
) from being overwritten by marking these segments read only. This is
also referred to as “partial RELRO”.
The Rust compiler supports read-only relocations, and enables it by default since version 1.21.0 (2017-10-12)[30], [31].
$ readelf -l target/release/hello-rust | grep GNU_RELRO
GNU_RELRO 0x000000000002ee00 0x000000000002fe00 0x000000000002fe00
Fig. 9. Checking if read-only relocations is enabled for a given binary.
The presence of an element of type PT_GNU_RELRO
in the program header
table indicates read-only relocations are enabled for a given binary (see
Fig. 9). Conversely, the absence of an element of type PT_GNU_RELRO
in the
program header table indicates read-only relocations are not enabled for a
given binary.
Immediate binding protects additional segments containing relocations
(i.e., .got.plt
) from being overwritten by instructing the dynamic linker
to perform all relocations before transferring control to the program during
startup, so all segments containing relocations can be marked read only
(when combined with read-only relocations). This is also referred to as
“full RELRO”.
The Rust compiler supports immediate binding, and enables it by default since version 1.21.0 (2017-10-12)[30], [31].
$ readelf -d target/release/hello-rust | grep BIND_NOW
0x000000000000001e (FLAGS) BIND_NOW
Fig. 10. Checking if immediate binding is enabled for a given binary.
The presence of an element with the DT_BIND_NOW
tag and the DF_BIND_NOW
flag4 in the dynamic section indicates immediate
binding is enabled for a given binary (see Fig. 10). Conversely, the absence
of an element with the DT_BIND_NOW
tag and the DF_BIND_NOW
flag in the
dynamic section indicates immediate binding is not enabled for a given
binary.
The presence of both an element of type PT_GNU_RELRO
in the program header
table and of an element with the DT_BIND_NOW
tag and the DF_BIND_NOW
flag in the dynamic section indicates full RELRO is enabled for a given
binary (see Fig. 9 and Fig. 10).
4. And the DF_1_NOW
flag for some link editors. ↩
Heap corruption protection
Heap corruption protection protects memory allocated dynamically by performing several checks, such as checks for corrupted links between list elements, invalid pointers, invalid sizes, double/multiple “frees” of the same memory allocated, and many corner cases of these. These checks are implementation specific, and vary per allocator.
ARM Memory Tagging Extension (MTE), when available, will provide hardware assistance for a probabilistic mitigation to detect memory safety violations by tagging memory allocations, and automatically checking that the correct tag is used on every memory access.
Rust’s default allocator has historically been jemalloc, and it has long been the cause of issues and the subject of much discussion[32]–[38]. Consequently, it has been removed as the default allocator in favor of the operating system’s standard C library default allocator5 since version 1.32.0 (2019-01-17)[39].
fn main() { let mut x = Box::new([0; 1024]); for i in 0..1026 { unsafe { let elem = x.get_unchecked_mut(i); *elem = 0x4141414141414141u64; } } }
Fig. 11. hello-rust-heap program.
$ cargo run
Compiling hello-rust-heap v0.1.0 (/home/rcvalle/hello-rust-heap)
Finished dev [unoptimized + debuginfo] target(s) in 0.25s
Running `target/debug/hello-rust-heap`
free(): invalid next size (normal)
Aborted
Fig. 12. Build and execution of hello-rust-heap with debug assertions enabled.
$ cargo run --release
Compiling hello-rust-heap v0.1.0 (/home/rcvalle/hello-rust-heap)
Finished release [optimized] target(s) in 0.25s
Running `target/release/hello-rust-heap`
free(): invalid next size (normal)
Aborted
Fig. 13. Build and execution of hello-rust-heap with debug assertions disabled.
Heap corruption checks are being performed when using the default allocator (i.e., the GNU Allocator) as seen in Fig. 12 and Fig. 13.
5. Linux's standard C library default allocator is the GNU Allocator, which is derived from ptmalloc (pthreads malloc) by Wolfram Gloger, which in turn is derived from dlmalloc (Doug Lea malloc) by Doug Lea. ↩
Stack smashing protection
Stack smashing protection protects programs from stack-based buffer overflows by inserting a random guard value between local variables and the saved return instruction pointer, and checking if this value has changed when returning from a function. This is also known as “Stack Protector” or “Stack Smashing Protector (SSP)”.
The Rust compiler does not support stack smashing protection. However, more comprehensive alternatives to stack smashing protection exist, such as shadow and safe stack (see backward-edge control flow protection).
Fig. 14. IDA Pro listing cross references to __stack_chk_fail
in
hello-rust.
To check if stack smashing protection is enabled for a given binary, search
for cross references to __stack_chk_fail
. The only cross references to
__stack_chk_fail
in hello-rust are from the statically-linked libbacktrace
library (see Fig. 14).
Forward-edge control flow protection
Forward-edge control flow protection protects programs from having its control flow changed/hijacked by performing checks to ensure that destinations of indirect branches are one of their valid destinations in the control flow graph. The comprehensiveness of these checks vary per implementation. This is also known as “forward-edge control flow integrity (CFI)”.
Newer processors provide hardware assistance for forward-edge control flow protection, such as ARM Branch Target Identification (BTI), ARM Pointer Authentication, and Intel Indirect Branch Tracking (IBT) as part of Intel Control-flow Enforcement Technology (CET). However, ARM BTI and Intel IBT -based implementations are less comprehensive than software-based implementations such as LLVM ControlFlowIntegrity (CFI), and the commercially available grsecurity/PaX Reuse Attack Protector (RAP).
The Rust compiler supports forward-edge control flow protection on nightly builds[40]-[41] 6.
$ readelf -s -W target/debug/rust-cfi | grep "\.cfi"
12: 0000000000005170 46 FUNC LOCAL DEFAULT 14 _RNvCsjaOHoaNjor6_8rust_cfi7add_one.cfi
15: 00000000000051a0 16 FUNC LOCAL DEFAULT 14 _RNvCsjaOHoaNjor6_8rust_cfi7add_two.cfi
17: 0000000000005270 396 FUNC LOCAL DEFAULT 14 _RNvCsjaOHoaNjor6_8rust_cfi4main.cfi
...
Fig. 15. Checking if LLVM CFI is enabled for a given binary[41].
The presence of symbols suffixed with ".cfi" or the __cfi_init
symbol (and
references to __cfi_check
) indicates that LLVM CFI (i.e., forward-edge control
flow protection) is enabled for a given binary. Conversely, the absence of
symbols suffixed with ".cfi" or the __cfi_init
symbol (and references to
__cfi_check
) indicates that LLVM CFI is not enabled for a given binary (see
Fig. 15).
6. It also supports Control Flow Guard (CFG) on Windows (see https://github.com/rust-lang/rust/issues/68793). ↩
Backward-edge control flow protection
Shadow stack protects saved return instruction pointers from being overwritten by storing a copy of them on a separate (shadow) stack, and using these copies as authoritative values when returning from functions. This is also known as “ShadowCallStack” and “Return Flow Guard”, and is considered an implementation of backward-edge control flow protection (or “backward-edge CFI”).
Safe stack protects not only the saved return instruction pointers, but also register spills and some local variables from being overwritten by storing unsafe variables, such as large arrays, on a separate (unsafe) stack, and using these unsafe variables on the separate stack instead. This is also known as “SafeStack”, and is also considered an implementation of backward-edge control flow protection.
Both shadow and safe stack are intended to be a more comprehensive alternatives to stack smashing protection as they protect the saved return instruction pointers (and other data in the case of safe stack) from arbitrary writes and non-linear out-of-bounds writes.
Newer processors provide hardware assistance for backward-edge control flow protection, such as ARM Pointer Authentication, and Intel Shadow Stack as part of Intel CET.
The Rust compiler does not support shadow or safe stack. There is work currently ongoing to add support for the sanitizers[40], which may or may not include support for safe stack7.
$ readelf -s target/release/hello-rust | grep __safestack_init
Fig. 16. Checking if LLVM SafeStack is enabled for a given binary.
The presence of the __safestack_init
symbol indicates that LLVM SafeStack
is enabled for a given binary. Conversely, the absence of the
__safestack_init
symbol indicates that LLVM SafeStack is not enabled for a
given binary (see Fig. 16).
7. The shadow stack implementation for the AMD64 architecture and equivalent in LLVM was removed due to performance and security issues. ↩
Appendix
As of the latest version of the Linux Standard Base (LSB) Core
Specification,
the PT_GNU_STACK
program header indicates whether the stack should be
executable, and the absence of this header indicates that the stack should
be executable. However, the Linux kernel currently sets the
READ_IMPLIES_EXEC
personality upon loading any executable with the
PT_GNU_STACK
program header and the PF_X
flag set or with the absence of
this header, resulting in not only the stack, but also all readable virtual
memory mappings being executable.
An attempt to fix this was made in
2012,
and another was made in
2020.
The former never landed, and the latter partially fixed it, but introduced
other issues—the absence of the PT_GNU_STACK
program header still causes
not only the stack, but also all readable virtual memory mappings to be
executable in some architectures, such as IA-32 and equivalent (or causes
the stack to be non-executable in some architectures, such as AMD64 and
equivalent, contradicting the LSB).
The READ_IMPLIES_EXEC
personality needs to be completely separated from
the PT_GNU_STACK
program header by having a separate option for it (or
setarch -X could just be used whenever READ_IMPLIES_EXEC
is needed), and
the absence of the PT_GNU_STACK
program header needs to have more secure
defaults (unrelated to READ_IMPLIES_EXEC
).
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Contributing to rustc
We'd love to have your help improving rustc
! To that end, we've written a
whole book on its
internals, how it works, and how to get started working on it. To learn
more, you'll want to check that out.
If you would like to contribute to this book, you can find its source in the rustc source at src/doc/rustc.