Linkage
Note: This section is described more in terms of the compiler than of the language.
The compiler supports various methods to link crates together both statically and dynamically. This section will explore the various methods to link crates together, and more information about native libraries can be found in the FFI section of the book.
In one session of compilation, the compiler can generate multiple artifacts
through the usage of either command line flags or the crate_type
attribute.
If one or more command line flags are specified, all crate_type
attributes will
be ignored in favor of only building the artifacts specified by command line.
-
--crate-type=bin
,#[crate_type = "bin"]
- A runnable executable will be produced. This requires that there is amain
function in the crate which will be run when the program begins executing. This will link in all Rust and native dependencies, producing a distributable binary. -
--crate-type=lib
,#[crate_type = "lib"]
- A Rust library will be produced. This is an ambiguous concept as to what exactly is produced because a library can manifest itself in several forms. The purpose of this genericlib
option is to generate the "compiler recommended" style of library. The output library will always be usable by rustc, but the actual type of library may change from time-to-time. The remaining output types are all different flavors of libraries, and thelib
type can be seen as an alias for one of them (but the actual one is compiler-defined). -
--crate-type=dylib
,#[crate_type = "dylib"]
- A dynamic Rust library will be produced. This is different from thelib
output type in that this forces dynamic library generation. The resulting dynamic library can be used as a dependency for other libraries and/or executables. This output type will create*.so
files on linux,*.dylib
files on osx, and*.dll
files on windows. -
--crate-type=staticlib
,#[crate_type = "staticlib"]
- A static system library will be produced. This is different from other library outputs in that the compiler will never attempt to link tostaticlib
outputs. The purpose of this output type is to create a static library containing all of the local crate's code along with all upstream dependencies. The static library is actually a*.a
archive on linux and osx and a*.lib
file on windows. This format is recommended for use in situations such as linking Rust code into an existing non-Rust application because it will not have dynamic dependencies on other Rust code. -
--crate-type=cdylib
,#[crate_type = "cdylib"]
- A dynamic system library will be produced. This is used when compiling a dynamic library to be loaded from another language. This output type will create*.so
files on Linux,*.dylib
files on macOS, and*.dll
files on Windows. -
--crate-type=rlib
,#[crate_type = "rlib"]
- A "Rust library" file will be produced. This is used as an intermediate artifact and can be thought of as a "static Rust library". Theserlib
files, unlikestaticlib
files, are interpreted by the compiler in future linkage. This essentially means thatrustc
will look for metadata inrlib
files like it looks for metadata in dynamic libraries. This form of output is used to produce statically linked executables as well asstaticlib
outputs. -
--crate-type=proc-macro
,#[crate_type = "proc-macro"]
- The output produced is not specified, but if a-L
path is provided to it then the compiler will recognize the output artifacts as a macro and it can be loaded for a program. Crates compiled with this crate type must only export procedural macros. The compiler will automatically set theproc_macro
configuration option. The crates are always compiled with the same target that the compiler itself was built with. For example, if you are executing the compiler from Linux with anx86_64
CPU, the target will bex86_64-unknown-linux-gnu
even if the crate is a dependency of another crate being built for a different target.
Note that these outputs are stackable in the sense that if multiple are
specified, then the compiler will produce each form of output at once without
having to recompile. However, this only applies for outputs specified by the
same method. If only crate_type
attributes are specified, then they will all
be built, but if one or more --crate-type
command line flags are specified,
then only those outputs will be built.
With all these different kinds of outputs, if crate A depends on crate B, then
the compiler could find B in various different forms throughout the system. The
only forms looked for by the compiler, however, are the rlib
format and the
dynamic library format. With these two options for a dependent library, the
compiler must at some point make a choice between these two formats. With this
in mind, the compiler follows these rules when determining what format of
dependencies will be used:
-
If a static library is being produced, all upstream dependencies are required to be available in
rlib
formats. This requirement stems from the reason that a dynamic library cannot be converted into a static format.Note that it is impossible to link in native dynamic dependencies to a static library, and in this case warnings will be printed about all unlinked native dynamic dependencies.
-
If an
rlib
file is being produced, then there are no restrictions on what format the upstream dependencies are available in. It is simply required that all upstream dependencies be available for reading metadata from.The reason for this is that
rlib
files do not contain any of their upstream dependencies. It wouldn't be very efficient for allrlib
files to contain a copy oflibstd.rlib
! -
If an executable is being produced and the
-C prefer-dynamic
flag is not specified, then dependencies are first attempted to be found in therlib
format. If some dependencies are not available in an rlib format, then dynamic linking is attempted (see below). -
If a dynamic library or an executable that is being dynamically linked is being produced, then the compiler will attempt to reconcile the available dependencies in either the rlib or dylib format to create a final product.
A major goal of the compiler is to ensure that a library never appears more than once in any artifact. For example, if dynamic libraries B and C were each statically linked to library A, then a crate could not link to B and C together because there would be two copies of A. The compiler allows mixing the rlib and dylib formats, but this restriction must be satisfied.
The compiler currently implements no method of hinting what format a library should be linked with. When dynamically linking, the compiler will attempt to maximize dynamic dependencies while still allowing some dependencies to be linked in via an rlib.
For most situations, having all libraries available as a dylib is recommended if dynamically linking. For other situations, the compiler will emit a warning if it is unable to determine which formats to link each library with.
In general, --crate-type=bin
or --crate-type=lib
should be sufficient for
all compilation needs, and the other options are just available if more
fine-grained control is desired over the output format of a crate.
Static and dynamic C runtimes
The standard library in general strives to support both statically linked and
dynamically linked C runtimes for targets as appropriate. For example the
x86_64-pc-windows-msvc
and x86_64-unknown-linux-musl
targets typically come
with both runtimes and the user selects which one they'd like. All targets in
the compiler have a default mode of linking to the C runtime. Typically targets
are linked dynamically by default, but there are exceptions which are static by
default such as:
arm-unknown-linux-musleabi
arm-unknown-linux-musleabihf
armv7-unknown-linux-musleabihf
i686-unknown-linux-musl
x86_64-unknown-linux-musl
The linkage of the C runtime is configured to respect the crt-static
target
feature. These target features are typically configured from the command line
via flags to the compiler itself. For example to enable a static runtime you
would execute:
rustc -C target-feature=+crt-static foo.rs
whereas to link dynamically to the C runtime you would execute:
rustc -C target-feature=-crt-static foo.rs
Targets which do not support switching between linkage of the C runtime will ignore this flag. It's recommended to inspect the resulting binary to ensure that it's linked as you would expect after the compiler succeeds.
Crates may also learn about how the C runtime is being linked. Code on MSVC, for
example, needs to be compiled differently (e.g. with /MT
or /MD
) depending
on the runtime being linked. This is exported currently through the
cfg
attribute target_feature
option:
#[cfg(target_feature = "crt-static")]
fn foo() {
println!("the C runtime should be statically linked");
}
#[cfg(not(target_feature = "crt-static"))]
fn foo() {
println!("the C runtime should be dynamically linked");
}
Also note that Cargo build scripts can learn about this feature through environment variables. In a build script you can detect the linkage via:
use std::env; fn main() { let linkage = env::var("CARGO_CFG_TARGET_FEATURE").unwrap_or(String::new()); if linkage.contains("crt-static") { println!("the C runtime will be statically linked"); } else { println!("the C runtime will be dynamically linked"); } }
To use this feature locally, you typically will use the RUSTFLAGS
environment
variable to specify flags to the compiler through Cargo. For example to compile
a statically linked binary on MSVC you would execute:
RUSTFLAGS='-C target-feature=+crt-static' cargo build --target x86_64-pc-windows-msvc