Cargo Targets
Cargo packages consist of targets which correspond to source files which can
be compiled into a crate. Packages can have library,
binary, example, test, and
benchmark targets. The list of targets can be configured in the
Cargo.toml
manifest, often inferred automatically
by the directory layout of the source files.
See Configuring a target below for details on configuring the settings for a target.
Library
The library target defines a "library" that can be used and linked by other
libraries and executables. The filename defaults to src/lib.rs
, and the name
of the library defaults to the name of the package. A package can have only
one library. The settings for the library can be customized in the [lib]
table in Cargo.toml
.
# Example of customizing the library in Cargo.toml.
[lib]
crate-type = ["cdylib"]
bench = false
Binaries
Binary targets are executables programs that can be run after being compiled.
The default binary filename is src/main.rs
, which defaults to the name of
the package. Additional binaries are stored in the src/bin/
directory. The settings for each binary can be customized
in the [[bin]]
tables in Cargo.toml
.
Binaries can use the public API of the package's library. They are also linked
with the [dependencies]
defined in Cargo.toml
.
You can run individual binaries with the cargo run
command with the --bin <bin-name>
option. cargo install
can be used to copy the executable to a
common location.
# Example of customizing binaries in Cargo.toml.
[[bin]]
name = "cool-tool"
test = false
bench = false
[[bin]]
name = "frobnicator"
required-features = ["frobnicate"]
Examples
Files located under the examples
directory are example
uses of the functionality provided by the library. When compiled, they are
placed in the target/debug/examples
directory.
Examples can use the public API of the package's library. They are also linked
with the [dependencies]
and
[dev-dependencies]
defined in Cargo.toml
.
By default, examples are executable binaries (with a main()
function). You
can specify the crate-type
field to make an example
be compiled as a library:
[[example]]
name = "foo"
crate-type = ["staticlib"]
You can run individual executable examples with the cargo run
command with
the --example <example-name>
option. Library examples can be built with
cargo build
with the --example <example-name>
option. cargo install
with the --example <example-name>
option can be used to copy executable
binaries to a common location. Examples are compiled by cargo test
by
default to protect them from bit-rotting. Set the test
field to true
if you have #[test]
functions in the
example that you want to run with cargo test
.
Tests
There are two styles of tests within a Cargo project:
- Unit tests which are functions marked with the
#[test]
attribute located within your library or binaries (or any target enabled with thetest
field). These tests have access to private APIs located within the target they are defined in. - Integration tests which is a separate executable binary, also containing
#[test]
functions, which is linked with the project's library and has access to its public API.
Tests are run with the cargo test
command. By default, Cargo and rustc
use the libtest harness which is responsible for collecting functions
annotated with the #[test]
attribute and executing them in
parallel, reporting the success and failure of each test. See the harness
field if you want to use a different harness or test
strategy.
Integration tests
Files located under the tests
directory are integration
tests. When you run cargo test
, Cargo will compile each of these files as
a separate crate, and execute them.
Integration tests can use the public API of the package's library. They are
also linked with the [dependencies]
and
[dev-dependencies]
defined in Cargo.toml
.
If you want to share code among multiple integration tests, you can place it
in a separate module such as tests/common/mod.rs
and then put mod common;
in each test to import it.
Each integration test results in a separate executable binary, and cargo test
will run them serially. In some cases this can be inefficient, as it
can take longer to compile, and may not make full use of multiple CPUs when
running the tests. If you have a lot of integration tests, you may want to
consider creating a single integration test, and split the tests into multiple
modules. The libtest harness will automatically find all of the #[test]
annotated functions and run them in parallel. You can pass module names to
cargo test
to only run the tests within that module.
Binary targets are automatically built if there is an integration test. This
allows an integration test to execute the binary to exercise and test its
behavior. The CARGO_BIN_EXE_<name>
environment variable is set when the
integration test is built so that it can use the env
macro to locate the
executable.
Benchmarks
Benchmarks provide a way to test the performance of your code using the
cargo bench
command. They follow the same structure as tests,
with each benchmark function annotated with the #[bench]
attribute.
Similarly to tests:
- Benchmarks are placed in the
benches
directory. - Benchmark functions defined in libraries and binaries have access to the
private API within the target they are defined in. Benchmarks in the
benches
directory may use the public API. - The
bench
field can be used to define which targets are benchmarked by default. - The
harness
field can be used to disable the built-in harness.
Note: The
#[bench]
attribute is currently unstable and only available on the nightly channel. There are some packages available on crates.io that may help with running benchmarks on the stable channel, such as Criterion.
Configuring a target
All of the [lib]
, [[bin]]
, [[example]]
, [[test]]
, and [[bench]]
sections in Cargo.toml
support similar configuration for specifying how a
target should be built. The double-bracket sections like [[bin]]
are
array-of-table of TOML,
which means you can write more than one [[bin]]
section to make several
executables in your crate. You can only specify one library, so [lib]
is a
normal TOML table.
The following is an overview of the TOML settings for each target, with each field described in detail below.
[lib]
name = "foo" # The name of the target.
path = "src/lib.rs" # The source file of the target.
test = true # Is tested by default.
doctest = true # Documentation examples are tested by default.
bench = true # Is benchmarked by default.
doc = true # Is documented by default.
plugin = false # Used as a compiler plugin (deprecated).
proc-macro = false # Set to `true` for a proc-macro library.
harness = true # Use libtest harness.
edition = "2015" # The edition of the target.
crate-type = ["lib"] # The crate types to generate.
required-features = [] # Features required to build this target (N/A for lib).
The name
field
The name
field specifies the name of the target, which corresponds to the
filename of the artifact that will be generated. For a library, this is the
crate name that dependencies will use to reference it.
For the [lib]
and the default binary (src/main.rs
), this defaults to the
name of the package, with any dashes replaced with underscores. For other
auto discovered targets, it defaults to the
directory or file name.
This is required for all targets except [lib]
.
The path
field
The path
field specifies where the source for the crate is located, relative
to the Cargo.toml
file.
If not specified, the inferred path is used based on the target name.
The test
field
The test
field indicates whether or not the target is tested by default by
cargo test
. The default is true
for lib, bins, and tests.
Note: Examples are built by
cargo test
by default to ensure they continue to compile, but they are not tested by default. Settingtest = true
for an example will also build it as a test and run any#[test]
functions defined in the example.
The doctest
field
The doctest
field indicates whether or not documentation examples are
tested by default by cargo test
. This is only relevant for libraries, it
has no effect on other sections. The default is true
for the library.
The bench
field
The bench
field indicates whether or not the target is benchmarked by
default by cargo bench
. The default is true
for lib, bins, and
benchmarks.
The doc
field
The doc
field indicates whether or not the target is included in the
documentation generated by cargo doc
by default. The default is true
for
libraries and binaries.
Note: The binary will be skipped if its name is the same as the lib target.
The plugin
field
This field is used for rustc
plugins, which are being deprecated.
The proc-macro
field
The proc-macro
field indicates that the library is a procedural macro
(reference). This is only valid for the [lib]
target.
The harness
field
The harness
field indicates that the --test
flag will be passed to
rustc
which will automatically include the libtest library which is the
driver for collecting and running tests marked with the #[test]
attribute or benchmarks with the #[bench]
attribute. The
default is true
for all targets.
If set to false
, then you are responsible for defining a main()
function
to run tests and benchmarks.
Tests have the cfg(test)
conditional expression enabled whether
or not the harness is enabled.
The edition
field
The edition
field defines the Rust edition the target will use. If not
specified, it defaults to the edition
field for the
[package]
. This field should usually not be set, and is only intended for
advanced scenarios such as incrementally transitioning a large package to a
new edition.
The crate-type
field
The crate-type
field defines the crate types that will be generated by the
target. It is an array of strings, allowing you to specify multiple crate
types for a single target. This can only be specified for libraries and
examples. Binaries, tests, and benchmarks are always the "bin" crate type. The
defaults are:
Target | Crate Type |
---|---|
Normal library | "lib" |
Proc-macro library | "proc-macro" |
Example | "bin" |
The available options are bin
, lib
, rlib
, dylib
, cdylib
,
staticlib
, and proc-macro
. You can read more about the different crate
types in the Rust Reference Manual.
The required-features
field
The required-features
field specifies which features the target needs in
order to be built. If any of the required features are not enabled, the
target will be skipped. This is only relevant for the [[bin]]
, [[bench]]
,
[[test]]
, and [[example]]
sections, it has no effect on [lib]
.
[features]
# ...
postgres = []
sqlite = []
tools = []
[[bin]]
name = "my-pg-tool"
required-features = ["postgres", "tools"]
Target auto-discovery
By default, Cargo automatically determines the targets to build based on the
layout of the files on the filesystem. The target
configuration tables, such as [lib]
, [[bin]]
, [[test]]
, [[bench]]
, or
[[example]]
, can be used to add additional targets that don't follow the
standard directory layout.
The automatic target discovery can be disabled so that only manually
configured targets will be built. Setting the keys autobins
, autoexamples
,
autotests
, or autobenches
to false
in the [package]
section will
disable auto-discovery of the corresponding target type.
[package]
# ...
autobins = false
autoexamples = false
autotests = false
autobenches = false
Disabling automatic discovery should only be needed for specialized
situations. For example, if you have a library where you want a module named
bin
, this would present a problem because Cargo would usually attempt to
compile anything in the bin
directory as an executable. Here is a sample
layout of this scenario:
├── Cargo.toml
└── src
├── lib.rs
└── bin
└── mod.rs
To prevent Cargo from inferring src/bin/mod.rs
as an executable, set
autobins = false
in Cargo.toml
to disable auto-discovery:
[package]
# …
autobins = false
Note: For packages with the 2015 edition, the default for auto-discovery is
false
if at least one target is manually defined inCargo.toml
. Beginning with the 2018 edition, the default is alwaystrue
.