The Manifest Format

The Cargo.toml file for each package is called its manifest. Every manifest file consists of one or more sections.

The [package] section

The first section in a Cargo.toml is [package].

name = "hello_world" # the name of the package
version = "0.1.0"    # the current version, obeying semver
authors = ["Alice <>", "Bob <>"]

The name field

The package name is an identifier used to refer to the package. It is used when listed as a dependency in another package, and as the default name of inferred lib and bin targets.

The name must not be empty, use only alphanumeric characters or - or _. Note that cargo new and cargo init impose some additional restrictions on the package name, such as enforcing that it is a valid Rust identifier and not a keyword. imposes even more restrictions, such as enforcing only ASCII characters, not a reserved name, not a special Windows name such as "nul", is not too long, etc.

The version field

Cargo bakes in the concept of Semantic Versioning, so make sure you follow some basic rules:

  • Before you reach 1.0.0, anything goes, but if you make breaking changes, increment the minor version. In Rust, breaking changes include adding fields to structs or variants to enums.
  • After 1.0.0, only make breaking changes when you increment the major version. Don’t break the build.
  • After 1.0.0, don’t add any new public API (no new pub anything) in patch-level versions. Always increment the minor version if you add any new pub structs, traits, fields, types, functions, methods or anything else.
  • Use version numbers with three numeric parts such as 1.0.0 rather than 1.0.

The authors field (optional)

The authors field lists people or organizations that are considered the "authors" of the package. The exact meaning is open to interpretation — it may list the original or primary authors, current maintainers, or owners of the package. These names will be listed on the crate's page on An optional email address may be included within angled brackets at the end of each author.

The edition field (optional)

You can opt in to a specific Rust Edition for your package with the edition key in Cargo.toml. If you don't specify the edition, it will default to 2015.

# ...
edition = '2018'

The edition key affects which edition your package is compiled with. Cargo will always generate packages via cargo new with the edition key set to the latest edition. Setting the edition key in [package] will affect all targets/crates in the package, including test suites, benchmarks, binaries, examples, etc.

The build field (optional)

This field specifies a file in the package root which is a build script for building native code. More information can be found in the build script guide.

# ...
build = ""

The links field (optional)

This field specifies the name of a native library that is being linked to. More information can be found in the links section of the build script guide.

# ...
links = "foo"
build = ""

The documentation field (optional)

This field specifies a URL to a website hosting the crate's documentation. If no URL is specified in the manifest file, will automatically link your crate to the corresponding page.

Documentation links from specific hosts are blacklisted. Hosts are added to the blacklist if they are known to not be hosting documentation and are possibly of malicious intent e.g., ad tracking networks. URLs from the following hosts are blacklisted:


Documentation URLs from blacklisted hosts will not appear on, and may be replaced by links.

The exclude and include fields (optional)

You can explicitly specify that a set of file patterns should be ignored or included for the purposes of packaging. The patterns specified in the exclude field identify a set of files that are not included, and the patterns in include specify files that are explicitly included.

The patterns should be gitignore-style patterns. Briefly:

  • foo matches any file or directory with the name foo anywhere in the package. This is equivalent to the pattern **/foo.
  • /foo matches any file or directory with the name foo only in the root of the package.
  • foo/ matches any directory with the name foo anywhere in the package.
  • Common glob patterns like *, ?, and [] are supported:
    • * matches zero or more characters except /. For example, *.html matches any file or directory with the .html extension anywhere in the package.
    • ? matches any character except /. For example, foo? matches food, but not foo.
    • [] allows for matching a range of characters. For example, [ab] matches either a or b. [a-z] matches letters a through z.
  • **/ prefix matches in any directory. For example, **/foo/bar matches the file or directory bar anywhere that is directly under directory foo.
  • /** suffix matches everything inside. For example, foo/** matches all files inside directory foo, including all files in subdirectories below foo.
  • /**/ matches zero or more directories. For example, a/**/b matches a/b, a/x/b, a/x/y/b, and so on.
  • ! prefix negates a pattern. For example, a pattern of src/**.rs and ! would match all files with the .rs extension inside the src directory, except for any file named

If git is being used for a package, the exclude field will be seeded with the gitignore settings from the repository.

# ...
exclude = ["build/**/*.o", "doc/**/*.html"]
# ...
include = ["src/**/*", "Cargo.toml"]

The options are mutually exclusive: setting include will override an exclude. Note that include must be an exhaustive list of files as otherwise necessary source files may not be included. The package's Cargo.toml is automatically included.

The include/exclude list is also used for change tracking in some situations. For targets built with rustdoc, it is used to determine the list of files to track to determine if the target should be rebuilt. If the package has a build script that does not emit any rerun-if-* directives, then the include/exclude list is used for tracking if the build script should be re-run if any of those files change.

The publish field (optional)

The publish field can be used to prevent a package from being published to a package registry (like by mistake, for instance to keep a package private in a company.

# ...
publish = false

The value many also be an array of strings which are registry names that are allowed to be published to.

# ...
publish = ["some-registry-name"]

The workspace field (optional)

The workspace field can be used to configure the workspace that this package will be a member of. If not specified this will be inferred as the first Cargo.toml with [workspace] upwards in the filesystem.

# ...
workspace = "path/to/workspace/root"

For more information, see the documentation for the workspace table below.

Package metadata

There are a number of optional metadata fields also accepted under the [package] section:

# ...

# A short blurb about the package. This is not rendered in any format when
# uploaded to (aka this is not markdown).
description = "..."

# These URLs point to more information about the package. These are
# intended to be webviews of the relevant data, not necessarily compatible
# with VCS tools and the like.
documentation = "..."
homepage = "..."
repository = "..."

# This points to a file under the package root (relative to this `Cargo.toml`).
# The contents of this file are stored and indexed in the registry.
# will render this file and place the result on the crate's page.
readme = "..."

# This is a list of up to five keywords that describe this crate. Keywords
# are searchable on, and you may choose any words that would
# help someone find this crate.
keywords = ["...", "..."]

# This is a list of up to five categories where this crate would fit.
# Categories are a fixed list available at, and
# they must match exactly.
categories = ["...", "..."]

# This is an SPDX 2.1 license expression for this package. Currently
# will validate the license provided against a whitelist of
# known license and exception identifiers from the SPDX license list
# 2.4. Parentheses are not currently supported.
# Multiple licenses can be separated with a `/`, although that usage
# is deprecated. Instead, use a license expression with AND and OR
# operators to get more explicit semantics.
license = "..."

# If a package is using a nonstandard license, then this key may be specified in
# lieu of the above key and must point to a file relative to this manifest
# (similar to the readme key).
license-file = "..."

# Optional specification of badges to be displayed on
# - The badges pertaining to build status that are currently available are
#   Appveyor, CircleCI, GitLab, Azure DevOps and TravisCI.
# - Available badges pertaining to code test coverage are Codecov and
#   Coveralls.
# - There are also maintenance-related badges based on
#   which state the issue resolution time, percent of open issues, and future
#   maintenance intentions.
# If a `repository` key is required, this refers to a repository in
# `user/repo` format.

# Appveyor: `repository` is required. `branch` is optional; default is `master`
# `service` is optional; valid values are `github` (default), `bitbucket`, and
# `gitlab`; `id` is optional; you can specify the appveyor project id if you
# want to use that instead. `project_name` is optional; use when the repository
# name differs from the appveyor project name.
appveyor = { repository = "...", branch = "master", service = "github" }

# Circle CI: `repository` is required. `branch` is optional; default is `master`
circle-ci = { repository = "...", branch = "master" }

# GitLab: `repository` is required. `branch` is optional; default is `master`
gitlab = { repository = "...", branch = "master" }

# Azure DevOps: `project` is required. `pipeline` is required. `build` is optional; default is `1`
# Note: project = `organization/project`, pipeline = `name_of_pipeline`, build = `definitionId`
azure-devops = { project = "...", pipeline = "...", build="2" }

# Travis CI: `repository` in format "<user>/<project>" is required.
# `branch` is optional; default is `master`
travis-ci = { repository = "...", branch = "master" }

# Codecov: `repository` is required. `branch` is optional; default is `master`
# `service` is optional; valid values are `github` (default), `bitbucket`, and
# `gitlab`.
codecov = { repository = "...", branch = "master", service = "github" }

# Coveralls: `repository` is required. `branch` is optional; default is `master`
# `service` is optional; valid values are `github` (default) and `bitbucket`.
coveralls = { repository = "...", branch = "master", service = "github" }

# Is it maintained resolution time: `repository` is required.
is-it-maintained-issue-resolution = { repository = "..." }

# Is it maintained percentage of open issues: `repository` is required.
is-it-maintained-open-issues = { repository = "..." }

# Maintenance: `status` is required. Available options are:
# - `actively-developed`: New features are being added and bugs are being fixed.
# - `passively-maintained`: There are no plans for new features, but the maintainer intends to
#   respond to issues that get filed.
# - `as-is`: The crate is feature complete, the maintainer does not intend to continue working on
#   it or providing support, but it works for the purposes it was designed for.
# - `experimental`: The author wants to share it with the community but is not intending to meet
#   anyone's particular use case.
# - `looking-for-maintainer`: The current maintainer would like to transfer the crate to someone
#   else.
# - `deprecated`: The maintainer does not recommend using this crate (the description of the crate
#   can describe why, there could be a better solution available or there could be problems with
#   the crate that the author does not want to fix).
# - `none`: Displays no badge on, since the maintainer has not chosen to specify
#   their intentions, potential crate users will need to investigate on their own.
maintenance = { status = "..." }

The registry will render the description, display the license, link to the three URLs and categorize by the keywords. These keys provide useful information to users of the registry and also influence the search ranking of a crate. It is highly discouraged to omit everything in a published crate.

SPDX 2.1 license expressions are documented here. The current version of the license list is available here, and version 2.4 is available here.

The metadata table (optional)

Cargo by default will warn about unused keys in Cargo.toml to assist in detecting typos and such. The package.metadata table, however, is completely ignored by Cargo and will not be warned about. This section can be used for tools which would like to store package configuration in Cargo.toml. For example:

name = "..."
# ...

# Metadata used when generating an Android APK, for example.
package-name = "my-awesome-android-app"
assets = "path/to/static"

Dependency sections

See the specifying dependencies page for information on the [dependencies], [dev-dependencies], [build-dependencies], and target-specific [target.*.dependencies] sections.

The [profile.*] sections

Cargo supports custom configuration of how rustc is invoked through profiles at the top level. Any manifest may declare a profile, but only the top level package’s profiles are actually read. All dependencies’ profiles will be overridden. This is done so the top-level package has control over how its dependencies are compiled.

There are four currently supported profile names, all of which have the same configuration available to them. Listed below is the configuration available, along with the defaults for each profile.

# The development profile, used for `cargo build`.
opt-level = 0      # controls the `--opt-level` the compiler builds with.
                   # 0-1 is good for debugging. 2 is well-optimized. Max is 3.
                   # 's' attempts to reduce size, 'z' reduces size even more.
debug = true       # (u32 or bool) Include debug information (debug symbols).
                   # Equivalent to `-C debuginfo=2` compiler flag.
rpath = false      # controls whether compiler should set loader paths.
                   # If true, passes `-C rpath` flag to the compiler.
lto = false        # Link Time Optimization usually reduces size of binaries
                   # and static libraries. Increases compilation time.
                   # If true, passes `-C lto` flag to the compiler, and if a
                   # string is specified like 'thin' then `-C lto=thin` will
                   # be passed.
debug-assertions = true # controls whether debug assertions are enabled
                   # (e.g., debug_assert!() and arithmetic overflow checks)
codegen-units = 16 # if > 1 enables parallel code generation which improves
                   # compile times, but prevents some optimizations.
                   # Passes `-C codegen-units`.
panic = 'unwind'   # panic strategy (`-C panic=...`), can also be 'abort'
incremental = true # whether or not incremental compilation is enabled
                   # This can be overridden globally with the CARGO_INCREMENTAL
                   # environment variable or `build.incremental` config
                   # variable. Incremental is only used for path sources.
overflow-checks = true # use overflow checks for integer arithmetic.
                   # Passes the `-C overflow-checks=...` flag to the compiler.

# The release profile, used for `cargo build --release` (and the dependencies
# for `cargo test --release`, including the local library or binary).
opt-level = 3
debug = false
rpath = false
lto = false
debug-assertions = false
codegen-units = 16
panic = 'unwind'
incremental = false
overflow-checks = false

# The testing profile, used for `cargo test` (for `cargo test --release` see
# the `release` and `bench` profiles).
opt-level = 0
debug = 2
rpath = false
lto = false
debug-assertions = true
codegen-units = 16
panic = 'unwind'
incremental = true
overflow-checks = true

# The benchmarking profile, used for `cargo bench` (and the test targets and
# unit tests for `cargo test --release`).
opt-level = 3
debug = false
rpath = false
lto = false
debug-assertions = false
codegen-units = 16
panic = 'unwind'
incremental = false
overflow-checks = false

The [features] section

Cargo supports features to allow expression of:

  • conditional compilation options (usable through cfg attributes);
  • optional dependencies, which enhance a package, but are not required; and
  • clusters of optional dependencies, such as postgres, that would include the postgres package, the postgres-macros package, and possibly other packages (such as development-time mocking libraries, debugging tools, etc.).

A feature of a package is either an optional dependency, or a set of other features. The format for specifying features is:

name = "awesome"

# The default set of optional packages. Most people will want to use these
# packages, but they are strictly optional. Note that `session` is not a package
# but rather another feature listed in this manifest.
default = ["jquery", "uglifier", "session"]

# A feature with no dependencies is used mainly for conditional compilation,
# like `#[cfg(feature = "go-faster")]`.
go-faster = []

# The `secure-password` feature depends on the bcrypt package. This aliasing
# will allow people to talk about the feature in a higher-level way and allow
# this package to add more requirements to the feature in the future.
secure-password = ["bcrypt"]

# Features can be used to reexport features of other packages. The `session`
# feature of package `awesome` will ensure that the `session` feature of the
# package `cookie` is also enabled.
session = ["cookie/session"]

# These packages are mandatory and form the core of this package’s distribution.
cookie = "1.2.0"
oauth = "1.1.0"
route-recognizer = "=2.1.0"

# A list of all of the optional dependencies, some of which are included in the
# above `features`. They can be opted into by apps.
jquery = { version = "1.0.2", optional = true }
uglifier = { version = "1.5.3", optional = true }
bcrypt = { version = "*", optional = true }
civet = { version = "*", optional = true }

To use the package awesome:

version = "1.3.5"
default-features = false # do not include the default features, and optionally
                         # cherry-pick individual features
features = ["secure-password", "civet"]


The usage of features is subject to a few rules:

  • Feature names must not conflict with other package names in the manifest. This is because they are opted into via features = [...], which only has a single namespace.
  • With the exception of the default feature, all features are opt-in. To opt out of the default feature, use default-features = false and cherry-pick individual features.
  • Feature groups are not allowed to cyclically depend on one another.
  • Dev-dependencies cannot be optional.
  • Features groups can only reference optional dependencies.
  • When a feature is selected, Cargo will call rustc with --cfg feature="${feature_name}". If a feature group is included, it and all of its individual features will be included. This can be tested in code via #[cfg(feature = "foo")].

Note that it is explicitly allowed for features to not actually activate any optional dependencies. This allows packages to internally enable/disable features without requiring a new dependency.

Usage in end products

One major use-case for this feature is specifying optional features in end-products. For example, the Servo package may want to include optional features that people can enable or disable when they build it.

In that case, Servo will describe features in its Cargo.toml and they can be enabled using command-line flags:

$ cargo build --release --features "shumway pdf"

Default features could be excluded using --no-default-features.

Usage in packages

In most cases, the concept of optional dependency in a library is best expressed as a separate package that the top-level application depends on.

However, high-level packages, like Iron or Piston, may want the ability to curate a number of packages for easy installation. The current Cargo system allows them to curate a number of mandatory dependencies into a single package for easy installation.

In some cases, packages may want to provide additional curation for optional dependencies:

  • grouping a number of low-level optional dependencies together into a single high-level feature;
  • specifying packages that are recommended (or suggested) to be included by users of the package; and
  • including a feature (like secure-password in the motivating example) that will only work if an optional dependency is available, and would be difficult to implement as a separate package (for example, it may be overly difficult to design an IO package to be completely decoupled from OpenSSL, with opt-in via the inclusion of a separate package).

In almost all cases, it is an antipattern to use these features outside of high-level packages that are designed for curation. If a feature is optional, it can almost certainly be expressed as a separate package.

The [workspace] section

Packages can define a workspace which is a set of crates that will all share the same Cargo.lock and output directory. The [workspace] table can be defined as:


# Optional key, inferred from path dependencies if not present.
# Additional non-path dependencies that should be included must be given here.
# In particular, for a virtual manifest, all members have to be listed.
members = ["path/to/member1", "path/to/member2", "path/to/member3/*"]

# Optional key, empty if not present.
exclude = ["path1", "path/to/dir2"]

Workspaces were added to Cargo as part of RFC 1525 and have a number of properties:

  • A workspace can contain multiple crates where one of them is the root crate.
  • The root crate's Cargo.toml contains the [workspace] table, but is not required to have other configuration.
  • Whenever any crate in the workspace is compiled, output is placed in the workspace root (i.e., next to the root crate's Cargo.toml).
  • The lock file for all crates in the workspace resides in the workspace root.
  • The [patch], [replace] and [profile.*] sections in Cargo.toml are only recognized in the root crate's manifest, and ignored in member crates' manifests.

The root crate of a workspace, indicated by the presence of [workspace] in its manifest, is responsible for defining the entire workspace. All path dependencies residing in the workspace directory become members. You can add additional packages to the workspace by listing them in the members key. Note that members of the workspaces listed explicitly will also have their path dependencies included in the workspace. Sometimes a package may have a lot of workspace members and it can be onerous to keep up to date. The path dependency can also use globs to match multiple paths. Finally, the exclude key can be used to blacklist paths from being included in a workspace. This can be useful if some path dependencies aren't desired to be in the workspace at all.

The package.workspace manifest key (described above) is used in member crates to point at a workspace's root crate. If this key is omitted then it is inferred to be the first crate whose manifest contains [workspace] upwards in the filesystem.

A crate may either specify package.workspace or specify [workspace]. That is, a crate cannot both be a root crate in a workspace (contain [workspace]) and also be a member crate of another workspace (contain package.workspace).

Most of the time workspaces will not need to be dealt with as cargo new and cargo init will handle workspace configuration automatically.

Virtual Manifest

In workspace manifests, if the package table is present, the workspace root crate will be treated as a normal package, as well as a workspace. If the package table is not present in a workspace manifest, it is called a virtual manifest.

Package selection

In a workspace, package-related cargo commands like cargo build apply to packages selected by -p / --package or --all command-line parameters. When neither is specified, the optional default-members configuration is used:

members = ["path/to/member1", "path/to/member2", "path/to/member3/*"]
default-members = ["path/to/member2", "path/to/member3/foo"]

When specified, default-members must expand to a subset of members.

When default-members is not specified, the default is the root manifest if it is a package, or every member manifest (as if --all were specified on the command-line) for virtual workspaces.

The project layout

If your package is an executable, name the main source file src/ If it is a library, name the main source file src/

Cargo will also treat any files located in src/bin/*.rs as executables. If your executable consists of more than just one source file, you might also use a directory inside src/bin containing a file which will be treated as an executable with a name of the parent directory.

Your package can optionally contain folders named examples, tests, and benches, which Cargo will treat as containing examples, integration tests, and benchmarks respectively. Analogous to bin targets, they may be composed of single files or directories with a file.

▾ src/           # directory containing source files         # the main entry point for libraries and packages        # the main entry point for packages producing executables
  ▾ bin/         # (optional) directory containing additional executables
  ▾ */           # (optional) directories containing multi-file executables
▾ examples/      # (optional) examples
  ▾ */           # (optional) directories containing multi-file examples
▾ tests/         # (optional) integration tests
  ▾ */           # (optional) directories containing multi-file tests
▾ benches/       # (optional) benchmarks
  ▾ */           # (optional) directories containing multi-file benchmarks

To structure your code after you've created the files and folders for your package, you should remember to use Rust's module system, which you can read about in the book.

See Configuring a target below for more details on manually configuring target settings. See Target auto-discovery below for more information on controlling how Cargo automatically infers targets.


Files located under examples are example uses of the functionality provided by the library. When compiled, they are placed in the target/examples directory.

They can compile either as executables (with a main() function) or libraries and pull in the library by using extern crate <library-name>. They are compiled when you run your tests to protect them from bitrotting.

You can run individual executable examples with the command cargo run --example <example-name>.

Specify crate-type to make an example be compiled as a library (additional information about crate types is available in The Rust Reference):

name = "foo"
crate-type = ["staticlib"]

You can build individual library examples with the command cargo build --example <example-name>.


When you run cargo test, Cargo will:

  • compile and run your library’s unit tests, which are in the files reachable from (naturally, any sections marked with #[cfg(test)] will be considered at this stage);
  • compile and run your library’s documentation tests, which are embedded inside of documentation blocks;
  • compile and run your library’s integration tests; and
  • compile your library’s examples.

Integration tests

Each file in tests/*.rs is an integration test. When you run cargo test, Cargo will compile each of these files as a separate crate. The crate can link to your library by using extern crate <library-name>, like any other code that depends on it.

Cargo will not automatically compile files inside subdirectories of tests, but an integration test can import modules from these directories as usual. For example, if you want several integration tests to share some code, you can put the shared code in tests/common/ and then put mod common; in each of the test files.

Configuring a target

All of the [[bin]], [lib], [[bench]], [[test]], and [[example]] sections 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.

The example below uses [lib], but it also applies to all other sections as well. All values listed are the defaults for that option unless otherwise specified.

# ...

# The name of a target is the name of the library that will be generated. This
# is defaulted to the name of the package, with any dashes replaced
# with underscores. (Rust `extern crate` declarations reference this name;
# therefore the value must be a valid Rust identifier to be usable.)
name = "foo"

# This field points at where the crate is located, relative to the `Cargo.toml`.
path = "src/"

# A flag for enabling unit tests for this target. This is used by `cargo test`.
test = true

# A flag for enabling documentation tests for this target. This is only relevant
# for libraries, it has no effect on other sections. This is used by
# `cargo test`.
doctest = true

# A flag for enabling benchmarks for this target. This is used by `cargo bench`.
bench = true

# A flag for enabling documentation of this target. This is used by `cargo doc`.
doc = true

# If the target is meant to be a compiler plugin, this field must be set to true
# for Cargo to correctly compile it and make it available for all dependencies.
plugin = false

# If the target is meant to be a "macros 1.1" procedural macro, this field must
# be set to true.
proc-macro = false

# If set to false, `cargo test` will omit the `--test` flag to rustc, which
# stops it from generating a test harness. This is useful when the binary being
# built manages the test runner itself.
harness = true

# If set then a target can be configured to use a different edition than the
# `[package]` is configured to use, perhaps only compiling a library with the
# 2018 edition or only compiling one unit test with the 2015 edition. By default
# all targets are compiled with the edition specified in `[package]`.
edition = '2015'

# Here's an example of a TOML "array of tables" section, in this case specifying
# a binary target name and path.
name = "my-cool-binary"
path = "src/"

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.

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
    └── bin

To prevent Cargo from inferring src/bin/ as an executable, set autobins = false in Cargo.toml to disable auto-discovery:

# …
autobins = false

Note: For packages with the 2015 edition, the default for auto-discovery is false if at least one target is manually defined in Cargo.toml. Beginning with the 2018 edition, the default is always true.

The required-features field (optional)

The required-features field specifies which features the target needs in order to be built. If any of the required features are not selected, the target will be skipped. This is only relevant for the [[bin]], [[bench]], [[test]], and [[example]] sections, it has no effect on [lib].

# ...
postgres = []
sqlite = []
tools = []

# ...
required-features = ["postgres", "tools"]

Building dynamic or static libraries

If your package produces a library, you can specify which kind of library to build by explicitly listing the library in your Cargo.toml:

# ...

name = "..."
crate-type = ["dylib"] # could be `staticlib` as well

The available options are dylib, rlib, staticlib, cdylib, and proc-macro.

You can read more about the different crate types in the Rust Reference Manual

The [patch] Section

This section of Cargo.toml can be used to override dependencies with other copies. The syntax is similar to the [dependencies] section:

foo = { git = '' }
bar = { path = 'my/local/bar' }

git = ''

baz = { git = '', branch = 'my-branch' }

The [patch] table is made of dependency-like sub-tables. Each key after [patch] is a URL of the source that is being patched, or the name of a registry. The name crates-io may be used to override the default registry The first [patch] in the example above demonstrates overriding, and the second [patch] demonstrates overriding a git source.

Each entry in these tables is a normal dependency specification, the same as found in the [dependencies] section of the manifest. The dependencies listed in the [patch] section are resolved and used to patch the source at the URL specified. The above manifest snippet patches the crates-io source (e.g. itself) with the foo crate and bar crate. It also patches the source with a my-branch that comes from elsewhere.

Sources can be patched with versions of crates that do not exist, and they can also be patched with versions of crates that already exist. If a source is patched with a crate version that already exists in the source, then the source's original crate is replaced.

More information about overriding dependencies can be found in the overriding dependencies section of the documentation and RFC 1969 for the technical specification of this feature.

The [replace] Section

This section of Cargo.toml can be used to override dependencies with other copies. The syntax is similar to the [dependencies] section:

"foo:0.1.0" = { git = '' }
"bar:1.0.2" = { path = 'my/local/bar' }

Each key in the [replace] table is a package ID specification, which allows arbitrarily choosing a node in the dependency graph to override. The value of each key is the same as the [dependencies] syntax for specifying dependencies, except that you can't specify features. Note that when a crate is overridden the copy it's overridden with must have both the same name and version, but it can come from a different source (e.g., git or a local path).

More information about overriding dependencies can be found in the overriding dependencies section of the documentation.