Functions

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package

package(default_deprecation, default_package_metadata, default_testonly, default_visibility, features)

This function declares metadata that applies to every rule in the package. It is used at most once within a package (BUILD file).

For the counterpart that declares metadata applying to every rule in the whole repository, use the repo() function in the REPO.bazel file at the root of your repo. The repo() function takes exactly the same arguments as package().

The package() function should be called right after all the load() statements at the top of the file, before any rule.

Arguments

Attribute Description
default_applicable_licenses

Alias for default_package_metadata.

default_visibility

List of labels; default is []

The default visibility of the rules in this package.

Every rule in this package has the visibility specified in this attribute, unless otherwise specified in the visibility attribute of the rule. For detailed information about the syntax of this attribute, see the documentation of visibility. The package default visibility does not apply to exports_files, which is public by default.

default_deprecation

String; default is ""

Sets the default deprecation message for all rules in this package.

default_package_metadata

List of labels; default is []

Sets a default list of metadata targets which apply to all other targets in the package. These are typically targets related to OSS package and license declarations. See rules_license for examples.

default_testonly

Boolean; default is False except as noted

Sets the default testonly property for all rules in this package.

In packages under javatests the default value is True.

features

List strings; default is []

Sets various flags that affect the semantics of this BUILD file.

This feature is mainly used by the people working on the build system to tag packages that need some kind of special handling. Do not use this unless explicitly requested by someone working on the build system.

Examples

The declaration below declares that the rules in this package are visible only to members of package group //foo:target. Individual visibility declarations on a rule, if present, override this specification.
package(default_visibility = ["//foo:target"])

package_group

package_group(name, packages, includes)

This function defines a set of packages and associates a label with the set. The label can be referenced in visibility attributes.

Package groups are primarily used for visibility control. A publicly visible target can be referenced from every package in the source tree. A privately visible target can only be referenced within its own package (not subpackages). In between these extremes, a target may allow access to its own package plus any of the packages described by one or more package groups. For a more detailed explanation of the visibility system, see the visibility attribute.

A given package is considered to be in the group if it either matches the packages attribute, or is already contained in one of the other package groups mentioned in the includes attribute.

Package groups are technically targets, but are not created by rules, and do not themselves have any visibility protection.

Arguments

Attribute Description
name

Name; required

A unique name for this target.

packages

List of strings; default is []

A list of zero or more package specifications.

Each package specification string can have one of the following forms:

  1. The full name of a package, without its repository, starting with a double slash. For example, //foo/bar specifies the package having that name and which lives in the same repository as the package group.
  2. As above, but with a trailing /.... For example, //foo/... specifies the set of //foo and all its subpackages. //... specifies all packages in the current repository.
  3. The strings public or private, which respectively specify every package or no package. (This form requires the flag --incompatible_package_group_has_public_syntax to be set.)

In addition, the first two kinds of package specifications may also be prefixed with - to indicate that they are negated.

The package group contains any package that matches at least one of its positive specifications and none of its negative specifications For instance, the value [//foo/..., -//foo/tests/...] includes all subpackages of //foo that are not also subpackages of //foo/tests. (//foo itself is included while //foo/tests itself is not.)

Aside from public visibility, there is no way to directly specify packages outside the current repository.

If this attribute is missing, it is the same as setting it to an empty list, which is also the same as setting it to a list containing only private.

Note: Prior to Bazel 6.0, the specification //... had a legacy behavior of being the same as public. This behavior is fixed when --incompatible_fix_package_group_reporoot_syntax is enabled, which is the default after Bazel 6.0.

Note: Prior to Bazel 6.0, when this attribute is serialized as part of bazel query --output=proto (or --output=xml), the leading slashes are omitted. For instance, //pkg/foo/... will output as \"pkg/foo/...\". This behavior is fixed when --incompatible_package_group_includes_double_slash is enabled, which is the default after Bazel 6.0.

includes

List of labels; default is []

Other package groups that are included in this one.

The labels in this attribute must refer to other package groups. Packages in referenced package groups are taken to be part of this package group. This is transitive — if package group a includes package group b, and b includes package group c, then every package in c will also be a member of a.

When used together with negated package specifications, note that the set of packages for each group is first computed independently and the results are then unioned together. This means that negated specifications in one group have no effect on the specifications in another group.

Examples

The following package_group declaration specifies a package group called "tropical" that contains tropical fruits.

package_group(
    name = "tropical",
    packages = [
        "//fruits/mango",
        "//fruits/orange",
        "//fruits/papaya/...",
    ],
)

The following declarations specify the package groups of a fictional application:

package_group(
    name = "fooapp",
    includes = [
        ":controller",
        ":model",
        ":view",
    ],
)

package_group(
    name = "model",
    packages = ["//fooapp/database"],
)

package_group(
    name = "view",
    packages = [
        "//fooapp/swingui",
        "//fooapp/webui",
    ],
)

package_group(
    name = "controller",
    packages = ["//fooapp/algorithm"],
)

exports_files

exports_files([label, ...], visibility, licenses)

exports_files() specifies a list of files belonging to this package that are exported to other packages.

The BUILD file for a package may only refer directly to source files belonging to another package if they are explicitly exported with an exports_files() statement. Read more about visibility of files.

As a legacy behaviour, also files mentioned as input to a rule are exported with the default visibility until the flag --incompatible_no_implicit_file_export is flipped. However, this behavior should not be relied upon and actively migrated away from.

Arguments

The argument is a list of names of files within the current package. A visibility declaration can also be specified; in this case, the files will be visible to the targets specified. If no visibility is specified, the files will be visible to every package, even if a package default visibility was specified in the package function. The licenses can also be specified.

Example

The following example exports golden.txt, a text file from the test_data package, so that other packages may use it, for example, in the data attribute of tests.

# from //test_data/BUILD

exports_files(["golden.txt"])

glob

glob(include, exclude=[], exclude_directories=1, allow_empty=True)

Glob is a helper function that finds all files that match certain path patterns, and returns a new, mutable, sorted list of their paths. Glob only searches files in its own package, and looks only for source files (not generated files nor other targets).

A source file's Label is included in the result if the file's package-relative path matches any of the include patterns and none of the exclude patterns.

The include and exclude lists contain path patterns that are relative to the current package. Every pattern may consist of one or more path segments. As usual with Unix paths, these segments are separated by /. The segments in the pattern are matched against the segments of the path. Segments may contain the * wildcard: this matches any substring in the path segment (even the empty substring), excluding the directory separator /. This wildcard can be used multiple times within one path segment. Additionally, the ** wildcard can match zero or more complete path segments, but it must be declared as a standalone path segment.

Examples:
  • foo/bar.txt matches exactly the foo/bar.txt file in this package (unless foo/ is a subpackage)
  • foo/*.txt matches every file in the foo/ directory if the file ends with .txt (unless foo/ is a subpackage)
  • foo/a*.htm* matches every file in the foo/ directory that starts with a, then has an arbitrary string (could be empty), then has .htm, and ends with another arbitrary string (unless foo/ is a subpackage); such as foo/axx.htm and foo/a.html or foo/axxx.html
  • foo/* matches every file in the foo/ directory, (unless foo/ is a subpackage); it does not match foo directory itself even if exclude_directories is set to 0
  • foo/** matches every file in every non-subpackage subdirectory under package's first level subdirectory foo/; if exclude_directories is set to 0, foo directory itself also matches the pattern; in this case, ** is considered to match zero path segments
  • **/a.txt matches a.txt files in this package's directory plus non-subpackage subdirectories.
  • **/bar/**/*.txt matches every .txt file in every non-subpackage subdirectory of this package, if at least one directory on the resulting path is called bar, such as xxx/bar/yyy/zzz/a.txt or bar/a.txt (remember that ** also matches zero segments) or bar/zzz/a.txt
  • ** matches every file in every non-subpackage subdirectory of this package
  • foo**/a.txt is an invalid pattern, because ** must stand on its own as a segment
  • foo/ is an invalid pattern, because the second segment defined after / is an empty string

If the exclude_directories argument is enabled (set to 1), files of type directory will be omitted from the results (default 1).

If the allow_empty argument is set to False, the glob function will error-out if the result would otherwise be the empty list.

There are several important limitations and caveats:

  1. Since glob() runs during BUILD file evaluation, glob() matches files only in your source tree, never generated files. If you are building a target that requires both source and generated files, you must append an explicit list of generated files to the glob. See the example below with :mylib and :gen_java_srcs.

  2. If a rule has the same name as a matched source file, the rule will "shadow" the file.

    To understand this, remember that glob() returns a list of paths, so using glob() in other rules' attribute (e.g. srcs = glob(["*.cc"])) has the same effect as listing the matched paths explicitly. If for example glob() yields ["Foo.java", "bar/Baz.java"] but there's also a rule in the package called "Foo.java" (which is allowed, though Bazel warns about it), then the consumer of the glob() will use the "Foo.java" rule (its outputs) instead of the "Foo.java" file. See GitHub issue #10395 for more details.

  3. Globs may match files in subdirectories. And subdirectory names may be wildcarded. However...
  4. Labels are not allowed to cross the package boundary and glob does not match files in subpackages.

    For example, the glob expression **/*.cc in package x does not include x/y/z.cc if x/y exists as a package (either as x/y/BUILD, or somewhere else on the package-path). This means that the result of the glob expression actually depends on the existence of BUILD files — that is, the same glob expression would include x/y/z.cc if there was no package called x/y or it was marked as deleted using the --deleted_packages flag.

  5. The restriction above applies to all glob expressions, no matter which wildcards they use.
  6. A hidden file with filename starting with . is completely matched by both the ** and the * wildcards. If you want to match a hidden file with a compound pattern, your pattern needs to begin with a .. For example, * and .*.txt will match .foo.txt, but *.txt will not. Hidden directories are also matched in the same manner. Hidden directories may include files that are not required as inputs, and can increase the number of unnecessarily globbed files and memory consumption. To exclude hidden directories, add them to the "exclude" list argument.
  7. The "**" wildcard has one corner case: the pattern "**" doesn't match the package's directory path. That is to say, glob(["**"], exclude_directories = 0) matches all files and directories transitively strictly under the current package's directory (but of course not going into directories of subpackages - see the previous note about that).

In general, you should try to provide an appropriate extension (e.g. *.html) instead of using a bare '*' for a glob pattern. The more explicit name is both self documenting and ensures that you don't accidentally match backup files, or emacs/vi/... auto-save files.

When writing build rules you can enumerate the elements of the glob. This enables generating individual rules for every input, for example. See the expanded glob example section below.

Glob Examples

Create a Java library built from all java files in this directory, and all files generated by the :gen_java_srcs rule.

java_library(
    name = "mylib",
    srcs = glob(["*.java"]) + [":gen_java_srcs"],
    deps = "...",
)

genrule(
    name = "gen_java_srcs",
    outs = [
        "Foo.java",
        "Bar.java",
    ],
    ...
)

Include all txt files in directory testdata except experimental.txt. Note that files in subdirectories of testdata will not be included. If you want those files to be included, use a recursive glob (**).

sh_test(
    name = "mytest",
    srcs = ["mytest.sh"],
    data = glob(
        ["testdata/*.txt"],
        exclude = ["testdata/experimental.txt"],
    ),
)

Recursive Glob Examples

Make the test depend on all txt files in the testdata directory and any of its subdirectories (and their subdirectories, and so on). Subdirectories containing a BUILD file are ignored. (See limitations and caveats above.)

sh_test(
    name = "mytest",
    srcs = ["mytest.sh"],
    data = glob(["testdata/**/*.txt"]),
)

Create a library built from all java files in this directory and all subdirectories except those whose path includes a directory named testing. This pattern should be avoided if possible, as it can reduce build incrementality and therefore increase build times.

java_library(
    name = "mylib",
    srcs = glob(
        ["**/*.java"],
        exclude = ["**/testing/**"],
    ),
)

Expanded Glob Examples

Create an individual genrule for *_test.cc in the current directory that counts the number of lines in the file.

# Conveniently, the build language supports list comprehensions.
[genrule(
    name = "count_lines_" + f[:-3],  # strip ".cc"
    srcs = [f],
    outs = ["%s-linecount.txt" % f[:-3]],
    cmd = "wc -l $< >$@",
 ) for f in glob(["*_test.cc"])]

If the BUILD file above is in package //foo and the package contains three matching files, a_test.cc, b_test.cc and c_test.cc then running bazel query '//foo:all' will list all rules that were generated:

$ bazel query '//foo:all' | sort
//foo:count_lines_a_test
//foo:count_lines_b_test
//foo:count_lines_c_test

select

select(
    {conditionA: valuesA, conditionB: valuesB, ...},
    no_match_error = "custom message"
)

select() is the helper function that makes a rule attribute configurable. It can replace the right-hand side of almost any attribute assignment so its value depends on command-line Bazel flags. You can use this, for example, to define platform-specific dependencies or to embed different resources depending on whether a rule is built in "developer" vs. "release" mode.

Basic use is as follows:

sh_binary(
    name = "mytarget",
    srcs = select({
        ":conditionA": ["mytarget_a.sh"],
        ":conditionB": ["mytarget_b.sh"],
        "//conditions:default": ["mytarget_default.sh"]
    })
)

This makes the srcs attribute of a sh_binary configurable by replacing its normal label list assignment with a select call that maps configuration conditions to matching values. Each condition is a label reference to a config_setting or constraint_value, which "matches" if the target's configuration matches an expected set of values. The value of mytarget#srcs then becomes whichever label list matches the current invocation.

Notes:

  • Exactly one condition is selected on any invocation.
  • If multiple conditions match and one is a specialization of the others, the specialization takes precedence. Condition B is considered a specialization of condition A if B has all the same flags and constraint values as A plus some additional flags or constraint values. This also means that specialization resolution is not designed to create an ordering as demonstrated in Example 2 below.
  • If multiple conditions match and one is not a specialization of all the others, Bazel fails with an error, unless all conditions resolve to the same value.
  • The special pseudo-label //conditions:default is considered to match if no other condition matches. If this condition is left out, some other rule must match to avoid an error.
  • select can be embedded inside a larger attribute assignment. So srcs = ["common.sh"] + select({ ":conditionA": ["myrule_a.sh"], ...}) and srcs = select({ ":conditionA": ["a.sh"]}) + select({ ":conditionB": ["b.sh"]}) are valid expressions.
  • select works with most, but not all, attributes. Incompatible attributes are marked nonconfigurable in their documentation.

    subpackages

    subpackages(include, exclude=[], allow_empty=True)

    subpackages() is a helper function, similar to glob() that lists subpackages instead of files and directories. It uses the same path patterns as glob() and can match any subpackage that is a direct descendant of the currently loading BUILD file. See glob for a detailed explanation and examples of include and exclude patterns.

    The resulting list of subpackages returned is in sorted order and contains paths relative to the current loading package that match the given patterns in include and not those in exclude.

    Example

    The following example lists all the direct subpackages for the package foo/BUILD

    # The following BUILD files exist:
    # foo/BUILD
    # foo/bar/baz/BUILD
    # foo/bar/but/bad/BUILD
    # foo/sub/BUILD
    # foo/sub/deeper/BUILD
    #
    # In foo/BUILD a call to
    subs1 = subpackages(include = ["**"])
    
    # results in subs1 == ["sub", "bar/baz", "bar/but/bad"]
    #
    # 'sub/deeper' is not included because it is a subpackage of 'foo/sub' not of
    # 'foo'
    
    subs2 = subpackages(include = ["bar/*"])
    # results in subs2 = ["bar/baz"]
    #
    # Since 'bar' is not a subpackage itself, this looks for any subpackages under
    # all first level subdirectories of 'bar'.
    
    subs3 = subpackages(include = ["bar/**"])
    # results in subs3 = ["bar/baz", "bar/but/bad"]
    #
    # Since bar is not a subpackage itself, this looks for any subpackages which are
    # (1) under all subdirectories of 'bar' which can be at any level, (2) not a
    # subpackage of another subpackages.
    
    subs4 = subpackages(include = ["sub"])
    subs5 = subpackages(include = ["sub/*"])
    subs6 = subpackages(include = ["sub/**"])
    # results in subs4 and subs6 being ["sub"]
    # results in subs5 = [].
    #
    # In subs4, expression "sub" checks whether 'foo/sub' is a package (i.e. is a
    # subpackage of 'foo').
    # In subs5, "sub/*" looks for subpackages under directory 'foo/sub'. Since
    # 'foo/sub' is already a subpackage itself, the subdirectories will not be
    # traversed anymore.
    # In subs6, 'foo/sub' is a subpackage itself and matches pattern "sub/**", so it
    # is returned. But the subdirectories of 'foo/sub' will not be traversed
    # anymore.
    

    In general it is preferred that instead of calling this function directly that users use the 'subpackages' module of skylib.