A command to run during the build, for example, a call to a compiler that takes artifacts as inputs and produces other artifacts as outputs. Includes metadata like the command line arguments, action key, environment variables, and declared input/output artifacts.
See also: Rules documentation
An on-disk cache that stores a mapping of executed actions to the outputs they created. The cache key is known as the action key. A core component for Bazel's incrementality model. The cache is stored in the output base directory and thus survives Bazel server restarts.
An in-memory graph of actions and the artifacts that these actions read and generate. The graph might include artifacts that exist as source files (for example, in the file system) as well as generated intermediate/final artifacts that are not mentioned in BUILD
files. Produced during the analysis phase and used during the execution phase.
A query tool that can query over build actions. This provides the ability to analyze how build rules translate into the actual work builds do.
The cache key of an action. Computed based on action metadata, which might include the command to be execution in the action, compiler flags, library locations, or system headers, depending on the action. Enables Bazel to cache or invalidate individual actions deterministically.
The second phase of a build. Processes the target graph specified in BUILD
files to produce an in-memory action graph that determines the order of actions to run during the execution phase. This is the phase in which rule implementations are evaluated.
A source file or a generated file. Can also be a directory of files, known as “tree artifacts”. Tree artifacts are black boxes to Bazel: Bazel does not treat the files in tree artifacts as individual artifacts and thus cannot reference them directly as action inputs / outputs. An artifact can be an input to multiple actions, but must only be generated by at most one action.
A mechanism for rules to create additional actions in their dependencies. For example, if target A depends on B, one can apply an aspect on A that traverses up a dependency edge to B, and runs additional actions in B to generate and collect additional output files. These additional actions are cached and reused between targets requiring the same aspect. Created with the aspect()
Starlark Build API function. Can be used, for example, to generate metadata for IDEs, and create actions for linting.
See also: Aspects documentation
An aspect composition mechanism, where aspects can be applied on other aspects. For an aspect A to inspect aspect B, aspect A must declare the providers it needs from aspect B (with the required_aspect_providers
attribute), and aspect B must declare the providers it returns (with the provides
attribute). For example, this can be used by IDE aspects to generate files using information also generated by aspects, like the java_proto_library
aspect.
Bazel’s configuration file used to change the default values for startup flags and command flags, and to define common groups of options that can then be set together on the Bazel command line using a --config
flag. Bazel can combine settings from multiple bazelrc files (systemwide, per-workspace, per-user, or from a custom location), and a bazelrc
file may also import settings from other bazelrc
files.
The Google-internal version of Bazel. Google’s main build system for its mono-repository.
A BUILD
file is the main configuration file that tells Bazel what software outputs to build, what their dependencies are, and how to build them. Bazel takes a BUILD
file as input and uses the file to create a graph of dependencies and to derive the actions that must be completed to build intermediate and final software outputs. A BUILD
file marks a directory and any sub-directories not containing a BUILD
file as a package, and can contain targets created by rules. The file can also be named BUILD.bazel
.
See BUILD
File. Takes precedence over a BUILD
file in the same directory.
A file that defines rules, macros, and constants written in Starlark. These can then be imported into BUILD
files using the load()
function.
The dependency graph that Bazel constructs and traverses to perform a build. Includes nodes like targets, configured targets, actions, and artifacts. A build is considered complete when all artifacts on which a set of requested targets depend are verified as up-to-date.
A Starlark-defined piece of configuration. Transitions can set build settings to change a subgraph's configuration. If exposed to the user as a command-line flag, also known as a build flag.
A build that doesn't use the results of earlier builds. This is generally slower than an incremental build but commonly considered to be more correct. Bazel guarantees both clean and incremental builds are always correct.
The bazel
command-line client automatically starts a background server on the local machine to execute Bazel commands. The server persists across commands but automatically stops after a period of inactivity (or explicitly via bazel shutdown). Splitting Bazel into a server and client helps amortize JVM startup time and supports faster incremental builds because the action graph remains in memory across commands.
Used on the command line to invoke different Bazel functions, like bazel build
, bazel test
, bazel run
, and bazel query
.
A set of flags specific to a command. Command flags are specified after the command (bazel build <command flags>
). Flags can be applicable to one or more commands. For example, --configure
is a flag exclusively for the bazel sync
command, but --keep_going
is applicable to sync
, build
, test
and more. Flags are often used for configuration purposes, so changes in flag values can cause Bazel to invalidate in-memory graphs and restart the analysis phase.
Information outside of rule definitions that impacts how rules generate actions. Every build has at least one configuration specifying the target platform, action environment variables, and command-line build flags. Transitions may create additional configurations, e.g. for host tools or cross-compilation.
See also: Configurations
The process of only including the pieces of configuration a target actually needs. For example, if you build Java binary //:j
with C++ dependency //:c
, it's wasteful to include the value of --javacopt
in the configuration of //:c
because changing --javacopt
unnecessarily breaks C++ build cacheability.
A query tool that queries over configured targets (after the analysis phase completes). This means select()
and build flags (e.g. --platforms
) are accurately reflected in the results.
See also: cquery documentation
The result of evaluating a target with a configuration. The analysis phase produces this by combining the build's options with the targets that need to be built. For example, if //:foo
builds for two different architectures in the same build, it has two configured targets: <//:foo, x86>
and <//:foo, arm>
.
A build is correct when its output faithfully reflects the state of its transitive inputs. To achieve correct builds, Bazel strives to be hermetic, reproducible, and making build analysis and action execution deterministic.
A directed edge between two targets. A target //:foo
has a target dependency on target //:bar
if //:foo
's attribute values contain a reference to //:bar
. //:foo
has an action dependency on //:bar
if an action in //:foo
depends on an input artifact created by an action in //:bar
.
A data structure for collecting data on transitive dependencies. Optimized so that merging depsets is time and space efficient, because it’s common to have very large depsets (e.g. hundreds of thousands of files). Implemented to recursively refer to other depsets for space efficiency reasons. Rule implementations should not “flatten” depsets by converting them to lists unless the rule is at the top level of the build graph. Flattening large depsets incurs huge memory consumption. Also known as nested sets in Bazel's internal implementation.
See also: Depset documentation
A local on-disk blob store for the remote caching feature. Can be used in conjunction with an actual remote blob store.
A read-only directory containing files that Bazel would otherwise fetch from the internet using repository rules. Enables builds to run fully offline.
An execution strategy that selects between local and remote execution based on various heuristics, and uses the execution results of the faster successful method. Certain actions are executed faster locally (for example, linking) and others are faster remotely (for example, highly parallelizable compilation). A dynamic execution strategy can provide the best possible incremental and clean build times.
The third phase of a build. Executes the actions in the action graph created during the analysis phase. These actions invoke executables (compilers, scripts) to read and write artifacts. Spawn strategies control how these actions are executed: locally, remotely, dynamically, sandboxed, docker, and so on.
A directory in the workspace’s output base directory where local actions are executed in non-sandboxed builds. The directory contents are mostly symlinks of input artifacts from the workspace. The execution root also contains symlinks to external repositories as other inputs and the bazel-out
directory to store outputs. Prepared during the loading phase by creating a symlink forest of the directories that represent the transitive closure of packages on which a build depends. Accessible with bazel info execution_root
on the command line.
See Artifact.
A build is hermetic if there are no external influences on its build and test operations, which helps to make sure that results are deterministic and correct. For example, hermetic builds typically disallow network access to actions, restrict access to declared inputs, use fixed timestamps and timezones, restrict access to environment variables, and use fixed seeds for random number generators
An incremental build reuses the results of earlier builds to reduce build time and resource usage. Dependency checking and caching aim to produce correct results for this type of build. An incremental build is the opposite of a clean build.
An identifier for a target. A fully-qualified label such as //path/to/package:target
consists of //
to mark the workspace root directory, path/to/package
as the directory that contains the BUILD
file declaring the target, and :target
as the name of the target declared in the aforementioned BUILD
file. May also be prefixed with @my_repository//<..>
to indicate that the target is declared in an ]external repository] named my_repository
.
The first phase of a build where Bazel parses WORKSPACE
, BUILD
, and .bzl
files to create packages. Macros and certain functions like glob()
are evaluated in this phase. Interleaved with the second phase of the build, the analysis phase, to build up a target graph.
A mechanism to compose multiple rule target declarations together under a single Starlark function. Enables reusing common rule declaration patterns across BUILD
files. Expanded to the underlying rule target declarations during the loading phase.
See also: Macro documentation
A short, human-readable string selected by a rule author to quickly understand what an action in the rule is doing. Mnemonics can be used as identifiers for spawn strategy selections. Some examples of action mnemonics are Javac
from Java rules, CppCompile
from C++ rules, and AndroidManifestMerger
from Android rules.
Rules that are built into Bazel and implemented in Java. Such rules appear in .bzl
files as functions in the native module (for example, native.cc_library
or native.java_library
). User-defined rules (non-native) are created using Starlark.
A workspace-specific directory to store Bazel output files. Used to separate outputs from the workspace's source tree. Located in the output user root.
A group of files that is expected to be built when Bazel finishes building a target. Rules put their usual outputs in the “default output group” (e.g the .jar
file of a java_library
, .a
and .so
for cc_library
targets). The default output group is the output group whose artifacts are built when a target is requested on the command line. Rules can define more named output groups that can be explicitly specified in BUILD
files (filegroup
rule) or the command line (--output_groups
flag).
A user-specific directory to store Bazel‘s outputs. The directory name is derived from the user’s system username. Prevents output file collisions if multiple users are building the same project on the system at the same time. Contains subdirectories corresponding to build outputs of individual workspaces, also known as output bases.
The set of targets defined by a BUILD
file. A package‘s name is the BUILD
file’s path relative to the workspace root. A package can contain subpackages, or subdirectories containing BUILD
files, thus forming a package hierarchy.
A target representing a set of packages. Often used in visibility attribute values.
A “machine type” involved in a build. This includes the machine Bazel runs on (the “host” platform), the machines build tools execute on (“exec” platforms), and the machines targets are built for (“target platforms”).
A set of information passed from a rule target to other rule targets. Usually contains information like: compiler options, transitive source files, transitive output files, and build metadata. Frequently used in conjunction with depsets.
See also: Provider documentation
The process of analyzing a build graph to understand target properties and dependency structures. Bazel supports three query variants: query, cquery, and aquery.
A query tool that operates over the build‘s post-loading phase target graph. This is relatively fast, but can’t analyze the effects of select()
, build flags, artifacts, or build actions.
See also: Query how-to, Query reference
A shared content-addressable cache of files downloaded by Bazel for builds, shareable across workspaces. Enables offline builds after the initial download. Commonly used to cache files downloaded through repository rules like http_archive
and repository rule APIs like repository_ctx.download
. Files are cached only if their SHA-256 checksums are specified for the download.
The property of a build or test that a set of inputs to the build or test will always produce the same set of outputs every time, regardless of time, method, or environment. Note that this does not necessarily imply that the outputs are correct or the desired outputs.
A function implementation that registers a series of actions to be performed on input artifacts to produce a set of output artifacts. Rules can read values from attributes as inputs (e.g. deps, testonly, name). Rule targets also produce and pass along information that may be useful to other rule targets in the form of providers (e.g. DefaultInfo
provider).
See also: Rules documentation
The runtime dependencies of an executable target. Most commonly, the executable is the executable output of a test rule, and the runfiles are runtime data dependencies of the test. Before the invocation of the executable (during bazel test), Bazel prepares the tree of runfiles alongside the test executable according to their source directory structure.
See also: Runfiles documentation
A technique to isolate a running action inside a restricted and temporary execution root, helping to ensure that it doesn’t read undeclared inputs or write undeclared outputs. Sandboxing greatly improves hermeticity, but usually has a performance cost, and requires support from the operating system. The performance cost depends on the platform. On Linux, it's not significant, but on macOS it can make sandboxing unusable.
The core parallel, functional, and incremental evaluation framework of Bazel. https://bazel.build/designs/skyframe.html
A feature to embed additional information into Bazel-built artifacts. For example, this can be used for source control, build time and other workspace or environment-related information for release builds. Enable through the --workspace_status_command
flag and rules that support the stamp attribute.
The extension language for writing rules and macros. A restricted subset of Python (syntactically and grammatically) aimed for the purpose of configuration, and for better performance. Uses the .bzl
file extension. BUILD
files use an even more restricted version of Starlark (e.g. no def
function definitions). Formerly known as Skylark.
See also: Starlark language documentation
The set of flags specified between bazel
and the command, for example, bazel --host_jvm_debug
build. These flags modify the configuration of the Bazel server, so any modification to startup flags causes a server restart. Startup flags are not specific to any command.
A buildable unit. Can be a rule target, file target, or a package group. Rule targets are instantiated from rule declarations in BUILD
files. Depending on the rule implementation, rule targets can also be testable or runnable. Every file used in BUILD
files is a file target. Targets can depend on other targets via attributes (most commonly but not necessarily deps
). A configured target is a pair of target and build configuration.
An in-memory graph of targets and their dependencies. Produced during the loading phase and used as an input to the analysis phase.
A way to specify a group of targets on the command line. Commonly used patterns are :all
(all rule targets), :*
(all rule + file targets), ...
(current package and all subpackages recursively). Can be used in combination, for example, //...:*
means all rule and file targets in all packages recursively from the root of the workspace.
Rule targets instantiated from test rules, and therefore contains a test executable. A return code of zero from the completion of the executable indicates test success. The exact contract between Bazel and tests (e.g. test environment variables, test result collection methods) is specified in the Test Encyclopedia.
A set of tools to build outputs for a language. Typically, a toolchain includes compilers, linkers, interpreters or/and linters. A toolchain can also vary by platform, that is, a Unix compiler toolchain's components may differ for the Windows variant, even though the toolchain is for the same language. Selecting the right toolchain for the platform is known as toolchain resolution.
A build target is top-level if it’s requested on the Bazel command line. For example, if //:foo
depends on //:bar
, and bazel build //:foo
is called, then for this build, //:foo
is top-level, and //:bar
isn’t top-level, although both targets will need to be built. An important difference between top-level and non-top-level targets is that command flags set on the Bazel command line (or via .bazelrc) will set the configuration for top-level targets, but might be modified by a transition for non-top-level targets.
A mapping of configuration state from one value to another. Enables targets in the build graph to have different configurations, even if they were instantiated from the same rule. A common usage of transitions is with split transitions, where certain parts of the target graph is forked with distinct configurations for each fork. For example, one can build an Android APK with native binaries compiled for ARM and x86 using split transitions in a single build.
See also: User-defined transitions
See Artifact.
Defines whether a target can be depended upon by other targets. By default, target visibility is private. That is, the target can only be depended upon by other targets in the same package. Can be made visible to specific packages or be completely public.
See also: Visibility documentation
A directory containing a WORKSPACE
file and source code for the software you want to build. Labels that start with //
are relative to the workspace directory.
Defines a directory to be a workspace. The file can be empty, although it usually contains external repository declarations to fetch additional dependencies from the network or local filesystem.