Bazel has sophisticated support for modeling platforms and toolchains. Integrating this into real projects requires coherent cooperation between project and library owners, rule maintainers, and core Bazel devs.
This page summarizes the arguments for using platforms and shows how to navigate these relationships for maximum value with minimum cognitive overhead.
In short: the core APIs are available but the rule and depot migrations required to make them work universally are ongoing. This means you may be able to use platforms and toolchains with your project, with some work. But you have to explicitly opt your project in.
For more formal documentation, see:
Platforms and toolchains were introduced to standardize the need for software projects to target different kinds of computers with different language-appropriate tools.
This is a relatively recent addition to Bazel. It was inspired by the observation that language maintainers were already doing this in ad hoc and incompatible ways. For example, C++ rules use --cpu
and --crosstool_top
to set a build‘s target CPU and C++ toolchain. Neither of these correctly models a “platform”. Historic attempts to use them for that inevitably led to awkward and inaccurate build APIs. They also don’t say anything about Java toolchains, which evolved their own independent interface with --java_toolchain
.
Bazel aims to excel at large, mixed-language, multi-platform projects. This demands more principled support for these concepts, including clear APIs that bind rather than diverge languages and projects. This is what the new platform and toolchain APIs achieve.
These APIs aren‘t enough for all projects to use platforms, and the old APIs have to be retired. This isn’t trivial because all of a project's languages, toolchains, dependencies, and select()
s have to support the new APIs. This requires an ordered migration sequence to keep projects working correctly.
For example, Bazel‘s C++ Rules aleady support platforms while the Android Rules don’t. Your C++ project may not care about Android. But others may. So it's not yet safe to globally enable platforms for all C++ builds.
The remainder of this page describes this migration sequence and how and when your projects can fit in.
Bazel's platform migration is complete when all projects build with the form:
$ bazel build //:myproject --platforms=//:myplatform
This implies:
//:myplatform
.//:myplatform
.//:myplatform
or your project supports the legacy APIs (like --crosstool_top
).//:myplatform
references [common declarations][Common Platform Declaration] of CPU
, OS
, and other generic concepts that support automatic cross-project compatibility.select()
s understand the machine properties implied by //:myplatform
.//:myplatform
is defined in a clear, reusable place: in your project's repo if the platform is unique to your project, otherwise somewhere all projects that may use this platform can find.The old APIs will be removed as soon as this goal is achieved and this will become the standard way projects select platforms and toolchains.
If you just want to build or cross-compile a project, you should follow the project’s official documentation.
If you’re a project, language, or toolchain maintainer, you'll eventually want to support the new APIs. Whether you wait until the global migration is complete or opt in early depends on your specific value / cost needs:
select()
or choose toolchains on the exact properties you care about instead of hard-coded flags like --cpu
. For example, multiple CPUs can support the same instruction set.select()
with --cpu
in the above example, then add a new CPU that supports the same instruction set, the select()
fails to recognize the new CPU. But a select()
on platforms remains accurate.--platforms=//:myplatform
. No need for multiple language-specific flags on the command line.OS
and CPU
are still evolving and may require extra initial contributions.A platform
is a collection of constraint_value
targets:
platform( name = "myplatform", constraint_values = [ "@platforms//os:linux", "@platforms//cpu:arm", ], )
A constraint_value
is a machine property. Values of the same “kind” are grouped under a common constraint_setting
:
constraint_setting(name = "os") constraint_value( name = "linux", constraint_setting = ":os", ) constraint_value( name = "mac", constraint_setting = ":os", )
A toolchain
is a Starlark rule. Its attributes declare a language's tools (like compiler = "//mytoolchain:custom_gcc"
). Its providers pass this information to rules that need to build with these tools.
Toolchains declare the constraint_value
s of machines they can target (target_compatible_with = ["@platforms//os:linux"]
) and machines their tools can run on (exec_compatible_with = ["@platforms//os:mac"]
).
When building $ bazel build //:myproject --platforms=//:myplatform
, Bazel automatically selects a toolchain that can run on the build machine and build binaries for //:myplatform
. This is known as toolchain resolution.
The set of available toolchains can be registered in the WORKSPACE
with register_toolchains
or at the command line with --extra_toolchains
.
See here for a deeper dive.
Current platform support varies among languages. All of Bazel's major rules are moving to platforms. But this process will take time. This is for three main reasons:
Rule logic must be updated to get tool info from the new toolchain API (ctx.toolchains
) and stop reading legacy settings like --cpu
and --crosstool_top
. This is relatively straightforward.
Toolchain maintainers must define toolchains and make them accessible to users (in GitHub repositories and WORKSPACE
entries). This is technically straightforward but must be intelligently organized to maintain an easy user experience.
Platform definitions are also necessary (unless you build for the same machine Bazel runs on). Generally, projects should define their own platforms.
Existing projects must be migrated. select()
s and transitions also have to be migrated. This is the biggest challenge. It‘s particularly challenging for multi-language projects (which may fail if all languages can’t read --platforms
).
If you're designing a new rule set, you must support platforms from the beginning. This automatically makes your rules compatible with other rules and projects, with increasing value as the platform API becomes more ubiquitious.
Details:
Platform properties like OS
and CPU
that are common across projects should be declared in a standard, centralized place. This encourages cross-project and cross-language compatibility.
For example, if MyApp has a select()
on constraint_value
@myapp//cpus:arm
and SomeCommonLib has a select()
on @commonlib//constraints:arm
, these trigger their “arm” modes with incompatible criteria.
Globally common properties are declared in the @platforms
repo (so the canonical label for the above example is @platforms//cpu:arm
). Language-common properties should be declared in the repos of their respective languages.
Generally, project owners should define explicit platforms to describe the kinds of machines they want to build for. These are then triggered with --platforms
.
When --platforms
isn‘t set, Bazel defaults to a platform
representing the local build machine. This is auto-generated at @local_config_platform//:host
so there’s no need to explicitly define it. It maps the local machine's OS
and CPU
with constraint_value
s declared in @platforms
.
Bazel's C++ rules use platforms to select toolchains when you set --incompatible_enable_cc_toolchain_resolution
(#7260).
This means you can configure a C++ project with
$ bazel build //:my_cpp_project --platforms=//:myplatform
instead of the legacy
$ bazel build //:my_cpp_project` --cpu=... --crosstool_top=... --compiler=...
If your project is pure C++ and not depended on by non-C++ projects, you can use this mode safely as long as your select
s and transitions also work with platforms. See #7260 and Configuring C++ toolchains for further migration guidance.
This mode is not enabled by default. This is because Android and iOS projects still configure C++ dependencies with --cpu
and --crosstool_top
(example). Enabling it requires adding platform support for Android and iOS.
Bazel's Java rules use platforms and configuration flags to select toolchains.
This replaces legacy flags --java_toolchain
, --host_java_toolchain
, --javabase
, and --host_javabase
.
To learn how to use the configuration flags, see the Bazel and Java manual. For additional information, see the Design document.
If you are still using legacy flags, follow the migration process in Issue #7849. -->
Bazel's Android rules do not yet support platforms to select Android toolchains.
They do support setting --platforms
to select NDK toolchains: see here.
Most importantly, --fat_apk_cpu
, which builds multi-architecture fat APKs, does not work with platform-enabled C++. This is because it sets legacy flags like --cpu
and --crosstool_top
, which platform-enabled C++ rules don't read. Until this is migrated, using --fat_apk_cpu
with --platforms
requires platform mappings.
Bazel's Apple rules do not yet support platforms to select Apple toolchains.
They also don't support platform-enabled C++ dependencies because they use the legacy --crosstool_top
to set the C++ toolchain. Until this is migrated, you can mix Apple projects with platorm-enabled C++ with platform mappings (example).
If you‘re designing rules for a new language, use platforms to select your language’s toolchains. See the toolchains documentation for a good walkthrough.
select()
Projects can select()
on constraint_value
targets but not complete platforms. This is intentional so that select()
s supports as wide a variety of machines as possible. A library with ARM
-specific sources should support all ARM
-powered machines unless there's reason to be more specific.
To select on one or more constraint_value
s, use
config_setting( name = "is_arm", constraint_values = [ "@platforms//cpu:arm", ], )
This is equivalent to traditionally selecting on --cpu
:
config_setting( name = "is_arm", values = { "cpu": "arm", }, )
More details here.
select
s on --cpu
, --crosstool_top
, etc. don't understand --platforms
. When migrating your project to platforms, you must either convert them to constraint_values
or use platform mappings to support both styles through the migration window.
Starlark transitions change flags down parts of your build graph. If your project uses a transition that sets --cpu
, --crossstool_top
, or other legacy flags, rules that read --platforms
won't see these changes.
When migrating your project to platforms, you must either convert changes like return { "//command_line_option:cpu": "arm" }
to return { "//command_line_options:platforms": "//:my_arm_platform" }
or use platform mappings to support both styles through the migration window.
If you just want to build or cross-compile a project, you should follow the project‘s official documentation. It’s up to language and project maintainers to determine how and when to integrate with platforms, and what value that offers.
If you‘re a project, language, or toolchain maintainer and your build doesn’t use platforms by default, you have three options (besides waiting for the global migration):
Flip on the “use platforms” flag for your project's languages (if they have one) and do whatever testing you need to see if the projects you care about work.
If the projects you care about still depend on legacy flags like --cpu
and --crosstool_top
, use these together with --platforms
:
$ bazel build //:my_mixed_project --platforms==//:myplatform --cpu=... --crosstool_top=...
This has some maintenance cost (you have to manually make sure the settings match). But this should work in the absence of renegade transitions.
Write platform mappings to support both styles by mapping --cpu
-style settings to corresponding platforms and vice versa.
Platform mappings is a temporary API that lets platform-powered and legacy-powered logic co-exist in the same build through the latter's deprecation window.
A platform mapping is a map of either a platform()
to a corresponding set of legacy flags or the reverse. For example:
platforms: # Maps "--platforms=//platforms:ios" to "--cpu=ios_x86_64 --apple_platform_type=ios". //platforms:ios --cpu=ios_x86_64 --apple_platform_type=ios flags: # Maps "--cpu=ios_x86_64 --apple_platform_type=ios" to "--platforms=//platforms:ios". --cpu=ios_x86_64 --apple_platform_type=ios //platforms:ios # Maps "--cpu=darwin --apple_platform_type=macos" to "//platform:macos". --cpu=darwin --apple_platform_type=macos //platforms:macos
Bazel uses this to guarantee all settings, both platform-based and legacy, are consistently applied throughout the build, including through transitions.
By default Bazel reads mappings from the platform_mappings
file in your workspace root. You can also set --platform_mappings=//:my_custom_mapping
.
See here for complete details.
For general support and questions about the migration timeline, contact bazel-discuss@googlegroups.com or the owners of the appropriate rules.
For discussions on the design and evolution of the platform/toolchain APIs, contact bazel-dev@googlegroups.com.