a778282a15
BEGIN_PUBLIC Fix action label evaluation in cc_sysroot Explicitly converts action labels in cc_sysroot to Label objects to address issues where the labels were being evaluated as relative to the module instantiating cc_sysroot rules. END_PUBLIC PiperOrigin-RevId: 667520654 Change-Id: Ia64306cc172dfaa747ef28a92390bcd90296b109 |
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.. | ||
actions | ||
args | ||
features | ||
impl | ||
variables | ||
BUILD | ||
README.md | ||
actions.bzl | ||
args.bzl | ||
args_list.bzl | ||
cc_flags_supplier.bzl | ||
cc_toolchain.bzl | ||
cc_toolchain_config_info.bzl | ||
cc_toolchain_info.bzl | ||
cc_toolchain_suite.bzl | ||
compiler_flag.bzl | ||
directory_tool.bzl | ||
fdo_prefetch_hints.bzl | ||
fdo_profile.bzl | ||
feature.bzl | ||
feature_constraint.bzl | ||
feature_set.bzl | ||
memprof_profile.bzl | ||
mutually_exclusive_category.bzl | ||
nested_args.bzl | ||
propeller_optimize.bzl | ||
tool.bzl | ||
tool_map.bzl | ||
toolchain.bzl |
README.md
Writing a custom rule_based C++ toolchain with rule-based definition.
Work in progress!
This document serves two purposes:
- Until complete, this serves as an agreement for the final user-facing API.
- Once complete, this will serve as onboarding documentation.
This section will be removed once complete.
Step 1: Define tools
A tool is simply a binary. Just like any other bazel binary, a tool can specify additional files required to run.
We can use any bazel binary as an input to anything that requires tools. In the example below, you could use both clang and ld as tools.
# @sysroot//:BUILD
cc_tool(
name = "clang",
exe = ":bin/clang",
execution_requirements = ["requires-mem:24g"],
data = [...],
)
sh_binary(
name = "ld",
srcs = ["ld_wrapper.sh"],
data = [":bin/ld"],
)
Step 2: Generate action configs from those tools
An action config is a mapping from action to:
- A list of tools, (the first one matching the execution requirements is used).
- A list of args and features that are always enabled for the action
- A set of additional files required for the action
Each action can only be specified once in the toolchain. Specifying multiple
actions in a single cc_action_type_config
is just a shorthand for specifying the
same config for every one of those actions.
If you're already familiar with how to define toolchains, the additional files
is a replacement for compile_files
, link_files
, etc.
Additionally, to replace all_files
, we add cc_additional_files_for_actions
.
This allows you to specify that particular files are required for particular
actions.
We provide additional_files
on the cc_action_type_config
as a shorthand for
specifying cc_additional_files_for_actions
Warning: Implying a feature that is not listed directly in the toolchain will throw an error. This is to ensure you don't accidentally add a feature to the toolchain.
cc_action_type_config(
name = "c_compile",
actions = ["@rules_cc//actions:all_c_compile"],
tools = ["@sysroot//:clang"],
args = [":my_args"],
implies = [":my_feature"],
additional_files = ["@sysroot//:all_header_files"],
)
cc_additional_files_for_actions(
name = "all_action_files",
actions = ["@rules_cc//actions:all_actions"],
additional_files = ["@sysroot//:always_needed_files"]
)
Step 3: Define some arguments
Arguments are our replacement for flag_set
and env_set
. To add arguments to
our tools, we take heavy inspiration from bazel's
Args
type. We provide the same
API, with the following caveats:
actions
specifies which actions the arguments apply to (same asflag_set
).requires_any_of
is equivalent towith_features
on theflag_set
.args
may be used instead ofadd
if your command-line is only strings.env
may be used to add environment variables to the arguments. Environment variables set by later args take priority.- By default, all inputs are automatically added to the corresponding actions.
additional_files
specifies files that are required for an action when using that argument.
cc_args(
name = "inline",
actions = ["@rules_cc//actions:all_cpp_compile_actions"],
args = ["--foo"],
requires_any_of = [":feature"]
env = {"FOO": "bar"},
additional_files = [":file"],
)
For more complex use cases, we use the same API as Args
. Values are either:
- A list of files (or a single file for
cc_add_args
). - Something returning
CcVariableInfo
, which is equivalent to a list of strings.
cc_variable(
name = "bar_baz",
values = ["bar", "baz"],
)
# Expands to CcVariableInfo(values = ["x86_64-unknown-linux-gnu"])
custom_variable_rule(
name = "triple",
...
)
# Taken from https://bazel.build/rules/lib/builtins/Args#add
cc_add_args(
name = "single",
arg_name = "--platform",
value = ":triple", # Either a single file or a cc_variable
format = "%s",
)
# Taken from https://bazel.build/rules/lib/builtins/Args#add_all
cc_add_args_all(
name = "multiple",
arg_name = "--foo",
values = [":file", ":file_set"], # Either files or cc_variable.
# map_each not supported. Write a custom rule if you want that.
format_each = "%s",
before_each = "--foo",
omit_if_empty = True,
uniquify = False,
# Expand_directories not yet supported.
terminate_with = "foo",
)
# Taken from https://bazel.build/rules/lib/builtins/Args#add_joined
cc_add_args_joined(
name = "joined",
arg_name = "--foo",
values = [":file", ":file_set"], # Either files or cc_variable.
join_with = ",",
# map_each not supported. Write a custom rule if you want that.
format_each = "%s",
format_joined = "--foo=%s",
omit_if_empty = True,
uniquify = False,
# Expand_directories not yet supported.
)
cc_args(
name = "complex",
actions = ["@rules_cc//actions:c_compile"],
add = [":single", ":multiple", ":joined"],
)
cc_args_list(
name = "all_flags",
args = [":inline", ":complex"],
)
Step 4: Define some features
A feature is a set of args and configurations that can be enabled or disabled.
Although the existing toolchain recommends using features to avoid duplication
of definitions, we recommend avoiding using features unless you want the user to
be able to enable / disable the feature themselves. This is because we provide
alternatives such as cc_args_list
to allow combining arguments and
specifying them on each action in the action config.
cc_feature(
name = "my_feature",
feature_name = "my_feature",
args = [":all_args"],
implies = [":other_feature"],
)
Step 5: Generate the toolchain
The cc_toolchain
macro:
- Performs validation on the inputs (eg. no two action configs for a single action)
- Converts the type-safe providers to the unsafe ones in
cc_toolchain_config_lib.bzl
- Generates a set of providers for each of the filegroups respectively
- Generates the appropriate
native.cc_toolchain
invocation.
cc_toolchain(
name = "toolchain",
features = [":my_feature"]
unconditional_args = [":all_warnings"],
action_type_configs = [":c_compile"],
additional_files = [":all_action_files"],
)
Ancillary components for type-safe toolchains.
Well-known features
Well-known features will be defined in @rules_cc//features/well_known:*
.
Any feature with feature_name
in the well known features will have to specify
overrides.
cc_toolchain
is aware of the builtin / well-known features. In order to
ensure that a user understands that this overrides the builtin opt feature (I
originally thought that it added extra flags to opt, but you still got the
default ones, so that can definitely happen), and to ensure that they don't
accidentally do so, we will force them to explicitly specify that it overrides
the builtin one. This is essentially just an acknowledgement of "I know what
I'm doing".
Warning: Specifying two features with the same name is an error, unless one overrides the other.
cc_feature(
name = "opt",
...,
overrides = "@rules_cc//features/well_known:opt",
)
In addition to well-known features, we could also consider in future iterations to also use known features for partial migrations, where you still imply a feature that's still defined by the legacy API:
# Implementation
def cc_legacy_features(name, features):
for feature in features:
cc_known_feature(name = name + "_" + feature.name)
cc_legacy_features(name = name, features = FEATURES)
# Build file
FOO = feature(name = "foo", args=[arg_group(...)])
FEATURES = [FOO]
cc_legacy_features(name = "legacy_features", features = FEATURES)
cc_feature(name = "bar", implies = [":legacy_features_foo"])
cc_toolchain(
name = "toolchain",
legacy_features = ":legacy_features",
features = [":bar"],
)
Mutual exclusion
Features can be mutually exclusive.
We allow two approaches to mutual exclusion - via features or via categories.
The existing toolchain uses provides
for both of these. We rename it so that
it makes more sense semantically.
cc_feature(
name = "incompatible_with_my_feature",
feature_name = "bar",
mutually_exclusive = [":my_feature"],
)
# This is an example of how we would define compilation mode.
# Since it already exists, this wouldn't work.
cc_mutual_exclusion_category(
name = "compilation_mode",
)
cc_feature(
name = "opt",
...
mutually_exclusive = [":compilation_mode"],
)
cc_feature(
name = "dbg",
...
mutually_exclusive = [":compilation_mode"],
)
Feature requirements
Feature requirements can come in two formats.
For example:
- Features can require some subset of features to be enabled.
- Arguments can require some subset of features to be enabled, but others to be disabled.
This is very confusing for toolchain authors, so we will simplify things with the use of providers:
cc_feature
will providefeature
,feature_set
, andwith_feature
cc_feature_set
will providefeature_set
andwith_feature
.cc_feature_constraint
will providewith_features
only.
We will rename all with_features
and requires
to requires_any_of
, to make
it very clear that only one of the requirements needs to be met.
cc_feature_set(
name = "my_feature_set",
all_of = [":my_feature"],
)
cc_feature_constraint(
name = "my_feature_constraint",
all_of = [":my_feature"],
none_of = [":my_other_feature"],
)
cc_args(
name = "foo",
# All of these provide with_feature.
requires_any_of = [":my_feature", ":my_feature_set", ":my_feature_constraint"]
)
# my_feature_constraint would be an error here.
cc_feature(
name = "foo",
# Both of these provide feature_set.
requires_any_of = [":my_feature", ":my_feature_set"]
implies = [":my_other_feature", :my_other_feature_set"],
)