blob: c12b37ee4940b4c9517469629bfc5e22eb931d8c [file] [log] [blame]
# Rules for distributable C++ libraries
load("@rules_cc//cc:action_names.bzl", cc_action_names = "ACTION_NAMES")
load("@rules_cc//cc:find_cc_toolchain.bzl", "find_cc_toolchain")
################################################################################
# Archive/linking support
################################################################################
def _collect_linker_input_objects(dep_label, cc_info, objs, pic_objs):
"""Accumulate .o and .pic.o files into `objs` and `pic_objs`."""
link_ctx = cc_info.linking_context
if link_ctx == None:
return
linker_inputs = link_ctx.linker_inputs.to_list()
for link_input in linker_inputs:
if link_input.owner != dep_label:
# This is a transitive dep: skip it.
continue
for lib in link_input.libraries:
objs.extend(lib.objects or [])
pic_objs.extend(lib.pic_objects or [])
# Creates an action to build the `output_file` static library (archive)
# using `object_files`.
def _create_archive_action(
ctx,
feature_configuration,
cc_toolchain_info,
output_file,
object_files):
# Based on Bazel's src/main/starlark/builtins_bzl/common/cc/cc_import.bzl:
# Build the command line and add args for all of the input files:
archiver_variables = cc_common.create_link_variables(
feature_configuration = feature_configuration,
cc_toolchain = cc_toolchain_info,
output_file = output_file.path,
is_using_linker = False,
)
command_line = cc_common.get_memory_inefficient_command_line(
feature_configuration = feature_configuration,
action_name = cc_action_names.cpp_link_static_library,
variables = archiver_variables,
)
args = ctx.actions.args()
args.add_all(command_line)
args.add_all(object_files)
args.use_param_file("@%s", use_always = True)
archiver_path = cc_common.get_tool_for_action(
feature_configuration = feature_configuration,
action_name = cc_action_names.cpp_link_static_library,
)
env = cc_common.get_environment_variables(
feature_configuration = feature_configuration,
action_name = cc_action_names.cpp_link_static_library,
variables = archiver_variables,
)
ctx.actions.run(
executable = archiver_path,
arguments = [args],
env = env,
inputs = depset(
direct = object_files,
transitive = [
cc_toolchain_info.all_files,
],
),
use_default_shell_env = False,
outputs = [output_file],
mnemonic = "CppArchiveDist",
)
def _create_dso_link_action(
ctx,
feature_configuration,
cc_toolchain_info,
object_files,
pic_object_files):
compilation_outputs = cc_common.create_compilation_outputs(
objects = depset(object_files),
pic_objects = depset(pic_object_files),
)
link_output = cc_common.link(
actions = ctx.actions,
feature_configuration = feature_configuration,
cc_toolchain = cc_toolchain_info,
compilation_outputs = compilation_outputs,
name = ctx.label.name,
output_type = "dynamic_library",
user_link_flags = ctx.attr.linkopts,
)
library_to_link = link_output.library_to_link
outputs = []
# Note: library_to_link.dynamic_library and interface_library are often
# symlinks in the solib directory. For DefaultInfo, prefer reporting
# the resolved artifact paths.
if library_to_link.resolved_symlink_dynamic_library != None:
outputs.append(library_to_link.resolved_symlink_dynamic_library)
elif library_to_link.dynamic_library != None:
outputs.append(library_to_link.dynamic_library)
if library_to_link.resolved_symlink_interface_library != None:
outputs.append(library_to_link.resolved_symlink_interface_library)
elif library_to_link.interface_library != None:
outputs.append(library_to_link.interface_library)
return outputs
################################################################################
# Source file/header support
################################################################################
CcFileList = provider(
doc = "List of files to be built into a library.",
fields = {
# As a rule of thumb, `hdrs` and `textual_hdrs` are the files that
# would be installed along with a prebuilt library.
"hdrs": "public header files, including those used by generated code",
"textual_hdrs": "files which are included but are not self-contained",
# The `internal_hdrs` are header files which appear in `srcs`.
# These are only used when compiling the library.
"internal_hdrs": "internal header files (only used to build .cc files)",
"srcs": "source files",
},
)
def _flatten_target_files(targets):
return depset(transitive = [
target.files
for target in targets
# Filter out targets from external workspaces. We also filter out
# utf8_range since that has a separate CMake build for now.
if (target.label.workspace_name == "" or
target.label.workspace_name == "com_google_protobuf") and
not target.label.package.startswith("third_party/utf8_range")
])
def _get_transitive_sources(targets, attr, deps):
return depset(targets, transitive = [getattr(dep[CcFileList], attr) for dep in deps if CcFileList in dep])
def _cc_file_list_aspect_impl(target, ctx):
# Extract sources from a `cc_library` (or similar):
if CcInfo not in target:
return []
# We're going to reach directly into the attrs on the traversed rule.
rule_attr = ctx.rule.attr
# CcInfo is a proxy for what we expect this rule to look like.
# However, some deps may expose `CcInfo` without having `srcs`,
# `hdrs`, etc., so we use `getattr` to handle that gracefully.
internal_hdrs = []
srcs = []
# Filter `srcs` so it only contains source files. Headers will go
# into `internal_headers`.
for src in _flatten_target_files(getattr(rule_attr, "srcs", [])).to_list():
if src.extension.lower() in ["c", "cc", "cpp", "cxx"]:
srcs.append(src)
else:
internal_hdrs.append(src)
return [CcFileList(
hdrs = _get_transitive_sources(
_flatten_target_files(getattr(rule_attr, "hdrs", [])).to_list(),
"hdrs",
rule_attr.deps,
),
textual_hdrs = _get_transitive_sources(
_flatten_target_files(getattr(rule_attr, "textual_hdrs", [])).to_list(),
"textual_hdrs",
rule_attr.deps,
),
internal_hdrs = _get_transitive_sources(
internal_hdrs,
"internal_hdrs",
rule_attr.deps,
),
srcs = _get_transitive_sources(srcs, "srcs", rule_attr.deps),
)]
cc_file_list_aspect = aspect(
doc = """
Aspect to provide the list of sources and headers from a rule.
Output is CcFileList. Example:
cc_library(
name = "foo",
srcs = [
"foo.cc",
"foo_internal.h",
],
hdrs = ["foo.h"],
textual_hdrs = ["foo_inl.inc"],
)
# produces:
# CcFileList(
# hdrs = depset([File("foo.h")]),
# textual_hdrs = depset([File("foo_inl.inc")]),
# internal_hdrs = depset([File("foo_internal.h")]),
# srcs = depset([File("foo.cc")]),
# )
""",
required_providers = [CcInfo],
implementation = _cc_file_list_aspect_impl,
attr_aspects = ["deps"],
)
################################################################################
# Rule impl
################################################################################
def _collect_inputs(deps):
"""Collects files from a list of deps.
This rule collects source files and linker inputs transitively for C++
deps.
The return value is a struct with object files (linker inputs),
partitioned by PIC and non-pic, and the rules' source and header files:
struct(
objects = ..., # non-PIC object files
pic_objects = ..., # PIC objects
cc_file_list = ..., # a CcFileList
)
Args:
deps: Iterable of immediate deps, which will be treated as roots to
recurse transitively.
Returns:
A struct with linker inputs, source files, and header files.
"""
objs = []
pic_objs = []
# The returned CcFileList will contain depsets of the deps' file lists.
# These lists hold `depset()`s from each of `deps`.
srcs = []
hdrs = []
internal_hdrs = []
textual_hdrs = []
for dep in deps:
if CcInfo in dep:
_collect_linker_input_objects(
dep.label,
dep[CcInfo],
objs,
pic_objs,
)
if CcFileList in dep:
cfl = dep[CcFileList]
srcs.append(cfl.srcs)
hdrs.append(cfl.hdrs)
internal_hdrs.append(cfl.internal_hdrs)
textual_hdrs.append(cfl.textual_hdrs)
return struct(
objects = objs,
pic_objects = pic_objs,
cc_file_list = CcFileList(
srcs = depset(transitive = srcs),
hdrs = depset(transitive = hdrs),
internal_hdrs = depset(transitive = internal_hdrs),
textual_hdrs = depset(transitive = textual_hdrs),
),
)
# Given structs a and b returned from _collect_inputs(), returns a copy of a
# but with all files from b subtracted out.
def _subtract_files(a, b):
result_args = {}
top_level_fields = ["objects", "pic_objects"]
for field in top_level_fields:
to_remove = {e: None for e in getattr(b, field)}
result_args[field] = [e for e in getattr(a, field) if not e in to_remove]
cc_file_list_args = {}
file_list_fields = ["srcs", "hdrs", "internal_hdrs", "textual_hdrs"]
for field in file_list_fields:
# only a subset of file.cc is used from protoc, to get all its symbols for tests we need to
# also build & link it to tests.
to_remove = {e: None for e in getattr(b.cc_file_list, field).to_list() if "src/google/protobuf/testing/file.cc" not in e.path}
cc_file_list_args[field] = depset(
[e for e in getattr(a.cc_file_list, field).to_list() if not e in to_remove],
)
result_args["cc_file_list"] = CcFileList(**cc_file_list_args)
return struct(**result_args)
# Implementation for cc_dist_library rule.
def _cc_dist_library_impl(ctx):
cc_toolchain_info = find_cc_toolchain(ctx)
feature_configuration = cc_common.configure_features(
ctx = ctx,
cc_toolchain = cc_toolchain_info,
)
inputs = _subtract_files(_collect_inputs(ctx.attr.deps), _collect_inputs(ctx.attr.dist_deps))
# For static libraries, build separately with and without pic.
stemname = "lib" + ctx.label.name
outputs = []
if len(inputs.objects) > 0:
archive_out = ctx.actions.declare_file(stemname + ".a")
_create_archive_action(
ctx,
feature_configuration,
cc_toolchain_info,
archive_out,
inputs.objects,
)
outputs.append(archive_out)
if len(inputs.pic_objects) > 0:
pic_archive_out = ctx.actions.declare_file(stemname + ".pic.a")
_create_archive_action(
ctx,
feature_configuration,
cc_toolchain_info,
pic_archive_out,
inputs.pic_objects,
)
outputs.append(pic_archive_out)
# For dynamic libraries, use the `cc_common.link` command to ensure
# everything gets built correctly according to toolchain definitions.
outputs.extend(_create_dso_link_action(
ctx,
feature_configuration,
cc_toolchain_info,
inputs.objects,
inputs.pic_objects,
))
# We could expose the libraries for use from cc rules:
#
# linking_context = cc_common.create_linking_context(
# linker_inputs = depset([
# cc_common.create_linker_input(
# owner = ctx.label,
# libraries = depset([library_to_link]),
# ),
# ]),
# )
# cc_info = CcInfo(linking_context = linking_context) # and return this
#
# However, if the goal is to force a protobuf dependency to use the
# DSO, then `cc_import` is a better-supported way to do so.
#
# If we wanted to expose CcInfo from this rule (and make it usable as a
# C++ dependency), then we would probably want to include the static
# archive and headers as well. exposing headers would probably require
# an additional aspect to extract CcInfos with just the deps' headers.
return [
DefaultInfo(files = depset(outputs)),
inputs.cc_file_list,
]
cc_dist_library = rule(
implementation = _cc_dist_library_impl,
doc = """
Create libraries suitable for distribution.
This rule creates static and dynamic libraries from the libraries listed in
'deps'. The resulting libraries are suitable for distributing all of 'deps'
in a single logical library, for example, in an installable binary package.
The result includes all transitive dependencies, excluding those reachable
from 'dist_deps' or defined in a separate repository (e.g. Abseil).
The outputs of this rule are a dynamic library and a static library. (If
the build produces both PIC and non-PIC object files, then there is also a
second static library.) The example below illustrates additional details.
This rule is different from Bazel's experimental `shared_cc_library` in two
ways. First, this rule produces a static archive library in addition to the
dynamic shared library. Second, this rule is not directly usable as a C++
dependency (although the outputs could be used, e.g., by `cc_import`).
Example:
cc_library(name = "a", srcs = ["a.cc"], hdrs = ["a.h"])
cc_library(name = "b", srcs = ["b.cc"], hdrs = ["b.h"], deps = [":a"])
cc_library(name = "c", srcs = ["c.cc"], hdrs = ["c.h"], deps = [":b"])
# Creates libdist.so and (typically) libdist.pic.a:
# (This may also produce libdist.a if the build produces non-PIC objects.)
cc_dist_library(
name = "dist",
linkopts = ["-la"], # libdist.so dynamically links against liba.so.
deps = [":b", ":c"], # Output contains a.o, b.o, and c.o.
)
""",
attrs = {
"deps": attr.label_list(
doc = ("The list of libraries to be included in the outputs, " +
"along with their transitive dependencies."),
aspects = [cc_file_list_aspect],
),
"dist_deps": attr.label_list(
doc = ("The list of cc_dist_library dependencies that " +
"should be excluded."),
aspects = [cc_file_list_aspect],
),
"linkopts": attr.string_list(
doc = ("Add these flags to the C++ linker command when creating " +
"the dynamic library."),
),
# C++ toolchain before https://github.com/bazelbuild/bazel/issues/7260:
"_cc_toolchain": attr.label(
default = Label("@rules_cc//cc:current_cc_toolchain"),
),
},
toolchains = [
# C++ toolchain after https://github.com/bazelbuild/bazel/issues/7260:
"@bazel_tools//tools/cpp:toolchain_type",
],
fragments = ["cpp"],
)