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How Protobuf supports multiple C++ build systems
This document explains how the Protobuf project supports multiple C++ build systems.
Background
Protobuf primarily uses Bazel to build the Protobuf C++ runtime and Protobuf compiler1. However, there are several different build systems in common use for C++, each one of which requires essentially a complete copy of the same build definitions.
On a historical note, prior to its release as Open Source Software, the Protobuf project was developed using Google's internal build system, which was the predecessor to Bazel (the vast majority of Google's contributions continue to be developed this way). The Open Source Protobuf project, however, historically used Autoconf to build the C++ implementation. Over time, other build systems (including Bazel) have been added, thanks in large part to substantial contributions from the Open Source community. Since the Protobuf project deals with multiple languages (all of which ultimately rely upon C++, for the Protobuf compiler), Bazel is a natural choice for a project-wide build system -- in fact, Bazel (and its predecessor, Blaze) was designed in large part to support exactly this type of rich, multi-language build.
Currently, C++ Protobuf can be built with Bazel, Autotools, and CMake. Each of these build systems has different semantics and structure, but share in common the list of files needed to build the runtime and compiler.
Design
Extracting information from Bazel
Bazel's Starlark API provides aspects to
traverse the build graph, inspect build rules, define additional actions, and
expose information through
providers. For example, the
cc_proto_library
rule uses an aspect to traverse the dependency graph of
proto_library
rules, and dynamically attaches actions to generate C++ code
using the Protobuf compiler and compile using the C++ compiler.
In order to support multiple build systems, the overall build structure is defined once for each system, and expose frequently-changing metadata from Bazel in a way that can be included from the build definition. Primarily, this means exposing the list of source files in a way that can be included in other build definitions.
Two aspects are used to extract this information from the Bazel build definitions:
cc_file_list_aspect
extractssrcs
,hdrs
, andtextual_hdrs
from build rules likecc_library
. The sources are exposed through a provider namedCcFileList
.proto_file_list_aspect
extracts thesrcs
from aproto_library
, and also generates the expected filenames that would be generated by the Protobuf compiler. This information is exposed through a provider namedProtoFileList
.
On their own, these aspects have limited utility. However, they can be
instantiated by custom rules, so that an ordinary BUILD.bazel
target can
produce outputs based on the information gleaned from these aspects.
(Aside) Distribution libraries
Bazel's native cc_library
rule is typically used on a "fine-grained" level, so
that, for example, lightweight unit tests can be written with narrow scope.
Although Bazel does build library artifacts (such as .so
and .a
files on
Linux), they correspond to cc_library
rules.
Since the entire "Protobuf library" includes many constituent cc_library
rules, a special rule, cc_dist_library
, combines several fine-grained
libraries into a single, monolithic library.
For the Protobuf project, these "distribution libraries" are intended to match
the granularity of the Autotools- and CMake-based builds. Since the Bazel-built
distribution library covers the rules with the source files needed by other
builds, the cc_dist_library
rule invokes the cc_file_list_aspect
on its
input libraries. The result is that a cc_dist_library
rule not only produces
composite library artifacts, but also collect and provide the list of sources
that were inputs.
For example:
$ cat cc_dist_library_example/BUILD.bazel
load("@rules_cc//cc:defs.bzl", "cc_library")
load("//pkg:cc_dist_library.bzl", "cc_dist_library")
cc_library(
name = "a",
srcs = ["a.cc"],
)
cc_library(
name = "b",
srcs = ["b.cc"],
deps = [":c"],
)
# N.B.: not part of the cc_dist_library, even though it is in the deps of 'b':
cc_library(
name = "c",
srcs = ["c.cc"],
)
cc_dist_library(
name = "lib",
deps = [
":a",
":b",
],
visbility = ["//visibility:public"],
)
# Note: the output below has been formatted for clarity:
$ bazel cquery //cc_dist_library_example:lib \
--output=starlark \
--starlark:expr='providers(target)["//pkg:cc_dist_library.bzl%CcFileList"]'
struct(
hdrs = depset([]),
internal_hdrs = depset([]),
srcs = depset([
<source file cc_dist_library_example/a.cc>,
<source file cc_dist_library_example/b.cc>,
]),
textual_hdrs = depset([]),
)
The upshot is that the "coarse-grained" library can be defined by the Bazel build, and then export the list of source files that are needed to reproduce the library in a different build system.
One major difference from most Bazel rule types is that the file list aspects do not propagate. In other words, they only expose the immediate dependency's sources, not transitive sources. This is for two reasons:
- Immediate dependencies are conceptually simple, while transitivity requires
substantially more thought. For example, if transitive dependencies were
considered, then some way would be needed to exclude dependencies that
should not be part of the final library (for example, a distribution library
for
//:protobuf
could be defined not to include all of//:protobuf_lite
). While dependency elision is an interesting design problem, the protobuf library is small enough that directly listing dependencies should not be problematic. - Dealing only with immediate dependencies gives finer-grained control over
what goes into the composite library. For example, a Starlark
select()
could conditionally add fine-grained libraries to some builds, but not others.
Another subtlety for tests is due to Bazel internals. Internally, a slightly
different configuration is used when evaluating cc_test
rules as compared to
cc_dist_library
. If cc_test
targets are included in a cc_dist_library
rule, and both are evaluated by Bazel, this can result in a build-time error:
the config used for the test contains additional options that tell Bazel how to
execute the test that the cc_file_list_aspect
build config does not. Bazel
detects this as two conflicting actions generating the same outputs. (For
cc_test
rules, the simplest workaround is to provide sources through a
filegroup
or similar.)
File list generation
Lists of input files are generated by Bazel in a format that can be imported to other build systems. Currently, Automake- and CMake-style files can be generated.
The lists of files are derived from Bazel build targets. The sources can be:
cc_dist_library
rules (as described above)proto_library
rules- individual files
filegroup
rulespkg_files
orpkg_filegroup
rules from https://github.com/bazelbuild/rules_pkg
For example:
$ cat gen_file_lists_example/BUILD.bazel
load("@rules_proto//proto:defs.bzl", "proto_library")
load("//pkg:build_systems.bzl", "gen_cmake_file_lists")
filegroup(
name = "doc_files",
srcs = [
"README.md",
"englilsh_paper.md",
],
)
proto_library(
name = "message",
srcs = ["message.proto"],
)
gen_cmake_file_lists(
name = "source_lists",
out = "source_lists.cmake",
src_libs = {
":doc_files": "docs",
":message": "buff",
"//cc_dist_library_example:c": "distlib",
},
)
$ bazel build gen_file_lists_example:source_lists
$ cat bazel-bin/gen_file_lists_example/source_lists.cmake
# Auto-generated by //gen_file_lists_example:source_lists
#
# This file contains lists of sources based on Bazel rules. It should
# be included from a hand-written CMake file that defines targets.
#
# Changes to this file will be overwritten based on Bazel definitions.
if(${CMAKE_VERSION} VERSION_GREATER 3.10 OR ${CMAKE_VERSION} VERSION_EQUAL 3.10)
include_guard()
endif()
# //gen_file_lists_example:doc_files
set(docs_files
gen_file_lists_example/README.md
gen_file_lists_example/englilsh_paper.md
)
# //gen_file_lists_example:message
set(buff_proto_srcs
gen_file_lists_example/message.proto
)
# //gen_file_lists_example:message
set(buff_srcs
gen_file_lists_example/message.proto.pb.cc
)
# //gen_file_lists_example:message
set(buff_hdrs
gen_file_lists_example/message.proto.pb.h
)
# //gen_file_lists_example:message
set(buff_files
gen_file_lists_example/message-descriptor-set.proto.bin
)
# //cc_dist_library_example:c
set(distlib_srcs
cc_dist_library_example/a.cc
cc_dist_library_example/b.cc
)
# //cc_dist_library_example:c
set(distlib_hdrs
)
A hand-written CMake build rule could then use the generated file to define libraries, such as:
include(source_lists.cmake)
add_library(distlib ${distlib_srcs} ${buff_srcs})
In addition to gen_cmake_file_lists
, there is also a gen_automake_file_lists
rule. These rules actually share most of the same implementation, but define
different file headers and different Starlark "fragment generator" functions
which format the generated list variables.
Protobuf usage
The main C++ runtimes (lite and full) and the Protobuf compiler use their
corresponding cc_dist_library
rules to generate file lists. For
proto_library
targets, the file list generation can extract the source files
directly. For other targets, notably cc_test
targets, the file list generators
use filegroup
rules.
In general, adding new targets to a non-Bazel build system in Protobuf (or adding a new build system altogether) requires some one-time setup:
- The overall structure of the new build system has to be defined. It should import lists of files and refer to them by variable, instead of listing files directly.
- (Only if the build system is new) A new rule type has to be added to
//pkg:build_systems.bzl
. Most of the implementation is shared, but a "fragment generator" is need to declare a file list variable, and the rule type itself has to be defined and call the shared implementation.
When files are added or deleted, or when the Protobuf Bazel structure is changed, these changes may need to be reflected in the file list logic. These are some example scenarios:
- Files are added to (or removed from) the
srcs
of an existingcc_library
: no changes needed. If thecc_library
is already part of acc_dist_library
, then regenerating the source lists will reflect the change. - A
cc_library
is added: the new target may need to be added to the Protobufcc_dist_library
targets, as appropriate. - A
cc_library
is deleted: if acc_dist_library
depends upon the deleted target, then a build-time error will result. The library needs to be removed from thecc_dist_library
. - A
cc_test
is added or deleted: test sources are handled byfilegroup
rules defined in the same package as thecc_test
rule. Thefilegroup
s are usually given a name like"test_srcs"
, and often useglob()
to find sources. This means that adding or removing a test may not require any extra work, but this can be verified within the same package as the test rule. - Test-only proto files are added: the
proto_library
might need to be added to the file list map in//pkg:BUILD.bazel
, and then the file added to various build systems. However, most test-only protos are already exposed through libraries like//src/google/protobuf:test_protos
.
If there are changes, then the regenerated file lists need to be copied back into the repo. That way, the corresponding build systems can be used with a git checkout, without needing to run Bazel first.
(Aside) Distribution archives
A very similar set of rules is defined in //pkg
to build source distribution
archives for releases. In addition to the full sources, Protobuf releases also
include source archives sliced by language, so that, for example, a Ruby-based
project can get just the sources needed to build the Ruby runtime. (The
per-language slices also include sources needed to build the protobuf compiler,
so they all effectively include the C++ runtime.)
These archives are defined using rules from the
rules_pkg project. Although they are
similar to cc_dist_library
and the file list generation rules, the goals are
different: the build system file lists described above only apply to C++, and
are organized according to what should or should not be included in different
parts of the build (e.g., no tests are included in the main library). On the
other hand, the distribution archives deal with languages other than C++, and
contain all the files that need to be distributed as part of a release (even for
C++, this is more than just the C++ sources).
While it might be possible to use information from the CcFileList
and
ProtoFileList
providers to define the distribution files, additional files
(such as the various BUILD.bazel
files) are also needed in the distribution
archive. The lists of distribution files can usually be generated by glob()
,
anyhow, so sharing logic with the file list aspects may not be beneficial.
Currently, all of the file lists are checked in. However, it would be possible to build the file lists on-the-fly and include them in the distribution archives, rather than checking them in.