rust/aspects.bzl - third_party/protobuf - Git at Google

 """This file implements an experimental, do-not-use-kind of rust_proto_library.

 Disclaimer: This project is experimental, under heavy development, and should not
 be used yet."""

 # buildifier: disable=bzl-visibility
 load("@rules_rust//rust/private:providers.bzl", "CrateInfo", "DepInfo", "DepVariantInfo")

 # buildifier: disable=bzl-visibility
 load("@rules_rust//rust/private:rustc.bzl", "rustc_compile_action")
 load("@rules_rust//rust:defs.bzl", "rust_common")
 load("//bazel:upb_proto_library.bzl", "UpbWrappedCcInfo", "upb_proto_library_aspect")
 load("@bazel_tools//tools/cpp:toolchain_utils.bzl", "find_cpp_toolchain")

 proto_common = proto_common_do_not_use

 visibility(["//rust/..."])

 RustProtoInfo = provider(
     doc = "Rust protobuf provider info",
     fields = {
         "dep_variant_info": "DepVariantInfo for the compiled Rust gencode (also covers its " +
                             "transitive dependencies)",
     },
 )

 def _generate_rust_gencode(
         ctx,
         proto_info,
         proto_lang_toolchain,
         is_upb):
     """Generates Rust gencode

         This function uses proto_common APIs and a ProtoLangToolchain to register an action
         that invokes protoc with the right flags.
     Args:
         ctx (RuleContext): current rule context
         proto_info (ProtoInfo): ProtoInfo of the proto_library target for which we are generating
                     gencode
         proto_lang_toolchain (ProtoLangToolchainInfo): proto lang toolchain for Rust
         is_upb (Bool): True when generating gencode for UPB, False otherwise.
     Returns:
         rs_outputs (([File], [File]): tuple(generated Rust files, generated C++ thunks).
     """
     actions = ctx.actions
     rs_outputs = proto_common.declare_generated_files(
         actions = actions,
         proto_info = proto_info,
         extension = ".{}.pb.rs".format("u" if is_upb else "c"),
     )
     if is_upb:
         cc_outputs = []
     else:
         cc_outputs = proto_common.declare_generated_files(
             actions = actions,
             proto_info = proto_info,
             extension = ".pb.thunks.cc",
         )

     proto_common.compile(
         actions = ctx.actions,
         proto_info = proto_info,
         generated_files = rs_outputs + cc_outputs,
         proto_lang_toolchain_info = proto_lang_toolchain,
         plugin_output = ctx.bin_dir.path,
     )
     return (rs_outputs, cc_outputs)

 def _get_crate_info(providers):
     for provider in providers:
         if hasattr(provider, "name"):
             return provider
     fail("Couldn't find a CrateInfo in the list of providers")

 def _get_dep_info(providers):
     for provider in providers:
         if hasattr(provider, "direct_crates"):
             return provider
     fail("Couldn't find a DepInfo in the list of providers")

 def _get_cc_info(providers):
     for provider in providers:
         if hasattr(provider, "linking_context"):
             return provider
     fail("Couldn't find a CcInfo in the list of providers")

 def _compile_cc(
         ctx,
         attr,
         cc_toolchain,
         feature_configuration,
         src,
         cc_infos):
     """Compiles a C++ source file.

     Args:
       ctx: The rule context.
       attr: The current rule's attributes.
       cc_toolchain: A cc_toolchain.
       feature_configuration: A feature configuration.
       src: The source file to be compiled.
       cc_infos: List[CcInfo]: A list of CcInfo dependencies.

     Returns:
       A CcInfo provider.
     """
     cc_info = cc_common.merge_cc_infos(direct_cc_infos = cc_infos)

     (compilation_context, compilation_outputs) = cc_common.compile(
         name = src.basename,
         actions = ctx.actions,
         feature_configuration = feature_configuration,
         cc_toolchain = cc_toolchain,
         srcs = [src],
         user_compile_flags = attr.copts if hasattr(attr, "copts") else [],
         compilation_contexts = [cc_info.compilation_context],
     )

     (linking_context, _) = cc_common.create_linking_context_from_compilation_outputs(
         name = src.basename,
         actions = ctx.actions,
         feature_configuration = feature_configuration,
         cc_toolchain = cc_toolchain,
         compilation_outputs = compilation_outputs,
         linking_contexts = [cc_info.linking_context],
     )

     return CcInfo(
         compilation_context = compilation_context,
         linking_context = linking_context,
     )

 def _compile_rust(ctx, attr, src, extra_srcs, deps):
     """Compiles a Rust source file.

     Eventually this function could be upstreamed into rules_rust and be made present in rust_common.

     Args:
       ctx (RuleContext): The rule context.
       attr (Attrs): The current rule's attributes (`ctx.attr` for rules, `ctx.rule.attr` for aspects)
       src (File): The crate root source file to be compiled.
       extra_srcs ([File]): Additional source files to include in the crate.
       deps (List[DepVariantInfo]): A list of dependencies needed.

     Returns:
       A DepVariantInfo provider.
     """
     toolchain = ctx.toolchains["@rules_rust//rust:toolchain_type"]
     output_hash = repr(hash(src.path))

     # TODO: Use the import! macro once available
     crate_name = ctx.label.name.replace("-", "_")

     lib_name = "{prefix}{name}-{lib_hash}{extension}".format(
         prefix = "lib",
         name = crate_name,
         lib_hash = output_hash,
         extension = ".rlib",
     )

     rmeta_name = "{prefix}{name}-{lib_hash}{extension}".format(
         prefix = "lib",
         name = crate_name,
         lib_hash = output_hash,
         extension = ".rmeta",
     )

     lib = ctx.actions.declare_file(lib_name)
     rmeta = ctx.actions.declare_file(rmeta_name)

     # TODO: Use higher level rules_rust API once available.
     providers = rustc_compile_action(
         ctx = ctx,
         attr = attr,
         toolchain = toolchain,
         crate_info = rust_common.create_crate_info(
             name = crate_name,
             type = "rlib",
             root = src,
             srcs = depset([src] + extra_srcs),
             deps = depset(deps),
             proc_macro_deps = depset([]),
             aliases = {},
             output = lib,
             metadata = rmeta,
             edition = "2021",
             is_test = False,
             rustc_env = {},
             compile_data = depset([]),
             compile_data_targets = depset([]),
             owner = ctx.label,
         ),
         output_hash = output_hash,
     )

     return DepVariantInfo(
         crate_info = _get_crate_info(providers),
         dep_info = _get_dep_info(providers),
         cc_info = _get_cc_info(providers),
         build_info = None,
     )

 def _is_cc_proto_library(rule):
     """Detects if the current rule is a cc_proto_library."""
     return rule.kind == "cc_proto_library"

 def _rust_upb_proto_aspect_impl(target, ctx):
     """Implements the Rust protobuf aspect logic for UPB kernel."""
     return _rust_proto_aspect_common(target, ctx, is_upb = True)

 def _rust_cc_proto_aspect_impl(target, ctx):
     """Implements the Rust protobuf aspect logic for C++ kernel."""
     return _rust_proto_aspect_common(target, ctx, is_upb = False)

 def _rust_proto_aspect_common(target, ctx, is_upb):
     if RustProtoInfo in target:
         return []

     if _is_cc_proto_library(ctx.rule):
         # This is cc_proto_library, but we need the RustProtoInfo provider of the proto_library that
         # this aspect provides. Luckily this aspect has already been attached on the proto_library
         # so we can just read the provider.
         return [ctx.rule.attr.deps[0][RustProtoInfo]]

     proto_lang_toolchain = ctx.attr._proto_lang_toolchain[proto_common.ProtoLangToolchainInfo]
     cc_toolchain = find_cpp_toolchain(ctx)

     feature_configuration = cc_common.configure_features(
         ctx = ctx,
         cc_toolchain = cc_toolchain,
         requested_features = ctx.features,
         unsupported_features = ctx.disabled_features,
     )

     (gencode, thunks) = _generate_rust_gencode(
         ctx,
         target[ProtoInfo],
         proto_lang_toolchain,
         is_upb,
     )

     if is_upb:
         thunks_cc_info = target[UpbWrappedCcInfo].cc_info_with_thunks
     else:
         thunks_cc_info = cc_common.merge_cc_infos(cc_infos = [_compile_cc(
             feature_configuration = feature_configuration,
             src = thunk,
             ctx = ctx,
             attr = attr,
             cc_toolchain = cc_toolchain,
             cc_infos = [target[CcInfo], ctx.attr._cpp_thunks_deps[CcInfo]],
         ) for thunk in thunks])

     runtime = proto_lang_toolchain.runtime
     dep_variant_info_for_runtime = DepVariantInfo(
         crate_info = runtime[CrateInfo] if CrateInfo in runtime else None,
         dep_info = runtime[DepInfo] if DepInfo in runtime else None,
         cc_info = runtime[CcInfo] if CcInfo in runtime else None,
         build_info = None,
     )
     dep_variant_info_for_native_gencode = DepVariantInfo(cc_info = thunks_cc_info)

     proto_dep = getattr(ctx.rule.attr, "deps", [])
     dep_variant_info = _compile_rust(
         ctx = ctx,
         attr = ctx.rule.attr,
         src = gencode[0],
         extra_srcs = gencode[1:],
         deps = [dep_variant_info_for_runtime, dep_variant_info_for_native_gencode] + (
             [proto_dep[0][RustProtoInfo].dep_variant_info] if proto_dep else []
         ),
     )
     return [RustProtoInfo(dep_variant_info = dep_variant_info)]

 def _make_proto_library_aspect(is_upb):
     return aspect(
         implementation = (_rust_upb_proto_aspect_impl if is_upb else _rust_cc_proto_aspect_impl),
         attr_aspects = ["deps"],
         # Since we can reference upb_proto_library_aspect by name, we can just ask Bazel to attach
         # it here.
         requires = ([upb_proto_library_aspect] if is_upb else []),
         required_aspect_providers = ([] if is_upb else [CcInfo]),
         attrs = {
             "_cc_toolchain": attr.label(
                 doc = (
                     "In order to use find_cc_toolchain, your rule has to depend " +
                     "on C++ toolchain. See `@rules_cc//cc:find_cc_toolchain.bzl` " +
                     "docs for details."
                 ),
                 default = Label("@bazel_tools//tools/cpp:current_cc_toolchain"),
             ),
             "_collect_cc_coverage": attr.label(
                 default = Label("@rules_rust//util:collect_coverage"),
                 executable = True,
                 cfg = "exec",
             ),
             "_cpp_thunks_deps": attr.label(
                 default = Label("//rust/cpp_kernel:cpp_api"),
             ),
             "_error_format": attr.label(
                 default = Label("@rules_rust//:error_format"),
             ),
             "_extra_exec_rustc_flag": attr.label(
                 default = Label("@rules_rust//:extra_exec_rustc_flag"),
             ),
             "_extra_exec_rustc_flags": attr.label(
                 default = Label("@rules_rust//:extra_exec_rustc_flags"),
             ),
             "_extra_rustc_flag": attr.label(
                 default = Label("@rules_rust//:extra_rustc_flag"),
             ),
             "_extra_rustc_flags": attr.label(
                 default = Label("@rules_rust//:extra_rustc_flags"),
             ),
             "_process_wrapper": attr.label(
                 doc = "A process wrapper for running rustc on all platforms.",
                 default = Label("@rules_rust//util/process_wrapper"),
                 executable = True,
                 allow_single_file = True,
                 cfg = "exec",
             ),
             "_proto_lang_toolchain": attr.label(
                 default = Label(("//rust:proto_rust_upb_toolchain" if is_upb else "//rust:proto_rust_cpp_toolchain")),
             ),
         },
         fragments = ["cpp"],
         host_fragments = ["cpp"],
         toolchains = [
             "@rules_rust//rust:toolchain_type",
             "@bazel_tools//tools/cpp:toolchain_type",
         ],
         incompatible_use_toolchain_transition = True,
     )

 rust_upb_proto_library_aspect = _make_proto_library_aspect(is_upb = True)
 rust_cc_proto_library_aspect = _make_proto_library_aspect(is_upb = False)
	"""This file implements an experimental, do-not-use-kind of rust_proto_library.

	Disclaimer: This project is experimental, under heavy development, and should not
	be used yet."""

	# buildifier: disable=bzl-visibility
	load("@rules_rust//rust/private:providers.bzl", "CrateInfo", "DepInfo", "DepVariantInfo")

	# buildifier: disable=bzl-visibility
	load("@rules_rust//rust/private:rustc.bzl", "rustc_compile_action")
	load("@rules_rust//rust:defs.bzl", "rust_common")
	load("//bazel:upb_proto_library.bzl", "UpbWrappedCcInfo", "upb_proto_library_aspect")
	load("@bazel_tools//tools/cpp:toolchain_utils.bzl", "find_cpp_toolchain")

	proto_common = proto_common_do_not_use

	visibility(["//rust/..."])

	RustProtoInfo = provider(
	doc = "Rust protobuf provider info",
	fields = {
	"dep_variant_info": "DepVariantInfo for the compiled Rust gencode (also covers its " +
	"transitive dependencies)",
	},
	)

	def _generate_rust_gencode(
	ctx,
	proto_info,
	proto_lang_toolchain,
	is_upb):
	"""Generates Rust gencode

	This function uses proto_common APIs and a ProtoLangToolchain to register an action
	that invokes protoc with the right flags.
	Args:
	ctx (RuleContext): current rule context
	proto_info (ProtoInfo): ProtoInfo of the proto_library target for which we are generating
	gencode
	proto_lang_toolchain (ProtoLangToolchainInfo): proto lang toolchain for Rust
	is_upb (Bool): True when generating gencode for UPB, False otherwise.
	Returns:
	rs_outputs (([File], [File]): tuple(generated Rust files, generated C++ thunks).
	"""
	actions = ctx.actions
	rs_outputs = proto_common.declare_generated_files(
	actions = actions,
	proto_info = proto_info,
	extension = ".{}.pb.rs".format("u" if is_upb else "c"),
	)
	if is_upb:
	cc_outputs = []
	else:
	cc_outputs = proto_common.declare_generated_files(
	actions = actions,
	proto_info = proto_info,
	extension = ".pb.thunks.cc",
	)

	proto_common.compile(
	actions = ctx.actions,
	proto_info = proto_info,
	generated_files = rs_outputs + cc_outputs,
	proto_lang_toolchain_info = proto_lang_toolchain,
	plugin_output = ctx.bin_dir.path,
	)
	return (rs_outputs, cc_outputs)

	def _get_crate_info(providers):
	for provider in providers:
	if hasattr(provider, "name"):
	return provider
	fail("Couldn't find a CrateInfo in the list of providers")

	def _get_dep_info(providers):
	for provider in providers:
	if hasattr(provider, "direct_crates"):
	return provider
	fail("Couldn't find a DepInfo in the list of providers")

	def _get_cc_info(providers):
	for provider in providers:
	if hasattr(provider, "linking_context"):
	return provider
	fail("Couldn't find a CcInfo in the list of providers")

	def _compile_cc(
	ctx,
	attr,
	cc_toolchain,
	feature_configuration,
	src,
	cc_infos):
	"""Compiles a C++ source file.

	Args:
	ctx: The rule context.
	attr: The current rule's attributes.
	cc_toolchain: A cc_toolchain.
	feature_configuration: A feature configuration.
	src: The source file to be compiled.
	cc_infos: List[CcInfo]: A list of CcInfo dependencies.

	Returns:
	A CcInfo provider.
	"""
	cc_info = cc_common.merge_cc_infos(direct_cc_infos = cc_infos)

	(compilation_context, compilation_outputs) = cc_common.compile(
	name = src.basename,
	actions = ctx.actions,
	feature_configuration = feature_configuration,
	cc_toolchain = cc_toolchain,
	srcs = [src],
	user_compile_flags = attr.copts if hasattr(attr, "copts") else [],
	compilation_contexts = [cc_info.compilation_context],
	)

	(linking_context, _) = cc_common.create_linking_context_from_compilation_outputs(
	name = src.basename,
	actions = ctx.actions,
	feature_configuration = feature_configuration,
	cc_toolchain = cc_toolchain,
	compilation_outputs = compilation_outputs,
	linking_contexts = [cc_info.linking_context],
	)

	return CcInfo(
	compilation_context = compilation_context,
	linking_context = linking_context,
	)

	def _compile_rust(ctx, attr, src, extra_srcs, deps):
	"""Compiles a Rust source file.

	Eventually this function could be upstreamed into rules_rust and be made present in rust_common.

	Args:
	ctx (RuleContext): The rule context.
	attr (Attrs): The current rule's attributes (`ctx.attr` for rules, `ctx.rule.attr` for aspects)
	src (File): The crate root source file to be compiled.
	extra_srcs ([File]): Additional source files to include in the crate.
	deps (List[DepVariantInfo]): A list of dependencies needed.

	Returns:
	A DepVariantInfo provider.
	"""
	toolchain = ctx.toolchains["@rules_rust//rust:toolchain_type"]
	output_hash = repr(hash(src.path))

	# TODO: Use the import! macro once available
	crate_name = ctx.label.name.replace("-", "_")

	lib_name = "{prefix}{name}-{lib_hash}{extension}".format(
	prefix = "lib",
	name = crate_name,
	lib_hash = output_hash,
	extension = ".rlib",
	)

	rmeta_name = "{prefix}{name}-{lib_hash}{extension}".format(
	prefix = "lib",
	name = crate_name,
	lib_hash = output_hash,
	extension = ".rmeta",
	)

	lib = ctx.actions.declare_file(lib_name)
	rmeta = ctx.actions.declare_file(rmeta_name)

	# TODO: Use higher level rules_rust API once available.
	providers = rustc_compile_action(
	ctx = ctx,
	attr = attr,
	toolchain = toolchain,
	crate_info = rust_common.create_crate_info(
	name = crate_name,
	type = "rlib",
	root = src,
	srcs = depset([src] + extra_srcs),
	deps = depset(deps),
	proc_macro_deps = depset([]),
	aliases = {},
	output = lib,
	metadata = rmeta,
	edition = "2021",
	is_test = False,
	rustc_env = {},
	compile_data = depset([]),
	compile_data_targets = depset([]),
	owner = ctx.label,
	),
	output_hash = output_hash,
	)

	return DepVariantInfo(
	crate_info = _get_crate_info(providers),
	dep_info = _get_dep_info(providers),
	cc_info = _get_cc_info(providers),
	build_info = None,
	)

	def _is_cc_proto_library(rule):
	"""Detects if the current rule is a cc_proto_library."""
	return rule.kind == "cc_proto_library"

	def _rust_upb_proto_aspect_impl(target, ctx):
	"""Implements the Rust protobuf aspect logic for UPB kernel."""
	return _rust_proto_aspect_common(target, ctx, is_upb = True)

	def _rust_cc_proto_aspect_impl(target, ctx):
	"""Implements the Rust protobuf aspect logic for C++ kernel."""
	return _rust_proto_aspect_common(target, ctx, is_upb = False)

	def _rust_proto_aspect_common(target, ctx, is_upb):
	if RustProtoInfo in target:
	return []

	if _is_cc_proto_library(ctx.rule):
	# This is cc_proto_library, but we need the RustProtoInfo provider of the proto_library that
	# this aspect provides. Luckily this aspect has already been attached on the proto_library
	# so we can just read the provider.
	return [ctx.rule.attr.deps[0][RustProtoInfo]]

	proto_lang_toolchain = ctx.attr._proto_lang_toolchain[proto_common.ProtoLangToolchainInfo]
	cc_toolchain = find_cpp_toolchain(ctx)

	feature_configuration = cc_common.configure_features(
	ctx = ctx,
	cc_toolchain = cc_toolchain,
	requested_features = ctx.features,
	unsupported_features = ctx.disabled_features,
	)

	(gencode, thunks) = _generate_rust_gencode(
	ctx,
	target[ProtoInfo],
	proto_lang_toolchain,
	is_upb,
	)

	if is_upb:
	thunks_cc_info = target[UpbWrappedCcInfo].cc_info_with_thunks
	else:
	thunks_cc_info = cc_common.merge_cc_infos(cc_infos = [_compile_cc(
	feature_configuration = feature_configuration,
	src = thunk,
	ctx = ctx,
	attr = attr,
	cc_toolchain = cc_toolchain,
	cc_infos = [target[CcInfo], ctx.attr._cpp_thunks_deps[CcInfo]],
	) for thunk in thunks])

	runtime = proto_lang_toolchain.runtime
	dep_variant_info_for_runtime = DepVariantInfo(
	crate_info = runtime[CrateInfo] if CrateInfo in runtime else None,
	dep_info = runtime[DepInfo] if DepInfo in runtime else None,
	cc_info = runtime[CcInfo] if CcInfo in runtime else None,
	build_info = None,
	)
	dep_variant_info_for_native_gencode = DepVariantInfo(cc_info = thunks_cc_info)

	proto_dep = getattr(ctx.rule.attr, "deps", [])
	dep_variant_info = _compile_rust(
	ctx = ctx,
	attr = ctx.rule.attr,
	src = gencode[0],
	extra_srcs = gencode[1:],
	deps = [dep_variant_info_for_runtime, dep_variant_info_for_native_gencode] + (
	[proto_dep[0][RustProtoInfo].dep_variant_info] if proto_dep else []
	),
	)
	return [RustProtoInfo(dep_variant_info = dep_variant_info)]

	def _make_proto_library_aspect(is_upb):
	return aspect(
	implementation = (_rust_upb_proto_aspect_impl if is_upb else _rust_cc_proto_aspect_impl),
	attr_aspects = ["deps"],
	# Since we can reference upb_proto_library_aspect by name, we can just ask Bazel to attach
	# it here.
	requires = ([upb_proto_library_aspect] if is_upb else []),
	required_aspect_providers = ([] if is_upb else [CcInfo]),
	attrs = {
	"_cc_toolchain": attr.label(
	doc = (
	"In order to use find_cc_toolchain, your rule has to depend " +
	"on C++ toolchain. See `@rules_cc//cc:find_cc_toolchain.bzl` " +
	"docs for details."
	),
	default = Label("@bazel_tools//tools/cpp:current_cc_toolchain"),
	),
	"_collect_cc_coverage": attr.label(
	default = Label("@rules_rust//util:collect_coverage"),
	executable = True,
	cfg = "exec",
	),
	"_cpp_thunks_deps": attr.label(
	default = Label("//rust/cpp_kernel:cpp_api"),
	),
	"_error_format": attr.label(
	default = Label("@rules_rust//:error_format"),
	),
	"_extra_exec_rustc_flag": attr.label(
	default = Label("@rules_rust//:extra_exec_rustc_flag"),
	),
	"_extra_exec_rustc_flags": attr.label(
	default = Label("@rules_rust//:extra_exec_rustc_flags"),
	),
	"_extra_rustc_flag": attr.label(
	default = Label("@rules_rust//:extra_rustc_flag"),
	),
	"_extra_rustc_flags": attr.label(
	default = Label("@rules_rust//:extra_rustc_flags"),
	),
	"_process_wrapper": attr.label(
	doc = "A process wrapper for running rustc on all platforms.",
	default = Label("@rules_rust//util/process_wrapper"),
	executable = True,
	allow_single_file = True,
	cfg = "exec",
	),
	"_proto_lang_toolchain": attr.label(
	default = Label(("//rust:proto_rust_upb_toolchain" if is_upb else "//rust:proto_rust_cpp_toolchain")),
	),
	},
	fragments = ["cpp"],
	host_fragments = ["cpp"],
	toolchains = [
	"@rules_rust//rust:toolchain_type",
	"@bazel_tools//tools/cpp:toolchain_type",
	],
	incompatible_use_toolchain_transition = True,
	)

	rust_upb_proto_library_aspect = _make_proto_library_aspect(is_upb = True)
	rust_cc_proto_library_aspect = _make_proto_library_aspect(is_upb = False)