platform_build_soong/cc/binary.go
Chris Parsons f874e46153 Refactor mixed builds to only take one pass
This large refactoring has both immense performance implications and
improves mixed builds complexity / usability. Summary:

1. Queueing calls to Bazel is done in a new mutator instead of a full
   soong_build pass. Normal soong_build flow is interrupted (via a
   functional hook in blueprint) to invoke bazel and parse its response.
2. Implementing mixed build support for additional modules is as simple
   as implementing MixedBuildsBuildable. In this interface, define the
   request that must be queued to Bazel, and then subsequently define
   how to handle the returned bazel cquery metadata.
3. Mixed builds consists of only a single pass. This greatly
   improves mixed build performance.

Result:
  A 33% runtime improvement on soong analysis phase with mixed builds.

Caveats:
  C++ BazelHandler handling still remains a bit of a mess; I did what
  I could within this CL's scope, but this may require additional cleanup.

Test: Treehugger
Test: Verified that aosp_arm ninja file is bit-for-bit identical with or
without this change.

Change-Id: I412d9c94d429105f4ebfafc84100d546069e6621
2022-05-20 10:04:13 -04:00

690 lines
23 KiB
Go

// Copyright 2016 Google Inc. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cc
import (
"path/filepath"
"android/soong/bazel/cquery"
"github.com/google/blueprint"
"github.com/google/blueprint/proptools"
"android/soong/android"
"android/soong/bazel"
)
type BinaryLinkerProperties struct {
// compile executable with -static
Static_executable *bool `android:"arch_variant"`
// set the name of the output
Stem *string `android:"arch_variant"`
// append to the name of the output
Suffix *string `android:"arch_variant"`
// if set, add an extra objcopy --prefix-symbols= step
Prefix_symbols *string
// if set, install a symlink to the preferred architecture
Symlink_preferred_arch *bool `android:"arch_variant"`
// install symlinks to the binary. Symlink names will have the suffix and the binary
// extension (if any) appended
Symlinks []string `android:"arch_variant"`
// override the dynamic linker
DynamicLinker string `blueprint:"mutated"`
// Names of modules to be overridden. Listed modules can only be other binaries
// (in Make or Soong).
// This does not completely prevent installation of the overridden binaries, but if both
// binaries would be installed by default (in PRODUCT_PACKAGES) the other binary will be removed
// from PRODUCT_PACKAGES.
Overrides []string
// Inject boringssl hash into the shared library. This is only intended for use by external/boringssl.
Inject_bssl_hash *bool `android:"arch_variant"`
}
func init() {
RegisterBinaryBuildComponents(android.InitRegistrationContext)
}
func RegisterBinaryBuildComponents(ctx android.RegistrationContext) {
ctx.RegisterModuleType("cc_binary", BinaryFactory)
ctx.RegisterModuleType("cc_binary_host", BinaryHostFactory)
}
// cc_binary produces a binary that is runnable on a device.
func BinaryFactory() android.Module {
module, _ := newBinary(android.HostAndDeviceSupported, true)
module.bazelHandler = &ccBinaryBazelHandler{module: module}
return module.Init()
}
// cc_binary_host produces a binary that is runnable on a host.
func BinaryHostFactory() android.Module {
module, _ := newBinary(android.HostSupported, true)
return module.Init()
}
//
// Executables
//
// binaryDecorator is a decorator containing information for C++ binary modules.
type binaryDecorator struct {
*baseLinker
*baseInstaller
stripper Stripper
Properties BinaryLinkerProperties
toolPath android.OptionalPath
// Location of the linked, unstripped binary
unstrippedOutputFile android.Path
// Names of symlinks to be installed for use in LOCAL_MODULE_SYMLINKS
symlinks []string
// If the module has symlink_preferred_arch set, the name of the symlink to the
// binary for the preferred arch.
preferredArchSymlink string
// Output archive of gcno coverage information
coverageOutputFile android.OptionalPath
// Location of the files that should be copied to dist dir when requested
distFiles android.TaggedDistFiles
// Action command lines to run directly after the binary is installed. For example,
// may be used to symlink runtime dependencies (such as bionic) alongside installation.
postInstallCmds []string
}
var _ linker = (*binaryDecorator)(nil)
// linkerProps returns the list of individual properties objects relevant
// for this binary.
func (binary *binaryDecorator) linkerProps() []interface{} {
return append(binary.baseLinker.linkerProps(),
&binary.Properties,
&binary.stripper.StripProperties)
}
// getStemWithoutSuffix returns the main section of the name to use for the symlink of
// the main output file of this binary module. This may be derived from the module name
// or other property overrides.
// For the full symlink name, the `Suffix` property of a binary module must be appended.
func (binary *binaryDecorator) getStemWithoutSuffix(ctx BaseModuleContext) string {
stem := ctx.baseModuleName()
if String(binary.Properties.Stem) != "" {
stem = String(binary.Properties.Stem)
}
return stem
}
// getStem returns the full name to use for the symlink of the main output file of this binary
// module. This may be derived from the module name and/or other property overrides.
func (binary *binaryDecorator) getStem(ctx BaseModuleContext) string {
return binary.getStemWithoutSuffix(ctx) + String(binary.Properties.Suffix)
}
// linkerDeps augments and returns the given `deps` to contain dependencies on
// modules common to most binaries, such as bionic libraries.
func (binary *binaryDecorator) linkerDeps(ctx DepsContext, deps Deps) Deps {
deps = binary.baseLinker.linkerDeps(ctx, deps)
if !Bool(binary.baseLinker.Properties.Nocrt) {
if binary.static() {
deps.CrtBegin = ctx.toolchain().CrtBeginStaticBinary()
deps.CrtEnd = ctx.toolchain().CrtEndStaticBinary()
} else {
deps.CrtBegin = ctx.toolchain().CrtBeginSharedBinary()
deps.CrtEnd = ctx.toolchain().CrtEndSharedBinary()
}
}
if binary.static() {
deps.StaticLibs = append(deps.StaticLibs, deps.SystemSharedLibs...)
}
if ctx.toolchain().Bionic() {
if binary.static() {
if ctx.selectedStl() == "libc++_static" {
deps.StaticLibs = append(deps.StaticLibs, "libm", "libc")
}
// static libraries libcompiler_rt, libc and libc_nomalloc need to be linked with
// --start-group/--end-group along with libgcc. If they are in deps.StaticLibs,
// move them to the beginning of deps.LateStaticLibs
var groupLibs []string
deps.StaticLibs, groupLibs = filterList(deps.StaticLibs,
[]string{"libc", "libc_nomalloc", "libcompiler_rt"})
deps.LateStaticLibs = append(groupLibs, deps.LateStaticLibs...)
}
if ctx.Os() == android.LinuxBionic && !binary.static() {
deps.DynamicLinker = "linker"
}
}
if !binary.static() && inList("libc", deps.StaticLibs) && !ctx.BazelConversionMode() {
ctx.ModuleErrorf("statically linking libc to dynamic executable, please remove libc\n" +
"from static libs or set static_executable: true")
}
return deps
}
// NewBinary builds and returns a new Module corresponding to a C++ binary.
// Individual module implementations which comprise a C++ binary should call this function,
// set some fields on the result, and then call the Init function.
func NewBinary(hod android.HostOrDeviceSupported) (*Module, *binaryDecorator) {
return newBinary(hod, true)
}
func newBinary(hod android.HostOrDeviceSupported, bazelable bool) (*Module, *binaryDecorator) {
module := newModule(hod, android.MultilibFirst)
binary := &binaryDecorator{
baseLinker: NewBaseLinker(module.sanitize),
baseInstaller: NewBaseInstaller("bin", "", InstallInSystem),
}
module.compiler = NewBaseCompiler()
module.linker = binary
module.installer = binary
module.bazelable = bazelable
// Allow module to be added as member of an sdk/module_exports.
module.sdkMemberTypes = []android.SdkMemberType{
ccBinarySdkMemberType,
}
return module, binary
}
// linkerInit initializes dynamic properties of the linker (such as runpath) based
// on properties of this binary.
func (binary *binaryDecorator) linkerInit(ctx BaseModuleContext) {
binary.baseLinker.linkerInit(ctx)
if ctx.Os().Linux() && ctx.Host() {
// Unless explicitly specified otherwise, host static binaries are built with -static
// if HostStaticBinaries is true for the product configuration.
if binary.Properties.Static_executable == nil && ctx.Config().HostStaticBinaries() {
binary.Properties.Static_executable = BoolPtr(true)
}
}
if ctx.Darwin() || ctx.Windows() {
// Static executables are not supported on Darwin or Windows
binary.Properties.Static_executable = nil
}
}
func (binary *binaryDecorator) static() bool {
return Bool(binary.Properties.Static_executable)
}
func (binary *binaryDecorator) staticBinary() bool {
return binary.static()
}
func (binary *binaryDecorator) binary() bool {
return true
}
// linkerFlags returns a Flags object containing linker flags that are defined
// by this binary, or that are implied by attributes of this binary. These flags are
// combined with the given flags.
func (binary *binaryDecorator) linkerFlags(ctx ModuleContext, flags Flags) Flags {
flags = binary.baseLinker.linkerFlags(ctx, flags)
// Passing -pie to clang for Windows binaries causes a warning that -pie is unused.
if ctx.Host() && !ctx.Windows() && !binary.static() {
if !ctx.Config().IsEnvTrue("DISABLE_HOST_PIE") {
flags.Global.LdFlags = append(flags.Global.LdFlags, "-pie")
}
}
// MinGW spits out warnings about -fPIC even for -fpie?!) being ignored because
// all code is position independent, and then those warnings get promoted to
// errors.
if !ctx.Windows() {
flags.Global.CFlags = append(flags.Global.CFlags, "-fPIE")
}
if ctx.toolchain().Bionic() {
if binary.static() {
// Clang driver needs -static to create static executable.
// However, bionic/linker uses -shared to overwrite.
// Linker for x86 targets does not allow coexistance of -static and -shared,
// so we add -static only if -shared is not used.
if !inList("-shared", flags.Local.LdFlags) {
flags.Global.LdFlags = append(flags.Global.LdFlags, "-static")
}
flags.Global.LdFlags = append(flags.Global.LdFlags,
"-nostdlib",
"-Bstatic",
"-Wl,--gc-sections",
)
} else { // not static
if flags.DynamicLinker == "" {
if binary.Properties.DynamicLinker != "" {
flags.DynamicLinker = binary.Properties.DynamicLinker
} else {
switch ctx.Os() {
case android.Android:
if ctx.bootstrap() && !ctx.inRecovery() && !ctx.inRamdisk() && !ctx.inVendorRamdisk() {
flags.DynamicLinker = "/system/bin/bootstrap/linker"
} else {
flags.DynamicLinker = "/system/bin/linker"
}
if flags.Toolchain.Is64Bit() {
flags.DynamicLinker += "64"
}
case android.LinuxBionic:
flags.DynamicLinker = ""
default:
ctx.ModuleErrorf("unknown dynamic linker")
}
}
if ctx.Os() == android.LinuxBionic {
// Use the dlwrap entry point, but keep _start around so
// that it can be used by host_bionic_inject
flags.Global.LdFlags = append(flags.Global.LdFlags,
"-Wl,--entry=__dlwrap__start",
"-Wl,--undefined=_start",
)
}
}
flags.Global.LdFlags = append(flags.Global.LdFlags,
"-pie",
"-nostdlib",
"-Bdynamic",
"-Wl,--gc-sections",
"-Wl,-z,nocopyreloc",
)
}
} else { // not bionic
if binary.static() {
flags.Global.LdFlags = append(flags.Global.LdFlags, "-static")
}
if ctx.Darwin() {
flags.Global.LdFlags = append(flags.Global.LdFlags, "-Wl,-headerpad_max_install_names")
}
}
return flags
}
// link registers actions to link this binary, and sets various fields
// on this binary to reflect information that should be exported up the build
// tree (for example, exported flags and include paths).
func (binary *binaryDecorator) link(ctx ModuleContext,
flags Flags, deps PathDeps, objs Objects) android.Path {
fileName := binary.getStem(ctx) + flags.Toolchain.ExecutableSuffix()
outputFile := android.PathForModuleOut(ctx, fileName)
ret := outputFile
var linkerDeps android.Paths
if flags.DynamicLinker != "" {
flags.Local.LdFlags = append(flags.Local.LdFlags, "-Wl,-dynamic-linker,"+flags.DynamicLinker)
} else if (ctx.toolchain().Bionic() || ctx.toolchain().Musl()) && !binary.static() {
flags.Local.LdFlags = append(flags.Local.LdFlags, "-Wl,--no-dynamic-linker")
}
if ctx.Darwin() && deps.DarwinSecondArchOutput.Valid() {
fatOutputFile := outputFile
outputFile = android.PathForModuleOut(ctx, "pre-fat", fileName)
transformDarwinUniversalBinary(ctx, fatOutputFile, outputFile, deps.DarwinSecondArchOutput.Path())
}
builderFlags := flagsToBuilderFlags(flags)
stripFlags := flagsToStripFlags(flags)
if binary.stripper.NeedsStrip(ctx) {
if ctx.Darwin() {
stripFlags.StripUseGnuStrip = true
}
strippedOutputFile := outputFile
outputFile = android.PathForModuleOut(ctx, "unstripped", fileName)
binary.stripper.StripExecutableOrSharedLib(ctx, outputFile, strippedOutputFile, stripFlags)
}
binary.unstrippedOutputFile = outputFile
if String(binary.Properties.Prefix_symbols) != "" {
afterPrefixSymbols := outputFile
outputFile = android.PathForModuleOut(ctx, "unprefixed", fileName)
transformBinaryPrefixSymbols(ctx, String(binary.Properties.Prefix_symbols), outputFile,
builderFlags, afterPrefixSymbols)
}
outputFile = maybeInjectBoringSSLHash(ctx, outputFile, binary.Properties.Inject_bssl_hash, fileName)
// If use_version_lib is true, make an android::build::GetBuildNumber() function available.
if Bool(binary.baseLinker.Properties.Use_version_lib) {
if ctx.Host() {
versionedOutputFile := outputFile
outputFile = android.PathForModuleOut(ctx, "unversioned", fileName)
binary.injectVersionSymbol(ctx, outputFile, versionedOutputFile)
} else {
// When dist'ing a library or binary that has use_version_lib set, always
// distribute the stamped version, even for the device.
versionedOutputFile := android.PathForModuleOut(ctx, "versioned", fileName)
binary.distFiles = android.MakeDefaultDistFiles(versionedOutputFile)
if binary.stripper.NeedsStrip(ctx) {
out := android.PathForModuleOut(ctx, "versioned-stripped", fileName)
binary.distFiles = android.MakeDefaultDistFiles(out)
binary.stripper.StripExecutableOrSharedLib(ctx, versionedOutputFile, out, stripFlags)
}
binary.injectVersionSymbol(ctx, outputFile, versionedOutputFile)
}
}
var validations android.Paths
// Handle host bionic linker symbols.
if ctx.Os() == android.LinuxBionic && !binary.static() {
verifyFile := android.PathForModuleOut(ctx, "host_bionic_verify.stamp")
if !deps.DynamicLinker.Valid() {
panic("Non-static host bionic modules must have a dynamic linker")
}
binary.verifyHostBionicLinker(ctx, outputFile, deps.DynamicLinker.Path(), verifyFile)
validations = append(validations, verifyFile)
}
var sharedLibs android.Paths
// Ignore shared libs for static executables.
if !binary.static() {
sharedLibs = deps.EarlySharedLibs
sharedLibs = append(sharedLibs, deps.SharedLibs...)
sharedLibs = append(sharedLibs, deps.LateSharedLibs...)
linkerDeps = append(linkerDeps, deps.EarlySharedLibsDeps...)
linkerDeps = append(linkerDeps, deps.SharedLibsDeps...)
linkerDeps = append(linkerDeps, deps.LateSharedLibsDeps...)
linkerDeps = append(linkerDeps, ndkSharedLibDeps(ctx)...)
}
validations = append(validations, objs.tidyDepFiles...)
linkerDeps = append(linkerDeps, flags.LdFlagsDeps...)
// Register link action.
transformObjToDynamicBinary(ctx, objs.objFiles, sharedLibs, deps.StaticLibs,
deps.LateStaticLibs, deps.WholeStaticLibs, linkerDeps, deps.CrtBegin, deps.CrtEnd, true,
builderFlags, outputFile, nil, validations)
objs.coverageFiles = append(objs.coverageFiles, deps.StaticLibObjs.coverageFiles...)
objs.coverageFiles = append(objs.coverageFiles, deps.WholeStaticLibObjs.coverageFiles...)
binary.coverageOutputFile = transformCoverageFilesToZip(ctx, objs, binary.getStem(ctx))
// Need to determine symlinks early since some targets (ie APEX) need this
// information but will not call 'install'
binary.setSymlinkList(ctx)
return ret
}
func (binary *binaryDecorator) unstrippedOutputFilePath() android.Path {
return binary.unstrippedOutputFile
}
func (binary *binaryDecorator) setSymlinkList(ctx ModuleContext) {
for _, symlink := range binary.Properties.Symlinks {
binary.symlinks = append(binary.symlinks,
symlink+String(binary.Properties.Suffix)+ctx.toolchain().ExecutableSuffix())
}
if Bool(binary.Properties.Symlink_preferred_arch) {
if String(binary.Properties.Suffix) == "" {
ctx.PropertyErrorf("symlink_preferred_arch", "must also specify suffix")
}
if ctx.TargetPrimary() {
// Install a symlink to the preferred architecture
symlinkName := binary.getStemWithoutSuffix(ctx)
binary.symlinks = append(binary.symlinks, symlinkName)
binary.preferredArchSymlink = symlinkName
}
}
}
func (binary *binaryDecorator) symlinkList() []string {
return binary.symlinks
}
func (binary *binaryDecorator) nativeCoverage() bool {
return true
}
func (binary *binaryDecorator) coverageOutputFilePath() android.OptionalPath {
return binary.coverageOutputFile
}
// /system/bin/linker -> /apex/com.android.runtime/bin/linker
func (binary *binaryDecorator) installSymlinkToRuntimeApex(ctx ModuleContext, file android.Path) {
dir := binary.baseInstaller.installDir(ctx)
dirOnDevice := android.InstallPathToOnDevicePath(ctx, dir)
target := "/" + filepath.Join("apex", "com.android.runtime", dir.Base(), file.Base())
ctx.InstallAbsoluteSymlink(dir, file.Base(), target)
binary.postInstallCmds = append(binary.postInstallCmds, makeSymlinkCmd(dirOnDevice, file.Base(), target))
for _, symlink := range binary.symlinks {
ctx.InstallAbsoluteSymlink(dir, symlink, target)
binary.postInstallCmds = append(binary.postInstallCmds, makeSymlinkCmd(dirOnDevice, symlink, target))
}
}
func (binary *binaryDecorator) install(ctx ModuleContext, file android.Path) {
// Bionic binaries (e.g. linker) is installed to the bootstrap subdirectory.
// The original path becomes a symlink to the corresponding file in the
// runtime APEX.
translatedArch := ctx.Target().NativeBridge == android.NativeBridgeEnabled
if InstallToBootstrap(ctx.baseModuleName(), ctx.Config()) && !ctx.Host() && ctx.directlyInAnyApex() &&
!translatedArch && ctx.apexVariationName() == "" && !ctx.inRamdisk() && !ctx.inRecovery() &&
!ctx.inVendorRamdisk() {
if ctx.Device() && isBionic(ctx.baseModuleName()) {
binary.installSymlinkToRuntimeApex(ctx, file)
}
binary.baseInstaller.subDir = "bootstrap"
}
binary.baseInstaller.install(ctx, file)
var preferredArchSymlinkPath android.OptionalPath
for _, symlink := range binary.symlinks {
installedSymlink := ctx.InstallSymlink(binary.baseInstaller.installDir(ctx), symlink,
binary.baseInstaller.path)
if symlink == binary.preferredArchSymlink {
// If this is the preferred arch symlink, save the installed path for use as the
// tool path.
preferredArchSymlinkPath = android.OptionalPathForPath(installedSymlink)
}
}
if ctx.Os().Class == android.Host {
// If the binary is multilib with a symlink to the preferred architecture, use the
// symlink instead of the binary because that's the more "canonical" name.
if preferredArchSymlinkPath.Valid() {
binary.toolPath = preferredArchSymlinkPath
} else {
binary.toolPath = android.OptionalPathForPath(binary.baseInstaller.path)
}
}
}
func (binary *binaryDecorator) hostToolPath() android.OptionalPath {
return binary.toolPath
}
func init() {
pctx.HostBinToolVariable("verifyHostBionicCmd", "host_bionic_verify")
}
var verifyHostBionic = pctx.AndroidStaticRule("verifyHostBionic",
blueprint.RuleParams{
Command: "$verifyHostBionicCmd -i $in -l $linker && touch $out",
CommandDeps: []string{"$verifyHostBionicCmd"},
}, "linker")
func (binary *binaryDecorator) verifyHostBionicLinker(ctx ModuleContext, in, linker android.Path, out android.WritablePath) {
ctx.Build(pctx, android.BuildParams{
Rule: verifyHostBionic,
Description: "verify host bionic",
Input: in,
Implicit: linker,
Output: out,
Args: map[string]string{
"linker": linker.String(),
},
})
}
type ccBinaryBazelHandler struct {
BazelHandler
module *Module
}
func (handler *ccBinaryBazelHandler) QueueBazelCall(ctx android.BaseModuleContext, label string) {
bazelCtx := ctx.Config().BazelContext
bazelCtx.QueueBazelRequest(label, cquery.GetOutputFiles, android.GetConfigKey(ctx))
}
func (handler *ccBinaryBazelHandler) ProcessBazelQueryResponse(ctx android.ModuleContext, label string) {
bazelCtx := ctx.Config().BazelContext
filePaths, err := bazelCtx.GetOutputFiles(label, android.GetConfigKey(ctx))
if err != nil {
ctx.ModuleErrorf(err.Error())
return
}
if len(filePaths) != 1 {
ctx.ModuleErrorf("expected exactly one output file for '%s', but got %s", label, filePaths)
return
}
outputFilePath := android.PathForBazelOut(ctx, filePaths[0])
handler.module.outputFile = android.OptionalPathForPath(outputFilePath)
// TODO(b/220164721): We need to decide if we should return the stripped as the unstripped.
handler.module.linker.(*binaryDecorator).unstrippedOutputFile = outputFilePath
}
func binaryBp2build(ctx android.TopDownMutatorContext, m *Module, typ string) {
baseAttrs := bp2BuildParseBaseProps(ctx, m)
binaryLinkerAttrs := bp2buildBinaryLinkerProps(ctx, m)
if proptools.BoolDefault(binaryLinkerAttrs.Linkshared, true) {
baseAttrs.implementationDynamicDeps.Add(baseAttrs.protoDependency)
} else {
baseAttrs.implementationDeps.Add(baseAttrs.protoDependency)
}
attrs := &binaryAttributes{
binaryLinkerAttrs: binaryLinkerAttrs,
Srcs: baseAttrs.srcs,
Srcs_c: baseAttrs.cSrcs,
Srcs_as: baseAttrs.asSrcs,
Copts: baseAttrs.copts,
Cppflags: baseAttrs.cppFlags,
Conlyflags: baseAttrs.conlyFlags,
Asflags: baseAttrs.asFlags,
Deps: baseAttrs.implementationDeps,
Dynamic_deps: baseAttrs.implementationDynamicDeps,
Whole_archive_deps: baseAttrs.wholeArchiveDeps,
System_deps: baseAttrs.systemDynamicDeps,
Local_includes: baseAttrs.localIncludes,
Absolute_includes: baseAttrs.absoluteIncludes,
Linkopts: baseAttrs.linkopts,
Link_crt: baseAttrs.linkCrt,
Use_libcrt: baseAttrs.useLibcrt,
Use_version_lib: baseAttrs.useVersionLib,
Rtti: baseAttrs.rtti,
Stl: baseAttrs.stl,
Cpp_std: baseAttrs.cppStd,
Additional_linker_inputs: baseAttrs.additionalLinkerInputs,
Strip: stripAttributes{
Keep_symbols: baseAttrs.stripKeepSymbols,
Keep_symbols_and_debug_frame: baseAttrs.stripKeepSymbolsAndDebugFrame,
Keep_symbols_list: baseAttrs.stripKeepSymbolsList,
All: baseAttrs.stripAll,
None: baseAttrs.stripNone,
},
Features: baseAttrs.features,
sdkAttributes: bp2BuildParseSdkAttributes(m),
}
ctx.CreateBazelTargetModule(bazel.BazelTargetModuleProperties{
Rule_class: "cc_binary",
Bzl_load_location: "//build/bazel/rules/cc:cc_binary.bzl",
},
android.CommonAttributes{Name: m.Name()},
attrs)
}
// binaryAttributes contains Bazel attributes corresponding to a cc binary
type binaryAttributes struct {
binaryLinkerAttrs
Srcs bazel.LabelListAttribute
Srcs_c bazel.LabelListAttribute
Srcs_as bazel.LabelListAttribute
Copts bazel.StringListAttribute
Cppflags bazel.StringListAttribute
Conlyflags bazel.StringListAttribute
Asflags bazel.StringListAttribute
Deps bazel.LabelListAttribute
Dynamic_deps bazel.LabelListAttribute
Whole_archive_deps bazel.LabelListAttribute
System_deps bazel.LabelListAttribute
Local_includes bazel.StringListAttribute
Absolute_includes bazel.StringListAttribute
Linkopts bazel.StringListAttribute
Additional_linker_inputs bazel.LabelListAttribute
Link_crt bazel.BoolAttribute
Use_libcrt bazel.BoolAttribute
Use_version_lib bazel.BoolAttribute
Rtti bazel.BoolAttribute
Stl *string
Cpp_std *string
Strip stripAttributes
Features bazel.StringListAttribute
sdkAttributes
}