platform_build_soong/android/config.go

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// Copyright 2015 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 android
// This is the primary location to write and read all configuration values and
// product variables necessary for soong_build's operation.
import (
"encoding/json"
"fmt"
"io/ioutil"
"os"
"path/filepath"
"runtime"
"strings"
"sync"
"github.com/google/blueprint"
"github.com/google/blueprint/bootstrap"
"github.com/google/blueprint/pathtools"
"github.com/google/blueprint/proptools"
"android/soong/android/soongconfig"
)
// Bool re-exports proptools.Bool for the android package.
var Bool = proptools.Bool
// String re-exports proptools.String for the android package.
var String = proptools.String
// StringDefault re-exports proptools.StringDefault for the android package.
var StringDefault = proptools.StringDefault
// FutureApiLevelInt is a placeholder constant for unreleased API levels.
const FutureApiLevelInt = 10000
// FutureApiLevel represents unreleased API levels.
var FutureApiLevel = ApiLevel{
value: "current",
number: FutureApiLevelInt,
isPreview: true,
}
// The product variables file name, containing product config from Kati.
const productVariablesFileName = "soong.variables"
// A Config object represents the entire build configuration for Android.
type Config struct {
*config
}
// BuildDir returns the build output directory for the configuration.
func (c Config) BuildDir() string {
return c.buildDir
}
// A DeviceConfig object represents the configuration for a particular device
// being built. For now there will only be one of these, but in the future there
// may be multiple devices being built.
type DeviceConfig struct {
*deviceConfig
}
// VendorConfig represents the configuration for vendor-specific behavior.
type VendorConfig soongconfig.SoongConfig
// Definition of general build configuration for soong_build. Some of these
// product configuration values are read from Kati-generated soong.variables.
type config struct {
// Options configurable with soong.variables
productVariables productVariables
// Only available on configs created by TestConfig
TestProductVariables *productVariables
// A specialized context object for Bazel/Soong mixed builds and migration
// purposes.
BazelContext BazelContext
ProductVariablesFileName string
Targets map[OsType][]Target
BuildOSTarget Target // the Target for tools run on the build machine
BuildOSCommonTarget Target // the Target for common (java) tools run on the build machine
AndroidCommonTarget Target // the Target for common modules for the Android device
AndroidFirstDeviceTarget Target // the first Target for modules for the Android device
// multilibConflicts for an ArchType is true if there is earlier configured
// device architecture with the same multilib value.
multilibConflicts map[ArchType]bool
deviceConfig *deviceConfig
srcDir string // the path of the root source directory
buildDir string // the path of the build output directory
moduleListFile string // the path to the file which lists blueprint files to parse.
env map[string]string
envLock sync.Mutex
envDeps map[string]string
envFrozen bool
// Changes behavior based on whether Kati runs after soong_build, or if soong_build
// runs standalone.
katiEnabled bool
captureBuild bool // true for tests, saves build parameters for each module
ignoreEnvironment bool // true for tests, returns empty from all Getenv calls
stopBefore bootstrap.StopBefore
fs pathtools.FileSystem
mockBpList string
// If testAllowNonExistentPaths is true then PathForSource and PathForModuleSrc won't error
// in tests when a path doesn't exist.
testAllowNonExistentPaths bool
// The list of files that when changed, must invalidate soong_build to
// regenerate build.ninja.
ninjaFileDepsSet sync.Map
OncePer
}
type deviceConfig struct {
config *config
OncePer
}
type jsonConfigurable interface {
SetDefaultConfig()
}
func loadConfig(config *config) error {
return loadFromConfigFile(&config.productVariables, absolutePath(config.ProductVariablesFileName))
}
// loadFromConfigFile loads and decodes configuration options from a JSON file
// in the current working directory.
func loadFromConfigFile(configurable jsonConfigurable, filename string) error {
// Try to open the file
configFileReader, err := os.Open(filename)
defer configFileReader.Close()
if os.IsNotExist(err) {
// Need to create a file, so that blueprint & ninja don't get in
// a dependency tracking loop.
// Make a file-configurable-options with defaults, write it out using
// a json writer.
configurable.SetDefaultConfig()
err = saveToConfigFile(configurable, filename)
if err != nil {
return err
}
} else if err != nil {
return fmt.Errorf("config file: could not open %s: %s", filename, err.Error())
} else {
// Make a decoder for it
jsonDecoder := json.NewDecoder(configFileReader)
err = jsonDecoder.Decode(configurable)
if err != nil {
return fmt.Errorf("config file: %s did not parse correctly: %s", filename, err.Error())
}
}
// No error
return nil
}
// atomically writes the config file in case two copies of soong_build are running simultaneously
// (for example, docs generation and ninja manifest generation)
func saveToConfigFile(config jsonConfigurable, filename string) error {
data, err := json.MarshalIndent(&config, "", " ")
if err != nil {
return fmt.Errorf("cannot marshal config data: %s", err.Error())
}
f, err := ioutil.TempFile(filepath.Dir(filename), "config")
if err != nil {
return fmt.Errorf("cannot create empty config file %s: %s", filename, err.Error())
}
defer os.Remove(f.Name())
defer f.Close()
_, err = f.Write(data)
if err != nil {
return fmt.Errorf("default config file: %s could not be written: %s", filename, err.Error())
}
_, err = f.WriteString("\n")
if err != nil {
return fmt.Errorf("default config file: %s could not be written: %s", filename, err.Error())
}
f.Close()
os.Rename(f.Name(), filename)
return nil
}
// NullConfig returns a mostly empty Config for use by standalone tools like dexpreopt_gen that
// use the android package.
func NullConfig(buildDir string) Config {
return Config{
config: &config{
buildDir: buildDir,
fs: pathtools.OsFs,
},
}
}
// TestConfig returns a Config object for testing.
func TestConfig(buildDir string, env map[string]string, bp string, fs map[string][]byte) Config {
envCopy := make(map[string]string)
for k, v := range env {
envCopy[k] = v
}
// Copy the real PATH value to the test environment, it's needed by
// NonHermeticHostSystemTool() used in x86_darwin_host.go
envCopy["PATH"] = originalEnv["PATH"]
config := &config{
productVariables: productVariables{
DeviceName: stringPtr("test_device"),
Platform_sdk_version: intPtr(30),
Platform_sdk_codename: stringPtr("S"),
Platform_version_active_codenames: []string{"S"},
DeviceSystemSdkVersions: []string{"14", "15"},
Platform_systemsdk_versions: []string{"29", "30"},
AAPTConfig: []string{"normal", "large", "xlarge", "hdpi", "xhdpi", "xxhdpi"},
AAPTPreferredConfig: stringPtr("xhdpi"),
AAPTCharacteristics: stringPtr("nosdcard"),
AAPTPrebuiltDPI: []string{"xhdpi", "xxhdpi"},
UncompressPrivAppDex: boolPtr(true),
},
buildDir: buildDir,
captureBuild: true,
env: envCopy,
// Set testAllowNonExistentPaths so that test contexts don't need to specify every path
// passed to PathForSource or PathForModuleSrc.
testAllowNonExistentPaths: true,
BazelContext: noopBazelContext{},
}
config.deviceConfig = &deviceConfig{
config: config,
}
config.TestProductVariables = &config.productVariables
config.mockFileSystem(bp, fs)
return Config{config}
}
// TestArchConfigNativeBridge returns a Config object suitable for using
// for tests that need to run the arch mutator for native bridge supported
// archs.
func TestArchConfigNativeBridge(buildDir string, env map[string]string, bp string, fs map[string][]byte) Config {
testConfig := TestArchConfig(buildDir, env, bp, fs)
config := testConfig.config
config.Targets[Android] = []Target{
{Android, Arch{ArchType: X86_64, ArchVariant: "silvermont", Abi: []string{"arm64-v8a"}}, NativeBridgeDisabled, "", "", false},
{Android, Arch{ArchType: X86, ArchVariant: "silvermont", Abi: []string{"armeabi-v7a"}}, NativeBridgeDisabled, "", "", false},
{Android, Arch{ArchType: Arm64, ArchVariant: "armv8-a", Abi: []string{"arm64-v8a"}}, NativeBridgeEnabled, "x86_64", "arm64", false},
{Android, Arch{ArchType: Arm, ArchVariant: "armv7-a-neon", Abi: []string{"armeabi-v7a"}}, NativeBridgeEnabled, "x86", "arm", false},
}
return testConfig
}
// TestArchConfigFuchsia returns a Config object suitable for using for
// tests that need to run the arch mutator for the Fuchsia arch.
func TestArchConfigFuchsia(buildDir string, env map[string]string, bp string, fs map[string][]byte) Config {
testConfig := TestConfig(buildDir, env, bp, fs)
config := testConfig.config
config.Targets = map[OsType][]Target{
Fuchsia: []Target{
{Fuchsia, Arch{ArchType: Arm64, ArchVariant: "", Abi: []string{"arm64-v8a"}}, NativeBridgeDisabled, "", "", false},
},
BuildOs: []Target{
{BuildOs, Arch{ArchType: X86_64}, NativeBridgeDisabled, "", "", false},
},
}
return testConfig
}
// TestArchConfig returns a Config object suitable for using for tests that
// need to run the arch mutator.
func TestArchConfig(buildDir string, env map[string]string, bp string, fs map[string][]byte) Config {
testConfig := TestConfig(buildDir, env, bp, fs)
config := testConfig.config
config.Targets = map[OsType][]Target{
Android: []Target{
{Android, Arch{ArchType: Arm64, ArchVariant: "armv8-a", Abi: []string{"arm64-v8a"}}, NativeBridgeDisabled, "", "", false},
{Android, Arch{ArchType: Arm, ArchVariant: "armv7-a-neon", Abi: []string{"armeabi-v7a"}}, NativeBridgeDisabled, "", "", false},
},
BuildOs: []Target{
{BuildOs, Arch{ArchType: X86_64}, NativeBridgeDisabled, "", "", false},
{BuildOs, Arch{ArchType: X86}, NativeBridgeDisabled, "", "", false},
},
}
if runtime.GOOS == "darwin" {
config.Targets[BuildOs] = config.Targets[BuildOs][:1]
}
config.BuildOSTarget = config.Targets[BuildOs][0]
config.BuildOSCommonTarget = getCommonTargets(config.Targets[BuildOs])[0]
config.AndroidCommonTarget = getCommonTargets(config.Targets[Android])[0]
config.AndroidFirstDeviceTarget = firstTarget(config.Targets[Android], "lib64", "lib32")[0]
config.TestProductVariables.DeviceArch = proptools.StringPtr("arm64")
config.TestProductVariables.DeviceArchVariant = proptools.StringPtr("armv8-a")
config.TestProductVariables.DeviceSecondaryArch = proptools.StringPtr("arm")
config.TestProductVariables.DeviceSecondaryArchVariant = proptools.StringPtr("armv7-a-neon")
return testConfig
}
// ConfigForAdditionalRun is a config object which is "reset" for another
// bootstrap run. Only per-run data is reset. Data which needs to persist across
// multiple runs in the same program execution is carried over (such as Bazel
// context or environment deps).
func ConfigForAdditionalRun(c Config) (Config, error) {
newConfig, err := NewConfig(c.srcDir, c.buildDir, c.moduleListFile)
if err != nil {
return Config{}, err
}
newConfig.BazelContext = c.BazelContext
newConfig.envDeps = c.envDeps
return newConfig, nil
}
// NewConfig creates a new Config object. The srcDir argument specifies the path
// to the root source directory. It also loads the config file, if found.
func NewConfig(srcDir, buildDir string, moduleListFile string) (Config, error) {
// Make a config with default options.
config := &config{
ProductVariablesFileName: filepath.Join(buildDir, productVariablesFileName),
env: originalEnv,
srcDir: srcDir,
buildDir: buildDir,
multilibConflicts: make(map[ArchType]bool),
moduleListFile: moduleListFile,
fs: pathtools.NewOsFs(absSrcDir),
}
config.deviceConfig = &deviceConfig{
config: config,
}
// Soundness check of the build and source directories. This won't catch strange
// configurations with symlinks, but at least checks the obvious case.
absBuildDir, err := filepath.Abs(buildDir)
if err != nil {
return Config{}, err
}
absSrcDir, err := filepath.Abs(srcDir)
if err != nil {
return Config{}, err
}
if strings.HasPrefix(absSrcDir, absBuildDir) {
return Config{}, fmt.Errorf("Build dir must not contain source directory")
}
// Load any configurable options from the configuration file
err = loadConfig(config)
if err != nil {
return Config{}, err
}
KatiEnabledMarkerFile := filepath.Join(buildDir, ".soong.kati_enabled")
if _, err := os.Stat(absolutePath(KatiEnabledMarkerFile)); err == nil {
config.katiEnabled = true
}
// Sets up the map of target OSes to the finer grained compilation targets
// that are configured from the product variables.
targets, err := decodeTargetProductVariables(config)
if err != nil {
return Config{}, err
}
// Make the CommonOS OsType available for all products.
targets[CommonOS] = []Target{commonTargetMap[CommonOS.Name]}
var archConfig []archConfig
if config.NdkAbis() {
archConfig = getNdkAbisConfig()
Add script for building all target arch's needed in AML (Android Mainline) prebuilts. This runs Soong in skip-make mode, using normal in-make mode only to query platform versions. The same ${OUT_DIR} cannot be used for both skip-make and in-make builds, because Soong generates a smaller build.ninja file in in-make builds where many build targets are expected to be provided by the mk files. Thus this script avoids using ${OUT_DIR} if it's an in-make build, defaulting instead to out-aml/. The script is based on build-ndk-prebuilts.sh, but uses a separate Soong variable Aml_abis to enable the appropriate target architectures for Mainline modules. Aml_abis is very similar to Ndk_abis, except "armeabi-v7a" is used instead of "armeabi", which is necessary to match prebuilt dependencies, e.g. for LLVM. Test: build/soong/scripts/build-aml-prebuilts.sh libart libdexfile_external (verify that libraries for arm, arm64, x86, x86_64 are built) Test: build/soong/scripts/build-aml-prebuilts.sh \ out-aml/soong/.intermediates/external/conscrypt/conscrypt-module-sdk/android_common/conscrypt-module-sdk-current.zip (verify that the zip file contains libconscrypt_jni.so's for all four arches) Test: build/soong/scripts/build-aml-prebuilts.sh com.android.art.{release,debug,testing,host} (verify that the build completes) Test: Two identical build/soong/scripts/build-aml-prebuilts.sh runs after each other (verify that the 2nd run completes both Soong and ninja steps quickly without any building) Change-Id: I35712f9f8f0b1cbb77107314c5927c6720e6c3bf
2019-11-15 16:00:31 +01:00
} else if config.AmlAbis() {
archConfig = getAmlAbisConfig()
}
if archConfig != nil {
androidTargets, err := decodeArchSettings(Android, archConfig)
if err != nil {
return Config{}, err
}
targets[Android] = androidTargets
}
multilib := make(map[string]bool)
for _, target := range targets[Android] {
if seen := multilib[target.Arch.ArchType.Multilib]; seen {
config.multilibConflicts[target.Arch.ArchType] = true
}
multilib[target.Arch.ArchType.Multilib] = true
}
// Map of OS to compilation targets.
config.Targets = targets
// Compilation targets for host tools.
config.BuildOSTarget = config.Targets[BuildOs][0]
config.BuildOSCommonTarget = getCommonTargets(config.Targets[BuildOs])[0]
// Compilation targets for Android.
if len(config.Targets[Android]) > 0 {
config.AndroidCommonTarget = getCommonTargets(config.Targets[Android])[0]
config.AndroidFirstDeviceTarget = firstTarget(config.Targets[Android], "lib64", "lib32")[0]
}
if Bool(config.productVariables.GcovCoverage) && Bool(config.productVariables.ClangCoverage) {
return Config{}, fmt.Errorf("GcovCoverage and ClangCoverage cannot both be set")
}
config.productVariables.Native_coverage = proptools.BoolPtr(
Bool(config.productVariables.GcovCoverage) ||
Bool(config.productVariables.ClangCoverage))
config.BazelContext, err = NewBazelContext(config)
return Config{config}, err
}
// mockFileSystem replaces all reads with accesses to the provided map of
// filenames to contents stored as a byte slice.
func (c *config) mockFileSystem(bp string, fs map[string][]byte) {
mockFS := map[string][]byte{}
if _, exists := mockFS["Android.bp"]; !exists {
mockFS["Android.bp"] = []byte(bp)
}
for k, v := range fs {
mockFS[k] = v
}
// no module list file specified; find every file named Blueprints or Android.bp
pathsToParse := []string{}
for candidate := range mockFS {
base := filepath.Base(candidate)
if base == "Blueprints" || base == "Android.bp" {
pathsToParse = append(pathsToParse, candidate)
}
}
if len(pathsToParse) < 1 {
panic(fmt.Sprintf("No Blueprint or Android.bp files found in mock filesystem: %v\n", mockFS))
}
mockFS[blueprint.MockModuleListFile] = []byte(strings.Join(pathsToParse, "\n"))
c.fs = pathtools.MockFs(mockFS)
c.mockBpList = blueprint.MockModuleListFile
}
func (c *config) StopBefore() bootstrap.StopBefore {
return c.stopBefore
}
// SetStopBefore configures soong_build to exit earlier at a specific point.
func (c *config) SetStopBefore(stopBefore bootstrap.StopBefore) {
c.stopBefore = stopBefore
}
var _ bootstrap.ConfigStopBefore = (*config)(nil)
// BlueprintToolLocation returns the directory containing build system tools
// from Blueprint, like soong_zip and merge_zips.
func (c *config) BlueprintToolLocation() string {
return filepath.Join(c.buildDir, "host", c.PrebuiltOS(), "bin")
}
var _ bootstrap.ConfigBlueprintToolLocation = (*config)(nil)
func (c *config) HostToolPath(ctx PathContext, tool string) Path {
return PathForOutput(ctx, "host", c.PrebuiltOS(), "bin", tool)
}
func (c *config) HostJNIToolPath(ctx PathContext, path string) Path {
ext := ".so"
if runtime.GOOS == "darwin" {
ext = ".dylib"
}
return PathForOutput(ctx, "host", c.PrebuiltOS(), "lib64", path+ext)
}
func (c *config) HostJavaToolPath(ctx PathContext, path string) Path {
return PathForOutput(ctx, "host", c.PrebuiltOS(), "framework", path)
}
// NonHermeticHostSystemTool looks for non-hermetic tools from the system we're
// running on. These tools are not checked-in to AOSP, and therefore could lead
// to reproducibility problems. Should not be used for other than finding the
// XCode SDK (xcrun, sw_vers), etc. See ui/build/paths/config.go for the
// allowlist of host system tools.
func (c *config) NonHermeticHostSystemTool(name string) string {
for _, dir := range filepath.SplitList(c.Getenv("PATH")) {
path := filepath.Join(dir, name)
if s, err := os.Stat(path); err != nil {
continue
} else if m := s.Mode(); !s.IsDir() && m&0111 != 0 {
return path
}
}
panic(fmt.Errorf(
"Unable to use '%s' as a host system tool for build system "+
"hermeticity reasons. See build/soong/ui/build/paths/config.go "+
"for the full list of allowed host tools on your system.", name))
}
// PrebuiltOS returns the name of the host OS used in prebuilts directories.
func (c *config) PrebuiltOS() string {
switch runtime.GOOS {
case "linux":
return "linux-x86"
case "darwin":
return "darwin-x86"
default:
panic("Unknown GOOS")
}
}
// GoRoot returns the path to the root directory of the Go toolchain.
func (c *config) GoRoot() string {
return fmt.Sprintf("%s/prebuilts/go/%s", c.srcDir, c.PrebuiltOS())
}
// PrebuiltBuildTool returns the path to a tool in the prebuilts directory containing
// checked-in tools, like Kati, Ninja or Toybox, for the current host OS.
func (c *config) PrebuiltBuildTool(ctx PathContext, tool string) Path {
return PathForSource(ctx, "prebuilts/build-tools", c.PrebuiltOS(), "bin", tool)
}
// CpPreserveSymlinksFlags returns the host-specific flag for the cp(1) command
// to preserve symlinks.
func (c *config) CpPreserveSymlinksFlags() string {
switch runtime.GOOS {
case "darwin":
return "-R"
case "linux":
return "-d"
default:
return ""
}
}
func (c *config) Getenv(key string) string {
var val string
var exists bool
c.envLock.Lock()
defer c.envLock.Unlock()
if c.envDeps == nil {
c.envDeps = make(map[string]string)
}
if val, exists = c.envDeps[key]; !exists {
if c.envFrozen {
panic("Cannot access new environment variables after envdeps are frozen")
}
val, _ = c.env[key]
c.envDeps[key] = val
}
return val
}
func (c *config) GetenvWithDefault(key string, defaultValue string) string {
ret := c.Getenv(key)
if ret == "" {
return defaultValue
}
return ret
}
func (c *config) IsEnvTrue(key string) bool {
value := c.Getenv(key)
return value == "1" || value == "y" || value == "yes" || value == "on" || value == "true"
}
func (c *config) IsEnvFalse(key string) bool {
value := c.Getenv(key)
return value == "0" || value == "n" || value == "no" || value == "off" || value == "false"
}
// EnvDeps returns the environment variables this build depends on. The first
// call to this function blocks future reads from the environment.
func (c *config) EnvDeps() map[string]string {
c.envLock.Lock()
defer c.envLock.Unlock()
c.envFrozen = true
return c.envDeps
}
func (c *config) KatiEnabled() bool {
return c.katiEnabled
}
func (c *config) BuildId() string {
return String(c.productVariables.BuildId)
}
// BuildNumberFile returns the path to a text file containing metadata
// representing the current build's number.
//
// Rules that want to reference the build number should read from this file
// without depending on it. They will run whenever their other dependencies
// require them to run and get the current build number. This ensures they don't
// rebuild on every incremental build when the build number changes.
func (c *config) BuildNumberFile(ctx PathContext) Path {
return PathForOutput(ctx, String(c.productVariables.BuildNumberFile))
}
// DeviceName returns the name of the current device target.
// TODO: take an AndroidModuleContext to select the device name for multi-device builds
func (c *config) DeviceName() string {
return *c.productVariables.DeviceName
}
func (c *config) DeviceResourceOverlays() []string {
return c.productVariables.DeviceResourceOverlays
}
func (c *config) ProductResourceOverlays() []string {
return c.productVariables.ProductResourceOverlays
}
func (c *config) PlatformVersionName() string {
return String(c.productVariables.Platform_version_name)
}
func (c *config) PlatformSdkVersion() ApiLevel {
return uncheckedFinalApiLevel(*c.productVariables.Platform_sdk_version)
}
func (c *config) PlatformSdkCodename() string {
return String(c.productVariables.Platform_sdk_codename)
}
func (c *config) PlatformSecurityPatch() string {
return String(c.productVariables.Platform_security_patch)
}
func (c *config) PlatformPreviewSdkVersion() string {
return String(c.productVariables.Platform_preview_sdk_version)
}
func (c *config) PlatformMinSupportedTargetSdkVersion() string {
return String(c.productVariables.Platform_min_supported_target_sdk_version)
}
func (c *config) PlatformBaseOS() string {
return String(c.productVariables.Platform_base_os)
}
func (c *config) MinSupportedSdkVersion() ApiLevel {
return uncheckedFinalApiLevel(16)
}
func (c *config) FinalApiLevels() []ApiLevel {
var levels []ApiLevel
for i := 1; i <= c.PlatformSdkVersion().FinalOrFutureInt(); i++ {
levels = append(levels, uncheckedFinalApiLevel(i))
}
return levels
}
func (c *config) PreviewApiLevels() []ApiLevel {
var levels []ApiLevel
for i, codename := range c.PlatformVersionActiveCodenames() {
levels = append(levels, ApiLevel{
value: codename,
number: i,
isPreview: true,
})
}
return levels
}
func (c *config) AllSupportedApiLevels() []ApiLevel {
var levels []ApiLevel
levels = append(levels, c.FinalApiLevels()...)
return append(levels, c.PreviewApiLevels()...)
}
// DefaultAppTargetSdk returns the API level that platform apps are targeting.
// This converts a codename to the exact ApiLevel it represents.
func (c *config) DefaultAppTargetSdk(ctx EarlyModuleContext) ApiLevel {
if Bool(c.productVariables.Platform_sdk_final) {
return c.PlatformSdkVersion()
}
codename := c.PlatformSdkCodename()
if codename == "" {
return NoneApiLevel
}
if codename == "REL" {
panic("Platform_sdk_codename should not be REL when Platform_sdk_final is true")
}
return ApiLevelOrPanic(ctx, codename)
}
func (c *config) AppsDefaultVersionName() string {
return String(c.productVariables.AppsDefaultVersionName)
}
// Codenames that are active in the current lunch target.
func (c *config) PlatformVersionActiveCodenames() []string {
return c.productVariables.Platform_version_active_codenames
}
func (c *config) ProductAAPTConfig() []string {
return c.productVariables.AAPTConfig
}
func (c *config) ProductAAPTPreferredConfig() string {
return String(c.productVariables.AAPTPreferredConfig)
}
func (c *config) ProductAAPTCharacteristics() string {
return String(c.productVariables.AAPTCharacteristics)
}
func (c *config) ProductAAPTPrebuiltDPI() []string {
return c.productVariables.AAPTPrebuiltDPI
}
func (c *config) DefaultAppCertificateDir(ctx PathContext) SourcePath {
defaultCert := String(c.productVariables.DefaultAppCertificate)
if defaultCert != "" {
return PathForSource(ctx, filepath.Dir(defaultCert))
}
return PathForSource(ctx, "build/make/target/product/security")
}
func (c *config) DefaultAppCertificate(ctx PathContext) (pem, key SourcePath) {
defaultCert := String(c.productVariables.DefaultAppCertificate)
if defaultCert != "" {
return PathForSource(ctx, defaultCert+".x509.pem"), PathForSource(ctx, defaultCert+".pk8")
}
defaultDir := c.DefaultAppCertificateDir(ctx)
return defaultDir.Join(ctx, "testkey.x509.pem"), defaultDir.Join(ctx, "testkey.pk8")
}
func (c *config) ApexKeyDir(ctx ModuleContext) SourcePath {
// TODO(b/121224311): define another variable such as TARGET_APEX_KEY_OVERRIDE
defaultCert := String(c.productVariables.DefaultAppCertificate)
if defaultCert == "" || filepath.Dir(defaultCert) == "build/make/target/product/security" {
// When defaultCert is unset or is set to the testkeys path, use the APEX keys
// that is under the module dir
return pathForModuleSrc(ctx)
}
// If not, APEX keys are under the specified directory
return PathForSource(ctx, filepath.Dir(defaultCert))
}
// AllowMissingDependencies configures Blueprint/Soong to not fail when modules
// are configured to depend on non-existent modules. Note that this does not
// affect missing input dependencies at the Ninja level.
func (c *config) AllowMissingDependencies() bool {
return Bool(c.productVariables.Allow_missing_dependencies)
}
// Returns true if a full platform source tree cannot be assumed.
func (c *config) UnbundledBuild() bool {
return Bool(c.productVariables.Unbundled_build)
}
// Returns true if building apps that aren't bundled with the platform.
// UnbundledBuild() is always true when this is true.
func (c *config) UnbundledBuildApps() bool {
return Bool(c.productVariables.Unbundled_build_apps)
}
// Returns true if building modules against prebuilt SDKs.
func (c *config) AlwaysUsePrebuiltSdks() bool {
return Bool(c.productVariables.Always_use_prebuilt_sdks)
}
// Returns true if the boot jars check should be skipped.
func (c *config) SkipBootJarsCheck() bool {
return Bool(c.productVariables.Skip_boot_jars_check)
}
func (c *config) Fuchsia() bool {
return Bool(c.productVariables.Fuchsia)
}
func (c *config) MinimizeJavaDebugInfo() bool {
return Bool(c.productVariables.MinimizeJavaDebugInfo) && !Bool(c.productVariables.Eng)
}
func (c *config) Debuggable() bool {
return Bool(c.productVariables.Debuggable)
}
func (c *config) Eng() bool {
return Bool(c.productVariables.Eng)
}
func (c *config) DevicePrimaryArchType() ArchType {
return c.Targets[Android][0].Arch.ArchType
}
func (c *config) SanitizeHost() []string {
return append([]string(nil), c.productVariables.SanitizeHost...)
}
func (c *config) SanitizeDevice() []string {
return append([]string(nil), c.productVariables.SanitizeDevice...)
}
func (c *config) SanitizeDeviceDiag() []string {
return append([]string(nil), c.productVariables.SanitizeDeviceDiag...)
}
func (c *config) SanitizeDeviceArch() []string {
return append([]string(nil), c.productVariables.SanitizeDeviceArch...)
}
func (c *config) EnableCFI() bool {
if c.productVariables.EnableCFI == nil {
return true
}
return *c.productVariables.EnableCFI
}
func (c *config) DisableScudo() bool {
return Bool(c.productVariables.DisableScudo)
}
func (c *config) Android64() bool {
for _, t := range c.Targets[Android] {
if t.Arch.ArchType.Multilib == "lib64" {
return true
}
}
return false
}
func (c *config) UseGoma() bool {
return Bool(c.productVariables.UseGoma)
}
func (c *config) UseRBE() bool {
return Bool(c.productVariables.UseRBE)
}
func (c *config) UseRBEJAVAC() bool {
return Bool(c.productVariables.UseRBEJAVAC)
}
func (c *config) UseRBER8() bool {
return Bool(c.productVariables.UseRBER8)
}
func (c *config) UseRBED8() bool {
return Bool(c.productVariables.UseRBED8)
}
func (c *config) UseRemoteBuild() bool {
return c.UseGoma() || c.UseRBE()
}
func (c *config) RunErrorProne() bool {
return c.IsEnvTrue("RUN_ERROR_PRONE")
}
// XrefCorpusName returns the Kythe cross-reference corpus name.
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
func (c *config) XrefCorpusName() string {
return c.Getenv("XREF_CORPUS")
}
// XrefCuEncoding returns the compilation unit encoding to use for Kythe code
// xrefs. Can be 'json' (default), 'proto' or 'all'.
func (c *config) XrefCuEncoding() string {
if enc := c.Getenv("KYTHE_KZIP_ENCODING"); enc != "" {
return enc
}
return "json"
}
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
func (c *config) EmitXrefRules() bool {
return c.XrefCorpusName() != ""
}
func (c *config) ClangTidy() bool {
return Bool(c.productVariables.ClangTidy)
}
func (c *config) TidyChecks() string {
if c.productVariables.TidyChecks == nil {
return ""
}
return *c.productVariables.TidyChecks
}
func (c *config) LibartImgHostBaseAddress() string {
return "0x60000000"
}
func (c *config) LibartImgDeviceBaseAddress() string {
return "0x70000000"
}
func (c *config) ArtUseReadBarrier() bool {
return Bool(c.productVariables.ArtUseReadBarrier)
}
// Enforce Runtime Resource Overlays for a module. RROs supersede static RROs,
// but some modules still depend on it.
//
// More info: https://source.android.com/devices/architecture/rros
func (c *config) EnforceRROForModule(name string) bool {
enforceList := c.productVariables.EnforceRROTargets
// TODO(b/150820813) Some modules depend on static overlay, remove this after eliminating the dependency.
exemptedList := c.productVariables.EnforceRROExemptedTargets
if len(exemptedList) > 0 {
if InList(name, exemptedList) {
return false
}
}
if len(enforceList) > 0 {
if InList("*", enforceList) {
return true
}
return InList(name, enforceList)
}
return false
}
func (c *config) EnforceRROExemptedForModule(name string) bool {
return InList(name, c.productVariables.EnforceRROExemptedTargets)
}
func (c *config) EnforceRROExcludedOverlay(path string) bool {
excluded := c.productVariables.EnforceRROExcludedOverlays
if len(excluded) > 0 {
return HasAnyPrefix(path, excluded)
}
return false
}
func (c *config) ExportedNamespaces() []string {
return append([]string(nil), c.productVariables.NamespacesToExport...)
}
func (c *config) HostStaticBinaries() bool {
return Bool(c.productVariables.HostStaticBinaries)
}
func (c *config) UncompressPrivAppDex() bool {
return Bool(c.productVariables.UncompressPrivAppDex)
}
func (c *config) ModulesLoadedByPrivilegedModules() []string {
return c.productVariables.ModulesLoadedByPrivilegedModules
}
// DexpreoptGlobalConfigPath returns the path to the dexpreopt.config file in
// the output directory, if it was created during the product configuration
// phase by Kati.
func (c *config) DexpreoptGlobalConfigPath(ctx PathContext) OptionalPath {
if c.productVariables.DexpreoptGlobalConfig == nil {
return OptionalPathForPath(nil)
}
return OptionalPathForPath(
pathForBuildToolDep(ctx, *c.productVariables.DexpreoptGlobalConfig))
}
// DexpreoptGlobalConfig returns the raw byte contents of the dexpreopt global
// configuration. Since the configuration file was created by Kati during
// product configuration (externally of soong_build), it's not tracked, so we
// also manually add a Ninja file dependency on the configuration file to the
// rule that creates the main build.ninja file. This ensures that build.ninja is
// regenerated correctly if dexpreopt.config changes.
func (c *config) DexpreoptGlobalConfig(ctx PathContext) ([]byte, error) {
path := c.DexpreoptGlobalConfigPath(ctx)
if !path.Valid() {
return nil, nil
}
ctx.AddNinjaFileDeps(path.String())
return ioutil.ReadFile(absolutePath(path.String()))
}
func (c *config) FrameworksBaseDirExists(ctx PathContext) bool {
return ExistentPathForSource(ctx, "frameworks", "base").Valid()
}
func (c *config) VndkSnapshotBuildArtifacts() bool {
return Bool(c.productVariables.VndkSnapshotBuildArtifacts)
}
func (c *config) HasMultilibConflict(arch ArchType) bool {
return c.multilibConflicts[arch]
}
func (c *deviceConfig) Arches() []Arch {
var arches []Arch
for _, target := range c.config.Targets[Android] {
arches = append(arches, target.Arch)
}
return arches
}
func (c *deviceConfig) BinderBitness() string {
is32BitBinder := c.config.productVariables.Binder32bit
if is32BitBinder != nil && *is32BitBinder {
return "32"
}
return "64"
}
func (c *deviceConfig) VendorPath() string {
if c.config.productVariables.VendorPath != nil {
return *c.config.productVariables.VendorPath
}
return "vendor"
}
func (c *deviceConfig) VndkVersion() string {
return String(c.config.productVariables.DeviceVndkVersion)
}
func (c *deviceConfig) CurrentApiLevelForVendorModules() string {
return StringDefault(c.config.productVariables.DeviceCurrentApiLevelForVendorModules, "current")
}
func (c *deviceConfig) PlatformVndkVersion() string {
return String(c.config.productVariables.Platform_vndk_version)
}
func (c *deviceConfig) ProductVndkVersion() string {
return String(c.config.productVariables.ProductVndkVersion)
}
func (c *deviceConfig) ExtraVndkVersions() []string {
return c.config.productVariables.ExtraVndkVersions
}
func (c *deviceConfig) VndkUseCoreVariant() bool {
return Bool(c.config.productVariables.VndkUseCoreVariant)
}
Add PLATFORM_SYSTEMSDK_VERSIONS and BOARD_SYSTEMSDK_VERSIONS PLATFORM_SYSTEMSDK_VERSIONS is the list of System SDK versions that the platform is supporting. Contrary to the public SDK where platform essentially supports all previous SDK versions, platform support only a few recent System SDK versions, since some of old System APIs are gradually deprecated, removed from the following SDKs and then finally deleted from the platform. This will be part of the framework manifest. The list can be specified by setting PLATFORM_SYSTEMSDK_MIN_VERSION. If it is set to an old version number, then System SDKs from the version to the current version (PLATFORM_SDK_VERSION) are considered to be supported by the platform. If PLATFORM_SYSTEMSDK_MIN_VERSION is not set, only the latest System SDK version is supported. Next, BOARD_SYSTEMSDK_VERSIONS is the list of System SDK versions that the device is using. This is put to the device compatibility matrix device is using. The device and the platform is considered as compatible only BOARD_SYSTEMSDK_VERSIONS in the device compatibility matrix are in the PLATFORM_SYSTEMSDK_VERSIONS in the framework manifest. When BOARD_SYSTEMSDK_VERSIONS is set, a Java app or library in vendor or odm partitions which didn't specify LOCAL_SDK_VERSION is forced to use System SDK. Also, the build system does the additional integrity check to ensure that LOCAL_SDK_VERSION is within BOARD_SYSTEMSDK_VERSIONS or PLATFORM_SYSTEMSDK_VERSIONS (if BOARD_SYSTEMSDK_VERSIONS isn't set). Bug: 69088799 Test: m -j Test: BOARD_SYSTEMSDK_VERSIONS=P m -j Change-Id: Id38f02b4be86710411be22bc28109e6894f8a483
2018-01-15 07:05:10 +01:00
func (c *deviceConfig) SystemSdkVersions() []string {
return c.config.productVariables.DeviceSystemSdkVersions
Add PLATFORM_SYSTEMSDK_VERSIONS and BOARD_SYSTEMSDK_VERSIONS PLATFORM_SYSTEMSDK_VERSIONS is the list of System SDK versions that the platform is supporting. Contrary to the public SDK where platform essentially supports all previous SDK versions, platform support only a few recent System SDK versions, since some of old System APIs are gradually deprecated, removed from the following SDKs and then finally deleted from the platform. This will be part of the framework manifest. The list can be specified by setting PLATFORM_SYSTEMSDK_MIN_VERSION. If it is set to an old version number, then System SDKs from the version to the current version (PLATFORM_SDK_VERSION) are considered to be supported by the platform. If PLATFORM_SYSTEMSDK_MIN_VERSION is not set, only the latest System SDK version is supported. Next, BOARD_SYSTEMSDK_VERSIONS is the list of System SDK versions that the device is using. This is put to the device compatibility matrix device is using. The device and the platform is considered as compatible only BOARD_SYSTEMSDK_VERSIONS in the device compatibility matrix are in the PLATFORM_SYSTEMSDK_VERSIONS in the framework manifest. When BOARD_SYSTEMSDK_VERSIONS is set, a Java app or library in vendor or odm partitions which didn't specify LOCAL_SDK_VERSION is forced to use System SDK. Also, the build system does the additional integrity check to ensure that LOCAL_SDK_VERSION is within BOARD_SYSTEMSDK_VERSIONS or PLATFORM_SYSTEMSDK_VERSIONS (if BOARD_SYSTEMSDK_VERSIONS isn't set). Bug: 69088799 Test: m -j Test: BOARD_SYSTEMSDK_VERSIONS=P m -j Change-Id: Id38f02b4be86710411be22bc28109e6894f8a483
2018-01-15 07:05:10 +01:00
}
func (c *deviceConfig) PlatformSystemSdkVersions() []string {
return c.config.productVariables.Platform_systemsdk_versions
Add PLATFORM_SYSTEMSDK_VERSIONS and BOARD_SYSTEMSDK_VERSIONS PLATFORM_SYSTEMSDK_VERSIONS is the list of System SDK versions that the platform is supporting. Contrary to the public SDK where platform essentially supports all previous SDK versions, platform support only a few recent System SDK versions, since some of old System APIs are gradually deprecated, removed from the following SDKs and then finally deleted from the platform. This will be part of the framework manifest. The list can be specified by setting PLATFORM_SYSTEMSDK_MIN_VERSION. If it is set to an old version number, then System SDKs from the version to the current version (PLATFORM_SDK_VERSION) are considered to be supported by the platform. If PLATFORM_SYSTEMSDK_MIN_VERSION is not set, only the latest System SDK version is supported. Next, BOARD_SYSTEMSDK_VERSIONS is the list of System SDK versions that the device is using. This is put to the device compatibility matrix device is using. The device and the platform is considered as compatible only BOARD_SYSTEMSDK_VERSIONS in the device compatibility matrix are in the PLATFORM_SYSTEMSDK_VERSIONS in the framework manifest. When BOARD_SYSTEMSDK_VERSIONS is set, a Java app or library in vendor or odm partitions which didn't specify LOCAL_SDK_VERSION is forced to use System SDK. Also, the build system does the additional integrity check to ensure that LOCAL_SDK_VERSION is within BOARD_SYSTEMSDK_VERSIONS or PLATFORM_SYSTEMSDK_VERSIONS (if BOARD_SYSTEMSDK_VERSIONS isn't set). Bug: 69088799 Test: m -j Test: BOARD_SYSTEMSDK_VERSIONS=P m -j Change-Id: Id38f02b4be86710411be22bc28109e6894f8a483
2018-01-15 07:05:10 +01:00
}
func (c *deviceConfig) OdmPath() string {
if c.config.productVariables.OdmPath != nil {
return *c.config.productVariables.OdmPath
}
return "odm"
}
func (c *deviceConfig) ProductPath() string {
if c.config.productVariables.ProductPath != nil {
return *c.config.productVariables.ProductPath
}
return "product"
}
func (c *deviceConfig) SystemExtPath() string {
if c.config.productVariables.SystemExtPath != nil {
return *c.config.productVariables.SystemExtPath
}
return "system_ext"
}
func (c *deviceConfig) BtConfigIncludeDir() string {
return String(c.config.productVariables.BtConfigIncludeDir)
}
func (c *deviceConfig) DeviceKernelHeaderDirs() []string {
return c.config.productVariables.DeviceKernelHeaders
}
func (c *deviceConfig) SamplingPGO() bool {
return Bool(c.config.productVariables.SamplingPGO)
}
// JavaCoverageEnabledForPath returns whether Java code coverage is enabled for
// path. Coverage is enabled by default when the product variable
// JavaCoveragePaths is empty. If JavaCoveragePaths is not empty, coverage is
// enabled for any path which is part of this variable (and not part of the
// JavaCoverageExcludePaths product variable). Value "*" in JavaCoveragePaths
// represents any path.
func (c *deviceConfig) JavaCoverageEnabledForPath(path string) bool {
coverage := false
if len(c.config.productVariables.JavaCoveragePaths) == 0 ||
InList("*", c.config.productVariables.JavaCoveragePaths) ||
HasAnyPrefix(path, c.config.productVariables.JavaCoveragePaths) {
coverage = true
}
if coverage && len(c.config.productVariables.JavaCoverageExcludePaths) > 0 {
if HasAnyPrefix(path, c.config.productVariables.JavaCoverageExcludePaths) {
coverage = false
}
}
return coverage
}
// Returns true if gcov or clang coverage is enabled.
func (c *deviceConfig) NativeCoverageEnabled() bool {
return Bool(c.config.productVariables.GcovCoverage) ||
Bool(c.config.productVariables.ClangCoverage)
}
func (c *deviceConfig) ClangCoverageEnabled() bool {
return Bool(c.config.productVariables.ClangCoverage)
}
func (c *deviceConfig) GcovCoverageEnabled() bool {
return Bool(c.config.productVariables.GcovCoverage)
}
// NativeCoverageEnabledForPath returns whether (GCOV- or Clang-based) native
// code coverage is enabled for path. By default, coverage is not enabled for a
// given path unless it is part of the NativeCoveragePaths product variable (and
// not part of the NativeCoverageExcludePaths product variable). Value "*" in
// NativeCoveragePaths represents any path.
func (c *deviceConfig) NativeCoverageEnabledForPath(path string) bool {
coverage := false
if len(c.config.productVariables.NativeCoveragePaths) > 0 {
if InList("*", c.config.productVariables.NativeCoveragePaths) || HasAnyPrefix(path, c.config.productVariables.NativeCoveragePaths) {
coverage = true
}
}
if coverage && len(c.config.productVariables.NativeCoverageExcludePaths) > 0 {
if HasAnyPrefix(path, c.config.productVariables.NativeCoverageExcludePaths) {
coverage = false
}
}
return coverage
}
func (c *deviceConfig) PgoAdditionalProfileDirs() []string {
return c.config.productVariables.PgoAdditionalProfileDirs
}
func (c *deviceConfig) VendorSepolicyDirs() []string {
return c.config.productVariables.BoardVendorSepolicyDirs
}
func (c *deviceConfig) OdmSepolicyDirs() []string {
return c.config.productVariables.BoardOdmSepolicyDirs
}
func (c *deviceConfig) SystemExtPublicSepolicyDirs() []string {
return c.config.productVariables.SystemExtPublicSepolicyDirs
}
func (c *deviceConfig) SystemExtPrivateSepolicyDirs() []string {
return c.config.productVariables.SystemExtPrivateSepolicyDirs
}
func (c *deviceConfig) SepolicyM4Defs() []string {
return c.config.productVariables.BoardSepolicyM4Defs
}
func (c *deviceConfig) OverrideManifestPackageNameFor(name string) (manifestName string, overridden bool) {
return findOverrideValue(c.config.productVariables.ManifestPackageNameOverrides, name,
"invalid override rule %q in PRODUCT_MANIFEST_PACKAGE_NAME_OVERRIDES should be <module_name>:<manifest_name>")
}
func (c *deviceConfig) OverrideCertificateFor(name string) (certificatePath string, overridden bool) {
return findOverrideValue(c.config.productVariables.CertificateOverrides, name,
"invalid override rule %q in PRODUCT_CERTIFICATE_OVERRIDES should be <module_name>:<certificate_module_name>")
}
func (c *deviceConfig) OverridePackageNameFor(name string) string {
newName, overridden := findOverrideValue(
c.config.productVariables.PackageNameOverrides,
name,
"invalid override rule %q in PRODUCT_PACKAGE_NAME_OVERRIDES should be <module_name>:<package_name>")
if overridden {
return newName
}
return name
}
func findOverrideValue(overrides []string, name string, errorMsg string) (newValue string, overridden bool) {
if overrides == nil || len(overrides) == 0 {
return "", false
}
for _, o := range overrides {
split := strings.Split(o, ":")
if len(split) != 2 {
// This shouldn't happen as this is first checked in make, but just in case.
panic(fmt.Errorf(errorMsg, o))
}
if matchPattern(split[0], name) {
return substPattern(split[0], split[1], name), true
}
}
return "", false
}
func (c *config) IntegerOverflowDisabledForPath(path string) bool {
if len(c.productVariables.IntegerOverflowExcludePaths) == 0 {
return false
}
return HasAnyPrefix(path, c.productVariables.IntegerOverflowExcludePaths)
}
func (c *config) CFIDisabledForPath(path string) bool {
if len(c.productVariables.CFIExcludePaths) == 0 {
return false
}
return HasAnyPrefix(path, c.productVariables.CFIExcludePaths)
}
func (c *config) CFIEnabledForPath(path string) bool {
if len(c.productVariables.CFIIncludePaths) == 0 {
return false
}
return HasAnyPrefix(path, c.productVariables.CFIIncludePaths)
}
func (c *config) VendorConfig(name string) VendorConfig {
return soongconfig.Config(c.productVariables.VendorVars[name])
}
func (c *config) NdkAbis() bool {
return Bool(c.productVariables.Ndk_abis)
}
Add script for building all target arch's needed in AML (Android Mainline) prebuilts. This runs Soong in skip-make mode, using normal in-make mode only to query platform versions. The same ${OUT_DIR} cannot be used for both skip-make and in-make builds, because Soong generates a smaller build.ninja file in in-make builds where many build targets are expected to be provided by the mk files. Thus this script avoids using ${OUT_DIR} if it's an in-make build, defaulting instead to out-aml/. The script is based on build-ndk-prebuilts.sh, but uses a separate Soong variable Aml_abis to enable the appropriate target architectures for Mainline modules. Aml_abis is very similar to Ndk_abis, except "armeabi-v7a" is used instead of "armeabi", which is necessary to match prebuilt dependencies, e.g. for LLVM. Test: build/soong/scripts/build-aml-prebuilts.sh libart libdexfile_external (verify that libraries for arm, arm64, x86, x86_64 are built) Test: build/soong/scripts/build-aml-prebuilts.sh \ out-aml/soong/.intermediates/external/conscrypt/conscrypt-module-sdk/android_common/conscrypt-module-sdk-current.zip (verify that the zip file contains libconscrypt_jni.so's for all four arches) Test: build/soong/scripts/build-aml-prebuilts.sh com.android.art.{release,debug,testing,host} (verify that the build completes) Test: Two identical build/soong/scripts/build-aml-prebuilts.sh runs after each other (verify that the 2nd run completes both Soong and ninja steps quickly without any building) Change-Id: I35712f9f8f0b1cbb77107314c5927c6720e6c3bf
2019-11-15 16:00:31 +01:00
func (c *config) AmlAbis() bool {
return Bool(c.productVariables.Aml_abis)
}
func (c *config) ExcludeDraftNdkApis() bool {
return Bool(c.productVariables.Exclude_draft_ndk_apis)
}
func (c *config) FlattenApex() bool {
return Bool(c.productVariables.Flatten_apex)
}
func (c *config) CompressedApex() bool {
return Bool(c.productVariables.CompressedApex)
}
func (c *config) EnforceSystemCertificate() bool {
return Bool(c.productVariables.EnforceSystemCertificate)
}
func (c *config) EnforceSystemCertificateAllowList() []string {
return c.productVariables.EnforceSystemCertificateAllowList
}
func (c *config) EnforceProductPartitionInterface() bool {
return Bool(c.productVariables.EnforceProductPartitionInterface)
}
func (c *config) EnforceInterPartitionJavaSdkLibrary() bool {
return Bool(c.productVariables.EnforceInterPartitionJavaSdkLibrary)
}
func (c *config) InterPartitionJavaLibraryAllowList() []string {
return c.productVariables.InterPartitionJavaLibraryAllowList
}
func (c *config) InstallExtraFlattenedApexes() bool {
return Bool(c.productVariables.InstallExtraFlattenedApexes)
}
func (c *config) ProductHiddenAPIStubs() []string {
return c.productVariables.ProductHiddenAPIStubs
}
func (c *config) ProductHiddenAPIStubsSystem() []string {
return c.productVariables.ProductHiddenAPIStubsSystem
}
func (c *config) ProductHiddenAPIStubsTest() []string {
return c.productVariables.ProductHiddenAPIStubsTest
}
func (c *deviceConfig) TargetFSConfigGen() []string {
return c.config.productVariables.TargetFSConfigGen
}
func (c *config) ProductPublicSepolicyDirs() []string {
return c.productVariables.ProductPublicSepolicyDirs
}
func (c *config) ProductPrivateSepolicyDirs() []string {
return c.productVariables.ProductPrivateSepolicyDirs
}
func (c *config) MissingUsesLibraries() []string {
return c.productVariables.MissingUsesLibraries
}
func (c *deviceConfig) DeviceArch() string {
return String(c.config.productVariables.DeviceArch)
}
func (c *deviceConfig) DeviceArchVariant() string {
return String(c.config.productVariables.DeviceArchVariant)
}
func (c *deviceConfig) DeviceSecondaryArch() string {
return String(c.config.productVariables.DeviceSecondaryArch)
}
func (c *deviceConfig) DeviceSecondaryArchVariant() string {
return String(c.config.productVariables.DeviceSecondaryArchVariant)
}
func (c *deviceConfig) BoardUsesRecoveryAsBoot() bool {
return Bool(c.config.productVariables.BoardUsesRecoveryAsBoot)
}
func (c *deviceConfig) BoardKernelBinaries() []string {
return c.config.productVariables.BoardKernelBinaries
}
func (c *deviceConfig) BoardKernelModuleInterfaceVersions() []string {
return c.config.productVariables.BoardKernelModuleInterfaceVersions
}
func (c *deviceConfig) BoardMoveRecoveryResourcesToVendorBoot() bool {
return Bool(c.config.productVariables.BoardMoveRecoveryResourcesToVendorBoot)
}
// The ConfiguredJarList struct provides methods for handling a list of (apex, jar) pairs.
// Such lists are used in the build system for things like bootclasspath jars or system server jars.
// The apex part is either an apex name, or a special names "platform" or "system_ext". Jar is a
// module name. The pairs come from Make product variables as a list of colon-separated strings.
//
// Examples:
// - "com.android.art:core-oj"
// - "platform:framework"
// - "system_ext:foo"
//
type ConfiguredJarList struct {
// A list of apex components, which can be an apex name,
// or special names like "platform" or "system_ext".
apexes []string
// A list of jar module name components.
jars []string
}
// Len returns the length of the list of jars.
func (l *ConfiguredJarList) Len() int {
return len(l.jars)
}
// Jar returns the idx-th jar component of (apex, jar) pairs.
func (l *ConfiguredJarList) Jar(idx int) string {
return l.jars[idx]
}
// Apex returns the idx-th apex component of (apex, jar) pairs.
func (l *ConfiguredJarList) Apex(idx int) string {
return l.apexes[idx]
}
// ContainsJar returns true if the (apex, jar) pairs contains a pair with the
// given jar module name.
func (l *ConfiguredJarList) ContainsJar(jar string) bool {
return InList(jar, l.jars)
}
// If the list contains the given (apex, jar) pair.
func (l *ConfiguredJarList) containsApexJarPair(apex, jar string) bool {
for i := 0; i < l.Len(); i++ {
if apex == l.apexes[i] && jar == l.jars[i] {
return true
}
}
return false
}
// IndexOfJar returns the first pair with the given jar name on the list, or -1
// if not found.
func (l *ConfiguredJarList) IndexOfJar(jar string) int {
return IndexList(jar, l.jars)
}
func copyAndAppend(list []string, item string) []string {
// Create the result list to be 1 longer than the input.
result := make([]string, len(list)+1)
// Copy the whole input list into the result.
count := copy(result, list)
// Insert the extra item at the end.
result[count] = item
return result
}
// Append an (apex, jar) pair to the list.
func (l *ConfiguredJarList) Append(apex string, jar string) ConfiguredJarList {
// Create a copy of the backing arrays before appending to avoid sharing backing
// arrays that are mutated across instances.
apexes := copyAndAppend(l.apexes, apex)
jars := copyAndAppend(l.jars, jar)
return ConfiguredJarList{apexes, jars}
}
// RemoveList filters out a list of (apex, jar) pairs from the receiving list of pairs.
func (l *ConfiguredJarList) RemoveList(list ConfiguredJarList) ConfiguredJarList {
apexes := make([]string, 0, l.Len())
jars := make([]string, 0, l.Len())
for i, jar := range l.jars {
apex := l.apexes[i]
if !list.containsApexJarPair(apex, jar) {
apexes = append(apexes, apex)
jars = append(jars, jar)
}
}
return ConfiguredJarList{apexes, jars}
}
// CopyOfJars returns a copy of the list of strings containing jar module name
// components.
func (l *ConfiguredJarList) CopyOfJars() []string {
return CopyOf(l.jars)
}
// CopyOfApexJarPairs returns a copy of the list of strings with colon-separated
// (apex, jar) pairs.
func (l *ConfiguredJarList) CopyOfApexJarPairs() []string {
pairs := make([]string, 0, l.Len())
for i, jar := range l.jars {
apex := l.apexes[i]
pairs = append(pairs, apex+":"+jar)
}
return pairs
}
// BuildPaths returns a list of build paths based on the given directory prefix.
func (l *ConfiguredJarList) BuildPaths(ctx PathContext, dir OutputPath) WritablePaths {
paths := make(WritablePaths, l.Len())
for i, jar := range l.jars {
paths[i] = dir.Join(ctx, ModuleStem(jar)+".jar")
}
return paths
}
// UnmarshalJSON converts JSON configuration from raw bytes into a
// ConfiguredJarList structure.
func (l *ConfiguredJarList) UnmarshalJSON(b []byte) error {
// Try and unmarshal into a []string each item of which contains a pair
// <apex>:<jar>.
var list []string
err := json.Unmarshal(b, &list)
if err != nil {
// Did not work so return
return err
}
apexes, jars, err := splitListOfPairsIntoPairOfLists(list)
if err != nil {
return err
}
l.apexes = apexes
l.jars = jars
return nil
}
// ModuleStem hardcodes the stem of framework-minus-apex to return "framework".
//
// TODO(b/139391334): hard coded until we find a good way to query the stem of a
// module before any other mutators are run.
func ModuleStem(module string) string {
if module == "framework-minus-apex" {
return "framework"
}
return module
}
// DevicePaths computes the on-device paths for the list of (apex, jar) pairs,
// based on the operating system.
func (l *ConfiguredJarList) DevicePaths(cfg Config, ostype OsType) []string {
paths := make([]string, l.Len())
for i, jar := range l.jars {
apex := l.apexes[i]
name := ModuleStem(jar) + ".jar"
var subdir string
if apex == "platform" {
subdir = "system/framework"
} else if apex == "system_ext" {
subdir = "system_ext/framework"
} else {
subdir = filepath.Join("apex", apex, "javalib")
}
if ostype.Class == Host {
paths[i] = filepath.Join(cfg.Getenv("OUT_DIR"), "host", cfg.PrebuiltOS(), subdir, name)
} else {
paths[i] = filepath.Join("/", subdir, name)
}
}
return paths
}
func (l *ConfiguredJarList) String() string {
var pairs []string
for i := 0; i < l.Len(); i++ {
pairs = append(pairs, l.apexes[i]+":"+l.jars[i])
}
return strings.Join(pairs, ",")
}
func splitListOfPairsIntoPairOfLists(list []string) ([]string, []string, error) {
// Now we need to populate this list by splitting each item in the slice of
// pairs and appending them to the appropriate list of apexes or jars.
apexes := make([]string, len(list))
jars := make([]string, len(list))
for i, apexjar := range list {
apex, jar, err := splitConfiguredJarPair(apexjar)
if err != nil {
return nil, nil, err
}
apexes[i] = apex
jars[i] = jar
}
return apexes, jars, nil
}
// Expected format for apexJarValue = <apex name>:<jar name>
func splitConfiguredJarPair(str string) (string, string, error) {
pair := strings.SplitN(str, ":", 2)
if len(pair) == 2 {
return pair[0], pair[1], nil
} else {
return "error-apex", "error-jar", fmt.Errorf("malformed (apex, jar) pair: '%s', expected format: <apex>:<jar>", str)
}
}
// CreateTestConfiguredJarList is a function to create ConfiguredJarList for
// tests.
func CreateTestConfiguredJarList(list []string) ConfiguredJarList {
apexes, jars, err := splitListOfPairsIntoPairOfLists(list)
if err != nil {
panic(err)
}
return ConfiguredJarList{apexes, jars}
}
// EmptyConfiguredJarList returns an empty jar list.
func EmptyConfiguredJarList() ConfiguredJarList {
return ConfiguredJarList{}
}
var earlyBootJarsKey = NewOnceKey("earlyBootJars")
func (c *config) BootJars() []string {
return c.Once(earlyBootJarsKey, func() interface{} {
list := c.productVariables.BootJars.CopyOfJars()
return append(list, c.productVariables.UpdatableBootJars.CopyOfJars()...)
}).([]string)
}
func (c *config) NonUpdatableBootJars() ConfiguredJarList {
return c.productVariables.BootJars
}
func (c *config) UpdatableBootJars() ConfiguredJarList {
return c.productVariables.UpdatableBootJars
}