platform_build_soong/java/dexpreopt_bootjars.go

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// Copyright 2019 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 java
import (
"fmt"
"path/filepath"
"sort"
"strings"
"android/soong/android"
"android/soong/dexpreopt"
"github.com/google/blueprint/proptools"
)
// =================================================================================================
// WIP - see http://b/177892522 for details
//
// The build support for boot images is currently being migrated away from singleton to modules so
// the documentation may not be strictly accurate. Rather than update the documentation at every
// step which will create a lot of churn the changes that have been made will be listed here and the
// documentation will be updated once it is closer to the final result.
//
// Changes:
// 1) dex_bootjars is now a singleton module and not a plain singleton.
// 2) Boot images are now represented by the boot_image module type.
// 3) The art boot image is called "art-boot-image", the framework boot image is called
// "framework-boot-image".
// 4) They are defined in art/build/boot/Android.bp and frameworks/base/boot/Android.bp
// respectively.
// 5) Each boot_image retrieves the appropriate boot image configuration from the map returned by
// genBootImageConfigs() using the image_name specified in the boot_image module.
// =================================================================================================
// This comment describes:
// 1. ART boot images in general (their types, structure, file layout, etc.)
// 2. build system support for boot images
//
// 1. ART boot images
// ------------------
//
// A boot image in ART is a set of files that contain AOT-compiled native code and a heap snapshot
// of AOT-initialized classes for the bootclasspath Java libraries. A boot image is compiled from a
// set of DEX jars by the dex2oat compiler. A boot image is used for two purposes: 1) it is
// installed on device and loaded at runtime, and 2) other Java libraries and apps are compiled
// against it (compilation may take place either on host, known as "dexpreopt", or on device, known
// as "dexopt").
//
// A boot image is not a single file, but a collection of interrelated files. Each boot image has a
// number of components that correspond to the Java libraries that constitute it. For each component
// there are multiple files:
// - *.oat or *.odex file with native code (architecture-specific, one per instruction set)
// - *.art file with pre-initialized Java classes (architecture-specific, one per instruction set)
// - *.vdex file with verification metadata for the DEX bytecode (architecture independent)
//
// *.vdex files for the boot images do not contain the DEX bytecode itself, because the
// bootclasspath DEX files are stored on disk in uncompressed and aligned form. Consequently a boot
// image is not self-contained and cannot be used without its DEX files. To simplify the management
// of boot image files, ART uses a certain naming scheme and associates the following metadata with
// each boot image:
// - A stem, which is a symbolic name that is prepended to boot image file names.
// - A location (on-device path to the boot image files).
// - A list of boot image locations (on-device paths to dependency boot images).
// - A set of DEX locations (on-device paths to the DEX files, one location for one DEX file used
// to compile the boot image).
//
// There are two kinds of boot images:
// - primary boot images
// - boot image extensions
//
// 1.1. Primary boot images
// ------------------------
//
// A primary boot image is compiled for a core subset of bootclasspath Java libraries. It does not
// depend on any other images, and other boot images may depend on it.
//
// For example, assuming that the stem is "boot", the location is /apex/com.android.art/javalib/,
// the set of core bootclasspath libraries is A B C, and the boot image is compiled for ARM targets
// (32 and 64 bits), it will have three components with the following files:
// - /apex/com.android.art/javalib/{arm,arm64}/boot.{art,oat,vdex}
// - /apex/com.android.art/javalib/{arm,arm64}/boot-B.{art,oat,vdex}
// - /apex/com.android.art/javalib/{arm,arm64}/boot-C.{art,oat,vdex}
//
// The files of the first component are special: they do not have the component name appended after
// the stem. This naming convention dates back to the times when the boot image was not split into
// components, and there were just boot.oat and boot.art. The decision to split was motivated by
// licensing reasons for one of the bootclasspath libraries.
//
// As of November 2020 the only primary boot image in Android is the image in the ART APEX
// com.android.art. The primary ART boot image contains the Core libraries that are part of the ART
// module. When the ART module gets updated, the primary boot image will be updated with it, and all
// dependent images will get invalidated (the checksum of the primary image stored in dependent
// images will not match), unless they are updated in sync with the ART module.
//
// 1.2. Boot image extensions
// --------------------------
//
// A boot image extension is compiled for a subset of bootclasspath Java libraries (in particular,
// this subset does not include the Core bootclasspath libraries that go into the primary boot
// image). A boot image extension depends on the primary boot image and optionally some other boot
// image extensions. Other images may depend on it. In other words, boot image extensions can form
// acyclic dependency graphs.
//
// The motivation for boot image extensions comes from the Mainline project. Consider a situation
// when the list of bootclasspath libraries is A B C, and both A and B are parts of the Android
// platform, but C is part of an updatable APEX com.android.C. When the APEX is updated, the Java
// code for C might have changed compared to the code that was used to compile the boot image.
// Consequently, the whole boot image is obsolete and invalidated (even though the code for A and B
// that does not depend on C is up to date). To avoid this, the original monolithic boot image is
// split in two parts: the primary boot image that contains A B, and the boot image extension that
// contains C and depends on the primary boot image (extends it).
//
// For example, assuming that the stem is "boot", the location is /system/framework, the set of
// bootclasspath libraries is D E (where D is part of the platform and is located in
// /system/framework, and E is part of a non-updatable APEX com.android.E and is located in
// /apex/com.android.E/javalib), and the boot image is compiled for ARM targets (32 and 64 bits),
// it will have two components with the following files:
// - /system/framework/{arm,arm64}/boot-D.{art,oat,vdex}
// - /system/framework/{arm,arm64}/boot-E.{art,oat,vdex}
//
// As of November 2020 the only boot image extension in Android is the Framework boot image
// extension. It extends the primary ART boot image and contains Framework libraries and other
// bootclasspath libraries from the platform and non-updatable APEXes that are not included in the
// ART image. The Framework boot image extension is updated together with the platform. In the
// future other boot image extensions may be added for some updatable modules.
//
//
// 2. Build system support for boot images
// ---------------------------------------
//
// The primary ART boot image needs to be compiled with one dex2oat invocation that depends on DEX
// jars for the core libraries. Framework boot image extension needs to be compiled with one dex2oat
// invocation that depends on the primary ART boot image and all bootclasspath DEX jars except the
// core libraries as they are already part of the primary ART boot image.
//
// 2.1. Libraries that go in the boot images
// -----------------------------------------
//
// The contents of each boot image are determined by the PRODUCT variables. The primary ART APEX
// boot image contains libraries listed in the ART_APEX_JARS variable in the AOSP makefiles. The
// Framework boot image extension contains libraries specified in the PRODUCT_BOOT_JARS and
// PRODUCT_BOOT_JARS_EXTRA variables. The AOSP makefiles specify some common Framework libraries,
// but more product-specific libraries can be added in the product makefiles.
//
// Each component of the PRODUCT_BOOT_JARS and PRODUCT_BOOT_JARS_EXTRA variables is either a simple
// name (if the library is a part of the Platform), or a colon-separated pair <apex, name> (if the
// library is a part of a non-updatable APEX).
//
// A related variable PRODUCT_UPDATABLE_BOOT_JARS contains bootclasspath libraries that are in
// updatable APEXes. They are not included in the boot image.
//
// One exception to the above rules are "coverage" builds (a special build flavor which requires
// setting environment variable EMMA_INSTRUMENT_FRAMEWORK=true). In coverage builds the Java code in
// boot image libraries is instrumented, which means that the instrumentation library (jacocoagent)
// needs to be added to the list of bootclasspath DEX jars.
//
// In general, there is a requirement that the source code for a boot image library must be
// available at build time (e.g. it cannot be a stub that has a separate implementation library).
//
// 2.2. Static configs
// -------------------
//
// Because boot images are used to dexpreopt other Java modules, the paths to boot image files must
// be known by the time dexpreopt build rules for the dependent modules are generated. Boot image
// configs are constructed very early during the build, before build rule generation. The configs
// provide predefined paths to boot image files (these paths depend only on static build
// configuration, such as PRODUCT variables, and use hard-coded directory names).
//
// 2.3. Singleton
// --------------
//
// Build rules for the boot images are generated with a Soong singleton. Because a singleton has no
// dependencies on other modules, it has to find the modules for the DEX jars using VisitAllModules.
// Soong loops through all modules and compares each module against a list of bootclasspath library
// names. Then it generates build rules that copy DEX jars from their intermediate module-specific
// locations to the hard-coded locations predefined in the boot image configs.
//
// It would be possible to use a module with proper dependencies instead, but that would require
// changes in the way Soong generates variables for Make: a singleton can use one MakeVars() method
// that writes variables to out/soong/make_vars-*.mk, which is included early by the main makefile,
// but module(s) would have to use out/soong/Android-*.mk which has a group of LOCAL_* variables
// for each module, and is included later.
//
// 2.4. Install rules
// ------------------
//
// The primary boot image and the Framework extension are installed in different ways. The primary
// boot image is part of the ART APEX: it is copied into the APEX intermediate files, packaged
// together with other APEX contents, extracted and mounted on device. The Framework boot image
// extension is installed by the rules defined in makefiles (make/core/dex_preopt_libart.mk). Soong
// writes out a few DEXPREOPT_IMAGE_* variables for Make; these variables contain boot image names,
// paths and so on.
//
// 2.5. JIT-Zygote configuration
// -----------------------------
//
// One special configuration is JIT-Zygote build, when the primary ART image is used for compiling
// apps instead of the Framework boot image extension (see DEXPREOPT_USE_ART_IMAGE and UseArtImage).
//
var artApexNames = []string{
"com.android.art",
"com.android.art.debug",
"com.android.art.testing",
"com.google.android.art",
"com.google.android.art.debug",
"com.google.android.art.testing",
}
func init() {
RegisterDexpreoptBootJarsComponents(android.InitRegistrationContext)
}
// Target-independent description of a boot image.
type bootImageConfig struct {
// If this image is an extension, the image that it extends.
extends *bootImageConfig
// Image name (used in directory names and ninja rule names).
name string
// Basename of the image: the resulting filenames are <stem>[-<jar>].{art,oat,vdex}.
stem string
// Output directory for the image files.
dir android.OutputPath
// Output directory for the image files with debug symbols.
symbolsDir android.OutputPath
// Subdirectory where the image files are installed.
installSubdir string
// A list of (location, jar) pairs for the Java modules in this image.
modules android.ConfiguredJarList
// File paths to jars.
dexPaths android.WritablePaths // for this image
dexPathsDeps android.WritablePaths // for the dependency images and in this image
// File path to a zip archive with all image files (or nil, if not needed).
zip android.WritablePath
// Rules which should be used in make to install the outputs.
profileInstalls android.RuleBuilderInstalls
// Target-dependent fields.
variants []*bootImageVariant
}
// Target-dependent description of a boot image.
type bootImageVariant struct {
*bootImageConfig
// Target for which the image is generated.
target android.Target
// The "locations" of jars.
dexLocations []string // for this image
dexLocationsDeps []string // for the dependency images and in this image
// Paths to image files.
images android.OutputPath // first image file
imagesDeps android.OutputPaths // all files
// Only for extensions, paths to the primary boot images.
primaryImages android.OutputPath
// Rules which should be used in make to install the outputs.
installs android.RuleBuilderInstalls
vdexInstalls android.RuleBuilderInstalls
unstrippedInstalls android.RuleBuilderInstalls
}
// Get target-specific boot image variant for the given boot image config and target.
func (image bootImageConfig) getVariant(target android.Target) *bootImageVariant {
for _, variant := range image.variants {
if variant.target.Os == target.Os && variant.target.Arch.ArchType == target.Arch.ArchType {
return variant
}
}
return nil
}
// Return any (the first) variant which is for the device (as opposed to for the host).
func (image bootImageConfig) getAnyAndroidVariant() *bootImageVariant {
for _, variant := range image.variants {
if variant.target.Os == android.Android {
return variant
}
}
return nil
}
// Return the name of a boot image module given a boot image config and a component (module) index.
// A module name is a combination of the Java library name, and the boot image stem (that is stored
// in the config).
func (image bootImageConfig) moduleName(ctx android.PathContext, idx int) string {
// The first module of the primary boot image is special: its module name has only the stem, but
// not the library name. All other module names are of the form <stem>-<library name>
m := image.modules.Jar(idx)
name := image.stem
if idx != 0 || image.extends != nil {
name += "-" + android.ModuleStem(m)
}
return name
}
// Return the name of the first boot image module, or stem if the list of modules is empty.
func (image bootImageConfig) firstModuleNameOrStem(ctx android.PathContext) string {
if image.modules.Len() > 0 {
return image.moduleName(ctx, 0)
} else {
return image.stem
}
}
// Return filenames for the given boot image component, given the output directory and a list of
// extensions.
func (image bootImageConfig) moduleFiles(ctx android.PathContext, dir android.OutputPath, exts ...string) android.OutputPaths {
ret := make(android.OutputPaths, 0, image.modules.Len()*len(exts))
for i := 0; i < image.modules.Len(); i++ {
name := image.moduleName(ctx, i)
for _, ext := range exts {
ret = append(ret, dir.Join(ctx, name+ext))
}
}
return ret
}
// Return boot image locations (as a list of symbolic paths).
//
// The image "location" is a symbolic path that, with multiarchitecture support, doesn't really
// exist on the device. Typically it is /apex/com.android.art/javalib/boot.art and should be the
// same for all supported architectures on the device. The concrete architecture specific files
// actually end up in architecture-specific sub-directory such as arm, arm64, x86, or x86_64.
//
// For example a physical file /apex/com.android.art/javalib/x86/boot.art has "image location"
// /apex/com.android.art/javalib/boot.art (which is not an actual file).
//
// For a primary boot image the list of locations has a single element.
//
// For a boot image extension the list of locations contains a location for all dependency images
// (including the primary image) and the location of the extension itself. For example, for the
// Framework boot image extension that depends on the primary ART boot image the list contains two
// elements.
//
// The location is passed as an argument to the ART tools like dex2oat instead of the real path.
// ART tools will then reconstruct the architecture-specific real path.
//
func (image *bootImageVariant) imageLocations() (imageLocations []string) {
if image.extends != nil {
imageLocations = image.extends.getVariant(image.target).imageLocations()
}
return append(imageLocations, dexpreopt.PathToLocation(image.images, image.target.Arch.ArchType))
}
func dexpreoptBootJarsFactory() android.SingletonModule {
m := &dexpreoptBootJars{}
android.InitAndroidModule(m)
return m
}
func RegisterDexpreoptBootJarsComponents(ctx android.RegistrationContext) {
ctx.RegisterSingletonModuleType("dex_bootjars", dexpreoptBootJarsFactory)
}
func SkipDexpreoptBootJars(ctx android.PathContext) bool {
return dexpreopt.GetGlobalConfig(ctx).DisablePreoptBootImages
}
// Singleton module for generating boot image build rules.
type dexpreoptBootJars struct {
android.SingletonModuleBase
// Default boot image config (currently always the Framework boot image extension). It should be
// noted that JIT-Zygote builds use ART APEX image instead of the Framework boot image extension,
// but the switch is handled not here, but in the makefiles (triggered with
// DEXPREOPT_USE_ART_IMAGE=true).
defaultBootImage *bootImageConfig
// Other boot image configs (currently the list contains only the primary ART APEX image. It
// used to contain an experimental JIT-Zygote image (now replaced with the ART APEX image). In
// the future other boot image extensions may be added.
otherImages []*bootImageConfig
// Build path to a config file that Soong writes for Make (to be used in makefiles that install
// the default boot image).
dexpreoptConfigForMake android.WritablePath
}
// Provide paths to boot images for use by modules that depend upon them.
//
// The build rules are created in GenerateSingletonBuildActions().
func (d *dexpreoptBootJars) GenerateAndroidBuildActions(ctx android.ModuleContext) {
// Placeholder for now.
}
// Generate build rules for boot images.
func (d *dexpreoptBootJars) GenerateSingletonBuildActions(ctx android.SingletonContext) {
if SkipDexpreoptBootJars(ctx) {
return
}
if dexpreopt.GetCachedGlobalSoongConfig(ctx) == nil {
// No module has enabled dexpreopting, so we assume there will be no boot image to make.
return
}
d.dexpreoptConfigForMake = android.PathForOutput(ctx, ctx.Config().DeviceName(), "dexpreopt.config")
writeGlobalConfigForMake(ctx, d.dexpreoptConfigForMake)
global := dexpreopt.GetGlobalConfig(ctx)
// Skip recompiling the boot image for the second sanitization phase. We'll get separate paths
// and invalidate first-stage artifacts which are crucial to SANITIZE_LITE builds.
// Note: this is technically incorrect. Compiled code contains stack checks which may depend
// on ASAN settings.
if len(ctx.Config().SanitizeDevice()) == 1 &&
ctx.Config().SanitizeDevice()[0] == "address" &&
global.SanitizeLite {
return
}
// Always create the default boot image first, to get a unique profile rule for all images.
d.defaultBootImage = buildBootImage(ctx, defaultBootImageConfig(ctx))
// Create boot image for the ART apex (build artifacts are accessed via the global boot image config).
d.otherImages = append(d.otherImages, buildBootImage(ctx, artBootImageConfig(ctx)))
copyUpdatableBootJars(ctx)
dumpOatRules(ctx, d.defaultBootImage)
}
// Inspect this module to see if it contains a bootclasspath dex jar.
// Note that the same jar may occur in multiple modules.
// This logic is tested in the apex package to avoid import cycle apex <-> java.
//
// This is similar to logic in isModuleInConfiguredList() so any changes needed here are likely to
// be needed there too.
//
// TODO(b/177892522): Avoid having to perform this type of check or if necessary dedup it.
func getBootJar(ctx android.SingletonContext, bootjars android.ConfiguredJarList,
module android.Module, fromWhere string) (int, android.Path, *android.ApexInfo) {
name := ctx.ModuleName(module)
Export dex implementation jars from prebuilt_apex Dexpreopt and boot jars package check all require access to dex implementation jars created for java_library and java_sdk_library. They were available when building from source but not when building from prebuilts, even though they are embedded within the .apex files that are referenced from prebuilt_apex. This changes adds support to prebuilt_apex to export the dex implementation jars and updates java_import to use those exported dex implementation jars. In a source build dexpreopt/boot jars package check access the apex (or platform) specific variant of a java_library, e.g. core-oj, from which it retrieves the dex implementation jar path. After this change in a prebuilt build dexpreopt/boot jars package check behave in the same way except in this case they retrieve the dex implementation jar path from the apex (or platform) specific variant of the java_import, e.g. core-oj. The work to export files from a `.apex` file for use by other modules is performed by a new `deapexer` module type. It is not used directly in an `Android.bp` file but instead is created implicitly by `prebuilt_apex`, In order to do that this contains the following changes: * Adds a new `dexapexer` module type to handle the exporting of files from the `.apex` file. * Adds an exported_java_libs property to prebuilt_apex to specify the set of libraries whose dex implementation jars need exporting. * Creates apex specific variants of the libraries listed in the exported_java_libs property. * Adds the set of exported files to the ApexInfo to make them available to the apex specific variants. * Prevents the prebuilt_apex variants from being merged together as they will not be compatible. * Modifies java_import to use the exported file for variants of a prebuilt_apex. * Adds a ninja rule to unpack (using deapexer) the contents of the prebuilt_apex's apex file, verify that the required files are present and make them available as outputs for other rules to use. * Some minor refactorings to support these changes. * Adds tests to cover prebuilt only, prebuilt with source preferred, and prebuilt preferred with source. Test: m nothing Bug: 171061220 Change-Id: Ic9bed81fb65b92f0d59f64c0bce168a9ed44cfac
2020-11-03 01:32:38 +08:00
// Strip a prebuilt_ prefix so that this can access the dex jar from a prebuilt module.
name = android.RemoveOptionalPrebuiltPrefix(name)
// Ignore any module that is not listed in the boot image configuration.
index := bootjars.IndexOfJar(name)
if index == -1 {
return -1, nil, nil
}
Export dex implementation jars from prebuilt_apex Dexpreopt and boot jars package check all require access to dex implementation jars created for java_library and java_sdk_library. They were available when building from source but not when building from prebuilts, even though they are embedded within the .apex files that are referenced from prebuilt_apex. This changes adds support to prebuilt_apex to export the dex implementation jars and updates java_import to use those exported dex implementation jars. In a source build dexpreopt/boot jars package check access the apex (or platform) specific variant of a java_library, e.g. core-oj, from which it retrieves the dex implementation jar path. After this change in a prebuilt build dexpreopt/boot jars package check behave in the same way except in this case they retrieve the dex implementation jar path from the apex (or platform) specific variant of the java_import, e.g. core-oj. The work to export files from a `.apex` file for use by other modules is performed by a new `deapexer` module type. It is not used directly in an `Android.bp` file but instead is created implicitly by `prebuilt_apex`, In order to do that this contains the following changes: * Adds a new `dexapexer` module type to handle the exporting of files from the `.apex` file. * Adds an exported_java_libs property to prebuilt_apex to specify the set of libraries whose dex implementation jars need exporting. * Creates apex specific variants of the libraries listed in the exported_java_libs property. * Adds the set of exported files to the ApexInfo to make them available to the apex specific variants. * Prevents the prebuilt_apex variants from being merged together as they will not be compatible. * Modifies java_import to use the exported file for variants of a prebuilt_apex. * Adds a ninja rule to unpack (using deapexer) the contents of the prebuilt_apex's apex file, verify that the required files are present and make them available as outputs for other rules to use. * Some minor refactorings to support these changes. * Adds tests to cover prebuilt only, prebuilt with source preferred, and prebuilt preferred with source. Test: m nothing Bug: 171061220 Change-Id: Ic9bed81fb65b92f0d59f64c0bce168a9ed44cfac
2020-11-03 01:32:38 +08:00
// It is an error if a module configured in the boot image does not support accessing the dex jar.
// This is safe because every module that has the same name has to have the same module type.
jar, hasJar := module.(interface{ DexJarBuildPath() android.Path })
if !hasJar {
ctx.Errorf("module %q %sdoes not support accessing dex jar", module, fromWhere)
return -1, nil, nil
}
// It is also an error if the module is not an ApexModule.
if _, ok := module.(android.ApexModule); !ok {
ctx.Errorf("module %q %sdoes not support being added to an apex", module, fromWhere)
return -1, nil, nil
}
apexInfo := ctx.ModuleProvider(module, android.ApexInfoProvider).(android.ApexInfo)
// Now match the apex part of the boot image configuration.
requiredApex := bootjars.Apex(index)
if requiredApex == "platform" || requiredApex == "system_ext" {
if len(apexInfo.InApexes) != 0 {
// A platform variant is required but this is for an apex so ignore it.
return -1, nil, nil
}
} else if !apexInfo.InApexByBaseName(requiredApex) {
// An apex variant for a specific apex is required but this is the wrong apex.
return -1, nil, nil
}
return index, jar.DexJarBuildPath(), &apexInfo
}
// Inspect this module to see if it contains a bootclasspath dex jar from a given boot image.
func getBootImageJar(ctx android.SingletonContext, image *bootImageConfig, module android.Module) (int, android.Path) {
fromImage := fmt.Sprintf("configured in boot image %q ", image.name)
index, jarPath, apexInfo := getBootJar(ctx, image.modules, module, fromImage)
if index == -1 {
return -1, nil
}
name := ctx.ModuleName(module)
// Check that this module satisfies any boot image specific constraints.
fromUpdatableApex := apexInfo.Updatable
switch image.name {
case artBootImageName:
inArtApex := false
for _, n := range artApexNames {
if apexInfo.InApexByBaseName(n) {
inArtApex = true
break
}
}
if inArtApex {
// ok: found the jar in the ART apex
} else if name == "jacocoagent" && ctx.Config().IsEnvTrue("EMMA_INSTRUMENT_FRAMEWORK") {
// exception (skip and continue): Jacoco platform variant for a coverage build
return -1, nil
} else if fromUpdatableApex {
// error: this jar is part of an updatable apex other than ART
ctx.Errorf("module %q from updatable apexes %q is not allowed in the ART boot image", name, apexInfo.InApexes)
} else {
// error: this jar is part of the platform or a non-updatable apex
Reland: Deduplicate APEX variants that would build identically APEX variants that share the same SDK version and updatability almost always use identical command line arguments to build but with different intermediates directories. This causes unnecessary build time and disk space for duplicated work. Deduplicate APEX variants that would build identically. Create aliases from the per-APEX variations to the new shared variations so that the APEX modules can continue to depend on them via the APEX name as the variation. This has one significant change in behavior. Before this change, if an APEX had two libraries in its direct dependencies and one of those libraries depended on the other, and the second library had stubs, then the first library would depend on the implementation of the second library and not the stubs. After this change, if the first library is also present in a second APEX but the second library is not, then the common variant shared between the two APEXes would use the stubs, not the implementation. In a correctly configured set of build rules this change will be irrelevant, because if the compilation worked for the second APEX using stubs then it will work for the common variant using stubs. However, if an incorrect change to the build rules is made this could lead to confusing errors, as a previously-working common variant could suddenly stop building when a module is added to a new APEX without its dependencies that require implementation APIs to compile. This change reduces the number of modules in an AOSP arm64-userdebug build by 3% (52242 to 50586), reduces the number of variants of the libcutils module from 74 to 53, and reduces the number of variants of the massive libart[d] modules from 44 to 32. This relands I0529837476a253c32b3dfb98dcccf107427c742c with a fix to always mark permissions XML files of java_sdk_library modules as unique per apex since they contain the APEX filename, and a fix to UpdateUniqueApexVariationsForDeps to check ApexInfo.InApexes instead of DepIsInSameApex to check if two modules are in the same apex to account for a module that depends on another in a way that doesn't normally include the dependency in the APEX (e.g. a libs property), but the dependency is directly included in the APEX. Bug: 164216768 Test: go test ./build/soong/apex/... Change-Id: I2ae170601f764e5b88d0be2e0e6adc84e3a4d9cc
2020-08-12 03:17:01 +08:00
ctx.Errorf("module %q is not allowed in the ART boot image", name)
}
case frameworkBootImageName:
if !fromUpdatableApex {
// ok: this jar is part of the platform or a non-updatable apex
} else {
// error: this jar is part of an updatable apex
ctx.Errorf("module %q from updatable apexes %q is not allowed in the framework boot image", name, apexInfo.InApexes)
}
default:
panic("unknown boot image: " + image.name)
}
return index, jarPath
}
// Generate commands that will copy boot jars to predefined paths in the global config.
func findAndCopyBootJars(ctx android.SingletonContext, bootjars android.ConfiguredJarList,
jarPathsPredefined android.WritablePaths,
getBootJar func(module android.Module) (int, android.Path)) []string {
// This logic is tested in the apex package to avoid import cycle apex <-> java.
jarPaths := make(android.Paths, bootjars.Len())
ctx.VisitAllModules(func(module android.Module) {
if !isActiveModule(module) {
return
}
if i, j := getBootJar(module); i != -1 {
if existing := jarPaths[i]; existing != nil {
ctx.Errorf("Multiple dex jars found for %s:%s - %q and %q",
bootjars.Apex(i), bootjars.Jar(i), existing, j)
return
}
jarPaths[i] = j
}
})
var missingDeps []string
// Ensure all modules were converted to paths
for i := range jarPaths {
if jarPaths[i] == nil {
m := bootjars.Jar(i)
if ctx.Config().AllowMissingDependencies() {
missingDeps = append(missingDeps, m)
jarPaths[i] = android.PathForOutput(ctx, "missing/module", m, "from/apex",
bootjars.Apex(i))
} else {
ctx.Errorf("failed to find a dex jar path for module '%s'"+
", note that some jars may be filtered out by module constraints", m)
}
}
}
// The paths to bootclasspath DEX files need to be known at module GenerateAndroidBuildAction
// time, before the boot images are built (these paths are used in dexpreopt rule generation for
// Java libraries and apps). Generate rules that copy bootclasspath DEX jars to the predefined
// paths.
for i := range jarPaths {
ctx.Build(pctx, android.BuildParams{
Rule: android.Cp,
Input: jarPaths[i],
Output: jarPathsPredefined[i],
})
}
return missingDeps
}
// buildBootImage takes a bootImageConfig, creates rules to build it, and returns the image.
func buildBootImage(ctx android.SingletonContext, image *bootImageConfig) *bootImageConfig {
getBootJarFunc := func(module android.Module) (int, android.Path) {
return getBootImageJar(ctx, image, module)
}
missingDeps := findAndCopyBootJars(ctx, image.modules, image.dexPaths, getBootJarFunc)
profile := bootImageProfileRule(ctx, image, missingDeps)
bootFrameworkProfileRule(ctx, image, missingDeps)
updatableBcpPackagesRule(ctx, image, missingDeps)
var zipFiles android.Paths
for _, variant := range image.variants {
files := buildBootImageVariant(ctx, variant, profile, missingDeps)
if variant.target.Os == android.Android {
zipFiles = append(zipFiles, files.Paths()...)
}
}
if image.zip != nil {
rule := android.NewRuleBuilder(pctx, ctx)
rule.Command().
BuiltTool("soong_zip").
FlagWithOutput("-o ", image.zip).
FlagWithArg("-C ", image.dir.Join(ctx, android.Android.String()).String()).
FlagWithInputList("-f ", zipFiles, " -f ")
rule.Build("zip_"+image.name, "zip "+image.name+" image")
}
return image
}
// Generate commands that will copy updatable boot jars to predefined paths in the global config.
func copyUpdatableBootJars(ctx android.SingletonContext) {
config := GetUpdatableBootConfig(ctx)
getBootJarFunc := func(module android.Module) (int, android.Path) {
index, jar, _ := getBootJar(ctx, config.modules, module, "configured in updatable boot jars ")
return index, jar
}
missingDeps := findAndCopyBootJars(ctx, config.modules, config.dexPaths, getBootJarFunc)
// Ignoring missing dependencies here. Ideally they should be added to the dexpreopt rule, but
// that is not possible as this rule is created after dexpreopt rules (it's in a singleton
// context, and they are in a module context). The true fix is to add dependencies from the
// dexpreopted modules on updatable boot jars and avoid this copying altogether.
_ = missingDeps
}
// Generate boot image build rules for a specific target.
func buildBootImageVariant(ctx android.SingletonContext, image *bootImageVariant,
profile android.Path, missingDeps []string) android.WritablePaths {
globalSoong := dexpreopt.GetCachedGlobalSoongConfig(ctx)
global := dexpreopt.GetGlobalConfig(ctx)
arch := image.target.Arch.ArchType
os := image.target.Os.String() // We need to distinguish host-x86 and device-x86.
symbolsDir := image.symbolsDir.Join(ctx, os, image.installSubdir, arch.String())
symbolsFile := symbolsDir.Join(ctx, image.stem+".oat")
outputDir := image.dir.Join(ctx, os, image.installSubdir, arch.String())
outputPath := outputDir.Join(ctx, image.stem+".oat")
oatLocation := dexpreopt.PathToLocation(outputPath, arch)
imagePath := outputPath.ReplaceExtension(ctx, "art")
rule := android.NewRuleBuilder(pctx, ctx)
rule.MissingDeps(missingDeps)
rule.Command().Text("mkdir").Flag("-p").Flag(symbolsDir.String())
rule.Command().Text("rm").Flag("-f").
Flag(symbolsDir.Join(ctx, "*.art").String()).
Flag(symbolsDir.Join(ctx, "*.oat").String()).
Flag(symbolsDir.Join(ctx, "*.invocation").String())
rule.Command().Text("rm").Flag("-f").
Flag(outputDir.Join(ctx, "*.art").String()).
Flag(outputDir.Join(ctx, "*.oat").String()).
Flag(outputDir.Join(ctx, "*.invocation").String())
cmd := rule.Command()
extraFlags := ctx.Config().Getenv("ART_BOOT_IMAGE_EXTRA_ARGS")
if extraFlags == "" {
// Use ANDROID_LOG_TAGS to suppress most logging by default...
cmd.Text(`ANDROID_LOG_TAGS="*:e"`)
} else {
// ...unless the boot image is generated specifically for testing, then allow all logging.
cmd.Text(`ANDROID_LOG_TAGS="*:v"`)
}
invocationPath := outputPath.ReplaceExtension(ctx, "invocation")
cmd.Tool(globalSoong.Dex2oat).
Flag("--avoid-storing-invocation").
FlagWithOutput("--write-invocation-to=", invocationPath).ImplicitOutput(invocationPath).
Flag("--runtime-arg").FlagWithArg("-Xms", global.Dex2oatImageXms).
Flag("--runtime-arg").FlagWithArg("-Xmx", global.Dex2oatImageXmx)
if profile != nil {
cmd.FlagWithArg("--compiler-filter=", "speed-profile")
cmd.FlagWithInput("--profile-file=", profile)
}
dirtyImageFile := "frameworks/base/config/dirty-image-objects"
dirtyImagePath := android.ExistentPathForSource(ctx, dirtyImageFile)
if dirtyImagePath.Valid() {
cmd.FlagWithInput("--dirty-image-objects=", dirtyImagePath.Path())
}
if image.extends != nil {
// It is a boot image extension, so it needs the boot image it depends on (in this case the
// primary ART APEX image).
artImage := image.primaryImages
cmd.
Flag("--runtime-arg").FlagWithInputList("-Xbootclasspath:", image.dexPathsDeps.Paths(), ":").
Flag("--runtime-arg").FlagWithList("-Xbootclasspath-locations:", image.dexLocationsDeps, ":").
FlagWithArg("--boot-image=", dexpreopt.PathToLocation(artImage, arch)).Implicit(artImage)
} else {
// It is a primary image, so it needs a base address.
cmd.FlagWithArg("--base=", ctx.Config().LibartImgDeviceBaseAddress())
}
cmd.
FlagForEachInput("--dex-file=", image.dexPaths.Paths()).
FlagForEachArg("--dex-location=", image.dexLocations).
Flag("--generate-debug-info").
Flag("--generate-build-id").
Flag("--image-format=lz4hc").
FlagWithArg("--oat-symbols=", symbolsFile.String()).
Flag("--strip").
FlagWithArg("--oat-file=", outputPath.String()).
FlagWithArg("--oat-location=", oatLocation).
FlagWithArg("--image=", imagePath.String()).
FlagWithArg("--instruction-set=", arch.String()).
FlagWithArg("--android-root=", global.EmptyDirectory).
FlagWithArg("--no-inline-from=", "core-oj.jar").
Flag("--force-determinism").
Flag("--abort-on-hard-verifier-error")
// Use the default variant/features for host builds.
// The map below contains only device CPU info (which might be x86 on some devices).
if image.target.Os == android.Android {
cmd.FlagWithArg("--instruction-set-variant=", global.CpuVariant[arch])
cmd.FlagWithArg("--instruction-set-features=", global.InstructionSetFeatures[arch])
}
if global.BootFlags != "" {
cmd.Flag(global.BootFlags)
}
if extraFlags != "" {
cmd.Flag(extraFlags)
}
cmd.Textf(`|| ( echo %s ; false )`, proptools.ShellEscape(failureMessage))
installDir := filepath.Join("/", image.installSubdir, arch.String())
var vdexInstalls android.RuleBuilderInstalls
var unstrippedInstalls android.RuleBuilderInstalls
var zipFiles android.WritablePaths
for _, artOrOat := range image.moduleFiles(ctx, outputDir, ".art", ".oat") {
cmd.ImplicitOutput(artOrOat)
zipFiles = append(zipFiles, artOrOat)
// Install the .oat and .art files
rule.Install(artOrOat, filepath.Join(installDir, artOrOat.Base()))
}
for _, vdex := range image.moduleFiles(ctx, outputDir, ".vdex") {
cmd.ImplicitOutput(vdex)
zipFiles = append(zipFiles, vdex)
// Note that the vdex files are identical between architectures.
// Make rules will create symlinks to share them between architectures.
vdexInstalls = append(vdexInstalls,
android.RuleBuilderInstall{vdex, filepath.Join(installDir, vdex.Base())})
}
for _, unstrippedOat := range image.moduleFiles(ctx, symbolsDir, ".oat") {
cmd.ImplicitOutput(unstrippedOat)
// Install the unstripped oat files. The Make rules will put these in $(TARGET_OUT_UNSTRIPPED)
unstrippedInstalls = append(unstrippedInstalls,
android.RuleBuilderInstall{unstrippedOat, filepath.Join(installDir, unstrippedOat.Base())})
}
rule.Build(image.name+"JarsDexpreopt_"+image.target.String(), "dexpreopt "+image.name+" jars "+arch.String())
// save output and installed files for makevars
image.installs = rule.Installs()
image.vdexInstalls = vdexInstalls
image.unstrippedInstalls = unstrippedInstalls
return zipFiles
}
const failureMessage = `ERROR: Dex2oat failed to compile a boot image.
It is likely that the boot classpath is inconsistent.
Rebuild with ART_BOOT_IMAGE_EXTRA_ARGS="--runtime-arg -verbose:verifier" to see verification errors.`
func bootImageProfileRule(ctx android.SingletonContext, image *bootImageConfig, missingDeps []string) android.WritablePath {
globalSoong := dexpreopt.GetCachedGlobalSoongConfig(ctx)
global := dexpreopt.GetGlobalConfig(ctx)
if global.DisableGenerateProfile {
return nil
}
profile := ctx.Config().Once(bootImageProfileRuleKey, func() interface{} {
defaultProfile := "frameworks/base/config/boot-image-profile.txt"
rule := android.NewRuleBuilder(pctx, ctx)
rule.MissingDeps(missingDeps)
var bootImageProfile android.Path
if len(global.BootImageProfiles) > 1 {
combinedBootImageProfile := image.dir.Join(ctx, "boot-image-profile.txt")
rule.Command().Text("cat").Inputs(global.BootImageProfiles).Text(">").Output(combinedBootImageProfile)
bootImageProfile = combinedBootImageProfile
} else if len(global.BootImageProfiles) == 1 {
bootImageProfile = global.BootImageProfiles[0]
} else if path := android.ExistentPathForSource(ctx, defaultProfile); path.Valid() {
bootImageProfile = path.Path()
} else {
// No profile (not even a default one, which is the case on some branches
// like master-art-host that don't have frameworks/base).
// Return nil and continue without profile.
return nil
}
profile := image.dir.Join(ctx, "boot.prof")
rule.Command().
Text(`ANDROID_LOG_TAGS="*:e"`).
Tool(globalSoong.Profman).
Flag("--output-profile-type=boot").
FlagWithInput("--create-profile-from=", bootImageProfile).
FlagForEachInput("--apk=", image.dexPathsDeps.Paths()).
FlagForEachArg("--dex-location=", image.getAnyAndroidVariant().dexLocationsDeps).
FlagWithOutput("--reference-profile-file=", profile)
rule.Install(profile, "/system/etc/boot-image.prof")
rule.Build("bootJarsProfile", "profile boot jars")
image.profileInstalls = rule.Installs()
return profile
})
if profile == nil {
return nil // wrap nil into a typed pointer with value nil
}
return profile.(android.WritablePath)
}
var bootImageProfileRuleKey = android.NewOnceKey("bootImageProfileRule")
func bootFrameworkProfileRule(ctx android.SingletonContext, image *bootImageConfig, missingDeps []string) android.WritablePath {
globalSoong := dexpreopt.GetCachedGlobalSoongConfig(ctx)
global := dexpreopt.GetGlobalConfig(ctx)
if global.DisableGenerateProfile || ctx.Config().UnbundledBuild() {
return nil
}
return ctx.Config().Once(bootFrameworkProfileRuleKey, func() interface{} {
rule := android.NewRuleBuilder(pctx, ctx)
rule.MissingDeps(missingDeps)
// Some branches like master-art-host don't have frameworks/base, so manually
// handle the case that the default is missing. Those branches won't attempt to build the profile rule,
// and if they do they'll get a missing deps error.
defaultProfile := "frameworks/base/config/boot-profile.txt"
path := android.ExistentPathForSource(ctx, defaultProfile)
var bootFrameworkProfile android.Path
if path.Valid() {
bootFrameworkProfile = path.Path()
} else {
missingDeps = append(missingDeps, defaultProfile)
bootFrameworkProfile = android.PathForOutput(ctx, "missing", defaultProfile)
}
profile := image.dir.Join(ctx, "boot.bprof")
rule.Command().
Text(`ANDROID_LOG_TAGS="*:e"`).
Tool(globalSoong.Profman).
Flag("--output-profile-type=bprof").
FlagWithInput("--create-profile-from=", bootFrameworkProfile).
FlagForEachInput("--apk=", image.dexPathsDeps.Paths()).
FlagForEachArg("--dex-location=", image.getAnyAndroidVariant().dexLocationsDeps).
FlagWithOutput("--reference-profile-file=", profile)
rule.Install(profile, "/system/etc/boot-image.bprof")
rule.Build("bootFrameworkProfile", "profile boot framework jars")
image.profileInstalls = append(image.profileInstalls, rule.Installs()...)
return profile
}).(android.WritablePath)
}
var bootFrameworkProfileRuleKey = android.NewOnceKey("bootFrameworkProfileRule")
func updatableBcpPackagesRule(ctx android.SingletonContext, image *bootImageConfig, missingDeps []string) android.WritablePath {
if ctx.Config().UnbundledBuild() {
return nil
}
return ctx.Config().Once(updatableBcpPackagesRuleKey, func() interface{} {
global := dexpreopt.GetGlobalConfig(ctx)
updatableModules := global.UpdatableBootJars.CopyOfJars()
// Collect `permitted_packages` for updatable boot jars.
var updatablePackages []string
ctx.VisitAllModules(func(module android.Module) {
if !isActiveModule(module) {
return
}
if j, ok := module.(PermittedPackagesForUpdatableBootJars); ok {
name := ctx.ModuleName(module)
if i := android.IndexList(name, updatableModules); i != -1 {
pp := j.PermittedPackagesForUpdatableBootJars()
if len(pp) > 0 {
updatablePackages = append(updatablePackages, pp...)
} else {
ctx.Errorf("Missing permitted_packages for %s", name)
}
// Do not match the same library repeatedly.
updatableModules = append(updatableModules[:i], updatableModules[i+1:]...)
}
}
})
// Sort updatable packages to ensure deterministic ordering.
sort.Strings(updatablePackages)
updatableBcpPackagesName := "updatable-bcp-packages.txt"
updatableBcpPackages := image.dir.Join(ctx, updatableBcpPackagesName)
// WriteFileRule automatically adds the last end-of-line.
android.WriteFileRule(ctx, updatableBcpPackages, strings.Join(updatablePackages, "\n"))
rule := android.NewRuleBuilder(pctx, ctx)
rule.MissingDeps(missingDeps)
rule.Install(updatableBcpPackages, "/system/etc/"+updatableBcpPackagesName)
// TODO: Rename `profileInstalls` to `extraInstalls`?
// Maybe even move the field out of the bootImageConfig into some higher level type?
image.profileInstalls = append(image.profileInstalls, rule.Installs()...)
return updatableBcpPackages
}).(android.WritablePath)
}
var updatableBcpPackagesRuleKey = android.NewOnceKey("updatableBcpPackagesRule")
func dumpOatRules(ctx android.SingletonContext, image *bootImageConfig) {
var allPhonies android.Paths
for _, image := range image.variants {
arch := image.target.Arch.ArchType
suffix := arch.String()
// Host and target might both use x86 arch. We need to ensure the names are unique.
if image.target.Os.Class == android.Host {
suffix = "host-" + suffix
}
// Create a rule to call oatdump.
output := android.PathForOutput(ctx, "boot."+suffix+".oatdump.txt")
rule := android.NewRuleBuilder(pctx, ctx)
rule.Command().
// TODO: for now, use the debug version for better error reporting
BuiltTool("oatdumpd").
FlagWithInputList("--runtime-arg -Xbootclasspath:", image.dexPathsDeps.Paths(), ":").
FlagWithList("--runtime-arg -Xbootclasspath-locations:", image.dexLocationsDeps, ":").
FlagWithArg("--image=", strings.Join(image.imageLocations(), ":")).Implicits(image.imagesDeps.Paths()).
FlagWithOutput("--output=", output).
FlagWithArg("--instruction-set=", arch.String())
rule.Build("dump-oat-boot-"+suffix, "dump oat boot "+arch.String())
// Create a phony rule that depends on the output file and prints the path.
phony := android.PathForPhony(ctx, "dump-oat-boot-"+suffix)
rule = android.NewRuleBuilder(pctx, ctx)
rule.Command().
Implicit(output).
ImplicitOutput(phony).
Text("echo").FlagWithArg("Output in ", output.String())
rule.Build("phony-dump-oat-boot-"+suffix, "dump oat boot "+arch.String())
allPhonies = append(allPhonies, phony)
}
phony := android.PathForPhony(ctx, "dump-oat-boot")
ctx.Build(pctx, android.BuildParams{
Rule: android.Phony,
Output: phony,
Inputs: allPhonies,
Description: "dump-oat-boot",
})
}
func writeGlobalConfigForMake(ctx android.SingletonContext, path android.WritablePath) {
data := dexpreopt.GetGlobalConfigRawData(ctx)
android.WriteFileRule(ctx, path, string(data))
}
// Define Make variables for boot image names, paths, etc. These variables are used in makefiles
// (make/core/dex_preopt_libart.mk) to generate install rules that copy boot image files to the
// correct output directories.
func (d *dexpreoptBootJars) MakeVars(ctx android.MakeVarsContext) {
if d.dexpreoptConfigForMake != nil {
ctx.Strict("DEX_PREOPT_CONFIG_FOR_MAKE", d.dexpreoptConfigForMake.String())
ctx.Strict("DEX_PREOPT_SOONG_CONFIG_FOR_MAKE", android.PathForOutput(ctx, "dexpreopt_soong.config").String())
}
image := d.defaultBootImage
if image != nil {
ctx.Strict("DEXPREOPT_IMAGE_PROFILE_BUILT_INSTALLED", image.profileInstalls.String())
global := dexpreopt.GetGlobalConfig(ctx)
dexPaths, dexLocations := bcpForDexpreopt(ctx, global.PreoptWithUpdatableBcp)
ctx.Strict("DEXPREOPT_BOOTCLASSPATH_DEX_FILES", strings.Join(dexPaths.Strings(), " "))
ctx.Strict("DEXPREOPT_BOOTCLASSPATH_DEX_LOCATIONS", strings.Join(dexLocations, " "))
var imageNames []string
// TODO: the primary ART boot image should not be exposed to Make, as it is installed in a
// different way as a part of the ART APEX. However, there is a special JIT-Zygote build
// configuration which uses the primary ART image instead of the Framework boot image
// extension, and it relies on the ART image being exposed to Make. To fix this, it is
// necessary to rework the logic in makefiles.
for _, current := range append(d.otherImages, image) {
imageNames = append(imageNames, current.name)
for _, variant := range current.variants {
suffix := ""
if variant.target.Os.Class == android.Host {
suffix = "_host"
}
sfx := variant.name + suffix + "_" + variant.target.Arch.ArchType.String()
ctx.Strict("DEXPREOPT_IMAGE_VDEX_BUILT_INSTALLED_"+sfx, variant.vdexInstalls.String())
ctx.Strict("DEXPREOPT_IMAGE_"+sfx, variant.images.String())
ctx.Strict("DEXPREOPT_IMAGE_DEPS_"+sfx, strings.Join(variant.imagesDeps.Strings(), " "))
ctx.Strict("DEXPREOPT_IMAGE_BUILT_INSTALLED_"+sfx, variant.installs.String())
ctx.Strict("DEXPREOPT_IMAGE_UNSTRIPPED_BUILT_INSTALLED_"+sfx, variant.unstrippedInstalls.String())
}
imageLocations := current.getAnyAndroidVariant().imageLocations()
ctx.Strict("DEXPREOPT_IMAGE_LOCATIONS_"+current.name, strings.Join(imageLocations, ":"))
ctx.Strict("DEXPREOPT_IMAGE_ZIP_"+current.name, current.zip.String())
}
ctx.Strict("DEXPREOPT_IMAGE_NAMES", strings.Join(imageNames, " "))
}
}