platform_build_soong/java/java.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 java
// This file contains the module types for compiling Java for Android, and converts the properties
// into the flags and filenames necessary to pass to the Module. The final creation of the rules
// is handled in builder.go
import (
"fmt"
"path/filepath"
"strconv"
"strings"
"github.com/google/blueprint"
"github.com/google/blueprint/pathtools"
"github.com/google/blueprint/proptools"
"android/soong/android"
"android/soong/dexpreopt"
"android/soong/java/config"
"android/soong/tradefed"
)
func init() {
RegisterJavaBuildComponents(android.InitRegistrationContext)
Decouple addition of new sdk member types from sdk code Previously, adding a new SdkMemberType would require adding a new sdkMemberListProperty instance to the sdkMemberListProperties as well as adding a new property into the sdkProperties struct. They are potential sources of conflict and couple the sdk code with all the packages that add members to it. This change switched to a registration model that allows each package to register its sdk member types decoupling them from the sdk code. Adds an SdkPropertyName() method to SdkMemberType that specifies the name of the property to use in the sdk/sdk_snapshot. Also provides an SdkMemberTypeBase struct to be used by providers of SdkMemberType implementations. SdkMemberType instances are registered using the RegisterSdkMemberType() func which sorts the registered instances by their SdkPropertyName() to ensure the behavior is consistent and not affected by order of registration. When creating a new sdk module a dynamicSdkMemberTypes instance is created that contains the following: * A properties struct is created dynamically that contains a field for each registered SdkMemberType, corresponding to that type's SdkPropertyName(). * A list of sdkMemberListProperty instances is also created, one for each registered SdkMemberType. The dynamicSdkMemberTypes instance is cached using a key that uniquely identifies the set of registered types just in case new types are registered after one has been created, e.g. by tests. Bug: 142918168 Test: m checkbuild Change-Id: I4bf2bf56a2a49025aa41454048bc1e8ccc6baca2
2019-12-13 19:22:16 +08:00
// Register sdk member types.
android.RegisterSdkMemberType(javaHeaderLibsSdkMemberType)
Decouple addition of new sdk member types from sdk code Previously, adding a new SdkMemberType would require adding a new sdkMemberListProperty instance to the sdkMemberListProperties as well as adding a new property into the sdkProperties struct. They are potential sources of conflict and couple the sdk code with all the packages that add members to it. This change switched to a registration model that allows each package to register its sdk member types decoupling them from the sdk code. Adds an SdkPropertyName() method to SdkMemberType that specifies the name of the property to use in the sdk/sdk_snapshot. Also provides an SdkMemberTypeBase struct to be used by providers of SdkMemberType implementations. SdkMemberType instances are registered using the RegisterSdkMemberType() func which sorts the registered instances by their SdkPropertyName() to ensure the behavior is consistent and not affected by order of registration. When creating a new sdk module a dynamicSdkMemberTypes instance is created that contains the following: * A properties struct is created dynamically that contains a field for each registered SdkMemberType, corresponding to that type's SdkPropertyName(). * A list of sdkMemberListProperty instances is also created, one for each registered SdkMemberType. The dynamicSdkMemberTypes instance is cached using a key that uniquely identifies the set of registered types just in case new types are registered after one has been created, e.g. by tests. Bug: 142918168 Test: m checkbuild Change-Id: I4bf2bf56a2a49025aa41454048bc1e8ccc6baca2
2019-12-13 19:22:16 +08:00
// Export implementation classes jar as part of the sdk.
exportImplementationClassesJar := func(_ android.SdkMemberContext, j *Library) android.Path {
implementationJars := j.ImplementationAndResourcesJars()
if len(implementationJars) != 1 {
panic(fmt.Errorf("there must be only one implementation jar from %q", j.Name()))
}
return implementationJars[0]
}
// Register java implementation libraries for use only in module_exports (not sdk).
android.RegisterSdkMemberType(&librarySdkMemberType{
android.SdkMemberTypeBase{
PropertyName: "java_libs",
},
exportImplementationClassesJar,
sdkSnapshotFilePathForJar,
copyEverythingToSnapshot,
Decouple addition of new sdk member types from sdk code Previously, adding a new SdkMemberType would require adding a new sdkMemberListProperty instance to the sdkMemberListProperties as well as adding a new property into the sdkProperties struct. They are potential sources of conflict and couple the sdk code with all the packages that add members to it. This change switched to a registration model that allows each package to register its sdk member types decoupling them from the sdk code. Adds an SdkPropertyName() method to SdkMemberType that specifies the name of the property to use in the sdk/sdk_snapshot. Also provides an SdkMemberTypeBase struct to be used by providers of SdkMemberType implementations. SdkMemberType instances are registered using the RegisterSdkMemberType() func which sorts the registered instances by their SdkPropertyName() to ensure the behavior is consistent and not affected by order of registration. When creating a new sdk module a dynamicSdkMemberTypes instance is created that contains the following: * A properties struct is created dynamically that contains a field for each registered SdkMemberType, corresponding to that type's SdkPropertyName(). * A list of sdkMemberListProperty instances is also created, one for each registered SdkMemberType. The dynamicSdkMemberTypes instance is cached using a key that uniquely identifies the set of registered types just in case new types are registered after one has been created, e.g. by tests. Bug: 142918168 Test: m checkbuild Change-Id: I4bf2bf56a2a49025aa41454048bc1e8ccc6baca2
2019-12-13 19:22:16 +08:00
})
// Register java boot libraries for use in sdk.
//
// The build has some implicit dependencies (via the boot jars configuration) on a number of
// modules, e.g. core-oj, apache-xml, that are part of the java boot class path and which are
// provided by mainline modules (e.g. art, conscrypt, runtime-i18n) but which are not otherwise
// used outside those mainline modules.
//
// As they are not needed outside the mainline modules adding them to the sdk/module-exports as
// either java_libs, or java_header_libs would end up exporting more information than was strictly
// necessary. The java_boot_libs property to allow those modules to be exported as part of the
// sdk/module_exports without exposing any unnecessary information.
android.RegisterSdkMemberType(&librarySdkMemberType{
android.SdkMemberTypeBase{
PropertyName: "java_boot_libs",
SupportsSdk: true,
},
// Temporarily export implementation classes jar for java_boot_libs as it is required for the
// hiddenapi processing.
// TODO(b/179354495): Revert once hiddenapi processing has been modularized.
exportImplementationClassesJar,
sdkSnapshotFilePathForJar,
onlyCopyJarToSnapshot,
})
// Register java test libraries for use only in module_exports (not sdk).
android.RegisterSdkMemberType(&testSdkMemberType{
SdkMemberTypeBase: android.SdkMemberTypeBase{
PropertyName: "java_tests",
},
})
}
func RegisterJavaBuildComponents(ctx android.RegistrationContext) {
ctx.RegisterModuleType("java_defaults", DefaultsFactory)
ctx.RegisterModuleType("java_library", LibraryFactory)
ctx.RegisterModuleType("java_library_static", LibraryStaticFactory)
ctx.RegisterModuleType("java_library_host", LibraryHostFactory)
ctx.RegisterModuleType("java_binary", BinaryFactory)
ctx.RegisterModuleType("java_binary_host", BinaryHostFactory)
ctx.RegisterModuleType("java_test", TestFactory)
ctx.RegisterModuleType("java_test_helper_library", TestHelperLibraryFactory)
ctx.RegisterModuleType("java_test_host", TestHostFactory)
ctx.RegisterModuleType("java_test_import", JavaTestImportFactory)
ctx.RegisterModuleType("java_import", ImportFactory)
ctx.RegisterModuleType("java_import_host", ImportFactoryHost)
ctx.RegisterModuleType("java_device_for_host", DeviceForHostFactory)
ctx.RegisterModuleType("java_host_for_device", HostForDeviceFactory)
ctx.RegisterModuleType("dex_import", DexImportFactory)
ctx.FinalDepsMutators(func(ctx android.RegisterMutatorsContext) {
ctx.BottomUp("dexpreopt_tool_deps", dexpreoptToolDepsMutator).Parallel()
})
ctx.RegisterSingletonType("logtags", LogtagsSingleton)
ctx.RegisterSingletonType("kythe_java_extract", kytheExtractJavaFactory)
}
func (j *Module) CheckStableSdkVersion() error {
sdkVersion := j.sdkVersion()
if sdkVersion.stable() {
return nil
}
return fmt.Errorf("non stable SDK %v", sdkVersion)
}
func (j *Module) checkSdkVersions(ctx android.ModuleContext) {
if j.RequiresStableAPIs(ctx) {
if sc, ok := ctx.Module().(sdkContext); ok {
if !sc.sdkVersion().specified() {
ctx.PropertyErrorf("sdk_version",
"sdk_version must have a value when the module is located at vendor or product(only if PRODUCT_ENFORCE_PRODUCT_PARTITION_INTERFACE is set).")
}
}
}
ctx.VisitDirectDeps(func(module android.Module) {
tag := ctx.OtherModuleDependencyTag(module)
switch module.(type) {
// TODO(satayev): cover other types as well, e.g. imports
case *Library, *AndroidLibrary:
switch tag {
case bootClasspathTag, libTag, staticLibTag, java9LibTag:
checkLinkType(ctx, j, module.(linkTypeContext), tag.(dependencyTag))
}
}
})
}
func (j *Module) checkPlatformAPI(ctx android.ModuleContext) {
if sc, ok := ctx.Module().(sdkContext); ok {
usePlatformAPI := proptools.Bool(j.deviceProperties.Platform_apis)
sdkVersionSpecified := sc.sdkVersion().specified()
if usePlatformAPI && sdkVersionSpecified {
ctx.PropertyErrorf("platform_apis", "platform_apis must be false when sdk_version is not empty.")
} else if !usePlatformAPI && !sdkVersionSpecified {
ctx.PropertyErrorf("platform_apis", "platform_apis must be true when sdk_version is empty.")
}
}
}
// TODO:
// Autogenerated files:
// Renderscript
// Post-jar passes:
// Proguard
// Rmtypedefs
// DroidDoc
// Findbugs
type CompilerProperties struct {
// list of source files used to compile the Java module. May be .java, .kt, .logtags, .proto,
// or .aidl files.
Srcs []string `android:"path,arch_variant"`
// list Kotlin of source files containing Kotlin code that should be treated as common code in
// a codebase that supports Kotlin multiplatform. See
// https://kotlinlang.org/docs/reference/multiplatform.html. May be only be .kt files.
Common_srcs []string `android:"path,arch_variant"`
// list of source files that should not be used to build the Java module.
// This is most useful in the arch/multilib variants to remove non-common files
Exclude_srcs []string `android:"path,arch_variant"`
// list of directories containing Java resources
Java_resource_dirs []string `android:"arch_variant"`
// list of directories that should be excluded from java_resource_dirs
Exclude_java_resource_dirs []string `android:"arch_variant"`
// list of files to use as Java resources
Java_resources []string `android:"path,arch_variant"`
// list of files that should be excluded from java_resources and java_resource_dirs
Exclude_java_resources []string `android:"path,arch_variant"`
// list of module-specific flags that will be used for javac compiles
Javacflags []string `android:"arch_variant"`
// list of module-specific flags that will be used for kotlinc compiles
Kotlincflags []string `android:"arch_variant"`
// list of of java libraries that will be in the classpath
Libs []string `android:"arch_variant"`
// list of java libraries that will be compiled into the resulting jar
Static_libs []string `android:"arch_variant"`
// manifest file to be included in resulting jar
Manifest *string `android:"path"`
// if not blank, run jarjar using the specified rules file
Jarjar_rules *string `android:"path,arch_variant"`
// If not blank, set the java version passed to javac as -source and -target
Java_version *string
// If set to true, allow this module to be dexed and installed on devices. Has no
// effect on host modules, which are always considered installable.
Installable *bool
// If set to true, include sources used to compile the module in to the final jar
Include_srcs *bool
// If not empty, classes are restricted to the specified packages and their sub-packages.
// This restriction is checked after applying jarjar rules and including static libs.
Permitted_packages []string
// List of modules to use as annotation processors
Plugins []string
// List of modules to export to libraries that directly depend on this library as annotation
// processors. Note that if the plugins set generates_api: true this will disable the turbine
// optimization on modules that depend on this module, which will reduce parallelism and cause
// more recompilation.
Exported_plugins []string
// The number of Java source entries each Javac instance can process
Javac_shard_size *int64
// Add host jdk tools.jar to bootclasspath
Use_tools_jar *bool
Openjdk9 struct {
// List of source files that should only be used when passing -source 1.9 or higher
Srcs []string `android:"path"`
// List of javac flags that should only be used when passing -source 1.9 or higher
Javacflags []string
}
// When compiling language level 9+ .java code in packages that are part of
// a system module, patch_module names the module that your sources and
// dependencies should be patched into. The Android runtime currently
// doesn't implement the JEP 261 module system so this option is only
// supported at compile time. It should only be needed to compile tests in
// packages that exist in libcore and which are inconvenient to move
// elsewhere.
Patch_module *string `android:"arch_variant"`
Jacoco struct {
// List of classes to include for instrumentation with jacoco to collect coverage
// information at runtime when building with coverage enabled. If unset defaults to all
// classes.
// Supports '*' as the last character of an entry in the list as a wildcard match.
// If preceded by '.' it matches all classes in the package and subpackages, otherwise
// it matches classes in the package that have the class name as a prefix.
Include_filter []string
// List of classes to exclude from instrumentation with jacoco to collect coverage
// information at runtime when building with coverage enabled. Overrides classes selected
// by the include_filter property.
// Supports '*' as the last character of an entry in the list as a wildcard match.
// If preceded by '.' it matches all classes in the package and subpackages, otherwise
// it matches classes in the package that have the class name as a prefix.
Exclude_filter []string
}
Errorprone struct {
// List of javac flags that should only be used when running errorprone.
Javacflags []string
// List of java_plugin modules that provide extra errorprone checks.
Extra_check_modules []string
}
Proto struct {
// List of extra options that will be passed to the proto generator.
Output_params []string
}
Instrument bool `blueprint:"mutated"`
// List of files to include in the META-INF/services folder of the resulting jar.
Services []string `android:"path,arch_variant"`
// If true, package the kotlin stdlib into the jar. Defaults to true.
Static_kotlin_stdlib *bool `android:"arch_variant"`
}
type CompilerDeviceProperties struct {
// if not blank, set to the version of the sdk to compile against.
// Defaults to compiling against the current platform.
Sdk_version *string
// if not blank, set the minimum version of the sdk that the compiled artifacts will run against.
// Defaults to sdk_version if not set.
Min_sdk_version *string
// if not blank, set the targetSdkVersion in the AndroidManifest.xml.
// Defaults to sdk_version if not set.
Target_sdk_version *string
// Whether to compile against the platform APIs instead of an SDK.
// If true, then sdk_version must be empty. The value of this field
// is ignored when module's type isn't android_app.
Platform_apis *bool
Aidl struct {
// Top level directories to pass to aidl tool
Include_dirs []string
// Directories rooted at the Android.bp file to pass to aidl tool
Local_include_dirs []string
// directories that should be added as include directories for any aidl sources of modules
// that depend on this module, as well as to aidl for this module.
Export_include_dirs []string
// whether to generate traces (for systrace) for this interface
Generate_traces *bool
// whether to generate Binder#GetTransaction name method.
Generate_get_transaction_name *bool
// list of flags that will be passed to the AIDL compiler
Flags []string
}
// If true, export a copy of the module as a -hostdex module for host testing.
Hostdex *bool
Target struct {
Hostdex struct {
// Additional required dependencies to add to -hostdex modules.
Required []string
}
}
// When targeting 1.9 and above, override the modules to use with --system,
// otherwise provides defaults libraries to add to the bootclasspath.
System_modules *string
// The name of the module as used in build configuration.
//
// Allows a library to separate its actual name from the name used in
// build configuration, e.g.ctx.Config().BootJars().
ConfigurationName *string `blueprint:"mutated"`
// set the name of the output
Stem *string
IsSDKLibrary bool `blueprint:"mutated"`
// If true, generate the signature file of APK Signing Scheme V4, along side the signed APK file.
// Defaults to false.
V4_signature *bool
}
// Functionality common to Module and Import
Improve tracking of exported sdk libraries The build tracks the java_sdk_library/_import modules that are referenced by libraries so that it can ensure that any Android app that includes code that depends on one of those modules has the appropriate <uses-library> entry in their manifest. Unfortunately, there were a couple of issues with that: 1) It only tracks direct references to the java_sdk_library module itself, e.g. android.test.mock. Direct references to the stubs module, e.g. android.test.mock.stubs were not tracked. Making it possible for Android apps to reference libraries which would not be available at runtime. 2) The logic for determining whether something was a java_sdk_library was repeated in a number of places making it difficult to allow java_sdk_library/_import instances to determine whether they should be treated as an Android shared library. 3) It tracks (and could use) even those java_sdk_library instances which do not represent a shared library, e.g. the ones that set api_only: true. While this change will simplifty fixing that the actual issue will be fixed in a follow up change. Changes: * Added EmbeddableSdkLibraryComponent and embedded it into java_sdk_library/_import, java_library and java_import. It provides the common code to minimize duplication. It contains an SdkLibraryToImplicitlyTrack field that if set will cause any references to the containing module to add the SdkLibraryParent to the list of implicit sdk libraries being tracked. * Changed code that assumed that anything that implemented SdkLibraryDependency required tracking to use the OptionalImplicitSdkLibrary() method to get the optional name of the sdk library to track. That will allow a follow up change to return nil from that method to exclude an sdk library from being tracked. * Moved SdkLibraryDependency from java.go to sdk_library.go as that is a better place for it to be. * Changed the stubs java_library/java_import creation code to initialize the SdkLibraryToImplicitlyTrack field with the name of the creating module. * Initialized the SdkLibraryToImplicitlyTrack field in the java_sdk_library/_import so that direct references to them will be tracked too. * Added tests to verify that direct access to the .stubs child of both java_sdk_library and java_sdk_library_import are tracked properly. Test: atest CtsProviderTestCases - which relies on android.test.mock being implicitly tracked to verify that I had not broken anything. Used aapt2 dump badging to read the manifest. m nothing - to run the new tests which failed before fixing the code. Bug: 156723295 Change-Id: Ia99def91e9b74d2ed0a777de04b476c00ea0393d
2020-05-15 17:20:31 +08:00
//
// It is embedded in Module so its functionality can be used by methods in Module
// but it is currently only initialized by Import and Library.
type embeddableInModuleAndImport struct {
Improve tracking of exported sdk libraries The build tracks the java_sdk_library/_import modules that are referenced by libraries so that it can ensure that any Android app that includes code that depends on one of those modules has the appropriate <uses-library> entry in their manifest. Unfortunately, there were a couple of issues with that: 1) It only tracks direct references to the java_sdk_library module itself, e.g. android.test.mock. Direct references to the stubs module, e.g. android.test.mock.stubs were not tracked. Making it possible for Android apps to reference libraries which would not be available at runtime. 2) The logic for determining whether something was a java_sdk_library was repeated in a number of places making it difficult to allow java_sdk_library/_import instances to determine whether they should be treated as an Android shared library. 3) It tracks (and could use) even those java_sdk_library instances which do not represent a shared library, e.g. the ones that set api_only: true. While this change will simplifty fixing that the actual issue will be fixed in a follow up change. Changes: * Added EmbeddableSdkLibraryComponent and embedded it into java_sdk_library/_import, java_library and java_import. It provides the common code to minimize duplication. It contains an SdkLibraryToImplicitlyTrack field that if set will cause any references to the containing module to add the SdkLibraryParent to the list of implicit sdk libraries being tracked. * Changed code that assumed that anything that implemented SdkLibraryDependency required tracking to use the OptionalImplicitSdkLibrary() method to get the optional name of the sdk library to track. That will allow a follow up change to return nil from that method to exclude an sdk library from being tracked. * Moved SdkLibraryDependency from java.go to sdk_library.go as that is a better place for it to be. * Changed the stubs java_library/java_import creation code to initialize the SdkLibraryToImplicitlyTrack field with the name of the creating module. * Initialized the SdkLibraryToImplicitlyTrack field in the java_sdk_library/_import so that direct references to them will be tracked too. * Added tests to verify that direct access to the .stubs child of both java_sdk_library and java_sdk_library_import are tracked properly. Test: atest CtsProviderTestCases - which relies on android.test.mock being implicitly tracked to verify that I had not broken anything. Used aapt2 dump badging to read the manifest. m nothing - to run the new tests which failed before fixing the code. Bug: 156723295 Change-Id: Ia99def91e9b74d2ed0a777de04b476c00ea0393d
2020-05-15 17:20:31 +08:00
// Functionality related to this being used as a component of a java_sdk_library.
EmbeddableSdkLibraryComponent
}
func (e *embeddableInModuleAndImport) initModuleAndImport(moduleBase *android.ModuleBase) {
e.initSdkLibraryComponent(moduleBase)
}
// Module/Import's DepIsInSameApex(...) delegates to this method.
//
// This cannot implement DepIsInSameApex(...) directly as that leads to ambiguity with
// the one provided by ApexModuleBase.
func (e *embeddableInModuleAndImport) depIsInSameApex(ctx android.BaseModuleContext, dep android.Module) bool {
// dependencies other than the static linkage are all considered crossing APEX boundary
if staticLibTag == ctx.OtherModuleDependencyTag(dep) {
return true
}
return false
}
// Module contains the properties and members used by all java module types
type Module struct {
android.ModuleBase
android.DefaultableModuleBase
android.ApexModuleBase
android.SdkBase
// Functionality common to Module and Import.
embeddableInModuleAndImport
properties CompilerProperties
protoProperties android.ProtoProperties
deviceProperties CompilerDeviceProperties
// jar file containing header classes including static library dependencies, suitable for
// inserting into the bootclasspath/classpath of another compile
headerJarFile android.Path
// jar file containing implementation classes including static library dependencies but no
// resources
implementationJarFile android.Path
// jar file containing only resources including from static library dependencies
resourceJar android.Path
// args and dependencies to package source files into a srcjar
srcJarArgs []string
srcJarDeps android.Paths
// jar file containing implementation classes and resources including static library
// dependencies
implementationAndResourcesJar android.Path
// output file containing classes.dex and resources
dexJarFile android.Path
// output file that contains classes.dex if it should be in the output file
maybeStrippedDexJarFile android.Path
// output file containing uninstrumented classes that will be instrumented by jacoco
jacocoReportClassesFile android.Path
// output file of the module, which may be a classes jar or a dex jar
outputFile android.Path
extraOutputFiles android.Paths
exportAidlIncludeDirs android.Paths
logtagsSrcs android.Paths
// installed file for binary dependency
installFile android.Path
// list of .java files and srcjars that was passed to javac
compiledJavaSrcs android.Paths
compiledSrcJars android.Paths
// manifest file to use instead of properties.Manifest
overrideManifest android.OptionalPath
// map of SDK version to class loader context
classLoaderContexts dexpreopt.ClassLoaderContextMap
// list of plugins that this java module is exporting
exportedPluginJars android.Paths
// list of plugins that this java module is exporting
exportedPluginClasses []string
// if true, the exported plugins generate API and require disabling turbine.
exportedDisableTurbine bool
// list of source files, collected from srcFiles with unique java and all kt files,
// will be used by android.IDEInfo struct
expandIDEInfoCompiledSrcs []string
// expanded Jarjar_rules
expandJarjarRules android.Path
// list of additional targets for checkbuild
additionalCheckedModules android.Paths
// Extra files generated by the module type to be added as java resources.
extraResources android.Paths
hiddenAPI
dexer
dexpreopter
usesLibrary
linter
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 08:49:08 +08:00
// list of the xref extraction files
kytheFiles android.Paths
// Collect the module directory for IDE info in java/jdeps.go.
modulePaths []string
hideApexVariantFromMake bool
}
func (j *Module) addHostProperties() {
j.AddProperties(
&j.properties,
&j.protoProperties,
&j.usesLibraryProperties,
)
}
func (j *Module) addHostAndDeviceProperties() {
j.addHostProperties()
j.AddProperties(
&j.deviceProperties,
&j.dexer.dexProperties,
&j.dexpreoptProperties,
&j.linter.properties,
)
}
func (j *Module) OutputFiles(tag string) (android.Paths, error) {
switch tag {
case "":
return append(android.Paths{j.outputFile}, j.extraOutputFiles...), nil
Differentiate between no dist tag and an empty dist tag Change https://r.android.com/1335521 added tag property to the Dist struct so that it could be used to select one of a number of different output files to copy to the dist instead of the single file that the module type made available for dist. The output files were selected by passing the tag to OutputFiles(tag). Module types that wanted to support this new approach had to explicitly set AndroidMkEntries.DistFiles = GenerateTaggedDistFiles(module). Unfortunately, doing that had a side effect of changing the behavior of dist entries without a tag. That was because the change treated a tag that was not specified, as being the same as "". So, prior to the change no tag meant use the default dist file but after it meant use the paths returned by OutputFiles(""). That changed the behavior of the java.Library type which affected the behavior of the android_app module type. Prior to the change the java_library would make the Library.outputFile available for dist when no tag was specified. After that change it would make Library.outputFile plus Library.extraOutputFiles. The latter is usually empty except for android_app which adds some extra files into there which will now be copied to the dist. That change may have been intentional but there was no mention of it in the change or the bug. Even if it wasn't intentional it may still be beneficial. Any module type that wants to add support for tags in dist runs the risk of introducing similar changes in behavior. This change differentiates between the tag not being set and the tag being set to "" to avoid that possibility and to make the default behavior explicit for those module types that have switched. It does so as follows: * Adds a DefaultDistTag constant that is used when the tag is not set. It is a string that is unlikely to be used as an actual tag as it does not start with a . and uses some special characters. * The DefaultDistTag is used in MakeDefaultDistFiles(paths) to indicate that the supplied paths are the default ones and and also in GenerateTaggedDistFiles() for Dist structures that have no tag property set. * The DefaultDistTag is passed to OutputFiles(tag) just in case the module type has explicitly defined the paths to associate with that tag in there. If it has then it overrides the legacy behavior. If it has not then it is just ignored and falls back to using the previous behavior. * The java.Library.OutputFiles(tag) method explicitly handles the DefaultDistTag and returns Library.outputFile for it which restores the behavior from before the change that added dist.tag support. * Similar change was made to apexBundle.OutputFiles(tag) in order to preserve its previous behaviour. * The customModule used by TestGetDistContributions has been modified to also preserve its previous behavior after this change. Test: m nothing m dist sdk - before and after this change, compare result to make sure that there are no significant differences. Test the effect on the apex by following instructions in http://b/172951145 Bug: 174226317 Change-Id: Ib8f0d9307751cc2ed34e3d9a5538d3c144666f6d
2020-11-26 00:37:46 +08:00
case android.DefaultDistTag:
return android.Paths{j.outputFile}, nil
case ".jar":
return android.Paths{j.implementationAndResourcesJar}, nil
case ".proguard_map":
if j.dexer.proguardDictionary.Valid() {
return android.Paths{j.dexer.proguardDictionary.Path()}, nil
}
return nil, fmt.Errorf("%q was requested, but no output file was found.", tag)
default:
return nil, fmt.Errorf("unsupported module reference tag %q", tag)
}
}
var _ android.OutputFileProducer = (*Module)(nil)
// Methods that need to be implemented for a module that is added to apex java_libs property.
type ApexDependency interface {
HeaderJars() android.Paths
ImplementationAndResourcesJars() android.Paths
}
// Provides build path and install path to DEX jars.
type UsesLibraryDependency interface {
DexJarBuildPath() android.Path
DexJarInstallPath() android.Path
ClassLoaderContexts() dexpreopt.ClassLoaderContextMap
}
type Dependency interface {
ApexDependency
UsesLibraryDependency
ImplementationJars() android.Paths
ResourceJars() android.Paths
AidlIncludeDirs() android.Paths
ExportedPlugins() (android.Paths, []string, bool)
SrcJarArgs() ([]string, android.Paths)
BaseModuleName() string
JacocoReportClassesFile() android.Path
}
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 08:49:08 +08:00
type xref interface {
XrefJavaFiles() android.Paths
}
func (j *Module) XrefJavaFiles() android.Paths {
return j.kytheFiles
}
func InitJavaModule(module android.DefaultableModule, hod android.HostOrDeviceSupported) {
initJavaModule(module, hod, false)
}
func InitJavaModuleMultiTargets(module android.DefaultableModule, hod android.HostOrDeviceSupported) {
initJavaModule(module, hod, true)
}
func initJavaModule(module android.DefaultableModule, hod android.HostOrDeviceSupported, multiTargets bool) {
multilib := android.MultilibCommon
if multiTargets {
android.InitAndroidMultiTargetsArchModule(module, hod, multilib)
} else {
android.InitAndroidArchModule(module, hod, multilib)
}
android.InitDefaultableModule(module)
}
type dependencyTag struct {
blueprint.BaseDependencyTag
name string
}
// installDependencyTag is a dependency tag that is annotated to cause the installed files of the
// dependency to be installed when the parent module is installed.
type installDependencyTag struct {
blueprint.BaseDependencyTag
android.InstallAlwaysNeededDependencyTag
name string
}
type usesLibraryDependencyTag struct {
dependencyTag
sdkVersion int // SDK version in which the library appared as a standalone library.
}
func makeUsesLibraryDependencyTag(sdkVersion int) usesLibraryDependencyTag {
return usesLibraryDependencyTag{
dependencyTag: dependencyTag{name: fmt.Sprintf("uses-library-%d", sdkVersion)},
sdkVersion: sdkVersion,
}
}
func IsJniDepTag(depTag blueprint.DependencyTag) bool {
return depTag == jniLibTag
}
var (
dataNativeBinsTag = dependencyTag{name: "dataNativeBins"}
staticLibTag = dependencyTag{name: "staticlib"}
libTag = dependencyTag{name: "javalib"}
java9LibTag = dependencyTag{name: "java9lib"}
pluginTag = dependencyTag{name: "plugin"}
errorpronePluginTag = dependencyTag{name: "errorprone-plugin"}
exportedPluginTag = dependencyTag{name: "exported-plugin"}
bootClasspathTag = dependencyTag{name: "bootclasspath"}
systemModulesTag = dependencyTag{name: "system modules"}
frameworkResTag = dependencyTag{name: "framework-res"}
kotlinStdlibTag = dependencyTag{name: "kotlin-stdlib"}
kotlinAnnotationsTag = dependencyTag{name: "kotlin-annotations"}
proguardRaiseTag = dependencyTag{name: "proguard-raise"}
certificateTag = dependencyTag{name: "certificate"}
instrumentationForTag = dependencyTag{name: "instrumentation_for"}
extraLintCheckTag = dependencyTag{name: "extra-lint-check"}
jniLibTag = dependencyTag{name: "jnilib"}
jniInstallTag = installDependencyTag{name: "jni install"}
binaryInstallTag = installDependencyTag{name: "binary install"}
usesLibTag = makeUsesLibraryDependencyTag(dexpreopt.AnySdkVersion)
usesLibCompat28Tag = makeUsesLibraryDependencyTag(28)
usesLibCompat29Tag = makeUsesLibraryDependencyTag(29)
usesLibCompat30Tag = makeUsesLibraryDependencyTag(30)
)
func IsLibDepTag(depTag blueprint.DependencyTag) bool {
return depTag == libTag
}
func IsStaticLibDepTag(depTag blueprint.DependencyTag) bool {
return depTag == staticLibTag
}
type sdkDep struct {
useModule, useFiles, invalidVersion bool
// The modules that will be added to the bootclasspath when targeting 1.8 or lower
bootclasspath []string
// The default system modules to use. Will be an empty string if no system
// modules are to be used.
systemModules string
// The modules that will be added to the classpath regardless of the Java language level targeted
classpath []string
// The modules that will be added ot the classpath when targeting 1.9 or higher
// (normally these will be on the bootclasspath when targeting 1.8 or lower)
java9Classpath []string
frameworkResModule string
jars android.Paths
aidl android.OptionalPath
Make sdkDep/decodeSdkDep the source of truth about the sdk Previously, different parts of the build used different sources of information about the SDK (i.e. the default libraries) against which a Java module aimed at the device was built. Some used the sdk_version property, others used the no_standard_libs or no_framework_libs, some used a combination of all three. That lead to inconsistent handling in the code, e.g. some parts treated no_standard_libs: true as implying no_framework_libs: true and others did not, and also in the build files, e.g. some modules specified no_framework_libs: true and sdk_version: "system_current" which makes no sense, or no_standard_libs: true and sdk_version: "core_current" which are inconsistent. This is the first step in a refactoring to simplify the sdk selection process by replacing the no_standard_libs/no_framework_libs properties with some extra options for the sdk_version property. This change consists of: 1) Extra functions sdkContext to access the no_standard_libs and no_framework_libs properties. 2) Extra field/functions in sdkDep to store and access the value of no_standard_libs/no_framework_libs. 3) Changes to decodeSdkDep(...) to pass the values of the no_... properties through to the returned sdkDep. 4) Change all code that accesses the no_... properties directly to call decodeSdkDep(...) to get an sdkDep object and then accessing the values of the no_... properties from there. The accessor functions on sdkDep are called has...() rather than no...() as most callers of the methods invert the value anyway and !no...() is harder to reason about than has...(). The hasFrameworkLibs() function returns true if and only if no_standard_libs and no_framework_libs are false. That is consistent with all but one usage of the no_framework_libs property and that is not affected by it. Bug: 134566750 Test: m droid Change-Id: I196e3304e8bd802fb154e897397b0dd337f868e2 Exempt-From-Owner-Approval: Colin has already given +2 modulo some minor nits and this blocking other changes.
2019-06-07 17:44:37 +08:00
noStandardLibs, noFrameworksLibs bool
}
func (s sdkDep) hasStandardLibs() bool {
return !s.noStandardLibs
}
func (s sdkDep) hasFrameworkLibs() bool {
return !s.noStandardLibs && !s.noFrameworksLibs
}
type jniLib struct {
name string
path android.Path
target android.Target
coverageFile android.OptionalPath
unstrippedFile android.Path
}
func (j *Module) shouldInstrument(ctx android.BaseModuleContext) bool {
return j.properties.Instrument &&
ctx.Config().IsEnvTrue("EMMA_INSTRUMENT") &&
ctx.DeviceConfig().JavaCoverageEnabledForPath(ctx.ModuleDir())
}
func (j *Module) shouldInstrumentStatic(ctx android.BaseModuleContext) bool {
return j.shouldInstrument(ctx) &&
(ctx.Config().IsEnvTrue("EMMA_INSTRUMENT_STATIC") ||
ctx.Config().UnbundledBuild())
}
func (j *Module) shouldInstrumentInApex(ctx android.BaseModuleContext) bool {
// Force enable the instrumentation for java code that is built for APEXes ...
// except for the jacocoagent itself (because instrumenting jacocoagent using jacocoagent
// doesn't make sense) or framework libraries (e.g. libraries found in the InstrumentFrameworkModules list) unless EMMA_INSTRUMENT_FRAMEWORK is true.
apexInfo := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)
isJacocoAgent := ctx.ModuleName() == "jacocoagent"
if j.DirectlyInAnyApex() && !isJacocoAgent && !apexInfo.IsForPlatform() {
if !inList(ctx.ModuleName(), config.InstrumentFrameworkModules) {
return true
} else if ctx.Config().IsEnvTrue("EMMA_INSTRUMENT_FRAMEWORK") {
return true
}
}
return false
}
func (j *Module) sdkVersion() sdkSpec {
return sdkSpecFrom(String(j.deviceProperties.Sdk_version))
}
func (j *Module) systemModules() string {
return proptools.String(j.deviceProperties.System_modules)
}
func (j *Module) minSdkVersion() sdkSpec {
if j.deviceProperties.Min_sdk_version != nil {
return sdkSpecFrom(*j.deviceProperties.Min_sdk_version)
}
return j.sdkVersion()
}
func (j *Module) targetSdkVersion() sdkSpec {
if j.deviceProperties.Target_sdk_version != nil {
return sdkSpecFrom(*j.deviceProperties.Target_sdk_version)
}
return j.sdkVersion()
}
func (j *Module) MinSdkVersion() string {
return j.minSdkVersion().version.String()
}
func (j *Module) AvailableFor(what string) bool {
if what == android.AvailableToPlatform && Bool(j.deviceProperties.Hostdex) {
// Exception: for hostdex: true libraries, the platform variant is created
// even if it's not marked as available to platform. In that case, the platform
// variant is used only for the hostdex and not installed to the device.
return true
}
return j.ApexModuleBase.AvailableFor(what)
}
func sdkDeps(ctx android.BottomUpMutatorContext, sdkContext sdkContext, d dexer) {
sdkDep := decodeSdkDep(ctx, sdkContext)
if sdkDep.useModule {
ctx.AddVariationDependencies(nil, bootClasspathTag, sdkDep.bootclasspath...)
ctx.AddVariationDependencies(nil, java9LibTag, sdkDep.java9Classpath...)
ctx.AddVariationDependencies(nil, libTag, sdkDep.classpath...)
if d.effectiveOptimizeEnabled() && sdkDep.hasStandardLibs() {
ctx.AddVariationDependencies(nil, proguardRaiseTag, config.LegacyCorePlatformBootclasspathLibraries...)
}
if d.effectiveOptimizeEnabled() && sdkDep.hasFrameworkLibs() {
ctx.AddVariationDependencies(nil, proguardRaiseTag, config.FrameworkLibraries...)
}
}
if sdkDep.systemModules != "" {
ctx.AddVariationDependencies(nil, systemModulesTag, sdkDep.systemModules)
}
}
func (j *Module) deps(ctx android.BottomUpMutatorContext) {
if ctx.Device() {
j.linter.deps(ctx)
sdkDeps(ctx, sdkContext(j), j.dexer)
}
syspropPublicStubs := syspropPublicStubs(ctx.Config())
// rewriteSyspropLibs validates if a java module can link against platform's sysprop_library,
// and redirects dependency to public stub depending on the link type.
rewriteSyspropLibs := func(libs []string, prop string) []string {
// make a copy
ret := android.CopyOf(libs)
for idx, lib := range libs {
stub, ok := syspropPublicStubs[lib]
if !ok {
continue
}
linkType, _ := j.getLinkType(ctx.ModuleName())
// only platform modules can use internal props
if linkType != javaPlatform {
ret[idx] = stub
}
}
return ret
}
libDeps := ctx.AddVariationDependencies(nil, libTag, rewriteSyspropLibs(j.properties.Libs, "libs")...)
ctx.AddVariationDependencies(nil, staticLibTag, rewriteSyspropLibs(j.properties.Static_libs, "static_libs")...)
if ctx.DeviceConfig().VndkVersion() != "" && ctx.Config().EnforceInterPartitionJavaSdkLibrary() {
// Require java_sdk_library at inter-partition java dependency to ensure stable
// interface between partitions. If inter-partition java_library dependency is detected,
// raise build error because java_library doesn't have a stable interface.
//
// Inputs:
// PRODUCT_ENFORCE_INTER_PARTITION_JAVA_SDK_LIBRARY
// if true, enable enforcement
// PRODUCT_INTER_PARTITION_JAVA_LIBRARY_ALLOWLIST
// exception list of java_library names to allow inter-partition dependency
for idx, lib := range j.properties.Libs {
if libDeps[idx] == nil {
continue
}
if _, ok := syspropPublicStubs[lib]; ok {
continue
}
if javaDep, ok := libDeps[idx].(javaSdkLibraryEnforceContext); ok {
// java_sdk_library is always allowed at inter-partition dependency.
// So, skip check.
if _, ok := javaDep.(*SdkLibrary); ok {
continue
}
j.checkPartitionsForJavaDependency(ctx, "libs", javaDep)
}
}
}
// For library dependencies that are component libraries (like stubs), add the implementation
// as a dependency (dexpreopt needs to be against the implementation library, not stubs).
for _, dep := range libDeps {
if dep != nil {
if component, ok := dep.(SdkLibraryComponentDependency); ok {
if lib := component.OptionalSdkLibraryImplementation(); lib != nil {
ctx.AddVariationDependencies(nil, usesLibTag, *lib)
}
}
}
}
ctx.AddFarVariationDependencies(ctx.Config().BuildOSCommonTarget.Variations(), pluginTag, j.properties.Plugins...)
ctx.AddFarVariationDependencies(ctx.Config().BuildOSCommonTarget.Variations(), errorpronePluginTag, j.properties.Errorprone.Extra_check_modules...)
ctx.AddFarVariationDependencies(ctx.Config().BuildOSCommonTarget.Variations(), exportedPluginTag, j.properties.Exported_plugins...)
android.ProtoDeps(ctx, &j.protoProperties)
if j.hasSrcExt(".proto") {
protoDeps(ctx, &j.protoProperties)
}
if j.hasSrcExt(".kt") {
// TODO(ccross): move this to a mutator pass that can tell if generated sources contain
// Kotlin files
ctx.AddVariationDependencies(nil, kotlinStdlibTag,
"kotlin-stdlib", "kotlin-stdlib-jdk7", "kotlin-stdlib-jdk8")
if len(j.properties.Plugins) > 0 {
ctx.AddVariationDependencies(nil, kotlinAnnotationsTag, "kotlin-annotations")
}
}
Do not add jacocoagent to framework libraries in static coverage builds. Framework libraries need special handling in static coverage builds: they should not have static dependency on jacoco, otherwise there would be multiple conflicting definitions of the same jacoco classes coming from different bootclasspath jars. This CL does two things: - Move the code that enables instrumentation of framework libraries from AndroidGenerateBuildActions phase to the earlier DepsMutator phase. This is necessary because DepsMutator phase already does some things that depend on the instrumentation flag. - Explicitely exclude framework libraries from those libraries which have static dependency on jacoco. This CL does not fix any apparent build problems: prior to it the framework libraries were not excluded properly, but this was masked by wrong order of checking / setting instrumentation flag. Note that static coverage builds without framework coverage fail to boot, namely this build command: $ build/soong/soong_ui.bash --make-mode \ SKIP_ABI_CHECKS=true \ TARGET_PRODUCT=aosp_walleye TARGET_BUILD_VARIANT=userdebug droid \ EMMA_INSTRUMENT=true \ EMMA_INSTRUMENT_STATIC=true \ NATIVE_COVERAGE=true ..causes the following boot-time errors in logcat: 01-08 12:31:48.670 1252 1252 E System : java.lang.StackOverflowError: stack size 8192KB 01-08 12:31:48.670 1252 1252 E System : at org.jacoco.agent.rt.internal.Offline.$jacocoInit(Unknown Source:13) 01-08 12:31:48.670 1252 1252 E System : at org.jacoco.agent.rt.internal.Offline.getProbes(Unknown Source:0) Also note that static coverage with framework coverage failed to build prior to CL Iaa198b8505aaff36e6685559642ff721637ce55f (dex2oat failed to create boot image due to missing classes). Test: non-static coverage without framework coverage boots: $ build/soong/soong_ui.bash --make-mode \ SKIP_ABI_CHECKS=true \ TARGET_PRODUCT=aosp_walleye TARGET_BUILD_VARIANT=userdebug droid \ EMMA_INSTRUMENT=true \ NATIVE_COVERAGE=true Test: non-static coverage with framework coverage boots: $ build/soong/soong_ui.bash --make-mode \ SKIP_ABI_CHECKS=true \ TARGET_PRODUCT=aosp_walleye TARGET_BUILD_VARIANT=userdebug droid \ EMMA_INSTRUMENT=true \ EMMA_INSTRUMENT_FRAMEWORK=true \ NATIVE_COVERAGE=true Test: static coverage with framework coverage boots: $ build/soong/soong_ui.bash --make-mode \ SKIP_ABI_CHECKS=true \ TARGET_PRODUCT=aosp_walleye TARGET_BUILD_VARIANT=userdebug droid \ EMMA_INSTRUMENT=true \ EMMA_INSTRUMENT_FRAMEWORK=true \ EMMA_INSTRUMENT_STATIC=true \ NATIVE_COVERAGE=true Change-Id: I700f979a5d638ce632f5e8b920b9d0adb3c80248
2020-01-08 00:37:02 +08:00
// Framework libraries need special handling in static coverage builds: they should not have
// static dependency on jacoco, otherwise there would be multiple conflicting definitions of
// the same jacoco classes coming from different bootclasspath jars.
if inList(ctx.ModuleName(), config.InstrumentFrameworkModules) {
if ctx.Config().IsEnvTrue("EMMA_INSTRUMENT_FRAMEWORK") {
j.properties.Instrument = true
}
} else if j.shouldInstrumentStatic(ctx) {
ctx.AddVariationDependencies(nil, staticLibTag, "jacocoagent")
}
}
func hasSrcExt(srcs []string, ext string) bool {
for _, src := range srcs {
if filepath.Ext(src) == ext {
return true
}
}
return false
}
func (j *Module) hasSrcExt(ext string) bool {
return hasSrcExt(j.properties.Srcs, ext)
}
func (j *Module) aidlFlags(ctx android.ModuleContext, aidlPreprocess android.OptionalPath,
aidlIncludeDirs android.Paths) (string, android.Paths) {
aidlIncludes := android.PathsForModuleSrc(ctx, j.deviceProperties.Aidl.Local_include_dirs)
aidlIncludes = append(aidlIncludes,
android.PathsForModuleSrc(ctx, j.deviceProperties.Aidl.Export_include_dirs)...)
aidlIncludes = append(aidlIncludes,
android.PathsForSource(ctx, j.deviceProperties.Aidl.Include_dirs)...)
var flags []string
var deps android.Paths
flags = append(flags, j.deviceProperties.Aidl.Flags...)
if aidlPreprocess.Valid() {
flags = append(flags, "-p"+aidlPreprocess.String())
deps = append(deps, aidlPreprocess.Path())
} else if len(aidlIncludeDirs) > 0 {
flags = append(flags, android.JoinWithPrefix(aidlIncludeDirs.Strings(), "-I"))
}
if len(j.exportAidlIncludeDirs) > 0 {
flags = append(flags, android.JoinWithPrefix(j.exportAidlIncludeDirs.Strings(), "-I"))
}
if len(aidlIncludes) > 0 {
flags = append(flags, android.JoinWithPrefix(aidlIncludes.Strings(), "-I"))
}
flags = append(flags, "-I"+android.PathForModuleSrc(ctx).String())
if src := android.ExistentPathForSource(ctx, ctx.ModuleDir(), "src"); src.Valid() {
flags = append(flags, "-I"+src.String())
}
if Bool(j.deviceProperties.Aidl.Generate_traces) {
flags = append(flags, "-t")
}
if Bool(j.deviceProperties.Aidl.Generate_get_transaction_name) {
flags = append(flags, "--transaction_names")
}
return strings.Join(flags, " "), deps
}
type deps struct {
classpath classpath
java9Classpath classpath
bootClasspath classpath
processorPath classpath
errorProneProcessorPath classpath
processorClasses []string
staticJars android.Paths
staticHeaderJars android.Paths
staticResourceJars android.Paths
aidlIncludeDirs android.Paths
srcs android.Paths
srcJars android.Paths
systemModules *systemModules
aidlPreprocess android.OptionalPath
kotlinStdlib android.Paths
kotlinAnnotations android.Paths
disableTurbine bool
}
func checkProducesJars(ctx android.ModuleContext, dep android.SourceFileProducer) {
for _, f := range dep.Srcs() {
if f.Ext() != ".jar" {
ctx.ModuleErrorf("genrule %q must generate files ending with .jar to be used as a libs or static_libs dependency",
ctx.OtherModuleName(dep.(blueprint.Module)))
}
}
}
type linkType int
const (
// TODO(jiyong) rename these for better readability. Make the allowed
// and disallowed link types explicit
javaCore linkType = iota
javaSdk
javaSystem
javaModule
javaSystemServer
javaPlatform
)
type linkTypeContext interface {
android.Module
getLinkType(name string) (ret linkType, stubs bool)
}
func (m *Module) getLinkType(name string) (ret linkType, stubs bool) {
switch name {
case "core.current.stubs", "legacy.core.platform.api.stubs", "stable.core.platform.api.stubs",
"stub-annotations", "private-stub-annotations-jar",
"core-lambda-stubs", "core-generated-annotation-stubs":
return javaCore, true
case "android_stubs_current":
return javaSdk, true
case "android_system_stubs_current":
return javaSystem, true
case "android_module_lib_stubs_current":
return javaModule, true
case "android_system_server_stubs_current":
return javaSystemServer, true
case "android_test_stubs_current":
return javaSystem, true
}
if stub, linkType := moduleStubLinkType(name); stub {
return linkType, true
}
ver := m.sdkVersion()
switch ver.kind {
case sdkCore:
return javaCore, false
case sdkSystem:
return javaSystem, false
case sdkPublic:
return javaSdk, false
case sdkModule:
return javaModule, false
case sdkSystemServer:
return javaSystemServer, false
case sdkPrivate, sdkNone, sdkCorePlatform, sdkTest:
return javaPlatform, false
}
if !ver.valid() {
panic(fmt.Errorf("sdk_version is invalid. got %q", ver.raw))
}
return javaSdk, false
}
func checkLinkType(ctx android.ModuleContext, from *Module, to linkTypeContext, tag dependencyTag) {
if ctx.Host() {
return
}
myLinkType, stubs := from.getLinkType(ctx.ModuleName())
if stubs {
return
}
otherLinkType, _ := to.getLinkType(ctx.OtherModuleName(to))
commonMessage := " In order to fix this, consider adjusting sdk_version: OR platform_apis: " +
"property of the source or target module so that target module is built with the same " +
"or smaller API set when compared to the source."
switch myLinkType {
case javaCore:
if otherLinkType != javaCore {
ctx.ModuleErrorf("compiles against core Java API, but dependency %q is compiling against non-core Java APIs."+commonMessage,
ctx.OtherModuleName(to))
}
break
case javaSdk:
if otherLinkType != javaCore && otherLinkType != javaSdk {
ctx.ModuleErrorf("compiles against Android API, but dependency %q is compiling against non-public Android API."+commonMessage,
ctx.OtherModuleName(to))
}
break
case javaSystem:
if otherLinkType == javaPlatform || otherLinkType == javaModule || otherLinkType == javaSystemServer {
ctx.ModuleErrorf("compiles against system API, but dependency %q is compiling against private API."+commonMessage,
ctx.OtherModuleName(to))
}
break
case javaModule:
if otherLinkType == javaPlatform || otherLinkType == javaSystemServer {
ctx.ModuleErrorf("compiles against module API, but dependency %q is compiling against private API."+commonMessage,
ctx.OtherModuleName(to))
}
break
case javaSystemServer:
if otherLinkType == javaPlatform {
ctx.ModuleErrorf("compiles against system server API, but dependency %q is compiling against private API."+commonMessage,
ctx.OtherModuleName(to))
}
break
case javaPlatform:
// no restriction on link-type
break
}
}
func (j *Module) collectDeps(ctx android.ModuleContext) deps {
var deps deps
if ctx.Device() {
sdkDep := decodeSdkDep(ctx, sdkContext(j))
if sdkDep.invalidVersion {
ctx.AddMissingDependencies(sdkDep.bootclasspath)
ctx.AddMissingDependencies(sdkDep.java9Classpath)
} else if sdkDep.useFiles {
// sdkDep.jar is actually equivalent to turbine header.jar.
deps.classpath = append(deps.classpath, sdkDep.jars...)
deps.aidlPreprocess = sdkDep.aidl
} else {
deps.aidlPreprocess = sdkDep.aidl
}
}
ctx.VisitDirectDeps(func(module android.Module) {
otherName := ctx.OtherModuleName(module)
tag := ctx.OtherModuleDependencyTag(module)
if IsJniDepTag(tag) {
// Handled by AndroidApp.collectAppDeps
return
}
if tag == certificateTag {
// Handled by AndroidApp.collectAppDeps
return
}
switch dep := module.(type) {
case SdkLibraryDependency:
switch tag {
case libTag:
deps.classpath = append(deps.classpath, dep.SdkHeaderJars(ctx, j.sdkVersion())...)
case staticLibTag:
ctx.ModuleErrorf("dependency on java_sdk_library %q can only be in libs", otherName)
}
case Dependency:
switch tag {
case bootClasspathTag:
deps.bootClasspath = append(deps.bootClasspath, dep.HeaderJars()...)
case libTag, instrumentationForTag:
deps.classpath = append(deps.classpath, dep.HeaderJars()...)
deps.aidlIncludeDirs = append(deps.aidlIncludeDirs, dep.AidlIncludeDirs()...)
pluginJars, pluginClasses, disableTurbine := dep.ExportedPlugins()
addPlugins(&deps, pluginJars, pluginClasses...)
deps.disableTurbine = deps.disableTurbine || disableTurbine
case java9LibTag:
deps.java9Classpath = append(deps.java9Classpath, dep.HeaderJars()...)
case staticLibTag:
deps.classpath = append(deps.classpath, dep.HeaderJars()...)
deps.staticJars = append(deps.staticJars, dep.ImplementationJars()...)
deps.staticHeaderJars = append(deps.staticHeaderJars, dep.HeaderJars()...)
deps.staticResourceJars = append(deps.staticResourceJars, dep.ResourceJars()...)
deps.aidlIncludeDirs = append(deps.aidlIncludeDirs, dep.AidlIncludeDirs()...)
pluginJars, pluginClasses, disableTurbine := dep.ExportedPlugins()
addPlugins(&deps, pluginJars, pluginClasses...)
// Turbine doesn't run annotation processors, so any module that uses an
// annotation processor that generates API is incompatible with the turbine
// optimization.
deps.disableTurbine = deps.disableTurbine || disableTurbine
case pluginTag:
if plugin, ok := dep.(*Plugin); ok {
if plugin.pluginProperties.Processor_class != nil {
addPlugins(&deps, plugin.ImplementationAndResourcesJars(), *plugin.pluginProperties.Processor_class)
} else {
addPlugins(&deps, plugin.ImplementationAndResourcesJars())
}
// Turbine doesn't run annotation processors, so any module that uses an
// annotation processor that generates API is incompatible with the turbine
// optimization.
deps.disableTurbine = deps.disableTurbine || Bool(plugin.pluginProperties.Generates_api)
} else {
ctx.PropertyErrorf("plugins", "%q is not a java_plugin module", otherName)
}
case errorpronePluginTag:
if plugin, ok := dep.(*Plugin); ok {
deps.errorProneProcessorPath = append(deps.errorProneProcessorPath, plugin.ImplementationAndResourcesJars()...)
} else {
ctx.PropertyErrorf("plugins", "%q is not a java_plugin module", otherName)
}
case exportedPluginTag:
if plugin, ok := dep.(*Plugin); ok {
j.exportedPluginJars = append(j.exportedPluginJars, plugin.ImplementationAndResourcesJars()...)
if plugin.pluginProperties.Processor_class != nil {
j.exportedPluginClasses = append(j.exportedPluginClasses, *plugin.pluginProperties.Processor_class)
}
// Turbine doesn't run annotation processors, so any module that uses an
// annotation processor that generates API is incompatible with the turbine
// optimization.
j.exportedDisableTurbine = Bool(plugin.pluginProperties.Generates_api)
} else {
ctx.PropertyErrorf("exported_plugins", "%q is not a java_plugin module", otherName)
}
case kotlinStdlibTag:
deps.kotlinStdlib = append(deps.kotlinStdlib, dep.HeaderJars()...)
case kotlinAnnotationsTag:
deps.kotlinAnnotations = dep.HeaderJars()
}
case android.SourceFileProducer:
switch tag {
case libTag:
checkProducesJars(ctx, dep)
deps.classpath = append(deps.classpath, dep.Srcs()...)
case staticLibTag:
checkProducesJars(ctx, dep)
deps.classpath = append(deps.classpath, dep.Srcs()...)
deps.staticJars = append(deps.staticJars, dep.Srcs()...)
deps.staticHeaderJars = append(deps.staticHeaderJars, dep.Srcs()...)
}
default:
switch tag {
case bootClasspathTag:
// If a system modules dependency has been added to the bootclasspath
// then add its libs to the bootclasspath.
sm := module.(SystemModulesProvider)
deps.bootClasspath = append(deps.bootClasspath, sm.HeaderJars()...)
case systemModulesTag:
if deps.systemModules != nil {
panic("Found two system module dependencies")
}
sm := module.(SystemModulesProvider)
outputDir, outputDeps := sm.OutputDirAndDeps()
deps.systemModules = &systemModules{outputDir, outputDeps}
}
}
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
addCLCFromDep(ctx, module, j.classLoaderContexts)
})
return deps
}
func addPlugins(deps *deps, pluginJars android.Paths, pluginClasses ...string) {
deps.processorPath = append(deps.processorPath, pluginJars...)
deps.processorClasses = append(deps.processorClasses, pluginClasses...)
}
func getJavaVersion(ctx android.ModuleContext, javaVersion string, sdkContext sdkContext) javaVersion {
if javaVersion != "" {
return normalizeJavaVersion(ctx, javaVersion)
} else if ctx.Device() {
return sdkContext.sdkVersion().defaultJavaLanguageVersion(ctx)
} else {
return JAVA_VERSION_9
}
}
type javaVersion int
const (
JAVA_VERSION_UNSUPPORTED = 0
JAVA_VERSION_6 = 6
JAVA_VERSION_7 = 7
JAVA_VERSION_8 = 8
JAVA_VERSION_9 = 9
)
func (v javaVersion) String() string {
switch v {
case JAVA_VERSION_6:
return "1.6"
case JAVA_VERSION_7:
return "1.7"
case JAVA_VERSION_8:
return "1.8"
case JAVA_VERSION_9:
return "1.9"
default:
return "unsupported"
}
}
// Returns true if javac targeting this version uses system modules instead of a bootclasspath.
func (v javaVersion) usesJavaModules() bool {
return v >= 9
}
func normalizeJavaVersion(ctx android.BaseModuleContext, javaVersion string) javaVersion {
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
switch javaVersion {
case "1.6", "6":
return JAVA_VERSION_6
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
case "1.7", "7":
return JAVA_VERSION_7
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
case "1.8", "8":
return JAVA_VERSION_8
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
case "1.9", "9":
return JAVA_VERSION_9
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
case "10", "11":
ctx.PropertyErrorf("java_version", "Java language levels above 9 are not supported")
return JAVA_VERSION_UNSUPPORTED
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
default:
ctx.PropertyErrorf("java_version", "Unrecognized Java language level")
return JAVA_VERSION_UNSUPPORTED
Normalize and validate the java_version property. There are two parts to this change. Normalization: If a module specifies 'java_version: "9"', this is now normalized into 'java_version: "1.9"'. Users might reasonably assume that "9" should be valid, since javac treats them as synonyms (and, in fact, the javac documentation lists "9" as a valid value but doesn't mention "1.9"). However, the soong code that triggers JPMS support (i.e. setting -system rather than --boot-class-path) looks for the string "1.9", so prior to this change modules specifying "9" would fail with a confusing error ('javac: option --boot-class-path not allowed with target 1.9'). Normalizing "9" to "1.9" fixes this. (The change normalizes the other supported values, too, for consistency.) Validation: This change also makes the build fail-fast with a clear error message for invalid values. In particular, modules specifying "10" or "11" fail with an explicit message that this is not supported, in anticipation of the switch to OpenJDK 11. Prior to this change, modules setting those values would get the confusing '--boot-class-path not allowed' error described about since JPMS support would not be triggered. (That could be fixed by changing the JPMS logic to trigger on "10" and "11", but that would be dangerous since support in the rest of the system for v54 and v55 class files is unproven: it is better to fail explicitly.) (This change also makes it fail-fast for any unrecognized values.) Test: make java Test: make targets with java_version set to "1.8", "8", "1.9", and "9", all succeed ("9" fails without this change) Test: make targets with java_version set to "10" and "11", fail with the explicit "not supported" message Test: make target with java_version set to "xxx", fails fast with the "unrecognized" message Bug: 131683177 Change-Id: I2f5eb496c29d7736c68c01401c3f0967aeae99fc
2019-07-12 20:16:17 +08:00
}
}
func (j *Module) collectBuilderFlags(ctx android.ModuleContext, deps deps) javaBuilderFlags {
var flags javaBuilderFlags
2018-09-11 23:21:05 +08:00
// javaVersion flag.
flags.javaVersion = getJavaVersion(ctx, String(j.properties.Java_version), sdkContext(j))
if ctx.Config().RunErrorProne() {
if config.ErrorProneClasspath == nil && ctx.Config().TestProductVariables == nil {
ctx.ModuleErrorf("cannot build with Error Prone, missing external/error_prone?")
}
errorProneFlags := []string{
"-Xplugin:ErrorProne",
"${config.ErrorProneChecks}",
}
errorProneFlags = append(errorProneFlags, j.properties.Errorprone.Javacflags...)
flags.errorProneExtraJavacFlags = "${config.ErrorProneFlags} " +
"'" + strings.Join(errorProneFlags, " ") + "'"
flags.errorProneProcessorPath = classpath(android.PathsForSource(ctx, config.ErrorProneClasspath))
}
// classpath
flags.bootClasspath = append(flags.bootClasspath, deps.bootClasspath...)
flags.classpath = append(flags.classpath, deps.classpath...)
flags.java9Classpath = append(flags.java9Classpath, deps.java9Classpath...)
flags.processorPath = append(flags.processorPath, deps.processorPath...)
flags.errorProneProcessorPath = append(flags.errorProneProcessorPath, deps.errorProneProcessorPath...)
flags.processors = append(flags.processors, deps.processorClasses...)
flags.processors = android.FirstUniqueStrings(flags.processors)
if len(flags.bootClasspath) == 0 && ctx.Host() && !flags.javaVersion.usesJavaModules() &&
decodeSdkDep(ctx, sdkContext(j)).hasStandardLibs() {
// Give host-side tools a version of OpenJDK's standard libraries
// close to what they're targeting. As of Dec 2017, AOSP is only
// bundling OpenJDK 8 and 9, so nothing < 8 is available.
//
// When building with OpenJDK 8, the following should have no
// effect since those jars would be available by default.
//
// When building with OpenJDK 9 but targeting a version < 1.8,
// putting them on the bootclasspath means that:
// a) code can't (accidentally) refer to OpenJDK 9 specific APIs
// b) references to existing APIs are not reinterpreted in an
// OpenJDK 9-specific way, eg. calls to subclasses of
// java.nio.Buffer as in http://b/70862583
java8Home := ctx.Config().Getenv("ANDROID_JAVA8_HOME")
flags.bootClasspath = append(flags.bootClasspath,
android.PathForSource(ctx, java8Home, "jre/lib/jce.jar"),
android.PathForSource(ctx, java8Home, "jre/lib/rt.jar"))
if Bool(j.properties.Use_tools_jar) {
flags.bootClasspath = append(flags.bootClasspath,
android.PathForSource(ctx, java8Home, "lib/tools.jar"))
}
}
// systemModules
flags.systemModules = deps.systemModules
// aidl flags.
flags.aidlFlags, flags.aidlDeps = j.aidlFlags(ctx, deps.aidlPreprocess, deps.aidlIncludeDirs)
return flags
}
func (j *Module) collectJavacFlags(
ctx android.ModuleContext, flags javaBuilderFlags, srcFiles android.Paths) javaBuilderFlags {
// javac flags.
javacFlags := j.properties.Javacflags
if ctx.Config().MinimizeJavaDebugInfo() && !ctx.Host() {
// For non-host binaries, override the -g flag passed globally to remove
// local variable debug info to reduce disk and memory usage.
javacFlags = append(javacFlags, "-g:source,lines")
}
javacFlags = append(javacFlags, "-Xlint:-dep-ann")
if flags.javaVersion.usesJavaModules() {
javacFlags = append(javacFlags, j.properties.Openjdk9.Javacflags...)
if j.properties.Patch_module != nil {
// Manually specify build directory in case it is not under the repo root.
// (javac doesn't seem to expand into symbolic links when searching for patch-module targets, so
// just adding a symlink under the root doesn't help.)
patchPaths := []string{".", ctx.Config().BuildDir()}
// b/150878007
//
// Workaround to support *Bazel-executed* JDK9 javac in Bazel's
// execution root for --patch-module. If this javac command line is
// invoked within Bazel's execution root working directory, the top
// level directories (e.g. libcore/, tools/, frameworks/) are all
// symlinks. JDK9 javac does not traverse into symlinks, which causes
// --patch-module to fail source file lookups when invoked in the
// execution root.
//
// Short of patching javac or enumerating *all* directories as possible
// input dirs, manually add the top level dir of the source files to be
// compiled.
topLevelDirs := map[string]bool{}
for _, srcFilePath := range srcFiles {
srcFileParts := strings.Split(srcFilePath.String(), "/")
// Ignore source files that are already in the top level directory
// as well as generated files in the out directory. The out
// directory may be an absolute path, which means srcFileParts[0] is the
// empty string, so check that as well. Note that "out" in Bazel's execution
// root is *not* a symlink, which doesn't cause problems for --patch-modules
// anyway, so it's fine to not apply this workaround for generated
// source files.
if len(srcFileParts) > 1 &&
srcFileParts[0] != "" &&
srcFileParts[0] != "out" {
topLevelDirs[srcFileParts[0]] = true
}
}
patchPaths = append(patchPaths, android.SortedStringKeys(topLevelDirs)...)
classPath := flags.classpath.FormJavaClassPath("")
if classPath != "" {
patchPaths = append(patchPaths, classPath)
}
javacFlags = append(
javacFlags,
"--patch-module="+String(j.properties.Patch_module)+"="+strings.Join(patchPaths, ":"))
}
}
if len(javacFlags) > 0 {
// optimization.
ctx.Variable(pctx, "javacFlags", strings.Join(javacFlags, " "))
flags.javacFlags = "$javacFlags"
}
return flags
}
func (j *Module) compile(ctx android.ModuleContext, aaptSrcJar android.Path) {
j.exportAidlIncludeDirs = android.PathsForModuleSrc(ctx, j.deviceProperties.Aidl.Export_include_dirs)
deps := j.collectDeps(ctx)
flags := j.collectBuilderFlags(ctx, deps)
if flags.javaVersion.usesJavaModules() {
j.properties.Srcs = append(j.properties.Srcs, j.properties.Openjdk9.Srcs...)
}
srcFiles := android.PathsForModuleSrcExcludes(ctx, j.properties.Srcs, j.properties.Exclude_srcs)
if hasSrcExt(srcFiles.Strings(), ".proto") {
flags = protoFlags(ctx, &j.properties, &j.protoProperties, flags)
}
kotlinCommonSrcFiles := android.PathsForModuleSrcExcludes(ctx, j.properties.Common_srcs, nil)
if len(kotlinCommonSrcFiles.FilterOutByExt(".kt")) > 0 {
ctx.PropertyErrorf("common_srcs", "common_srcs must be .kt files")
}
srcFiles = j.genSources(ctx, srcFiles, flags)
// Collect javac flags only after computing the full set of srcFiles to
// ensure that the --patch-module lookup paths are complete.
flags = j.collectJavacFlags(ctx, flags, srcFiles)
srcJars := srcFiles.FilterByExt(".srcjar")
srcJars = append(srcJars, deps.srcJars...)
if aaptSrcJar != nil {
srcJars = append(srcJars, aaptSrcJar)
}
if j.properties.Jarjar_rules != nil {
j.expandJarjarRules = android.PathForModuleSrc(ctx, *j.properties.Jarjar_rules)
}
jarName := ctx.ModuleName() + ".jar"
javaSrcFiles := srcFiles.FilterByExt(".java")
var uniqueSrcFiles android.Paths
set := make(map[string]bool)
for _, v := range javaSrcFiles {
if _, found := set[v.String()]; !found {
set[v.String()] = true
uniqueSrcFiles = append(uniqueSrcFiles, v)
}
}
// Collect .java files for AIDEGen
j.expandIDEInfoCompiledSrcs = append(j.expandIDEInfoCompiledSrcs, uniqueSrcFiles.Strings()...)
var kotlinJars android.Paths
if srcFiles.HasExt(".kt") {
// user defined kotlin flags.
kotlincFlags := j.properties.Kotlincflags
CheckKotlincFlags(ctx, kotlincFlags)
// Dogfood the JVM_IR backend.
kotlincFlags = append(kotlincFlags, "-Xuse-ir")
// If there are kotlin files, compile them first but pass all the kotlin and java files
// kotlinc will use the java files to resolve types referenced by the kotlin files, but
// won't emit any classes for them.
kotlincFlags = append(kotlincFlags, "-no-stdlib")
if ctx.Device() {
kotlincFlags = append(kotlincFlags, "-no-jdk")
}
if len(kotlincFlags) > 0 {
// optimization.
ctx.Variable(pctx, "kotlincFlags", strings.Join(kotlincFlags, " "))
flags.kotlincFlags += "$kotlincFlags"
}
var kotlinSrcFiles android.Paths
kotlinSrcFiles = append(kotlinSrcFiles, uniqueSrcFiles...)
kotlinSrcFiles = append(kotlinSrcFiles, srcFiles.FilterByExt(".kt")...)
// Collect .kt files for AIDEGen
j.expandIDEInfoCompiledSrcs = append(j.expandIDEInfoCompiledSrcs, srcFiles.FilterByExt(".kt").Strings()...)
j.expandIDEInfoCompiledSrcs = append(j.expandIDEInfoCompiledSrcs, kotlinCommonSrcFiles.Strings()...)
flags.classpath = append(flags.classpath, deps.kotlinStdlib...)
flags.classpath = append(flags.classpath, deps.kotlinAnnotations...)
flags.kotlincClasspath = append(flags.kotlincClasspath, flags.bootClasspath...)
flags.kotlincClasspath = append(flags.kotlincClasspath, flags.classpath...)
if len(flags.processorPath) > 0 {
// Use kapt for annotation processing
kaptSrcJar := android.PathForModuleOut(ctx, "kapt", "kapt-sources.jar")
kaptResJar := android.PathForModuleOut(ctx, "kapt", "kapt-res.jar")
kotlinKapt(ctx, kaptSrcJar, kaptResJar, kotlinSrcFiles, kotlinCommonSrcFiles, srcJars, flags)
srcJars = append(srcJars, kaptSrcJar)
kotlinJars = append(kotlinJars, kaptResJar)
// Disable annotation processing in javac, it's already been handled by kapt
flags.processorPath = nil
flags.processors = nil
}
kotlinJar := android.PathForModuleOut(ctx, "kotlin", jarName)
kotlinCompile(ctx, kotlinJar, kotlinSrcFiles, kotlinCommonSrcFiles, srcJars, flags)
if ctx.Failed() {
return
}
// Make javac rule depend on the kotlinc rule
flags.classpath = append(flags.classpath, kotlinJar)
kotlinJars = append(kotlinJars, kotlinJar)
// Jar kotlin classes into the final jar after javac
if BoolDefault(j.properties.Static_kotlin_stdlib, true) {
kotlinJars = append(kotlinJars, deps.kotlinStdlib...)
}
}
jars := append(android.Paths(nil), kotlinJars...)
// Store the list of .java files that was passed to javac
j.compiledJavaSrcs = uniqueSrcFiles
j.compiledSrcJars = srcJars
enableSharding := false
var headerJarFileWithoutJarjar android.Path
if ctx.Device() && !ctx.Config().IsEnvFalse("TURBINE_ENABLED") && !deps.disableTurbine {
if j.properties.Javac_shard_size != nil && *(j.properties.Javac_shard_size) > 0 {
enableSharding = true
// Formerly, there was a check here that prevented annotation processors
// from being used when sharding was enabled, as some annotation processors
// do not function correctly in sharded environments. It was removed to
// allow for the use of annotation processors that do function correctly
// with sharding enabled. See: b/77284273.
}
headerJarFileWithoutJarjar, j.headerJarFile =
j.compileJavaHeader(ctx, uniqueSrcFiles, srcJars, deps, flags, jarName, kotlinJars)
if ctx.Failed() {
return
}
}
if len(uniqueSrcFiles) > 0 || len(srcJars) > 0 {
var extraJarDeps android.Paths
if ctx.Config().RunErrorProne() {
// If error-prone is enabled, add an additional rule to compile the java files into
// a separate set of classes (so that they don't overwrite the normal ones and require
// a rebuild when error-prone is turned off).
// TODO(ccross): Once we always compile with javac9 we may be able to conditionally
// enable error-prone without affecting the output class files.
errorprone := android.PathForModuleOut(ctx, "errorprone", jarName)
RunErrorProne(ctx, errorprone, uniqueSrcFiles, srcJars, flags)
extraJarDeps = append(extraJarDeps, errorprone)
}
if enableSharding {
flags.classpath = append(flags.classpath, headerJarFileWithoutJarjar)
shardSize := int(*(j.properties.Javac_shard_size))
var shardSrcs []android.Paths
if len(uniqueSrcFiles) > 0 {
shardSrcs = android.ShardPaths(uniqueSrcFiles, shardSize)
for idx, shardSrc := range shardSrcs {
classes := j.compileJavaClasses(ctx, jarName, idx, shardSrc,
nil, flags, extraJarDeps)
jars = append(jars, classes)
}
}
if len(srcJars) > 0 {
classes := j.compileJavaClasses(ctx, jarName, len(shardSrcs),
nil, srcJars, flags, extraJarDeps)
jars = append(jars, classes)
}
} else {
classes := j.compileJavaClasses(ctx, jarName, -1, uniqueSrcFiles, srcJars, flags, extraJarDeps)
jars = append(jars, classes)
}
if ctx.Failed() {
return
}
}
j.srcJarArgs, j.srcJarDeps = resourcePathsToJarArgs(srcFiles), srcFiles
var includeSrcJar android.WritablePath
if Bool(j.properties.Include_srcs) {
includeSrcJar = android.PathForModuleOut(ctx, ctx.ModuleName()+".srcjar")
TransformResourcesToJar(ctx, includeSrcJar, j.srcJarArgs, j.srcJarDeps)
}
dirArgs, dirDeps := ResourceDirsToJarArgs(ctx, j.properties.Java_resource_dirs,
j.properties.Exclude_java_resource_dirs, j.properties.Exclude_java_resources)
fileArgs, fileDeps := ResourceFilesToJarArgs(ctx, j.properties.Java_resources, j.properties.Exclude_java_resources)
extraArgs, extraDeps := resourcePathsToJarArgs(j.extraResources), j.extraResources
var resArgs []string
var resDeps android.Paths
resArgs = append(resArgs, dirArgs...)
resDeps = append(resDeps, dirDeps...)
resArgs = append(resArgs, fileArgs...)
resDeps = append(resDeps, fileDeps...)
resArgs = append(resArgs, extraArgs...)
resDeps = append(resDeps, extraDeps...)
if len(resArgs) > 0 {
resourceJar := android.PathForModuleOut(ctx, "res", jarName)
TransformResourcesToJar(ctx, resourceJar, resArgs, resDeps)
j.resourceJar = resourceJar
if ctx.Failed() {
return
}
}
var resourceJars android.Paths
if j.resourceJar != nil {
resourceJars = append(resourceJars, j.resourceJar)
}
if Bool(j.properties.Include_srcs) {
resourceJars = append(resourceJars, includeSrcJar)
}
resourceJars = append(resourceJars, deps.staticResourceJars...)
if len(resourceJars) > 1 {
combinedJar := android.PathForModuleOut(ctx, "res-combined", jarName)
TransformJarsToJar(ctx, combinedJar, "for resources", resourceJars, android.OptionalPath{},
false, nil, nil)
j.resourceJar = combinedJar
} else if len(resourceJars) == 1 {
j.resourceJar = resourceJars[0]
}
if len(deps.staticJars) > 0 {
jars = append(jars, deps.staticJars...)
}
manifest := j.overrideManifest
if !manifest.Valid() && j.properties.Manifest != nil {
manifest = android.OptionalPathForPath(android.PathForModuleSrc(ctx, *j.properties.Manifest))
}
services := android.PathsForModuleSrc(ctx, j.properties.Services)
if len(services) > 0 {
servicesJar := android.PathForModuleOut(ctx, "services", jarName)
var zipargs []string
for _, file := range services {
serviceFile := file.String()
zipargs = append(zipargs, "-C", filepath.Dir(serviceFile), "-f", serviceFile)
}
rule := zip
args := map[string]string{
"jarArgs": "-P META-INF/services/ " + strings.Join(proptools.NinjaAndShellEscapeList(zipargs), " "),
}
if ctx.Config().UseRBE() && ctx.Config().IsEnvTrue("RBE_ZIP") {
rule = zipRE
args["implicits"] = strings.Join(services.Strings(), ",")
}
ctx.Build(pctx, android.BuildParams{
Rule: rule,
Output: servicesJar,
Implicits: services,
Args: args,
})
jars = append(jars, servicesJar)
}
// Combine the classes built from sources, any manifests, and any static libraries into
// classes.jar. If there is only one input jar this step will be skipped.
var outputFile android.OutputPath
if len(jars) == 1 && !manifest.Valid() {
// Optimization: skip the combine step as there is nothing to do
// TODO(ccross): this leaves any module-info.class files, but those should only come from
// prebuilt dependencies until we support modules in the platform build, so there shouldn't be
// any if len(jars) == 1.
// Transform the single path to the jar into an OutputPath as that is required by the following
// code.
if moduleOutPath, ok := jars[0].(android.ModuleOutPath); ok {
// The path contains an embedded OutputPath so reuse that.
outputFile = moduleOutPath.OutputPath
} else if outputPath, ok := jars[0].(android.OutputPath); ok {
// The path is an OutputPath so reuse it directly.
outputFile = outputPath
} else {
// The file is not in the out directory so create an OutputPath into which it can be copied
// and which the following code can use to refer to it.
combinedJar := android.PathForModuleOut(ctx, "combined", jarName)
ctx.Build(pctx, android.BuildParams{
Rule: android.Cp,
Input: jars[0],
Output: combinedJar,
})
outputFile = combinedJar.OutputPath
}
} else {
combinedJar := android.PathForModuleOut(ctx, "combined", jarName)
TransformJarsToJar(ctx, combinedJar, "for javac", jars, manifest,
false, nil, nil)
outputFile = combinedJar.OutputPath
}
// jarjar implementation jar if necessary
if j.expandJarjarRules != nil {
// Transform classes.jar into classes-jarjar.jar
jarjarFile := android.PathForModuleOut(ctx, "jarjar", jarName).OutputPath
TransformJarJar(ctx, jarjarFile, outputFile, j.expandJarjarRules)
outputFile = jarjarFile
// jarjar resource jar if necessary
if j.resourceJar != nil {
resourceJarJarFile := android.PathForModuleOut(ctx, "res-jarjar", jarName)
TransformJarJar(ctx, resourceJarJarFile, j.resourceJar, j.expandJarjarRules)
j.resourceJar = resourceJarJarFile
}
if ctx.Failed() {
return
}
}
// Check package restrictions if necessary.
if len(j.properties.Permitted_packages) > 0 {
// Check packages and copy to package-checked file.
pkgckFile := android.PathForModuleOut(ctx, "package-check.stamp")
CheckJarPackages(ctx, pkgckFile, outputFile, j.properties.Permitted_packages)
j.additionalCheckedModules = append(j.additionalCheckedModules, pkgckFile)
if ctx.Failed() {
return
}
}
j.implementationJarFile = outputFile
if j.headerJarFile == nil {
j.headerJarFile = j.implementationJarFile
}
if j.shouldInstrumentInApex(ctx) {
j.properties.Instrument = true
}
if j.shouldInstrument(ctx) {
outputFile = j.instrument(ctx, flags, outputFile, jarName)
}
// merge implementation jar with resources if necessary
implementationAndResourcesJar := outputFile
if j.resourceJar != nil {
jars := android.Paths{j.resourceJar, implementationAndResourcesJar}
combinedJar := android.PathForModuleOut(ctx, "withres", jarName).OutputPath
TransformJarsToJar(ctx, combinedJar, "for resources", jars, manifest,
false, nil, nil)
implementationAndResourcesJar = combinedJar
}
j.implementationAndResourcesJar = implementationAndResourcesJar
// Enable dex compilation for the APEX variants, unless it is disabled explicitly
apexInfo := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)
if j.DirectlyInAnyApex() && !apexInfo.IsForPlatform() {
if j.dexProperties.Compile_dex == nil {
j.dexProperties.Compile_dex = proptools.BoolPtr(true)
}
if j.deviceProperties.Hostdex == nil {
j.deviceProperties.Hostdex = proptools.BoolPtr(true)
}
}
if ctx.Device() && j.hasCode(ctx) &&
(Bool(j.properties.Installable) || Bool(j.dexProperties.Compile_dex)) {
if j.shouldInstrumentStatic(ctx) {
j.dexer.extraProguardFlagFiles = append(j.dexer.extraProguardFlagFiles,
android.PathForSource(ctx, "build/make/core/proguard.jacoco.flags"))
}
// Dex compilation
var dexOutputFile android.OutputPath
dexOutputFile = j.dexer.compileDex(ctx, flags, j.minSdkVersion(), outputFile, jarName)
if ctx.Failed() {
return
}
configurationName := j.ConfigurationName()
primary := configurationName == ctx.ModuleName()
// If the prebuilt is being used rather than the from source, skip this
// module to prevent duplicated classes
primary = primary && !j.IsReplacedByPrebuilt()
// Hidden API CSV generation and dex encoding
dexOutputFile = j.hiddenAPIExtractAndEncode(ctx, configurationName, primary, dexOutputFile, j.implementationJarFile,
proptools.Bool(j.dexProperties.Uncompress_dex))
// merge dex jar with resources if necessary
if j.resourceJar != nil {
jars := android.Paths{dexOutputFile, j.resourceJar}
combinedJar := android.PathForModuleOut(ctx, "dex-withres", jarName).OutputPath
TransformJarsToJar(ctx, combinedJar, "for dex resources", jars, android.OptionalPath{},
false, nil, nil)
if *j.dexProperties.Uncompress_dex {
combinedAlignedJar := android.PathForModuleOut(ctx, "dex-withres-aligned", jarName).OutputPath
TransformZipAlign(ctx, combinedAlignedJar, combinedJar)
dexOutputFile = combinedAlignedJar
} else {
dexOutputFile = combinedJar
}
}
j.dexJarFile = dexOutputFile
// Dexpreopting
j.dexpreopt(ctx, dexOutputFile)
j.maybeStrippedDexJarFile = dexOutputFile
outputFile = dexOutputFile
if ctx.Failed() {
return
}
} else {
outputFile = implementationAndResourcesJar
}
if ctx.Device() {
lintSDKVersionString := func(sdkSpec sdkSpec) string {
if v := sdkSpec.version; v.isNumbered() {
return v.String()
} else {
return ctx.Config().DefaultAppTargetSdk(ctx).String()
}
}
j.linter.name = ctx.ModuleName()
j.linter.srcs = srcFiles
j.linter.srcJars = srcJars
j.linter.classpath = append(append(android.Paths(nil), flags.bootClasspath...), flags.classpath...)
j.linter.classes = j.implementationJarFile
j.linter.minSdkVersion = lintSDKVersionString(j.minSdkVersion())
j.linter.targetSdkVersion = lintSDKVersionString(j.targetSdkVersion())
j.linter.compileSdkVersion = lintSDKVersionString(j.sdkVersion())
j.linter.javaLanguageLevel = flags.javaVersion.String()
j.linter.kotlinLanguageLevel = "1.3"
if !apexInfo.IsForPlatform() && ctx.Config().UnbundledBuildApps() {
j.linter.buildModuleReportZip = true
}
j.linter.lint(ctx)
}
ctx.CheckbuildFile(outputFile)
// Save the output file with no relative path so that it doesn't end up in a subdirectory when used as a resource
j.outputFile = outputFile.WithoutRel()
}
func (j *Module) compileJavaClasses(ctx android.ModuleContext, jarName string, idx int,
srcFiles, srcJars android.Paths, flags javaBuilderFlags, extraJarDeps android.Paths) android.WritablePath {
kzipName := pathtools.ReplaceExtension(jarName, "kzip")
if idx >= 0 {
kzipName = strings.TrimSuffix(jarName, filepath.Ext(jarName)) + strconv.Itoa(idx) + ".kzip"
jarName += strconv.Itoa(idx)
}
classes := android.PathForModuleOut(ctx, "javac", jarName).OutputPath
TransformJavaToClasses(ctx, classes, idx, srcFiles, srcJars, flags, extraJarDeps)
if ctx.Config().EmitXrefRules() {
extractionFile := android.PathForModuleOut(ctx, kzipName)
emitXrefRule(ctx, extractionFile, idx, srcFiles, srcJars, flags, extraJarDeps)
j.kytheFiles = append(j.kytheFiles, extractionFile)
}
return classes
}
// Check for invalid kotlinc flags. Only use this for flags explicitly passed by the user,
// since some of these flags may be used internally.
func CheckKotlincFlags(ctx android.ModuleContext, flags []string) {
for _, flag := range flags {
flag = strings.TrimSpace(flag)
if !strings.HasPrefix(flag, "-") {
ctx.PropertyErrorf("kotlincflags", "Flag `%s` must start with `-`", flag)
} else if strings.HasPrefix(flag, "-Xintellij-plugin-root") {
ctx.PropertyErrorf("kotlincflags",
"Bad flag: `%s`, only use internal compiler for consistency.", flag)
} else if inList(flag, config.KotlincIllegalFlags) {
ctx.PropertyErrorf("kotlincflags", "Flag `%s` already used by build system", flag)
} else if flag == "-include-runtime" {
ctx.PropertyErrorf("kotlincflags", "Bad flag: `%s`, do not include runtime.", flag)
} else {
args := strings.Split(flag, " ")
if args[0] == "-kotlin-home" {
ctx.PropertyErrorf("kotlincflags",
"Bad flag: `%s`, kotlin home already set to default (path to kotlinc in the repo).", flag)
}
}
}
}
func (j *Module) compileJavaHeader(ctx android.ModuleContext, srcFiles, srcJars android.Paths,
deps deps, flags javaBuilderFlags, jarName string,
extraJars android.Paths) (headerJar, jarjarHeaderJar android.Path) {
var jars android.Paths
if len(srcFiles) > 0 || len(srcJars) > 0 {
// Compile java sources into turbine.jar.
turbineJar := android.PathForModuleOut(ctx, "turbine", jarName)
TransformJavaToHeaderClasses(ctx, turbineJar, srcFiles, srcJars, flags)
if ctx.Failed() {
return nil, nil
}
jars = append(jars, turbineJar)
}
jars = append(jars, extraJars...)
// Combine any static header libraries into classes-header.jar. If there is only
// one input jar this step will be skipped.
jars = append(jars, deps.staticHeaderJars...)
// we cannot skip the combine step for now if there is only one jar
// since we have to strip META-INF/TRANSITIVE dir from turbine.jar
combinedJar := android.PathForModuleOut(ctx, "turbine-combined", jarName)
TransformJarsToJar(ctx, combinedJar, "for turbine", jars, android.OptionalPath{},
false, nil, []string{"META-INF/TRANSITIVE"})
headerJar = combinedJar
jarjarHeaderJar = combinedJar
if j.expandJarjarRules != nil {
// Transform classes.jar into classes-jarjar.jar
jarjarFile := android.PathForModuleOut(ctx, "turbine-jarjar", jarName)
TransformJarJar(ctx, jarjarFile, headerJar, j.expandJarjarRules)
jarjarHeaderJar = jarjarFile
if ctx.Failed() {
return nil, nil
}
}
return headerJar, jarjarHeaderJar
}
func (j *Module) instrument(ctx android.ModuleContext, flags javaBuilderFlags,
classesJar android.Path, jarName string) android.OutputPath {
specs := j.jacocoModuleToZipCommand(ctx)
jacocoReportClassesFile := android.PathForModuleOut(ctx, "jacoco-report-classes", jarName)
instrumentedJar := android.PathForModuleOut(ctx, "jacoco", jarName).OutputPath
jacocoInstrumentJar(ctx, instrumentedJar, jacocoReportClassesFile, classesJar, specs)
j.jacocoReportClassesFile = jacocoReportClassesFile
return instrumentedJar
}
var _ Dependency = (*Module)(nil)
func (j *Module) HeaderJars() android.Paths {
if j.headerJarFile == nil {
return nil
}
return android.Paths{j.headerJarFile}
}
func (j *Module) ImplementationJars() android.Paths {
if j.implementationJarFile == nil {
return nil
}
return android.Paths{j.implementationJarFile}
}
func (j *Module) DexJarBuildPath() android.Path {
return j.dexJarFile
}
func (j *Module) DexJarInstallPath() android.Path {
return j.installFile
}
func (j *Module) ResourceJars() android.Paths {
if j.resourceJar == nil {
return nil
}
return android.Paths{j.resourceJar}
}
func (j *Module) ImplementationAndResourcesJars() android.Paths {
if j.implementationAndResourcesJar == nil {
return nil
}
return android.Paths{j.implementationAndResourcesJar}
}
func (j *Module) AidlIncludeDirs() android.Paths {
// exportAidlIncludeDirs is type android.Paths already
return j.exportAidlIncludeDirs
}
func (j *Module) ClassLoaderContexts() dexpreopt.ClassLoaderContextMap {
return j.classLoaderContexts
}
// ExportedPlugins returns the list of jars needed to run the exported plugins, the list of
// classes for the plugins, and a boolean for whether turbine needs to be disabled due to plugins
// that generate APIs.
func (j *Module) ExportedPlugins() (android.Paths, []string, bool) {
return j.exportedPluginJars, j.exportedPluginClasses, j.exportedDisableTurbine
}
func (j *Module) SrcJarArgs() ([]string, android.Paths) {
return j.srcJarArgs, j.srcJarDeps
}
var _ logtagsProducer = (*Module)(nil)
func (j *Module) logtags() android.Paths {
return j.logtagsSrcs
}
// Collect information for opening IDE project files in java/jdeps.go.
func (j *Module) IDEInfo(dpInfo *android.IdeInfo) {
dpInfo.Deps = append(dpInfo.Deps, j.CompilerDeps()...)
dpInfo.Srcs = append(dpInfo.Srcs, j.expandIDEInfoCompiledSrcs...)
dpInfo.SrcJars = append(dpInfo.SrcJars, j.compiledSrcJars.Strings()...)
dpInfo.Aidl_include_dirs = append(dpInfo.Aidl_include_dirs, j.deviceProperties.Aidl.Include_dirs...)
if j.expandJarjarRules != nil {
dpInfo.Jarjar_rules = append(dpInfo.Jarjar_rules, j.expandJarjarRules.String())
}
dpInfo.Paths = append(dpInfo.Paths, j.modulePaths...)
}
func (j *Module) CompilerDeps() []string {
jdeps := []string{}
jdeps = append(jdeps, j.properties.Libs...)
jdeps = append(jdeps, j.properties.Static_libs...)
return jdeps
}
func (j *Module) hasCode(ctx android.ModuleContext) bool {
srcFiles := android.PathsForModuleSrcExcludes(ctx, j.properties.Srcs, j.properties.Exclude_srcs)
return len(srcFiles) > 0 || len(ctx.GetDirectDepsWithTag(staticLibTag)) > 0
}
// Implements android.ApexModule
func (j *Module) DepIsInSameApex(ctx android.BaseModuleContext, dep android.Module) bool {
return j.depIsInSameApex(ctx, dep)
}
// Implements android.ApexModule
func (j *Module) ShouldSupportSdkVersion(ctx android.BaseModuleContext,
sdkVersion android.ApiLevel) error {
sdkSpec := j.minSdkVersion()
if !sdkSpec.specified() {
return fmt.Errorf("min_sdk_version is not specified")
}
if sdkSpec.kind == sdkCore {
return nil
}
ver, err := sdkSpec.effectiveVersion(ctx)
if err != nil {
return err
}
if ver.ApiLevel(ctx).GreaterThan(sdkVersion) {
return fmt.Errorf("newer SDK(%v)", ver)
}
return nil
}
func (j *Module) Stem() string {
return proptools.StringDefault(j.deviceProperties.Stem, j.Name())
}
// ConfigurationName returns the name of the module as used in build configuration.
//
// This is usually the same as BaseModuleName() except for the <x>.impl libraries created by
// java_sdk_library in which case this is the BaseModuleName() without the ".impl" suffix,
// i.e. just <x>.
func (j *Module) ConfigurationName() string {
return proptools.StringDefault(j.deviceProperties.ConfigurationName, j.BaseModuleName())
}
func (j *Module) JacocoReportClassesFile() android.Path {
return j.jacocoReportClassesFile
}
func (j *Module) IsInstallable() bool {
return Bool(j.properties.Installable)
}
//
// Java libraries (.jar file)
//
type Library struct {
Module
InstallMixin func(ctx android.ModuleContext, installPath android.Path) (extraInstallDeps android.Paths)
}
var _ android.ApexModule = (*Library)(nil)
// Provides access to the list of permitted packages from updatable boot jars.
type PermittedPackagesForUpdatableBootJars interface {
PermittedPackagesForUpdatableBootJars() []string
}
var _ PermittedPackagesForUpdatableBootJars = (*Library)(nil)
func (j *Library) PermittedPackagesForUpdatableBootJars() []string {
return j.properties.Permitted_packages
}
func shouldUncompressDex(ctx android.ModuleContext, dexpreopter *dexpreopter) bool {
// Store uncompressed (and aligned) any dex files from jars in APEXes.
if apexInfo := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo); !apexInfo.IsForPlatform() {
return true
}
// Store uncompressed (and do not strip) dex files from boot class path jars.
if inList(ctx.ModuleName(), ctx.Config().BootJars()) {
return true
}
// Store uncompressed dex files that are preopted on /system.
if !dexpreopter.dexpreoptDisabled(ctx) && (ctx.Host() || !odexOnSystemOther(ctx, dexpreopter.installPath)) {
return true
}
if ctx.Config().UncompressPrivAppDex() &&
inList(ctx.ModuleName(), ctx.Config().ModulesLoadedByPrivilegedModules()) {
return true
}
return false
}
func (j *Library) GenerateAndroidBuildActions(ctx android.ModuleContext) {
// Initialize the hiddenapi structure. Pass in the configuration name rather than the module name
// so the hidden api will encode the <x>.impl java_ library created by java_sdk_library just as it
// would the <x> library if <x> was configured as a boot jar.
j.initHiddenAPI(ctx, j.ConfigurationName())
apexInfo := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)
if !apexInfo.IsForPlatform() {
j.hideApexVariantFromMake = true
}
j.checkSdkVersions(ctx)
j.dexpreopter.installPath = android.PathForModuleInstall(ctx, "framework", j.Stem()+".jar")
j.dexpreopter.isSDKLibrary = j.deviceProperties.IsSDKLibrary
if j.dexProperties.Uncompress_dex == nil {
// If the value was not force-set by the user, use reasonable default based on the module.
j.dexProperties.Uncompress_dex = proptools.BoolPtr(shouldUncompressDex(ctx, &j.dexpreopter))
}
j.dexpreopter.uncompressedDex = *j.dexProperties.Uncompress_dex
j.classLoaderContexts = make(dexpreopt.ClassLoaderContextMap)
j.compile(ctx, nil)
// Collect the module directory for IDE info in java/jdeps.go.
j.modulePaths = append(j.modulePaths, ctx.ModuleDir())
exclusivelyForApex := !apexInfo.IsForPlatform()
if (Bool(j.properties.Installable) || ctx.Host()) && !exclusivelyForApex {
var extraInstallDeps android.Paths
if j.InstallMixin != nil {
extraInstallDeps = j.InstallMixin(ctx, j.outputFile)
}
j.installFile = ctx.InstallFile(android.PathForModuleInstall(ctx, "framework"),
j.Stem()+".jar", j.outputFile, extraInstallDeps...)
}
}
func (j *Library) DepsMutator(ctx android.BottomUpMutatorContext) {
j.deps(ctx)
}
const (
aidlIncludeDir = "aidl"
javaDir = "java"
jarFileSuffix = ".jar"
testConfigSuffix = "-AndroidTest.xml"
)
// path to the jar file of a java library. Relative to <sdk_root>/<api_dir>
func sdkSnapshotFilePathForJar(osPrefix, name string) string {
return sdkSnapshotFilePathForMember(osPrefix, name, jarFileSuffix)
}
func sdkSnapshotFilePathForMember(osPrefix, name string, suffix string) string {
return filepath.Join(javaDir, osPrefix, name+suffix)
}
Parameterize the sdk member processing Extracts the type specific functionality into the SdkMemberType interface which has to be implemented by each module type that can be added as a member of the sdk. It provides functionality to add the required dependencies for the module type, check to see if a resolved module is the correct instance and build the snapshot. The latter was previously part of SdkAware but was moved because it has to be able to process multiple SdkAware variants so delegating it to a single instance did not make sense. The custom code for handling each member type specific property, e.g. java_libs, has been replaced with common code that processes a list of sdkMemberListProperty struct which associates the property (name and getter) with the SdkMemberType and a special DependencyTag which is passed to the SdkMemberType when it has to add dependencies. The DependencyTag contains a reference to the appropriate sdkMemberListProperty which allows the resolved dependencies to be grouped by type. Previously, the dependency collection methods would ignore a module if it was an unsupported type because they did not have a way of determining which property it was initially listed in. That meant it was possible to add say a droidstubs module to the java_libs property (and because they had the same variants) it would work as if it was added to the stubs_sources property. Or alternatively, a module of an unsupported type could be added to any property and it would just be ignored. However, the DependencyTag provides information about which property a resolved module was referenced in and so it can detect when the resolved module is of the wrong type and report an error. That check identified a bug in one of the tests where the sdk referenced a java_import module (which is not allowed in an sdk) instead of a java_library module (which is allowed). That test was fixed as part of this. A list of sdkMemberListProperty structs defines the member properties supported by the sdk and are processed in order to ensure consistent behaviour. The resolved dependencies are grouped by type and each group is then processed in defined order. Within each type dependencies are grouped by name and encapsulated behind an SdkMember interface which includes the name and the list of variants. The Droidstubs and java.Library types can only support one variant and will fail if given more. The processing for the native_shared_libs property has been moved into the cc/library.go file so the sdk package code should now have no type specific information in it apart from what is if the list of sdkMemberListProperty structs. Bug: 143678475 Test: m conscrypt-module-sdk Change-Id: I10203594d33dbf53441f655aff124f9ab3538d87
2019-11-28 22:31:38 +08:00
type librarySdkMemberType struct {
Decouple addition of new sdk member types from sdk code Previously, adding a new SdkMemberType would require adding a new sdkMemberListProperty instance to the sdkMemberListProperties as well as adding a new property into the sdkProperties struct. They are potential sources of conflict and couple the sdk code with all the packages that add members to it. This change switched to a registration model that allows each package to register its sdk member types decoupling them from the sdk code. Adds an SdkPropertyName() method to SdkMemberType that specifies the name of the property to use in the sdk/sdk_snapshot. Also provides an SdkMemberTypeBase struct to be used by providers of SdkMemberType implementations. SdkMemberType instances are registered using the RegisterSdkMemberType() func which sorts the registered instances by their SdkPropertyName() to ensure the behavior is consistent and not affected by order of registration. When creating a new sdk module a dynamicSdkMemberTypes instance is created that contains the following: * A properties struct is created dynamically that contains a field for each registered SdkMemberType, corresponding to that type's SdkPropertyName(). * A list of sdkMemberListProperty instances is also created, one for each registered SdkMemberType. The dynamicSdkMemberTypes instance is cached using a key that uniquely identifies the set of registered types just in case new types are registered after one has been created, e.g. by tests. Bug: 142918168 Test: m checkbuild Change-Id: I4bf2bf56a2a49025aa41454048bc1e8ccc6baca2
2019-12-13 19:22:16 +08:00
android.SdkMemberTypeBase
// Function to retrieve the appropriate output jar (implementation or header) from
// the library.
jarToExportGetter func(ctx android.SdkMemberContext, j *Library) android.Path
// Function to compute the snapshot relative path to which the named library's
// jar should be copied.
snapshotPathGetter func(osPrefix, name string) string
// True if only the jar should be copied to the snapshot, false if the jar plus any additional
// files like aidl files should also be copied.
onlyCopyJarToSnapshot bool
Parameterize the sdk member processing Extracts the type specific functionality into the SdkMemberType interface which has to be implemented by each module type that can be added as a member of the sdk. It provides functionality to add the required dependencies for the module type, check to see if a resolved module is the correct instance and build the snapshot. The latter was previously part of SdkAware but was moved because it has to be able to process multiple SdkAware variants so delegating it to a single instance did not make sense. The custom code for handling each member type specific property, e.g. java_libs, has been replaced with common code that processes a list of sdkMemberListProperty struct which associates the property (name and getter) with the SdkMemberType and a special DependencyTag which is passed to the SdkMemberType when it has to add dependencies. The DependencyTag contains a reference to the appropriate sdkMemberListProperty which allows the resolved dependencies to be grouped by type. Previously, the dependency collection methods would ignore a module if it was an unsupported type because they did not have a way of determining which property it was initially listed in. That meant it was possible to add say a droidstubs module to the java_libs property (and because they had the same variants) it would work as if it was added to the stubs_sources property. Or alternatively, a module of an unsupported type could be added to any property and it would just be ignored. However, the DependencyTag provides information about which property a resolved module was referenced in and so it can detect when the resolved module is of the wrong type and report an error. That check identified a bug in one of the tests where the sdk referenced a java_import module (which is not allowed in an sdk) instead of a java_library module (which is allowed). That test was fixed as part of this. A list of sdkMemberListProperty structs defines the member properties supported by the sdk and are processed in order to ensure consistent behaviour. The resolved dependencies are grouped by type and each group is then processed in defined order. Within each type dependencies are grouped by name and encapsulated behind an SdkMember interface which includes the name and the list of variants. The Droidstubs and java.Library types can only support one variant and will fail if given more. The processing for the native_shared_libs property has been moved into the cc/library.go file so the sdk package code should now have no type specific information in it apart from what is if the list of sdkMemberListProperty structs. Bug: 143678475 Test: m conscrypt-module-sdk Change-Id: I10203594d33dbf53441f655aff124f9ab3538d87
2019-11-28 22:31:38 +08:00
}
const (
onlyCopyJarToSnapshot = true
copyEverythingToSnapshot = false
)
Parameterize the sdk member processing Extracts the type specific functionality into the SdkMemberType interface which has to be implemented by each module type that can be added as a member of the sdk. It provides functionality to add the required dependencies for the module type, check to see if a resolved module is the correct instance and build the snapshot. The latter was previously part of SdkAware but was moved because it has to be able to process multiple SdkAware variants so delegating it to a single instance did not make sense. The custom code for handling each member type specific property, e.g. java_libs, has been replaced with common code that processes a list of sdkMemberListProperty struct which associates the property (name and getter) with the SdkMemberType and a special DependencyTag which is passed to the SdkMemberType when it has to add dependencies. The DependencyTag contains a reference to the appropriate sdkMemberListProperty which allows the resolved dependencies to be grouped by type. Previously, the dependency collection methods would ignore a module if it was an unsupported type because they did not have a way of determining which property it was initially listed in. That meant it was possible to add say a droidstubs module to the java_libs property (and because they had the same variants) it would work as if it was added to the stubs_sources property. Or alternatively, a module of an unsupported type could be added to any property and it would just be ignored. However, the DependencyTag provides information about which property a resolved module was referenced in and so it can detect when the resolved module is of the wrong type and report an error. That check identified a bug in one of the tests where the sdk referenced a java_import module (which is not allowed in an sdk) instead of a java_library module (which is allowed). That test was fixed as part of this. A list of sdkMemberListProperty structs defines the member properties supported by the sdk and are processed in order to ensure consistent behaviour. The resolved dependencies are grouped by type and each group is then processed in defined order. Within each type dependencies are grouped by name and encapsulated behind an SdkMember interface which includes the name and the list of variants. The Droidstubs and java.Library types can only support one variant and will fail if given more. The processing for the native_shared_libs property has been moved into the cc/library.go file so the sdk package code should now have no type specific information in it apart from what is if the list of sdkMemberListProperty structs. Bug: 143678475 Test: m conscrypt-module-sdk Change-Id: I10203594d33dbf53441f655aff124f9ab3538d87
2019-11-28 22:31:38 +08:00
func (mt *librarySdkMemberType) AddDependencies(mctx android.BottomUpMutatorContext, dependencyTag blueprint.DependencyTag, names []string) {
mctx.AddVariationDependencies(nil, dependencyTag, names...)
}
func (mt *librarySdkMemberType) IsInstance(module android.Module) bool {
_, ok := module.(*Library)
return ok
}
func (mt *librarySdkMemberType) AddPrebuiltModule(ctx android.SdkMemberContext, member android.SdkMember) android.BpModule {
return ctx.SnapshotBuilder().AddPrebuiltModule(member, "java_import")
}
func (mt *librarySdkMemberType) CreateVariantPropertiesStruct() android.SdkMemberProperties {
return &librarySdkMemberProperties{}
}
type librarySdkMemberProperties struct {
android.SdkMemberPropertiesBase
JarToExport android.Path `android:"arch_variant"`
AidlIncludeDirs android.Paths
}
func (p *librarySdkMemberProperties) PopulateFromVariant(ctx android.SdkMemberContext, variant android.Module) {
Parameterize the sdk member processing Extracts the type specific functionality into the SdkMemberType interface which has to be implemented by each module type that can be added as a member of the sdk. It provides functionality to add the required dependencies for the module type, check to see if a resolved module is the correct instance and build the snapshot. The latter was previously part of SdkAware but was moved because it has to be able to process multiple SdkAware variants so delegating it to a single instance did not make sense. The custom code for handling each member type specific property, e.g. java_libs, has been replaced with common code that processes a list of sdkMemberListProperty struct which associates the property (name and getter) with the SdkMemberType and a special DependencyTag which is passed to the SdkMemberType when it has to add dependencies. The DependencyTag contains a reference to the appropriate sdkMemberListProperty which allows the resolved dependencies to be grouped by type. Previously, the dependency collection methods would ignore a module if it was an unsupported type because they did not have a way of determining which property it was initially listed in. That meant it was possible to add say a droidstubs module to the java_libs property (and because they had the same variants) it would work as if it was added to the stubs_sources property. Or alternatively, a module of an unsupported type could be added to any property and it would just be ignored. However, the DependencyTag provides information about which property a resolved module was referenced in and so it can detect when the resolved module is of the wrong type and report an error. That check identified a bug in one of the tests where the sdk referenced a java_import module (which is not allowed in an sdk) instead of a java_library module (which is allowed). That test was fixed as part of this. A list of sdkMemberListProperty structs defines the member properties supported by the sdk and are processed in order to ensure consistent behaviour. The resolved dependencies are grouped by type and each group is then processed in defined order. Within each type dependencies are grouped by name and encapsulated behind an SdkMember interface which includes the name and the list of variants. The Droidstubs and java.Library types can only support one variant and will fail if given more. The processing for the native_shared_libs property has been moved into the cc/library.go file so the sdk package code should now have no type specific information in it apart from what is if the list of sdkMemberListProperty structs. Bug: 143678475 Test: m conscrypt-module-sdk Change-Id: I10203594d33dbf53441f655aff124f9ab3538d87
2019-11-28 22:31:38 +08:00
j := variant.(*Library)
p.JarToExport = ctx.MemberType().(*librarySdkMemberType).jarToExportGetter(ctx, j)
p.AidlIncludeDirs = j.AidlIncludeDirs()
}
func (p *librarySdkMemberProperties) AddToPropertySet(ctx android.SdkMemberContext, propertySet android.BpPropertySet) {
builder := ctx.SnapshotBuilder()
memberType := ctx.MemberType().(*librarySdkMemberType)
exportedJar := p.JarToExport
if exportedJar != nil {
// Delegate the creation of the snapshot relative path to the member type.
snapshotRelativeJavaLibPath := memberType.snapshotPathGetter(p.OsPrefix(), ctx.Name())
// Copy the exported jar to the snapshot.
builder.CopyToSnapshot(exportedJar, snapshotRelativeJavaLibPath)
propertySet.AddProperty("jars", []string{snapshotRelativeJavaLibPath})
}
// Do not copy anything else to the snapshot.
if memberType.onlyCopyJarToSnapshot {
return
}
aidlIncludeDirs := p.AidlIncludeDirs
if len(aidlIncludeDirs) != 0 {
sdkModuleContext := ctx.SdkModuleContext()
for _, dir := range aidlIncludeDirs {
// TODO(jiyong): copy parcelable declarations only
aidlFiles, _ := sdkModuleContext.GlobWithDeps(dir.String()+"/**/*.aidl", nil)
for _, file := range aidlFiles {
builder.CopyToSnapshot(android.PathForSource(sdkModuleContext, file), filepath.Join(aidlIncludeDir, file))
}
}
// TODO(b/151933053) - add aidl include dirs property
}
}
var javaHeaderLibsSdkMemberType android.SdkMemberType = &librarySdkMemberType{
android.SdkMemberTypeBase{
PropertyName: "java_header_libs",
SupportsSdk: true,
},
func(_ android.SdkMemberContext, j *Library) android.Path {
headerJars := j.HeaderJars()
if len(headerJars) != 1 {
panic(fmt.Errorf("there must be only one header jar from %q", j.Name()))
}
return headerJars[0]
},
sdkSnapshotFilePathForJar,
copyEverythingToSnapshot,
}
// java_library builds and links sources into a `.jar` file for the device, and possibly for the host as well.
//
// By default, a java_library has a single variant that produces a `.jar` file containing `.class` files that were
// compiled against the device bootclasspath. This jar is not suitable for installing on a device, but can be used
// as a `static_libs` dependency of another module.
//
// Specifying `installable: true` will product a `.jar` file containing `classes.dex` files, suitable for installing on
// a device.
//
// Specifying `host_supported: true` will produce two variants, one compiled against the device bootclasspath and one
// compiled against the host bootclasspath.
func LibraryFactory() android.Module {
module := &Library{}
module.addHostAndDeviceProperties()
Improve tracking of exported sdk libraries The build tracks the java_sdk_library/_import modules that are referenced by libraries so that it can ensure that any Android app that includes code that depends on one of those modules has the appropriate <uses-library> entry in their manifest. Unfortunately, there were a couple of issues with that: 1) It only tracks direct references to the java_sdk_library module itself, e.g. android.test.mock. Direct references to the stubs module, e.g. android.test.mock.stubs were not tracked. Making it possible for Android apps to reference libraries which would not be available at runtime. 2) The logic for determining whether something was a java_sdk_library was repeated in a number of places making it difficult to allow java_sdk_library/_import instances to determine whether they should be treated as an Android shared library. 3) It tracks (and could use) even those java_sdk_library instances which do not represent a shared library, e.g. the ones that set api_only: true. While this change will simplifty fixing that the actual issue will be fixed in a follow up change. Changes: * Added EmbeddableSdkLibraryComponent and embedded it into java_sdk_library/_import, java_library and java_import. It provides the common code to minimize duplication. It contains an SdkLibraryToImplicitlyTrack field that if set will cause any references to the containing module to add the SdkLibraryParent to the list of implicit sdk libraries being tracked. * Changed code that assumed that anything that implemented SdkLibraryDependency required tracking to use the OptionalImplicitSdkLibrary() method to get the optional name of the sdk library to track. That will allow a follow up change to return nil from that method to exclude an sdk library from being tracked. * Moved SdkLibraryDependency from java.go to sdk_library.go as that is a better place for it to be. * Changed the stubs java_library/java_import creation code to initialize the SdkLibraryToImplicitlyTrack field with the name of the creating module. * Initialized the SdkLibraryToImplicitlyTrack field in the java_sdk_library/_import so that direct references to them will be tracked too. * Added tests to verify that direct access to the .stubs child of both java_sdk_library and java_sdk_library_import are tracked properly. Test: atest CtsProviderTestCases - which relies on android.test.mock being implicitly tracked to verify that I had not broken anything. Used aapt2 dump badging to read the manifest. m nothing - to run the new tests which failed before fixing the code. Bug: 156723295 Change-Id: Ia99def91e9b74d2ed0a777de04b476c00ea0393d
2020-05-15 17:20:31 +08:00
module.initModuleAndImport(&module.ModuleBase)
android.InitApexModule(module)
android.InitSdkAwareModule(module)
InitJavaModule(module, android.HostAndDeviceSupported)
return module
}
// java_library_static is an obsolete alias for java_library.
func LibraryStaticFactory() android.Module {
return LibraryFactory()
}
// java_library_host builds and links sources into a `.jar` file for the host.
//
// A java_library_host has a single variant that produces a `.jar` file containing `.class` files that were
// compiled against the host bootclasspath.
func LibraryHostFactory() android.Module {
module := &Library{}
module.addHostProperties()
module.Module.properties.Installable = proptools.BoolPtr(true)
android.InitApexModule(module)
InitJavaModule(module, android.HostSupported)
return module
}
//
// Java Tests
//
// Test option struct.
type TestOptions struct {
// a list of extra test configuration files that should be installed with the module.
Extra_test_configs []string `android:"path,arch_variant"`
// If the test is a hostside(no device required) unittest that shall be run during presubmit check.
Unit_test *bool
}
type testProperties struct {
// list of compatibility suites (for example "cts", "vts") that the module should be
// installed into.
Test_suites []string `android:"arch_variant"`
// the name of the test configuration (for example "AndroidTest.xml") that should be
// installed with the module.
Test_config *string `android:"path,arch_variant"`
// the name of the test configuration template (for example "AndroidTestTemplate.xml") that
// should be installed with the module.
Test_config_template *string `android:"path,arch_variant"`
// list of files or filegroup modules that provide data that should be installed alongside
// the test
Data []string `android:"path,arch_variant"`
// Flag to indicate whether or not to create test config automatically. If AndroidTest.xml
// doesn't exist next to the Android.bp, this attribute doesn't need to be set to true
// explicitly.
Auto_gen_config *bool
// Add parameterized mainline modules to auto generated test config. The options will be
// handled by TradeFed to do downloading and installing the specified modules on the device.
Test_mainline_modules []string
// Test options.
Test_options TestOptions
}
type hostTestProperties struct {
// list of native binary modules that should be installed alongside the test
Data_native_bins []string `android:"arch_variant"`
}
type testHelperLibraryProperties struct {
// list of compatibility suites (for example "cts", "vts") that the module should be
// installed into.
Test_suites []string `android:"arch_variant"`
}
type prebuiltTestProperties struct {
// list of compatibility suites (for example "cts", "vts") that the module should be
// installed into.
Test_suites []string `android:"arch_variant"`
// the name of the test configuration (for example "AndroidTest.xml") that should be
// installed with the module.
Test_config *string `android:"path,arch_variant"`
}
type Test struct {
Library
testProperties testProperties
testConfig android.Path
extraTestConfigs android.Paths
data android.Paths
}
type TestHost struct {
Test
testHostProperties hostTestProperties
}
type TestHelperLibrary struct {
Library
testHelperLibraryProperties testHelperLibraryProperties
}
type JavaTestImport struct {
Import
prebuiltTestProperties prebuiltTestProperties
testConfig android.Path
dexJarFile android.Path
}
func (j *TestHost) DepsMutator(ctx android.BottomUpMutatorContext) {
if len(j.testHostProperties.Data_native_bins) > 0 {
for _, target := range ctx.MultiTargets() {
ctx.AddVariationDependencies(target.Variations(), dataNativeBinsTag, j.testHostProperties.Data_native_bins...)
}
}
j.deps(ctx)
}
func (j *Test) GenerateAndroidBuildActions(ctx android.ModuleContext) {
j.testConfig = tradefed.AutoGenJavaTestConfig(ctx, j.testProperties.Test_config, j.testProperties.Test_config_template,
j.testProperties.Test_suites, j.testProperties.Auto_gen_config, j.testProperties.Test_options.Unit_test)
j.data = android.PathsForModuleSrc(ctx, j.testProperties.Data)
j.extraTestConfigs = android.PathsForModuleSrc(ctx, j.testProperties.Test_options.Extra_test_configs)
ctx.VisitDirectDepsWithTag(dataNativeBinsTag, func(dep android.Module) {
j.data = append(j.data, android.OutputFileForModule(ctx, dep, ""))
})
j.Library.GenerateAndroidBuildActions(ctx)
}
func (j *TestHelperLibrary) GenerateAndroidBuildActions(ctx android.ModuleContext) {
j.Library.GenerateAndroidBuildActions(ctx)
}
func (j *JavaTestImport) GenerateAndroidBuildActions(ctx android.ModuleContext) {
j.testConfig = tradefed.AutoGenJavaTestConfig(ctx, j.prebuiltTestProperties.Test_config, nil,
j.prebuiltTestProperties.Test_suites, nil, nil)
j.Import.GenerateAndroidBuildActions(ctx)
}
type testSdkMemberType struct {
android.SdkMemberTypeBase
}
func (mt *testSdkMemberType) AddDependencies(mctx android.BottomUpMutatorContext, dependencyTag blueprint.DependencyTag, names []string) {
mctx.AddVariationDependencies(nil, dependencyTag, names...)
}
func (mt *testSdkMemberType) IsInstance(module android.Module) bool {
_, ok := module.(*Test)
return ok
}
func (mt *testSdkMemberType) AddPrebuiltModule(ctx android.SdkMemberContext, member android.SdkMember) android.BpModule {
return ctx.SnapshotBuilder().AddPrebuiltModule(member, "java_test_import")
}
func (mt *testSdkMemberType) CreateVariantPropertiesStruct() android.SdkMemberProperties {
return &testSdkMemberProperties{}
}
type testSdkMemberProperties struct {
android.SdkMemberPropertiesBase
JarToExport android.Path
TestConfig android.Path
}
func (p *testSdkMemberProperties) PopulateFromVariant(ctx android.SdkMemberContext, variant android.Module) {
test := variant.(*Test)
implementationJars := test.ImplementationJars()
if len(implementationJars) != 1 {
panic(fmt.Errorf("there must be only one implementation jar from %q", test.Name()))
}
p.JarToExport = implementationJars[0]
p.TestConfig = test.testConfig
}
func (p *testSdkMemberProperties) AddToPropertySet(ctx android.SdkMemberContext, propertySet android.BpPropertySet) {
builder := ctx.SnapshotBuilder()
exportedJar := p.JarToExport
if exportedJar != nil {
snapshotRelativeJavaLibPath := sdkSnapshotFilePathForJar(p.OsPrefix(), ctx.Name())
builder.CopyToSnapshot(exportedJar, snapshotRelativeJavaLibPath)
propertySet.AddProperty("jars", []string{snapshotRelativeJavaLibPath})
}
testConfig := p.TestConfig
if testConfig != nil {
snapshotRelativeTestConfigPath := sdkSnapshotFilePathForMember(p.OsPrefix(), ctx.Name(), testConfigSuffix)
builder.CopyToSnapshot(testConfig, snapshotRelativeTestConfigPath)
propertySet.AddProperty("test_config", snapshotRelativeTestConfigPath)
}
}
// java_test builds a and links sources into a `.jar` file for the device, and possibly for the host as well, and
// creates an `AndroidTest.xml` file to allow running the test with `atest` or a `TEST_MAPPING` file.
//
// By default, a java_test has a single variant that produces a `.jar` file containing `classes.dex` files that were
// compiled against the device bootclasspath.
//
// Specifying `host_supported: true` will produce two variants, one compiled against the device bootclasspath and one
// compiled against the host bootclasspath.
func TestFactory() android.Module {
module := &Test{}
module.addHostAndDeviceProperties()
module.AddProperties(&module.testProperties)
module.Module.properties.Installable = proptools.BoolPtr(true)
module.Module.dexpreopter.isTest = true
module.Module.linter.test = true
InitJavaModule(module, android.HostAndDeviceSupported)
return module
}
// java_test_helper_library creates a java library and makes sure that it is added to the appropriate test suite.
func TestHelperLibraryFactory() android.Module {
module := &TestHelperLibrary{}
module.addHostAndDeviceProperties()
module.AddProperties(&module.testHelperLibraryProperties)
module.Module.properties.Installable = proptools.BoolPtr(true)
module.Module.dexpreopter.isTest = true
module.Module.linter.test = true
InitJavaModule(module, android.HostAndDeviceSupported)
return module
}
// java_test_import imports one or more `.jar` files into the build graph as if they were built by a java_test module
// and makes sure that it is added to the appropriate test suite.
//
// By default, a java_test_import has a single variant that expects a `.jar` file containing `.class` files that were
// compiled against an Android classpath.
//
// Specifying `host_supported: true` will produce two variants, one for use as a dependency of device modules and one
// for host modules.
func JavaTestImportFactory() android.Module {
module := &JavaTestImport{}
module.AddProperties(
&module.Import.properties,
&module.prebuiltTestProperties)
module.Import.properties.Installable = proptools.BoolPtr(true)
android.InitPrebuiltModule(module, &module.properties.Jars)
android.InitApexModule(module)
android.InitSdkAwareModule(module)
InitJavaModule(module, android.HostAndDeviceSupported)
return module
}
// java_test_host builds a and links sources into a `.jar` file for the host, and creates an `AndroidTest.xml` file to
// allow running the test with `atest` or a `TEST_MAPPING` file.
//
// A java_test_host has a single variant that produces a `.jar` file containing `.class` files that were
// compiled against the host bootclasspath.
func TestHostFactory() android.Module {
module := &TestHost{}
module.addHostProperties()
module.AddProperties(&module.testProperties)
module.AddProperties(&module.testHostProperties)
module.Module.properties.Installable = proptools.BoolPtr(true)
InitJavaModuleMultiTargets(module, android.HostSupported)
return module
}
//
// Java Binaries (.jar file plus wrapper script)
//
type binaryProperties struct {
// installable script to execute the resulting jar
Wrapper *string `android:"path"`
// Name of the class containing main to be inserted into the manifest as Main-Class.
Main_class *string
// Names of modules containing JNI libraries that should be installed alongside the host
// variant of the binary.
Jni_libs []string
}
type Binary struct {
Library
binaryProperties binaryProperties
isWrapperVariant bool
wrapperFile android.Path
binaryFile android.InstallPath
}
func (j *Binary) HostToolPath() android.OptionalPath {
return android.OptionalPathForPath(j.binaryFile)
}
func (j *Binary) GenerateAndroidBuildActions(ctx android.ModuleContext) {
if ctx.Arch().ArchType == android.Common {
// Compile the jar
if j.binaryProperties.Main_class != nil {
if j.properties.Manifest != nil {
ctx.PropertyErrorf("main_class", "main_class cannot be used when manifest is set")
}
manifestFile := android.PathForModuleOut(ctx, "manifest.txt")
GenerateMainClassManifest(ctx, manifestFile, String(j.binaryProperties.Main_class))
j.overrideManifest = android.OptionalPathForPath(manifestFile)
}
j.Library.GenerateAndroidBuildActions(ctx)
} else {
// Handle the binary wrapper
j.isWrapperVariant = true
if j.binaryProperties.Wrapper != nil {
j.wrapperFile = android.PathForModuleSrc(ctx, *j.binaryProperties.Wrapper)
} else {
j.wrapperFile = android.PathForSource(ctx, "build/soong/scripts/jar-wrapper.sh")
}
// The host installation rules make the installed wrapper depend on all the dependencies
// of the wrapper variant, which will include the common variant's jar file and any JNI
// libraries. This is verified by TestBinary.
j.binaryFile = ctx.InstallExecutable(android.PathForModuleInstall(ctx, "bin"),
ctx.ModuleName(), j.wrapperFile)
}
}
func (j *Binary) DepsMutator(ctx android.BottomUpMutatorContext) {
if ctx.Arch().ArchType == android.Common || ctx.BazelConversionMode() {
j.deps(ctx)
}
if ctx.Arch().ArchType != android.Common || ctx.BazelConversionMode() {
// These dependencies ensure the host installation rules will install the jar file and
// the jni libraries when the wrapper is installed.
ctx.AddVariationDependencies(nil, jniInstallTag, j.binaryProperties.Jni_libs...)
ctx.AddVariationDependencies(
[]blueprint.Variation{{Mutator: "arch", Variation: android.CommonArch.String()}},
binaryInstallTag, ctx.ModuleName())
}
}
// java_binary builds a `.jar` file and a shell script that executes it for the device, and possibly for the host
// as well.
//
// By default, a java_binary has a single variant that produces a `.jar` file containing `classes.dex` files that were
// compiled against the device bootclasspath.
//
// Specifying `host_supported: true` will produce two variants, one compiled against the device bootclasspath and one
// compiled against the host bootclasspath.
func BinaryFactory() android.Module {
module := &Binary{}
module.addHostAndDeviceProperties()
module.AddProperties(&module.binaryProperties)
module.Module.properties.Installable = proptools.BoolPtr(true)
android.InitAndroidArchModule(module, android.HostAndDeviceSupported, android.MultilibCommonFirst)
android.InitDefaultableModule(module)
return module
}
// java_binary_host builds a `.jar` file and a shell script that executes it for the host.
//
// A java_binary_host has a single variant that produces a `.jar` file containing `.class` files that were
// compiled against the host bootclasspath.
func BinaryHostFactory() android.Module {
module := &Binary{}
module.addHostProperties()
module.AddProperties(&module.binaryProperties)
module.Module.properties.Installable = proptools.BoolPtr(true)
android.InitAndroidArchModule(module, android.HostSupported, android.MultilibCommonFirst)
android.InitDefaultableModule(module)
return module
}
//
// Java prebuilts
//
type ImportProperties struct {
Jars []string `android:"path,arch_variant"`
Sdk_version *string
Installable *bool
// List of shared java libs that this module has dependencies to
Libs []string
// List of files to remove from the jar file(s)
Exclude_files []string
// List of directories to remove from the jar file(s)
Exclude_dirs []string
// if set to true, run Jetifier against .jar file. Defaults to false.
Jetifier *bool
// set the name of the output
Stem *string
Aidl struct {
// directories that should be added as include directories for any aidl sources of modules
// that depend on this module, as well as to aidl for this module.
Export_include_dirs []string
}
}
type Import struct {
android.ModuleBase
android.DefaultableModuleBase
android.ApexModuleBase
prebuilt android.Prebuilt
android.SdkBase
// Functionality common to Module and Import.
embeddableInModuleAndImport
hiddenAPI
dexer
dexpreopter
properties ImportProperties
// output file containing classes.dex and resources
dexJarFile android.Path
combinedClasspathFile android.Path
classLoaderContexts dexpreopt.ClassLoaderContextMap
exportAidlIncludeDirs android.Paths
hideApexVariantFromMake bool
}
func (j *Import) sdkVersion() sdkSpec {
return sdkSpecFrom(String(j.properties.Sdk_version))
}
func (j *Import) makeSdkVersion() string {
return j.sdkVersion().raw
}
func (j *Import) systemModules() string {
return "none"
}
func (j *Import) minSdkVersion() sdkSpec {
return j.sdkVersion()
}
func (j *Import) targetSdkVersion() sdkSpec {
return j.sdkVersion()
}
func (j *Import) MinSdkVersion() string {
return j.minSdkVersion().version.String()
}
func (j *Import) Prebuilt() *android.Prebuilt {
return &j.prebuilt
}
func (j *Import) PrebuiltSrcs() []string {
return j.properties.Jars
}
func (j *Import) Name() string {
return j.prebuilt.Name(j.ModuleBase.Name())
}
func (j *Import) Stem() string {
return proptools.StringDefault(j.properties.Stem, j.ModuleBase.Name())
}
func (a *Import) JacocoReportClassesFile() android.Path {
return nil
}
func (j *Import) LintDepSets() LintDepSets {
return LintDepSets{}
}
func (j *Import) DepsMutator(ctx android.BottomUpMutatorContext) {
ctx.AddVariationDependencies(nil, libTag, j.properties.Libs...)
if ctx.Device() && Bool(j.dexProperties.Compile_dex) {
sdkDeps(ctx, sdkContext(j), j.dexer)
}
}
func (j *Import) GenerateAndroidBuildActions(ctx android.ModuleContext) {
// Initialize the hiddenapi structure.
j.initHiddenAPI(ctx, j.BaseModuleName())
if !ctx.Provider(android.ApexInfoProvider).(android.ApexInfo).IsForPlatform() {
j.hideApexVariantFromMake = true
}
jars := android.PathsForModuleSrc(ctx, j.properties.Jars)
jarName := j.Stem() + ".jar"
outputFile := android.PathForModuleOut(ctx, "combined", jarName)
TransformJarsToJar(ctx, outputFile, "for prebuilts", jars, android.OptionalPath{},
false, j.properties.Exclude_files, j.properties.Exclude_dirs)
if Bool(j.properties.Jetifier) {
inputFile := outputFile
outputFile = android.PathForModuleOut(ctx, "jetifier", jarName)
TransformJetifier(ctx, outputFile, inputFile)
}
j.combinedClasspathFile = outputFile
j.classLoaderContexts = make(dexpreopt.ClassLoaderContextMap)
Improve tracking of exported sdk libraries The build tracks the java_sdk_library/_import modules that are referenced by libraries so that it can ensure that any Android app that includes code that depends on one of those modules has the appropriate <uses-library> entry in their manifest. Unfortunately, there were a couple of issues with that: 1) It only tracks direct references to the java_sdk_library module itself, e.g. android.test.mock. Direct references to the stubs module, e.g. android.test.mock.stubs were not tracked. Making it possible for Android apps to reference libraries which would not be available at runtime. 2) The logic for determining whether something was a java_sdk_library was repeated in a number of places making it difficult to allow java_sdk_library/_import instances to determine whether they should be treated as an Android shared library. 3) It tracks (and could use) even those java_sdk_library instances which do not represent a shared library, e.g. the ones that set api_only: true. While this change will simplifty fixing that the actual issue will be fixed in a follow up change. Changes: * Added EmbeddableSdkLibraryComponent and embedded it into java_sdk_library/_import, java_library and java_import. It provides the common code to minimize duplication. It contains an SdkLibraryToImplicitlyTrack field that if set will cause any references to the containing module to add the SdkLibraryParent to the list of implicit sdk libraries being tracked. * Changed code that assumed that anything that implemented SdkLibraryDependency required tracking to use the OptionalImplicitSdkLibrary() method to get the optional name of the sdk library to track. That will allow a follow up change to return nil from that method to exclude an sdk library from being tracked. * Moved SdkLibraryDependency from java.go to sdk_library.go as that is a better place for it to be. * Changed the stubs java_library/java_import creation code to initialize the SdkLibraryToImplicitlyTrack field with the name of the creating module. * Initialized the SdkLibraryToImplicitlyTrack field in the java_sdk_library/_import so that direct references to them will be tracked too. * Added tests to verify that direct access to the .stubs child of both java_sdk_library and java_sdk_library_import are tracked properly. Test: atest CtsProviderTestCases - which relies on android.test.mock being implicitly tracked to verify that I had not broken anything. Used aapt2 dump badging to read the manifest. m nothing - to run the new tests which failed before fixing the code. Bug: 156723295 Change-Id: Ia99def91e9b74d2ed0a777de04b476c00ea0393d
2020-05-15 17:20:31 +08:00
var flags javaBuilderFlags
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
var deapexerModule android.Module
ctx.VisitDirectDeps(func(module android.Module) {
tag := ctx.OtherModuleDependencyTag(module)
switch dep := module.(type) {
case Dependency:
switch tag {
case libTag, staticLibTag:
flags.classpath = append(flags.classpath, dep.HeaderJars()...)
case bootClasspathTag:
flags.bootClasspath = append(flags.bootClasspath, dep.HeaderJars()...)
}
case SdkLibraryDependency:
switch tag {
case libTag:
flags.classpath = append(flags.classpath, dep.SdkHeaderJars(ctx, j.sdkVersion())...)
}
}
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
addCLCFromDep(ctx, module, j.classLoaderContexts)
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
// Save away the `deapexer` module on which this depends, if any.
if tag == android.DeapexerTag {
deapexerModule = module
}
})
if Bool(j.properties.Installable) {
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
ctx.InstallFile(android.PathForModuleInstall(ctx, "framework"),
jarName, outputFile)
}
j.exportAidlIncludeDirs = android.PathsForModuleSrc(ctx, j.properties.Aidl.Export_include_dirs)
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
if ctx.Device() {
configurationName := j.BaseModuleName()
primary := j.Prebuilt().UsePrebuilt()
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
// If this is a variant created for a prebuilt_apex then use the dex implementation jar
// obtained from the associated deapexer module.
ai := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)
if ai.ForPrebuiltApex {
if deapexerModule == nil {
// This should never happen as a variant for a prebuilt_apex is only created if the
// deapxer module has been configured to export the dex implementation jar for this module.
ctx.ModuleErrorf("internal error: module %q does not depend on a `deapexer` module for prebuilt_apex %q",
j.Name(), ai.ApexVariationName)
}
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
// Get the path of the dex implementation jar from the `deapexer` module.
di := ctx.OtherModuleProvider(deapexerModule, android.DeapexerProvider).(android.DeapexerInfo)
if dexOutputPath := di.PrebuiltExportPath(j.BaseModuleName(), ".dexjar"); dexOutputPath != nil {
j.dexJarFile = dexOutputPath
j.hiddenAPI.hiddenAPIExtractInformation(ctx, dexOutputPath, outputFile, primary)
} else {
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
// This should never happen as a variant for a prebuilt_apex is only created if the
// prebuilt_apex has been configured to export the java library dex file.
ctx.ModuleErrorf("internal error: no dex implementation jar available from prebuilt_apex %q", deapexerModule.Name())
}
} else if Bool(j.dexProperties.Compile_dex) {
sdkDep := decodeSdkDep(ctx, sdkContext(j))
if sdkDep.invalidVersion {
ctx.AddMissingDependencies(sdkDep.bootclasspath)
ctx.AddMissingDependencies(sdkDep.java9Classpath)
} else if sdkDep.useFiles {
// sdkDep.jar is actually equivalent to turbine header.jar.
flags.classpath = append(flags.classpath, sdkDep.jars...)
}
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
// Dex compilation
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
j.dexpreopter.installPath = android.PathForModuleInstall(ctx, "framework", jarName)
if j.dexProperties.Uncompress_dex == nil {
// If the value was not force-set by the user, use reasonable default based on the module.
j.dexProperties.Uncompress_dex = proptools.BoolPtr(shouldUncompressDex(ctx, &j.dexpreopter))
}
j.dexpreopter.uncompressedDex = *j.dexProperties.Uncompress_dex
var dexOutputFile android.OutputPath
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
dexOutputFile = j.dexer.compileDex(ctx, flags, j.minSdkVersion(), outputFile, jarName)
if ctx.Failed() {
return
}
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
// Hidden API CSV generation and dex encoding
dexOutputFile = j.hiddenAPIExtractAndEncode(ctx, configurationName, primary, dexOutputFile, outputFile,
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
proptools.Bool(j.dexProperties.Uncompress_dex))
j.dexJarFile = dexOutputFile
}
}
}
func (j *Import) OutputFiles(tag string) (android.Paths, error) {
switch tag {
case "", ".jar":
return android.Paths{j.combinedClasspathFile}, nil
default:
return nil, fmt.Errorf("unsupported module reference tag %q", tag)
}
}
var _ android.OutputFileProducer = (*Import)(nil)
var _ Dependency = (*Import)(nil)
func (j *Import) HeaderJars() android.Paths {
if j.combinedClasspathFile == nil {
return nil
}
return android.Paths{j.combinedClasspathFile}
}
func (j *Import) ImplementationJars() android.Paths {
if j.combinedClasspathFile == nil {
return nil
}
return android.Paths{j.combinedClasspathFile}
}
func (j *Import) ResourceJars() android.Paths {
return nil
}
func (j *Import) ImplementationAndResourcesJars() android.Paths {
if j.combinedClasspathFile == nil {
return nil
}
return android.Paths{j.combinedClasspathFile}
}
func (j *Import) DexJarBuildPath() android.Path {
return j.dexJarFile
}
func (j *Import) DexJarInstallPath() android.Path {
return nil
}
func (j *Import) AidlIncludeDirs() android.Paths {
return j.exportAidlIncludeDirs
}
func (j *Import) ClassLoaderContexts() dexpreopt.ClassLoaderContextMap {
return j.classLoaderContexts
}
func (j *Import) ExportedPlugins() (android.Paths, []string, bool) {
return nil, nil, false
}
func (j *Import) SrcJarArgs() ([]string, android.Paths) {
return nil, nil
}
var _ android.ApexModule = (*Import)(nil)
// Implements android.ApexModule
apex_available tracks static dependencies This change fixes a bug that apex_available is not enforced for static dependencies. For example, a module with 'apex_available: ["//apex_available:platform"]' was able to be statically linked to any APEX. This was happening because the check was done on the modules that are actually installed to an APEX. Static dependencies of the modules were not counted as they are not installed to the APEX as files. Fixing this bug by doing the check by traversing the tree in the method checkApexAvailability. This change includes a few number of related changes: 1) DepIsInSameApex implementation for cc.Module was changed as well. Previuosly, it returned false only when the dependency is actually a stub variant of a lib. Now, it returns false when the dependency has one or more stub variants. To understand why, we need to recall that when there is a dependency to a lib having stubs, we actually create two dependencies: to the non-stub variant and to the stub variant during the DepsMutator phase. And later in the build action generation phase, we choose one of them depending on the context. Also recall that an APEX variant is created only when DepIsInSameApex returns true. Given these, with the previous implementatin of DepIsInSameApex, we did create apex variants of the non-stub variant of the dependency, while not creating the apex variant for the stub variant. This is not right; we needlessly created the apex variant. The extra apex variant has caused no harm so far, but since the apex_available check became more correct, it actually breaks the build. To fix the issue, we stop creating the APEX variant both for non-stub and stub variants. 2) platform variant is created regardless of the apex_available value. This is required for the case when a library X that provides stub is in an APEX A and is configured to be available only for A. In that case, libs in other APEX can't use the stub library since the stub library is mutated only for apex A. By creating the platform variant for the stub library, it can be used from outside as the default dependency variation is set to the platform variant when creating the APEX variations. 3) The ApexAvailableWhitelist is added with the dependencies that were revealed with this change. Exempt-From-Owner-Approval: cherry-pick from internal Bug: 147671264 Test: m Merged-In: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e (cherry picked from commit fa89944c79f19552e906b41fd03a4981903eee7e) Change-Id: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e
2020-01-31 01:49:53 +08:00
func (j *Import) DepIsInSameApex(ctx android.BaseModuleContext, dep android.Module) bool {
return j.depIsInSameApex(ctx, dep)
apex_available tracks static dependencies This change fixes a bug that apex_available is not enforced for static dependencies. For example, a module with 'apex_available: ["//apex_available:platform"]' was able to be statically linked to any APEX. This was happening because the check was done on the modules that are actually installed to an APEX. Static dependencies of the modules were not counted as they are not installed to the APEX as files. Fixing this bug by doing the check by traversing the tree in the method checkApexAvailability. This change includes a few number of related changes: 1) DepIsInSameApex implementation for cc.Module was changed as well. Previuosly, it returned false only when the dependency is actually a stub variant of a lib. Now, it returns false when the dependency has one or more stub variants. To understand why, we need to recall that when there is a dependency to a lib having stubs, we actually create two dependencies: to the non-stub variant and to the stub variant during the DepsMutator phase. And later in the build action generation phase, we choose one of them depending on the context. Also recall that an APEX variant is created only when DepIsInSameApex returns true. Given these, with the previous implementatin of DepIsInSameApex, we did create apex variants of the non-stub variant of the dependency, while not creating the apex variant for the stub variant. This is not right; we needlessly created the apex variant. The extra apex variant has caused no harm so far, but since the apex_available check became more correct, it actually breaks the build. To fix the issue, we stop creating the APEX variant both for non-stub and stub variants. 2) platform variant is created regardless of the apex_available value. This is required for the case when a library X that provides stub is in an APEX A and is configured to be available only for A. In that case, libs in other APEX can't use the stub library since the stub library is mutated only for apex A. By creating the platform variant for the stub library, it can be used from outside as the default dependency variation is set to the platform variant when creating the APEX variations. 3) The ApexAvailableWhitelist is added with the dependencies that were revealed with this change. Exempt-From-Owner-Approval: cherry-pick from internal Bug: 147671264 Test: m Merged-In: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e (cherry picked from commit fa89944c79f19552e906b41fd03a4981903eee7e) Change-Id: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e
2020-01-31 01:49:53 +08:00
}
// Implements android.ApexModule
func (j *Import) ShouldSupportSdkVersion(ctx android.BaseModuleContext,
sdkVersion android.ApiLevel) error {
// Do not check for prebuilts against the min_sdk_version of enclosing APEX
return nil
}
// Add compile time check for interface implementation
var _ android.IDEInfo = (*Import)(nil)
var _ android.IDECustomizedModuleName = (*Import)(nil)
// Collect information for opening IDE project files in java/jdeps.go.
const (
removedPrefix = "prebuilt_"
)
func (j *Import) IDEInfo(dpInfo *android.IdeInfo) {
dpInfo.Jars = append(dpInfo.Jars, j.PrebuiltSrcs()...)
}
func (j *Import) IDECustomizedModuleName() string {
// TODO(b/113562217): Extract the base module name from the Import name, often the Import name
// has a prefix "prebuilt_". Remove the prefix explicitly if needed until we find a better
// solution to get the Import name.
name := j.Name()
if strings.HasPrefix(name, removedPrefix) {
name = strings.TrimPrefix(name, removedPrefix)
}
return name
}
var _ android.PrebuiltInterface = (*Import)(nil)
func (j *Import) IsInstallable() bool {
return Bool(j.properties.Installable)
}
var _ dexpreopterInterface = (*Import)(nil)
// java_import imports one or more `.jar` files into the build graph as if they were built by a java_library module.
//
// By default, a java_import has a single variant that expects a `.jar` file containing `.class` files that were
// compiled against an Android classpath.
//
// Specifying `host_supported: true` will produce two variants, one for use as a dependency of device modules and one
// for host modules.
func ImportFactory() android.Module {
module := &Import{}
module.AddProperties(
&module.properties,
&module.dexer.dexProperties,
)
Improve tracking of exported sdk libraries The build tracks the java_sdk_library/_import modules that are referenced by libraries so that it can ensure that any Android app that includes code that depends on one of those modules has the appropriate <uses-library> entry in their manifest. Unfortunately, there were a couple of issues with that: 1) It only tracks direct references to the java_sdk_library module itself, e.g. android.test.mock. Direct references to the stubs module, e.g. android.test.mock.stubs were not tracked. Making it possible for Android apps to reference libraries which would not be available at runtime. 2) The logic for determining whether something was a java_sdk_library was repeated in a number of places making it difficult to allow java_sdk_library/_import instances to determine whether they should be treated as an Android shared library. 3) It tracks (and could use) even those java_sdk_library instances which do not represent a shared library, e.g. the ones that set api_only: true. While this change will simplifty fixing that the actual issue will be fixed in a follow up change. Changes: * Added EmbeddableSdkLibraryComponent and embedded it into java_sdk_library/_import, java_library and java_import. It provides the common code to minimize duplication. It contains an SdkLibraryToImplicitlyTrack field that if set will cause any references to the containing module to add the SdkLibraryParent to the list of implicit sdk libraries being tracked. * Changed code that assumed that anything that implemented SdkLibraryDependency required tracking to use the OptionalImplicitSdkLibrary() method to get the optional name of the sdk library to track. That will allow a follow up change to return nil from that method to exclude an sdk library from being tracked. * Moved SdkLibraryDependency from java.go to sdk_library.go as that is a better place for it to be. * Changed the stubs java_library/java_import creation code to initialize the SdkLibraryToImplicitlyTrack field with the name of the creating module. * Initialized the SdkLibraryToImplicitlyTrack field in the java_sdk_library/_import so that direct references to them will be tracked too. * Added tests to verify that direct access to the .stubs child of both java_sdk_library and java_sdk_library_import are tracked properly. Test: atest CtsProviderTestCases - which relies on android.test.mock being implicitly tracked to verify that I had not broken anything. Used aapt2 dump badging to read the manifest. m nothing - to run the new tests which failed before fixing the code. Bug: 156723295 Change-Id: Ia99def91e9b74d2ed0a777de04b476c00ea0393d
2020-05-15 17:20:31 +08:00
module.initModuleAndImport(&module.ModuleBase)
module.dexProperties.Optimize.EnabledByDefault = false
android.InitPrebuiltModule(module, &module.properties.Jars)
android.InitApexModule(module)
android.InitSdkAwareModule(module)
InitJavaModule(module, android.HostAndDeviceSupported)
return module
}
// java_import imports one or more `.jar` files into the build graph as if they were built by a java_library_host
// module.
//
// A java_import_host has a single variant that expects a `.jar` file containing `.class` files that were
// compiled against a host bootclasspath.
func ImportFactoryHost() android.Module {
module := &Import{}
module.AddProperties(&module.properties)
android.InitPrebuiltModule(module, &module.properties.Jars)
android.InitApexModule(module)
InitJavaModule(module, android.HostSupported)
return module
}
// dex_import module
type DexImportProperties struct {
Jars []string `android:"path"`
// set the name of the output
Stem *string
}
type DexImport struct {
android.ModuleBase
android.DefaultableModuleBase
android.ApexModuleBase
prebuilt android.Prebuilt
properties DexImportProperties
dexJarFile android.Path
maybeStrippedDexJarFile android.Path
dexpreopter
hideApexVariantFromMake bool
}
func (j *DexImport) Prebuilt() *android.Prebuilt {
return &j.prebuilt
}
func (j *DexImport) PrebuiltSrcs() []string {
return j.properties.Jars
}
func (j *DexImport) Name() string {
return j.prebuilt.Name(j.ModuleBase.Name())
}
func (j *DexImport) Stem() string {
return proptools.StringDefault(j.properties.Stem, j.ModuleBase.Name())
}
func (a *DexImport) JacocoReportClassesFile() android.Path {
return nil
}
func (a *DexImport) LintDepSets() LintDepSets {
return LintDepSets{}
}
func (j *DexImport) IsInstallable() bool {
return true
}
func (j *DexImport) GenerateAndroidBuildActions(ctx android.ModuleContext) {
if len(j.properties.Jars) != 1 {
ctx.PropertyErrorf("jars", "exactly one jar must be provided")
}
apexInfo := ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)
if !apexInfo.IsForPlatform() {
j.hideApexVariantFromMake = true
}
j.dexpreopter.installPath = android.PathForModuleInstall(ctx, "framework", j.Stem()+".jar")
j.dexpreopter.uncompressedDex = shouldUncompressDex(ctx, &j.dexpreopter)
inputJar := ctx.ExpandSource(j.properties.Jars[0], "jars")
dexOutputFile := android.PathForModuleOut(ctx, ctx.ModuleName()+".jar")
if j.dexpreopter.uncompressedDex {
rule := android.NewRuleBuilder(pctx, ctx)
temporary := android.PathForModuleOut(ctx, ctx.ModuleName()+".jar.unaligned")
rule.Temporary(temporary)
// use zip2zip to uncompress classes*.dex files
rule.Command().
BuiltTool("zip2zip").
FlagWithInput("-i ", inputJar).
FlagWithOutput("-o ", temporary).
FlagWithArg("-0 ", "'classes*.dex'")
// use zipalign to align uncompressed classes*.dex files
rule.Command().
BuiltTool("zipalign").
Flag("-f").
Text("4").
Input(temporary).
Output(dexOutputFile)
rule.DeleteTemporaryFiles()
rule.Build("uncompress_dex", "uncompress dex")
} else {
ctx.Build(pctx, android.BuildParams{
Rule: android.Cp,
Input: inputJar,
Output: dexOutputFile,
})
}
j.dexJarFile = dexOutputFile
j.dexpreopt(ctx, dexOutputFile)
j.maybeStrippedDexJarFile = dexOutputFile
if apexInfo.IsForPlatform() {
ctx.InstallFile(android.PathForModuleInstall(ctx, "framework"),
j.Stem()+".jar", dexOutputFile)
}
}
func (j *DexImport) DexJarBuildPath() android.Path {
return j.dexJarFile
}
var _ android.ApexModule = (*DexImport)(nil)
// Implements android.ApexModule
func (j *DexImport) ShouldSupportSdkVersion(ctx android.BaseModuleContext,
sdkVersion android.ApiLevel) error {
// we don't check prebuilt modules for sdk_version
return nil
}
// dex_import imports a `.jar` file containing classes.dex files.
//
// A dex_import module cannot be used as a dependency of a java_* or android_* module, it can only be installed
// to the device.
func DexImportFactory() android.Module {
module := &DexImport{}
module.AddProperties(&module.properties)
android.InitPrebuiltModule(module, &module.properties.Jars)
android.InitApexModule(module)
InitJavaModule(module, android.DeviceSupported)
return module
}
//
// Defaults
//
type Defaults struct {
android.ModuleBase
android.DefaultsModuleBase
android.ApexModuleBase
}
// java_defaults provides a set of properties that can be inherited by other java or android modules.
//
// A module can use the properties from a java_defaults module using `defaults: ["defaults_module_name"]`. Each
// property in the defaults module that exists in the depending module will be prepended to the depending module's
// value for that property.
//
// Example:
//
// java_defaults {
// name: "example_defaults",
// srcs: ["common/**/*.java"],
// javacflags: ["-Xlint:all"],
// aaptflags: ["--auto-add-overlay"],
// }
//
// java_library {
// name: "example",
// defaults: ["example_defaults"],
// srcs: ["example/**/*.java"],
// }
//
// is functionally identical to:
//
// java_library {
// name: "example",
// srcs: [
// "common/**/*.java",
// "example/**/*.java",
// ],
// javacflags: ["-Xlint:all"],
// }
func defaultsFactory() android.Module {
return DefaultsFactory()
}
func DefaultsFactory() android.Module {
module := &Defaults{}
module.AddProperties(
&CompilerProperties{},
&CompilerDeviceProperties{},
&DexProperties{},
&DexpreoptProperties{},
&android.ProtoProperties{},
&aaptProperties{},
&androidLibraryProperties{},
&appProperties{},
&appTestProperties{},
&overridableAppProperties{},
&testProperties{},
&ImportProperties{},
&AARImportProperties{},
&sdkLibraryProperties{},
&commonToSdkLibraryAndImportProperties{},
&DexImportProperties{},
&android.ApexProperties{},
&RuntimeResourceOverlayProperties{},
&LintProperties{},
&appTestHelperAppProperties{},
)
android.InitDefaultsModule(module)
return module
}
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 08:49:08 +08:00
func kytheExtractJavaFactory() android.Singleton {
return &kytheExtractJavaSingleton{}
}
type kytheExtractJavaSingleton struct {
}
func (ks *kytheExtractJavaSingleton) GenerateBuildActions(ctx android.SingletonContext) {
var xrefTargets android.Paths
ctx.VisitAllModules(func(module android.Module) {
if javaModule, ok := module.(xref); ok {
xrefTargets = append(xrefTargets, javaModule.XrefJavaFiles()...)
}
})
// TODO(asmundak): perhaps emit a rule to output a warning if there were no xrefTargets
if len(xrefTargets) > 0 {
ctx.Phony("xref_java", xrefTargets...)
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 08:49:08 +08:00
}
}
var Bool = proptools.Bool
var BoolDefault = proptools.BoolDefault
var String = proptools.String
var inList = android.InList
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
// TODO(b/132357300) Generalize SdkLibrarComponentDependency to non-SDK libraries and merge with
// this interface.
type ProvidesUsesLib interface {
ProvidesUsesLib() *string
}
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
func (j *Module) ProvidesUsesLib() *string {
return j.usesLibraryProperties.Provides_uses_lib
}
// Add class loader context (CLC) of a given dependency to the current CLC.
func addCLCFromDep(ctx android.ModuleContext, depModule android.Module,
clcMap dexpreopt.ClassLoaderContextMap) {
dep, ok := depModule.(UsesLibraryDependency)
if !ok {
return
}
// Find out if the dependency is either an SDK library or an ordinary library that is disguised
// as an SDK library by the means of `provides_uses_lib` property. If yes, the library is itself
// a <uses-library> and should be added as a node in the CLC tree, and its CLC should be added
// as subtree of that node. Otherwise the library is not a <uses_library> and should not be
// added to CLC, but the transitive <uses-library> dependencies from its CLC should be added to
// the current CLC.
var implicitSdkLib *string
comp, isComp := depModule.(SdkLibraryComponentDependency)
if isComp {
implicitSdkLib = comp.OptionalImplicitSdkLibrary()
// OptionalImplicitSdkLibrary() may be nil so need to fall through to ProvidesUsesLib().
}
if implicitSdkLib == nil {
if ulib, ok := depModule.(ProvidesUsesLib); ok {
implicitSdkLib = ulib.ProvidesUsesLib()
}
}
depTag := ctx.OtherModuleDependencyTag(depModule)
if depTag == libTag || depTag == usesLibTag {
// Ok, propagate <uses-library> through non-static library dependencies.
} else if depTag == staticLibTag {
// Propagate <uses-library> through static library dependencies, unless it is a component
// library (such as stubs). Component libraries have a dependency on their SDK library,
// which should not be pulled just because of a static component library.
if implicitSdkLib != nil {
return
}
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
} else {
// Don't propagate <uses-library> for other dependency tags.
return
}
if implicitSdkLib != nil {
clcMap.AddContext(ctx, dexpreopt.AnySdkVersion, *implicitSdkLib,
Unify addition of class loader subcontext from dependencies. Previously CLC construction was scattered across different module types and dependency tags. This CL moves all logic to one function, which handles all special cases. This will allow to simplify CLC API and reduce the number of different ways in which CLC is constructed. Previously some of the cases failed early (at the time when a library is added to CLC) if the build/install paths were unknown. Other cases did not fail early, but were validated later before CLC was used. Late failures are necessary because some of the libraries with unknown paths still have to be processed by manifest_fixer (which doesn't need library paths), but they do not use dexpreopt (which needs library paths). This CL removes the early failures (all paths are still validated later). The CLC tests do not fail because they use a private method that toggles the "strict" flag (that enforces early/late failure mode) manually in the method call. The CL also makes a functional change in the way CLC is constructed for component libraries that have an OptionalImplicitSdkLibrary(), or libraries that are disguised as SDK libraries via `provides_uses_lib`. Previously such a component/disguised library X was added to its own CLC as a sibling element of X's own <uses-library> dependencies, which created incorrect CLC structure. Now this is handled by addCLCFromDep, when X is processed as dependency and added as a top-level CLC element with its sub-CLC properly nested under it. Bug: 132357300 Test: lunch aosp_cf_x86_phone-userdebug && m Change-Id: I6a512209b87b81d785875f10f76b21c81b2ed579
2020-12-17 00:16:11 +08:00
dep.DexJarBuildPath(), dep.DexJarInstallPath(), dep.ClassLoaderContexts())
} else {
depName := ctx.OtherModuleName(depModule)
clcMap.AddContextMap(dep.ClassLoaderContexts(), depName)
}
}