platform_build_soong/cc/cc.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 cc
// This file contains the module types for compiling C/C++ for Android, and converts the properties
// into the flags and filenames necessary to pass to the compiler. The final creation of the rules
// is handled in builder.go
import (
"fmt"
"io"
"strconv"
"strings"
"github.com/google/blueprint"
"github.com/google/blueprint/proptools"
"android/soong/android"
"android/soong/cc/config"
"android/soong/genrule"
)
func init() {
android.RegisterModuleType("cc_defaults", defaultsFactory)
android.PreDepsMutators(func(ctx android.RegisterMutatorsContext) {
ctx.BottomUp("vndk", VndkMutator).Parallel()
ctx.BottomUp("image", ImageMutator).Parallel()
ctx.BottomUp("link", LinkageMutator).Parallel()
ctx.BottomUp("ndk_api", ndkApiMutator).Parallel()
ctx.BottomUp("test_per_src", TestPerSrcMutator).Parallel()
ctx.BottomUp("version", VersionMutator).Parallel()
ctx.BottomUp("begin", BeginMutator).Parallel()
ctx.BottomUp("sysprop", SyspropMutator).Parallel()
})
android.PostDepsMutators(func(ctx android.RegisterMutatorsContext) {
ctx.TopDown("asan_deps", sanitizerDepsMutator(asan))
ctx.BottomUp("asan", sanitizerMutator(asan)).Parallel()
ctx.TopDown("hwasan_deps", sanitizerDepsMutator(hwasan))
ctx.BottomUp("hwasan", sanitizerMutator(hwasan)).Parallel()
ctx.TopDown("fuzzer_deps", sanitizerDepsMutator(fuzzer))
ctx.BottomUp("fuzzer", sanitizerMutator(fuzzer)).Parallel()
// cfi mutator shouldn't run before sanitizers that return true for
// incompatibleWithCfi()
ctx.TopDown("cfi_deps", sanitizerDepsMutator(cfi))
ctx.BottomUp("cfi", sanitizerMutator(cfi)).Parallel()
ctx.TopDown("scs_deps", sanitizerDepsMutator(scs))
ctx.BottomUp("scs", sanitizerMutator(scs)).Parallel()
ctx.TopDown("tsan_deps", sanitizerDepsMutator(tsan))
ctx.BottomUp("tsan", sanitizerMutator(tsan)).Parallel()
ctx.TopDown("sanitize_runtime_deps", sanitizerRuntimeDepsMutator).Parallel()
ctx.BottomUp("sanitize_runtime", sanitizerRuntimeMutator).Parallel()
ctx.BottomUp("coverage", coverageMutator).Parallel()
ctx.TopDown("vndk_deps", sabiDepsMutator)
ctx.TopDown("lto_deps", ltoDepsMutator)
ctx.BottomUp("lto", ltoMutator).Parallel()
ctx.TopDown("double_loadable", checkDoubleLoadableLibraries).Parallel()
})
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
android.RegisterSingletonType("kythe_extract_all", kytheExtractAllFactory)
pctx.Import("android/soong/cc/config")
}
type Deps struct {
SharedLibs, LateSharedLibs []string
StaticLibs, LateStaticLibs, WholeStaticLibs []string
HeaderLibs []string
RuntimeLibs []string
ReexportSharedLibHeaders, ReexportStaticLibHeaders, ReexportHeaderLibHeaders []string
ObjFiles []string
GeneratedSources []string
GeneratedHeaders []string
ReexportGeneratedHeaders []string
CrtBegin, CrtEnd string
// Used for host bionic
LinkerFlagsFile string
DynamicLinker string
}
type PathDeps struct {
// Paths to .so files
SharedLibs, EarlySharedLibs, LateSharedLibs android.Paths
// Paths to the dependencies to use for .so files (.so.toc files)
SharedLibsDeps, EarlySharedLibsDeps, LateSharedLibsDeps android.Paths
// Paths to .a files
StaticLibs, LateStaticLibs, WholeStaticLibs android.Paths
// Paths to .o files
Objs Objects
StaticLibObjs Objects
WholeStaticLibObjs Objects
// Paths to generated source files
GeneratedSources android.Paths
GeneratedHeaders android.Paths
Flags []string
IncludeDirs android.Paths
SystemIncludeDirs android.Paths
ReexportedDirs android.Paths
ReexportedSystemDirs android.Paths
ReexportedFlags []string
ReexportedDeps android.Paths
// Paths to crt*.o files
CrtBegin, CrtEnd android.OptionalPath
// Path to the file container flags to use with the linker
LinkerFlagsFile android.OptionalPath
// Path to the dynamic linker binary
DynamicLinker android.OptionalPath
}
type Flags struct {
GlobalFlags []string // Flags that apply to C, C++, and assembly source files
ArFlags []string // Flags that apply to ar
AsFlags []string // Flags that apply to assembly source files
CFlags []string // Flags that apply to C and C++ source files
ToolingCFlags []string // Flags that apply to C and C++ source files parsed by clang LibTooling tools
ConlyFlags []string // Flags that apply to C source files
CppFlags []string // Flags that apply to C++ source files
ToolingCppFlags []string // Flags that apply to C++ source files parsed by clang LibTooling tools
aidlFlags []string // Flags that apply to aidl source files
rsFlags []string // Flags that apply to renderscript source files
LdFlags []string // Flags that apply to linker command lines
libFlags []string // Flags to add libraries early to the link order
extraLibFlags []string // Flags to add libraries late in the link order after LdFlags
TidyFlags []string // Flags that apply to clang-tidy
SAbiFlags []string // Flags that apply to header-abi-dumper
YasmFlags []string // Flags that apply to yasm assembly source files
// Global include flags that apply to C, C++, and assembly source files
// These must be after any module include flags, which will be in GlobalFlags.
SystemIncludeFlags []string
Toolchain config.Toolchain
Tidy bool
Coverage bool
SAbiDump bool
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
EmitXrefs bool // If true, generate Ninja rules to generate emitXrefs input files for Kythe
RequiredInstructionSet string
DynamicLinker string
CFlagsDeps android.Paths // Files depended on by compiler flags
LdFlagsDeps android.Paths // Files depended on by linker flags
AssemblerWithCpp bool
GroupStaticLibs bool
proto android.ProtoFlags
protoC bool // Whether to use C instead of C++
protoOptionsFile bool // Whether to look for a .options file next to the .proto
Yacc *YaccProperties
}
// Properties used to compile all C or C++ modules
type BaseProperties struct {
// Deprecated. true is the default, false is invalid.
Clang *bool `android:"arch_variant"`
// Minimum sdk version supported when compiling against the ndk
Sdk_version *string
AndroidMkSharedLibs []string `blueprint:"mutated"`
AndroidMkStaticLibs []string `blueprint:"mutated"`
AndroidMkRuntimeLibs []string `blueprint:"mutated"`
AndroidMkWholeStaticLibs []string `blueprint:"mutated"`
HideFromMake bool `blueprint:"mutated"`
PreventInstall bool `blueprint:"mutated"`
ApexesProvidingSharedLibs []string `blueprint:"mutated"`
VndkVersion string `blueprint:"mutated"`
SubName string `blueprint:"mutated"`
// *.logtags files, to combine together in order to generate the /system/etc/event-log-tags
// file
Logtags []string
// Make this module available when building for recovery
Recovery_available *bool
InRecovery bool `blueprint:"mutated"`
// Allows this module to use non-APEX version of libraries. Useful
// for building binaries that are started before APEXes are activated.
Bootstrap *bool
// Even if DeviceConfig().VndkUseCoreVariant() is set, this module must use vendor variant.
// see soong/cc/config/vndk.go
MustUseVendorVariant bool `blueprint:"mutated"`
}
type VendorProperties struct {
// whether this module should be allowed to be directly depended by other
// modules with `vendor: true`, `proprietary: true`, or `vendor_available:true`.
// If set to true, two variants will be built separately, one like
// normal, and the other limited to the set of libraries and headers
// that are exposed to /vendor modules.
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
//
// The vendor variant may be used with a different (newer) /system,
// so it shouldn't have any unversioned runtime dependencies, or
// make assumptions about the system that may not be true in the
// future.
//
// If set to false, this module becomes inaccessible from /vendor modules.
//
// Default value is true when vndk: {enabled: true} or vendor: true.
//
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
// Nothing happens if BOARD_VNDK_VERSION isn't set in the BoardConfig.mk
Vendor_available *bool
// whether this module is capable of being loaded with other instance
// (possibly an older version) of the same module in the same process.
// Currently, a shared library that is a member of VNDK (vndk: {enabled: true})
// can be double loaded in a vendor process if the library is also a
// (direct and indirect) dependency of an LLNDK library. Such libraries must be
// explicitly marked as `double_loadable: true` by the owner, or the dependency
// from the LLNDK lib should be cut if the lib is not designed to be double loaded.
Double_loadable *bool
}
type ModuleContextIntf interface {
static() bool
staticBinary() bool
header() bool
toolchain() config.Toolchain
useSdk() bool
sdkVersion() string
useVndk() bool
isNdk() bool
isLlndk(config android.Config) bool
isLlndkPublic(config android.Config) bool
isVndkPrivate(config android.Config) bool
isVndk() bool
isVndkSp() bool
isVndkExt() bool
inRecovery() bool
shouldCreateSourceAbiDump() bool
selectedStl() string
baseModuleName() string
getVndkExtendsModuleName() string
isPgoCompile() bool
isNDKStubLibrary() bool
useClangLld(actx ModuleContext) bool
apexName() string
hasStubsVariants() bool
isStubs() bool
bootstrap() bool
mustUseVendorVariant() bool
nativeCoverage() bool
}
type ModuleContext interface {
android.ModuleContext
ModuleContextIntf
}
type BaseModuleContext interface {
android.BaseModuleContext
ModuleContextIntf
}
type DepsContext interface {
android.BottomUpMutatorContext
ModuleContextIntf
}
type feature interface {
begin(ctx BaseModuleContext)
deps(ctx DepsContext, deps Deps) Deps
flags(ctx ModuleContext, flags Flags) Flags
props() []interface{}
}
type compiler interface {
compilerInit(ctx BaseModuleContext)
compilerDeps(ctx DepsContext, deps Deps) Deps
compilerFlags(ctx ModuleContext, flags Flags, deps PathDeps) Flags
compilerProps() []interface{}
appendCflags([]string)
appendAsflags([]string)
compile(ctx ModuleContext, flags Flags, deps PathDeps) Objects
}
type linker interface {
linkerInit(ctx BaseModuleContext)
linkerDeps(ctx DepsContext, deps Deps) Deps
linkerFlags(ctx ModuleContext, flags Flags) Flags
linkerProps() []interface{}
useClangLld(actx ModuleContext) bool
link(ctx ModuleContext, flags Flags, deps PathDeps, objs Objects) android.Path
appendLdflags([]string)
unstrippedOutputFilePath() android.Path
nativeCoverage() bool
coverageOutputFilePath() android.OptionalPath
}
type installer interface {
installerProps() []interface{}
install(ctx ModuleContext, path android.Path)
inData() bool
inSanitizerDir() bool
hostToolPath() android.OptionalPath
relativeInstallPath() string
}
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
type xref interface {
XrefCcFiles() android.Paths
}
var (
sharedExportDepTag = DependencyTag{Name: "shared", Library: true, Shared: true, ReexportFlags: true}
earlySharedDepTag = DependencyTag{Name: "early_shared", Library: true, Shared: true}
lateSharedDepTag = DependencyTag{Name: "late shared", Library: true, Shared: true}
staticExportDepTag = DependencyTag{Name: "static", Library: true, ReexportFlags: true}
lateStaticDepTag = DependencyTag{Name: "late static", Library: true}
wholeStaticDepTag = DependencyTag{Name: "whole static", Library: true, ReexportFlags: true}
headerDepTag = DependencyTag{Name: "header", Library: true}
headerExportDepTag = DependencyTag{Name: "header", Library: true, ReexportFlags: true}
genSourceDepTag = DependencyTag{Name: "gen source"}
genHeaderDepTag = DependencyTag{Name: "gen header"}
genHeaderExportDepTag = DependencyTag{Name: "gen header", ReexportFlags: true}
objDepTag = DependencyTag{Name: "obj"}
linkerFlagsDepTag = DependencyTag{Name: "linker flags file"}
dynamicLinkerDepTag = DependencyTag{Name: "dynamic linker"}
reuseObjTag = DependencyTag{Name: "reuse objects"}
staticVariantTag = DependencyTag{Name: "static variant"}
ndkStubDepTag = DependencyTag{Name: "ndk stub", Library: true}
ndkLateStubDepTag = DependencyTag{Name: "ndk late stub", Library: true}
vndkExtDepTag = DependencyTag{Name: "vndk extends", Library: true}
runtimeDepTag = DependencyTag{Name: "runtime lib"}
coverageDepTag = DependencyTag{Name: "coverage"}
testPerSrcDepTag = DependencyTag{Name: "test_per_src"}
)
func IsSharedDepTag(depTag blueprint.DependencyTag) bool {
ccDepTag, ok := depTag.(DependencyTag)
return ok && ccDepTag.Shared
}
func IsRuntimeDepTag(depTag blueprint.DependencyTag) bool {
ccDepTag, ok := depTag.(DependencyTag)
return ok && ccDepTag == runtimeDepTag
}
func IsTestPerSrcDepTag(depTag blueprint.DependencyTag) bool {
ccDepTag, ok := depTag.(DependencyTag)
return ok && ccDepTag == testPerSrcDepTag
}
// Module contains the properties and members used by all C/C++ module types, and implements
// the blueprint.Module interface. It delegates to compiler, linker, and installer interfaces
// to construct the output file. Behavior can be customized with a Customizer interface
type Module struct {
android.ModuleBase
android.DefaultableModuleBase
android.ApexModuleBase
android.SdkBase
Properties BaseProperties
VendorProperties VendorProperties
// initialize before calling Init
hod android.HostOrDeviceSupported
multilib android.Multilib
// delegates, initialize before calling Init
features []feature
compiler compiler
linker linker
installer installer
stl *stl
sanitize *sanitize
coverage *coverage
sabi *sabi
vndkdep *vndkdep
lto *lto
pgo *pgo
xom *xom
androidMkSharedLibDeps []string
outputFile android.OptionalPath
cachedToolchain config.Toolchain
subAndroidMkOnce map[subAndroidMkProvider]bool
// Flags used to compile this module
flags Flags
// When calling a linker, if module A depends on module B, then A must precede B in its command
// line invocation. depsInLinkOrder stores the proper ordering of all of the transitive
// deps of this module
depsInLinkOrder android.Paths
// only non-nil when this is a shared library that reuses the objects of a static library
staticVariant LinkableInterface
makeLinkType string
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
// Kythe (source file indexer) paths for this compilation module
kytheFiles android.Paths
}
func (c *Module) Toc() android.OptionalPath {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
return library.toc()
}
}
panic(fmt.Errorf("Toc() called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) ApiLevel() string {
if c.linker != nil {
if stub, ok := c.linker.(*stubDecorator); ok {
return stub.properties.ApiLevel
}
}
panic(fmt.Errorf("ApiLevel() called on non-stub library module: %q", c.BaseModuleName()))
}
func (c *Module) Static() bool {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
return library.static()
}
}
panic(fmt.Errorf("Static() called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) Shared() bool {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
return library.shared()
}
}
panic(fmt.Errorf("Shared() called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) SelectedStl() string {
return c.stl.Properties.SelectedStl
}
func (c *Module) ToolchainLibrary() bool {
if _, ok := c.linker.(*toolchainLibraryDecorator); ok {
return true
}
return false
}
func (c *Module) NdkPrebuiltStl() bool {
if _, ok := c.linker.(*ndkPrebuiltStlLinker); ok {
return true
}
return false
}
func (c *Module) StubDecorator() bool {
if _, ok := c.linker.(*stubDecorator); ok {
return true
}
return false
}
func (c *Module) SdkVersion() string {
return String(c.Properties.Sdk_version)
}
func (c *Module) IncludeDirs(ctx android.BaseModuleContext) android.Paths {
if c.linker != nil {
if library, ok := c.linker.(exportedFlagsProducer); ok {
return library.exportedDirs()
}
}
panic(fmt.Errorf("IncludeDirs called on non-exportedFlagsProducer module: %q", c.BaseModuleName()))
}
func (c *Module) HasStaticVariant() bool {
if c.staticVariant != nil {
return true
}
return false
}
func (c *Module) GetStaticVariant() LinkableInterface {
return c.staticVariant
}
func (c *Module) SetDepsInLinkOrder(depsInLinkOrder []android.Path) {
c.depsInLinkOrder = depsInLinkOrder
}
func (c *Module) GetDepsInLinkOrder() []android.Path {
return c.depsInLinkOrder
}
func (c *Module) StubsVersions() []string {
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
return library.Properties.Stubs.Versions
}
}
panic(fmt.Errorf("StubsVersions called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) CcLibrary() bool {
if c.linker != nil {
if _, ok := c.linker.(*libraryDecorator); ok {
return true
}
}
return false
}
func (c *Module) CcLibraryInterface() bool {
if _, ok := c.linker.(libraryInterface); ok {
return true
}
return false
}
func (c *Module) SetBuildStubs() {
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
library.MutatedProperties.BuildStubs = true
c.Properties.HideFromMake = true
c.sanitize = nil
c.stl = nil
c.Properties.PreventInstall = true
return
}
}
panic(fmt.Errorf("SetBuildStubs called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) BuildStubs() bool {
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
return library.buildStubs()
}
}
panic(fmt.Errorf("BuildStubs called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) SetStubsVersions(version string) {
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
library.MutatedProperties.StubsVersion = version
return
}
}
panic(fmt.Errorf("SetStubsVersions called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) SetStatic() {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
library.setStatic()
return
}
}
panic(fmt.Errorf("SetStatic called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) SetShared() {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
library.setShared()
return
}
}
panic(fmt.Errorf("SetShared called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) BuildStaticVariant() bool {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
return library.buildStatic()
}
}
panic(fmt.Errorf("BuildStaticVariant called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) BuildSharedVariant() bool {
if c.linker != nil {
if library, ok := c.linker.(libraryInterface); ok {
return library.buildShared()
}
}
panic(fmt.Errorf("BuildSharedVariant called on non-library module: %q", c.BaseModuleName()))
}
func (c *Module) Module() android.Module {
return c
}
func (c *Module) OutputFile() android.OptionalPath {
return c.outputFile
}
var _ LinkableInterface = (*Module)(nil)
func (c *Module) UnstrippedOutputFile() android.Path {
if c.linker != nil {
return c.linker.unstrippedOutputFilePath()
}
return nil
}
func (c *Module) CoverageOutputFile() android.OptionalPath {
if c.linker != nil {
return c.linker.coverageOutputFilePath()
}
return android.OptionalPath{}
}
func (c *Module) RelativeInstallPath() string {
if c.installer != nil {
return c.installer.relativeInstallPath()
}
return ""
}
func (c *Module) VndkVersion() string {
return c.vndkVersion()
}
func (c *Module) Init() android.Module {
c.AddProperties(&c.Properties, &c.VendorProperties)
if c.compiler != nil {
c.AddProperties(c.compiler.compilerProps()...)
}
if c.linker != nil {
c.AddProperties(c.linker.linkerProps()...)
}
if c.installer != nil {
c.AddProperties(c.installer.installerProps()...)
}
if c.stl != nil {
c.AddProperties(c.stl.props()...)
}
if c.sanitize != nil {
c.AddProperties(c.sanitize.props()...)
}
if c.coverage != nil {
c.AddProperties(c.coverage.props()...)
}
if c.sabi != nil {
c.AddProperties(c.sabi.props()...)
}
if c.vndkdep != nil {
c.AddProperties(c.vndkdep.props()...)
}
if c.lto != nil {
c.AddProperties(c.lto.props()...)
}
if c.pgo != nil {
c.AddProperties(c.pgo.props()...)
}
if c.xom != nil {
c.AddProperties(c.xom.props()...)
}
for _, feature := range c.features {
c.AddProperties(feature.props()...)
}
c.Prefer32(func(ctx android.BaseModuleContext, base *android.ModuleBase, class android.OsClass) bool {
switch class {
case android.Device:
return ctx.Config().DevicePrefer32BitExecutables()
case android.HostCross:
// Windows builds always prefer 32-bit
return true
default:
return false
}
})
android.InitAndroidArchModule(c, c.hod, c.multilib)
android.InitDefaultableModule(c)
android.InitApexModule(c)
android.InitSdkAwareModule(c)
return c
}
// Returns true for dependency roots (binaries)
// TODO(ccross): also handle dlopenable libraries
func (c *Module) isDependencyRoot() bool {
if root, ok := c.linker.(interface {
isDependencyRoot() bool
}); ok {
return root.isDependencyRoot()
}
return false
}
func (c *Module) UseVndk() bool {
return c.Properties.VndkVersion != ""
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
}
func (c *Module) isCoverageVariant() bool {
return c.coverage.Properties.IsCoverageVariant
}
func (c *Module) isNdk() bool {
return inList(c.Name(), ndkMigratedLibs)
}
func (c *Module) isLlndk(config android.Config) bool {
// Returns true for both LLNDK (public) and LLNDK-private libs.
return isLlndkLibrary(c.BaseModuleName(), config)
}
func (c *Module) isLlndkPublic(config android.Config) bool {
// Returns true only for LLNDK (public) libs.
name := c.BaseModuleName()
return isLlndkLibrary(name, config) && !isVndkPrivateLibrary(name, config)
}
func (c *Module) isVndkPrivate(config android.Config) bool {
// Returns true for LLNDK-private, VNDK-SP-private, and VNDK-core-private.
return isVndkPrivateLibrary(c.BaseModuleName(), config)
}
func (c *Module) IsVndk() bool {
if vndkdep := c.vndkdep; vndkdep != nil {
return vndkdep.isVndk()
}
return false
}
func (c *Module) vndkVersion() string {
return c.Properties.VndkVersion
}
func (c *Module) isPgoCompile() bool {
if pgo := c.pgo; pgo != nil {
return pgo.Properties.PgoCompile
}
return false
}
func (c *Module) isNDKStubLibrary() bool {
if _, ok := c.compiler.(*stubDecorator); ok {
return true
}
return false
}
func (c *Module) isVndkSp() bool {
if vndkdep := c.vndkdep; vndkdep != nil {
return vndkdep.isVndkSp()
}
return false
}
func (c *Module) isVndkExt() bool {
if vndkdep := c.vndkdep; vndkdep != nil {
return vndkdep.isVndkExt()
}
return false
}
func (c *Module) MustUseVendorVariant() bool {
return c.isVndkSp() || c.Properties.MustUseVendorVariant
}
func (c *Module) getVndkExtendsModuleName() string {
if vndkdep := c.vndkdep; vndkdep != nil {
return vndkdep.getVndkExtendsModuleName()
}
return ""
}
// Returns true only when this module is configured to have core and vendor
// variants.
func (c *Module) HasVendorVariant() bool {
return c.IsVndk() || Bool(c.VendorProperties.Vendor_available)
}
func (c *Module) InRecovery() bool {
return c.Properties.InRecovery || c.ModuleBase.InstallInRecovery()
}
func (c *Module) OnlyInRecovery() bool {
return c.ModuleBase.InstallInRecovery()
}
func (c *Module) IsStubs() bool {
if library, ok := c.linker.(*libraryDecorator); ok {
return library.buildStubs()
} else if _, ok := c.linker.(*llndkStubDecorator); ok {
return true
}
return false
}
func (c *Module) HasStubsVariants() bool {
if library, ok := c.linker.(*libraryDecorator); ok {
return len(library.Properties.Stubs.Versions) > 0
}
if library, ok := c.linker.(*prebuiltLibraryLinker); ok {
return len(library.Properties.Stubs.Versions) > 0
}
return false
}
func (c *Module) bootstrap() bool {
return Bool(c.Properties.Bootstrap)
}
func (c *Module) nativeCoverage() bool {
// Bug: http://b/137883967 - native-bridge modules do not currently work with coverage
if c.Target().NativeBridge == android.NativeBridgeEnabled {
return false
}
return c.linker != nil && c.linker.nativeCoverage()
}
func (c *Module) ExportedIncludeDirs() android.Paths {
if flagsProducer, ok := c.linker.(exportedFlagsProducer); ok {
return flagsProducer.exportedDirs()
}
return []android.Path{}
}
func (c *Module) ExportedSystemIncludeDirs() android.Paths {
if flagsProducer, ok := c.linker.(exportedFlagsProducer); ok {
return flagsProducer.exportedSystemDirs()
}
return []android.Path{}
}
func (c *Module) ExportedFlags() []string {
if flagsProducer, ok := c.linker.(exportedFlagsProducer); ok {
return flagsProducer.exportedFlags()
}
return []string{}
}
func isBionic(name string) bool {
switch name {
case "libc", "libm", "libdl", "libdl_android", "linker":
return true
}
return false
}
func InstallToBootstrap(name string, config android.Config) bool {
if name == "libclang_rt.hwasan-aarch64-android" {
return inList("hwaddress", config.SanitizeDevice())
}
return isBionic(name)
}
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
func (c *Module) XrefCcFiles() android.Paths {
return c.kytheFiles
}
type baseModuleContext struct {
android.BaseModuleContext
moduleContextImpl
}
type depsContext struct {
android.BottomUpMutatorContext
moduleContextImpl
}
type moduleContext struct {
android.ModuleContext
moduleContextImpl
}
func (ctx *moduleContext) SocSpecific() bool {
return ctx.ModuleContext.SocSpecific() ||
(ctx.mod.HasVendorVariant() && ctx.mod.UseVndk() && !ctx.mod.IsVndk())
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
}
type moduleContextImpl struct {
mod *Module
ctx BaseModuleContext
}
func (ctx *moduleContextImpl) toolchain() config.Toolchain {
return ctx.mod.toolchain(ctx.ctx)
}
func (ctx *moduleContextImpl) static() bool {
return ctx.mod.static()
}
func (ctx *moduleContextImpl) staticBinary() bool {
return ctx.mod.staticBinary()
}
func (ctx *moduleContextImpl) header() bool {
return ctx.mod.header()
}
func (ctx *moduleContextImpl) useSdk() bool {
if ctx.ctx.Device() && !ctx.useVndk() && !ctx.inRecovery() && !ctx.ctx.Fuchsia() {
return String(ctx.mod.Properties.Sdk_version) != ""
}
return false
}
func (ctx *moduleContextImpl) sdkVersion() string {
if ctx.ctx.Device() {
if ctx.useVndk() {
vndk_ver := ctx.ctx.DeviceConfig().VndkVersion()
if vndk_ver == "current" {
platform_vndk_ver := ctx.ctx.DeviceConfig().PlatformVndkVersion()
if inList(platform_vndk_ver, ctx.ctx.Config().PlatformVersionCombinedCodenames()) {
return "current"
}
return platform_vndk_ver
}
return vndk_ver
}
return String(ctx.mod.Properties.Sdk_version)
}
return ""
}
func (ctx *moduleContextImpl) useVndk() bool {
return ctx.mod.UseVndk()
}
func (ctx *moduleContextImpl) isNdk() bool {
return ctx.mod.isNdk()
}
func (ctx *moduleContextImpl) isLlndk(config android.Config) bool {
return ctx.mod.isLlndk(config)
}
func (ctx *moduleContextImpl) isLlndkPublic(config android.Config) bool {
return ctx.mod.isLlndkPublic(config)
}
func (ctx *moduleContextImpl) isVndkPrivate(config android.Config) bool {
return ctx.mod.isVndkPrivate(config)
}
func (ctx *moduleContextImpl) isVndk() bool {
return ctx.mod.IsVndk()
}
func (ctx *moduleContextImpl) isPgoCompile() bool {
return ctx.mod.isPgoCompile()
}
func (ctx *moduleContextImpl) isNDKStubLibrary() bool {
return ctx.mod.isNDKStubLibrary()
}
func (ctx *moduleContextImpl) isVndkSp() bool {
return ctx.mod.isVndkSp()
}
func (ctx *moduleContextImpl) isVndkExt() bool {
return ctx.mod.isVndkExt()
}
func (ctx *moduleContextImpl) mustUseVendorVariant() bool {
return ctx.mod.MustUseVendorVariant()
}
func (ctx *moduleContextImpl) inRecovery() bool {
return ctx.mod.InRecovery()
}
// Check whether ABI dumps should be created for this module.
func (ctx *moduleContextImpl) shouldCreateSourceAbiDump() bool {
if ctx.ctx.Config().IsEnvTrue("SKIP_ABI_CHECKS") {
return false
}
if ctx.ctx.Fuchsia() {
return false
}
if sanitize := ctx.mod.sanitize; sanitize != nil {
if !sanitize.isVariantOnProductionDevice() {
return false
}
}
if !ctx.ctx.Device() {
// Host modules do not need ABI dumps.
return false
}
if !ctx.mod.IsForPlatform() {
// APEX variants do not need ABI dumps.
return false
}
if ctx.isStubs() {
// Stubs do not need ABI dumps.
return false
}
return true
}
func (ctx *moduleContextImpl) selectedStl() string {
if stl := ctx.mod.stl; stl != nil {
return stl.Properties.SelectedStl
}
return ""
}
func (ctx *moduleContextImpl) useClangLld(actx ModuleContext) bool {
return ctx.mod.linker.useClangLld(actx)
}
func (ctx *moduleContextImpl) baseModuleName() string {
return ctx.mod.ModuleBase.BaseModuleName()
}
func (ctx *moduleContextImpl) getVndkExtendsModuleName() string {
return ctx.mod.getVndkExtendsModuleName()
}
func (ctx *moduleContextImpl) apexName() string {
return ctx.mod.ApexName()
}
func (ctx *moduleContextImpl) hasStubsVariants() bool {
return ctx.mod.HasStubsVariants()
}
func (ctx *moduleContextImpl) isStubs() bool {
return ctx.mod.IsStubs()
}
func (ctx *moduleContextImpl) bootstrap() bool {
return ctx.mod.bootstrap()
}
func (ctx *moduleContextImpl) nativeCoverage() bool {
return ctx.mod.nativeCoverage()
}
func newBaseModule(hod android.HostOrDeviceSupported, multilib android.Multilib) *Module {
return &Module{
hod: hod,
multilib: multilib,
}
}
func newModule(hod android.HostOrDeviceSupported, multilib android.Multilib) *Module {
module := newBaseModule(hod, multilib)
module.features = []feature{
&tidyFeature{},
}
module.stl = &stl{}
module.sanitize = &sanitize{}
module.coverage = &coverage{}
module.sabi = &sabi{}
module.vndkdep = &vndkdep{}
module.lto = &lto{}
module.pgo = &pgo{}
module.xom = &xom{}
return module
}
func (c *Module) Prebuilt() *android.Prebuilt {
if p, ok := c.linker.(prebuiltLinkerInterface); ok {
return p.prebuilt()
}
return nil
}
func (c *Module) Name() string {
name := c.ModuleBase.Name()
if p, ok := c.linker.(interface {
Name(string) string
}); ok {
name = p.Name(name)
}
return name
}
func (c *Module) Symlinks() []string {
if p, ok := c.installer.(interface {
symlinkList() []string
}); ok {
return p.symlinkList()
}
return nil
}
// orderDeps reorders dependencies into a list such that if module A depends on B, then
// A will precede B in the resultant list.
// This is convenient for passing into a linker.
// Note that directSharedDeps should be the analogous static library for each shared lib dep
func orderDeps(directStaticDeps []android.Path, directSharedDeps []android.Path, allTransitiveDeps map[android.Path][]android.Path) (orderedAllDeps []android.Path, orderedDeclaredDeps []android.Path) {
// If A depends on B, then
// Every list containing A will also contain B later in the list
// So, after concatenating all lists, the final instance of B will have come from the same
// original list as the final instance of A
// So, the final instance of B will be later in the concatenation than the final A
// So, keeping only the final instance of A and of B ensures that A is earlier in the output
// list than B
for _, dep := range directStaticDeps {
orderedAllDeps = append(orderedAllDeps, dep)
orderedAllDeps = append(orderedAllDeps, allTransitiveDeps[dep]...)
}
for _, dep := range directSharedDeps {
orderedAllDeps = append(orderedAllDeps, dep)
orderedAllDeps = append(orderedAllDeps, allTransitiveDeps[dep]...)
}
orderedAllDeps = android.LastUniquePaths(orderedAllDeps)
// We don't want to add any new dependencies into directStaticDeps (to allow the caller to
// intentionally exclude or replace any unwanted transitive dependencies), so we limit the
// resultant list to only what the caller has chosen to include in directStaticDeps
_, orderedDeclaredDeps = android.FilterPathList(orderedAllDeps, directStaticDeps)
return orderedAllDeps, orderedDeclaredDeps
}
func orderStaticModuleDeps(module LinkableInterface, staticDeps []LinkableInterface, sharedDeps []LinkableInterface) (results []android.Path) {
// convert Module to Path
var depsInLinkOrder []android.Path
allTransitiveDeps := make(map[android.Path][]android.Path, len(staticDeps))
staticDepFiles := []android.Path{}
for _, dep := range staticDeps {
allTransitiveDeps[dep.OutputFile().Path()] = dep.GetDepsInLinkOrder()
staticDepFiles = append(staticDepFiles, dep.OutputFile().Path())
}
sharedDepFiles := []android.Path{}
for _, sharedDep := range sharedDeps {
if sharedDep.HasStaticVariant() {
staticAnalogue := sharedDep.GetStaticVariant()
allTransitiveDeps[staticAnalogue.OutputFile().Path()] = staticAnalogue.GetDepsInLinkOrder()
sharedDepFiles = append(sharedDepFiles, staticAnalogue.OutputFile().Path())
}
}
// reorder the dependencies based on transitive dependencies
depsInLinkOrder, results = orderDeps(staticDepFiles, sharedDepFiles, allTransitiveDeps)
module.SetDepsInLinkOrder(depsInLinkOrder)
return results
}
func (c *Module) IsTestPerSrcAllTestsVariation() bool {
test, ok := c.linker.(testPerSrc)
return ok && test.isAllTestsVariation()
}
func (c *Module) GenerateAndroidBuildActions(actx android.ModuleContext) {
// Handle the case of a test module split by `test_per_src` mutator.
//
// The `test_per_src` mutator adds an extra variation named "", depending on all the other
// `test_per_src` variations of the test module. Set `outputFile` to an empty path for this
// module and return early, as this module does not produce an output file per se.
if c.IsTestPerSrcAllTestsVariation() {
c.outputFile = android.OptionalPath{}
return
}
c.makeLinkType = c.getMakeLinkType(actx)
c.Properties.SubName = ""
if c.Target().NativeBridge == android.NativeBridgeEnabled {
c.Properties.SubName += nativeBridgeSuffix
}
if _, ok := c.linker.(*vndkPrebuiltLibraryDecorator); ok {
// .vendor suffix is added for backward compatibility with VNDK snapshot whose names with
// such suffixes are already hard-coded in prebuilts/vndk/.../Android.bp.
c.Properties.SubName += vendorSuffix
} else if _, ok := c.linker.(*llndkStubDecorator); ok || (c.UseVndk() && c.HasVendorVariant()) {
// .vendor.{version} suffix is added only when we will have two variants: core and vendor.
// The suffix is not added for vendor-only module.
c.Properties.SubName += vendorSuffix
vendorVersion := actx.DeviceConfig().VndkVersion()
if vendorVersion == "current" {
vendorVersion = actx.DeviceConfig().PlatformVndkVersion()
}
if c.Properties.VndkVersion != vendorVersion {
c.Properties.SubName += "." + c.Properties.VndkVersion
}
} else if c.InRecovery() && !c.OnlyInRecovery() {
c.Properties.SubName += recoverySuffix
}
ctx := &moduleContext{
ModuleContext: actx,
moduleContextImpl: moduleContextImpl{
mod: c,
},
}
ctx.ctx = ctx
deps := c.depsToPaths(ctx)
if ctx.Failed() {
return
}
if c.Properties.Clang != nil && *c.Properties.Clang == false {
ctx.PropertyErrorf("clang", "false (GCC) is no longer supported")
}
flags := Flags{
Toolchain: c.toolchain(ctx),
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
EmitXrefs: ctx.Config().EmitXrefRules(),
}
if c.compiler != nil {
flags = c.compiler.compilerFlags(ctx, flags, deps)
}
if c.linker != nil {
flags = c.linker.linkerFlags(ctx, flags)
}
if c.stl != nil {
flags = c.stl.flags(ctx, flags)
}
if c.sanitize != nil {
flags = c.sanitize.flags(ctx, flags)
}
if c.coverage != nil {
Refactor libprofile-extras to be added as a whole static library Bug: http://b/134177005 Bug: http://b/116873221 Previously, the libprofile-extras dependency was added as a LateStaticLib and the constructor in this library was included during linking with the '-uinit_profile_extras' linker flag. This was done because at the deps() stage, the exact binaries that need coverage are not known (in fact the coverage-enabled variants are not created yet). This meant that for a link command, if one of the shared libraries already exported the constructor, the output of the link command did not load/link libprofile-extras. For other reasons, we now want to add more symbols to this library that need to be linked into all libraries and executables. To accomplish that, refactor the dependency handling so libprofile-extras can be added as a 'WholeStaticLib'. This is done by creating a new dependency type (with a coverageDepTag dependency tag) to add libprofile-extras as a dependency for all modules that can potentially link with coverage. During the flags() call, this dependency is moved as a WholeStaticLib dependency iff coverage is enabled in this link step. There are a few NFC changes as well: - deps() takes a DepsContext parameter. - flags() has an extra PathDeps parameter and return value. - add useSdk() helper to cc.Module. Test: Build with coverage and check that we can generate coverage using SIGUSR1 and the debug.coverage.flush sysprop. Change-Id: I7e7d8201956a150febbda5bb1794f8ece016db8b
2019-07-02 23:55:35 +02:00
flags, deps = c.coverage.flags(ctx, flags, deps)
}
if c.lto != nil {
flags = c.lto.flags(ctx, flags)
}
if c.pgo != nil {
flags = c.pgo.flags(ctx, flags)
}
if c.xom != nil {
flags = c.xom.flags(ctx, flags)
}
for _, feature := range c.features {
flags = feature.flags(ctx, flags)
}
if ctx.Failed() {
return
}
flags.CFlags, _ = filterList(flags.CFlags, config.IllegalFlags)
flags.CppFlags, _ = filterList(flags.CppFlags, config.IllegalFlags)
flags.ConlyFlags, _ = filterList(flags.ConlyFlags, config.IllegalFlags)
flags.GlobalFlags = append(flags.GlobalFlags, deps.Flags...)
for _, dir := range deps.IncludeDirs {
flags.GlobalFlags = append(flags.GlobalFlags, "-I"+dir.String())
}
for _, dir := range deps.SystemIncludeDirs {
flags.GlobalFlags = append(flags.GlobalFlags, "-isystem "+dir.String())
}
c.flags = flags
// We need access to all the flags seen by a source file.
if c.sabi != nil {
flags = c.sabi.flags(ctx, flags)
}
flags.AssemblerWithCpp = inList("-xassembler-with-cpp", flags.AsFlags)
// Optimization to reduce size of build.ninja
// Replace the long list of flags for each file with a module-local variable
ctx.Variable(pctx, "cflags", strings.Join(flags.CFlags, " "))
ctx.Variable(pctx, "cppflags", strings.Join(flags.CppFlags, " "))
ctx.Variable(pctx, "asflags", strings.Join(flags.AsFlags, " "))
flags.CFlags = []string{"$cflags"}
flags.CppFlags = []string{"$cppflags"}
flags.AsFlags = []string{"$asflags"}
var objs Objects
if c.compiler != nil {
objs = c.compiler.compile(ctx, flags, deps)
if ctx.Failed() {
return
}
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
c.kytheFiles = objs.kytheFiles
}
if c.linker != nil {
outputFile := c.linker.link(ctx, flags, deps, objs)
if ctx.Failed() {
return
}
c.outputFile = android.OptionalPathForPath(outputFile)
// If a lib is directly included in any of the APEXes, unhide the stubs
// variant having the latest version gets visible to make. In addition,
// the non-stubs variant is renamed to <libname>.bootstrap. This is to
// force anything in the make world to link against the stubs library.
// (unless it is explicitly referenced via .bootstrap suffix or the
// module is marked with 'bootstrap: true').
if c.HasStubsVariants() &&
android.DirectlyInAnyApex(ctx, ctx.baseModuleName()) &&
!c.InRecovery() && !c.UseVndk() && !c.static() && !c.isCoverageVariant() &&
c.IsStubs() {
c.Properties.HideFromMake = false // unhide
// Note: this is still non-installable
}
}
if c.installable() {
c.installer.install(ctx, c.outputFile.Path())
if ctx.Failed() {
return
}
}
}
func (c *Module) toolchain(ctx android.BaseModuleContext) config.Toolchain {
if c.cachedToolchain == nil {
c.cachedToolchain = config.FindToolchain(ctx.Os(), ctx.Arch())
}
return c.cachedToolchain
}
func (c *Module) begin(ctx BaseModuleContext) {
if c.compiler != nil {
c.compiler.compilerInit(ctx)
}
if c.linker != nil {
c.linker.linkerInit(ctx)
}
if c.stl != nil {
c.stl.begin(ctx)
}
if c.sanitize != nil {
c.sanitize.begin(ctx)
}
if c.coverage != nil {
c.coverage.begin(ctx)
}
if c.sabi != nil {
c.sabi.begin(ctx)
}
if c.vndkdep != nil {
c.vndkdep.begin(ctx)
}
if c.lto != nil {
c.lto.begin(ctx)
}
if c.pgo != nil {
c.pgo.begin(ctx)
}
for _, feature := range c.features {
feature.begin(ctx)
}
if ctx.useSdk() {
version, err := normalizeNdkApiLevel(ctx, ctx.sdkVersion(), ctx.Arch())
if err != nil {
ctx.PropertyErrorf("sdk_version", err.Error())
}
c.Properties.Sdk_version = StringPtr(version)
}
}
func (c *Module) deps(ctx DepsContext) Deps {
deps := Deps{}
if c.compiler != nil {
deps = c.compiler.compilerDeps(ctx, deps)
}
// Add the PGO dependency (the clang_rt.profile runtime library), which
// sometimes depends on symbols from libgcc, before libgcc gets added
// in linkerDeps().
if c.pgo != nil {
deps = c.pgo.deps(ctx, deps)
}
if c.linker != nil {
deps = c.linker.linkerDeps(ctx, deps)
}
if c.stl != nil {
deps = c.stl.deps(ctx, deps)
}
if c.sanitize != nil {
deps = c.sanitize.deps(ctx, deps)
}
if c.coverage != nil {
deps = c.coverage.deps(ctx, deps)
}
if c.sabi != nil {
deps = c.sabi.deps(ctx, deps)
}
if c.vndkdep != nil {
deps = c.vndkdep.deps(ctx, deps)
}
if c.lto != nil {
deps = c.lto.deps(ctx, deps)
}
for _, feature := range c.features {
deps = feature.deps(ctx, deps)
}
deps.WholeStaticLibs = android.LastUniqueStrings(deps.WholeStaticLibs)
deps.StaticLibs = android.LastUniqueStrings(deps.StaticLibs)
deps.LateStaticLibs = android.LastUniqueStrings(deps.LateStaticLibs)
deps.SharedLibs = android.LastUniqueStrings(deps.SharedLibs)
deps.LateSharedLibs = android.LastUniqueStrings(deps.LateSharedLibs)
deps.HeaderLibs = android.LastUniqueStrings(deps.HeaderLibs)
deps.RuntimeLibs = android.LastUniqueStrings(deps.RuntimeLibs)
for _, lib := range deps.ReexportSharedLibHeaders {
if !inList(lib, deps.SharedLibs) {
ctx.PropertyErrorf("export_shared_lib_headers", "Shared library not in shared_libs: '%s'", lib)
}
}
for _, lib := range deps.ReexportStaticLibHeaders {
if !inList(lib, deps.StaticLibs) {
ctx.PropertyErrorf("export_static_lib_headers", "Static library not in static_libs: '%s'", lib)
}
}
for _, lib := range deps.ReexportHeaderLibHeaders {
if !inList(lib, deps.HeaderLibs) {
ctx.PropertyErrorf("export_header_lib_headers", "Header library not in header_libs: '%s'", lib)
}
}
for _, gen := range deps.ReexportGeneratedHeaders {
if !inList(gen, deps.GeneratedHeaders) {
ctx.PropertyErrorf("export_generated_headers", "Generated header module not in generated_headers: '%s'", gen)
}
}
return deps
}
func (c *Module) beginMutator(actx android.BottomUpMutatorContext) {
ctx := &baseModuleContext{
BaseModuleContext: actx,
moduleContextImpl: moduleContextImpl{
mod: c,
},
}
ctx.ctx = ctx
c.begin(ctx)
}
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
// Split name#version into name and version
func StubsLibNameAndVersion(name string) (string, string) {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
if sharp := strings.LastIndex(name, "#"); sharp != -1 && sharp != len(name)-1 {
version := name[sharp+1:]
libname := name[:sharp]
return libname, version
}
return name, ""
}
func (c *Module) DepsMutator(actx android.BottomUpMutatorContext) {
ctx := &depsContext{
BottomUpMutatorContext: actx,
moduleContextImpl: moduleContextImpl{
mod: c,
},
}
ctx.ctx = ctx
deps := c.deps(ctx)
variantNdkLibs := []string{}
variantLateNdkLibs := []string{}
if ctx.Os() == android.Android {
version := ctx.sdkVersion()
// rewriteNdkLibs takes a list of names of shared libraries and scans it for three types
// of names:
//
// 1. Name of an NDK library that refers to a prebuilt module.
// For each of these, it adds the name of the prebuilt module (which will be in
// prebuilts/ndk) to the list of nonvariant libs.
// 2. Name of an NDK library that refers to an ndk_library module.
// For each of these, it adds the name of the ndk_library module to the list of
// variant libs.
// 3. Anything else (so anything that isn't an NDK library).
// It adds these to the nonvariantLibs list.
//
// The caller can then know to add the variantLibs dependencies differently from the
// nonvariantLibs
vendorPublicLibraries := vendorPublicLibraries(actx.Config())
rewriteNdkLibs := func(list []string) (nonvariantLibs []string, variantLibs []string) {
variantLibs = []string{}
nonvariantLibs = []string{}
for _, entry := range list {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
// strip #version suffix out
name, _ := StubsLibNameAndVersion(entry)
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
if ctx.useSdk() && inList(name, ndkPrebuiltSharedLibraries) {
if !inList(name, ndkMigratedLibs) {
nonvariantLibs = append(nonvariantLibs, name+".ndk."+version)
} else {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
variantLibs = append(variantLibs, name+ndkLibrarySuffix)
}
} else if ctx.useVndk() && isLlndkLibrary(name, ctx.Config()) {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
nonvariantLibs = append(nonvariantLibs, name+llndkLibrarySuffix)
} else if (ctx.Platform() || ctx.ProductSpecific()) && inList(name, *vendorPublicLibraries) {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
vendorPublicLib := name + vendorPublicLibrarySuffix
if actx.OtherModuleExists(vendorPublicLib) {
nonvariantLibs = append(nonvariantLibs, vendorPublicLib)
} else {
// This can happen if vendor_public_library module is defined in a
// namespace that isn't visible to the current module. In that case,
// link to the original library.
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
nonvariantLibs = append(nonvariantLibs, name)
}
} else {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
// put name#version back
nonvariantLibs = append(nonvariantLibs, entry)
}
}
return nonvariantLibs, variantLibs
}
deps.SharedLibs, variantNdkLibs = rewriteNdkLibs(deps.SharedLibs)
deps.LateSharedLibs, variantLateNdkLibs = rewriteNdkLibs(deps.LateSharedLibs)
deps.ReexportSharedLibHeaders, _ = rewriteNdkLibs(deps.ReexportSharedLibHeaders)
}
buildStubs := false
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
if library.buildStubs() {
buildStubs = true
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
}
}
}
for _, lib := range deps.HeaderLibs {
depTag := headerDepTag
if inList(lib, deps.ReexportHeaderLibHeaders) {
depTag = headerExportDepTag
}
if buildStubs {
actx.AddFarVariationDependencies(append(ctx.Target().Variations(),
blueprint.Variation{Mutator: "image", Variation: c.imageVariation()}),
depTag, lib)
} else {
actx.AddVariationDependencies(nil, depTag, lib)
}
}
if buildStubs {
// Stubs lib does not have dependency to other static/shared libraries.
// Don't proceed.
return
}
syspropImplLibraries := syspropImplLibraries(actx.Config())
for _, lib := range deps.WholeStaticLibs {
depTag := wholeStaticDepTag
if impl, ok := syspropImplLibraries[lib]; ok {
lib = impl
}
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "link", Variation: "static"},
}, depTag, lib)
}
for _, lib := range deps.StaticLibs {
depTag := StaticDepTag
if inList(lib, deps.ReexportStaticLibHeaders) {
depTag = staticExportDepTag
}
if impl, ok := syspropImplLibraries[lib]; ok {
lib = impl
}
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "link", Variation: "static"},
}, depTag, lib)
}
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "link", Variation: "static"},
}, lateStaticDepTag, deps.LateStaticLibs...)
addSharedLibDependencies := func(depTag DependencyTag, name string, version string) {
var variations []blueprint.Variation
variations = append(variations, blueprint.Variation{Mutator: "link", Variation: "shared"})
versionVariantAvail := !ctx.useVndk() && !c.InRecovery()
if version != "" && versionVariantAvail {
// Version is explicitly specified. i.e. libFoo#30
variations = append(variations, blueprint.Variation{Mutator: "version", Variation: version})
depTag.ExplicitlyVersioned = true
}
actx.AddVariationDependencies(variations, depTag, name)
// If the version is not specified, add dependency to the latest stubs library.
// The stubs library will be used when the depending module is built for APEX and
// the dependent module is not in the same APEX.
latestVersion := LatestStubsVersionFor(actx.Config(), name)
if version == "" && latestVersion != "" && versionVariantAvail {
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "link", Variation: "shared"},
{Mutator: "version", Variation: latestVersion},
}, depTag, name)
// Note that depTag.ExplicitlyVersioned is false in this case.
}
}
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
// shared lib names without the #version suffix
var sharedLibNames []string
for _, lib := range deps.SharedLibs {
depTag := SharedDepTag
if inList(lib, deps.ReexportSharedLibHeaders) {
depTag = sharedExportDepTag
}
if impl, ok := syspropImplLibraries[lib]; ok {
lib = impl
}
name, version := StubsLibNameAndVersion(lib)
sharedLibNames = append(sharedLibNames, name)
addSharedLibDependencies(depTag, name, version)
}
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
for _, lib := range deps.LateSharedLibs {
if inList(lib, sharedLibNames) {
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
// This is to handle the case that some of the late shared libs (libc, libdl, libm, ...)
// are added also to SharedLibs with version (e.g., libc#10). If not skipped, we will be
// linking against both the stubs lib and the non-stubs lib at the same time.
continue
}
addSharedLibDependencies(lateSharedDepTag, lib, "")
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
}
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "link", Variation: "shared"},
}, runtimeDepTag, deps.RuntimeLibs...)
actx.AddDependency(c, genSourceDepTag, deps.GeneratedSources...)
for _, gen := range deps.GeneratedHeaders {
depTag := genHeaderDepTag
if inList(gen, deps.ReexportGeneratedHeaders) {
depTag = genHeaderExportDepTag
}
actx.AddDependency(c, depTag, gen)
}
actx.AddVariationDependencies(nil, objDepTag, deps.ObjFiles...)
if deps.CrtBegin != "" {
actx.AddVariationDependencies(nil, CrtBeginDepTag, deps.CrtBegin)
}
if deps.CrtEnd != "" {
actx.AddVariationDependencies(nil, CrtEndDepTag, deps.CrtEnd)
}
if deps.LinkerFlagsFile != "" {
actx.AddDependency(c, linkerFlagsDepTag, deps.LinkerFlagsFile)
}
if deps.DynamicLinker != "" {
actx.AddDependency(c, dynamicLinkerDepTag, deps.DynamicLinker)
}
version := ctx.sdkVersion()
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "ndk_api", Variation: version},
{Mutator: "link", Variation: "shared"},
}, ndkStubDepTag, variantNdkLibs...)
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "ndk_api", Variation: version},
{Mutator: "link", Variation: "shared"},
}, ndkLateStubDepTag, variantLateNdkLibs...)
if vndkdep := c.vndkdep; vndkdep != nil {
if vndkdep.isVndkExt() {
var baseModuleMode string
if actx.DeviceConfig().VndkVersion() == "" {
baseModuleMode = coreMode
} else {
baseModuleMode = c.imageVariation()
}
actx.AddVariationDependencies([]blueprint.Variation{
{Mutator: "image", Variation: baseModuleMode},
{Mutator: "link", Variation: "shared"},
}, vndkExtDepTag, vndkdep.getVndkExtendsModuleName())
}
}
}
func BeginMutator(ctx android.BottomUpMutatorContext) {
if c, ok := ctx.Module().(*Module); ok && c.Enabled() {
c.beginMutator(ctx)
}
}
// Whether a module can link to another module, taking into
// account NDK linking.
func checkLinkType(ctx android.ModuleContext, from LinkableInterface, to LinkableInterface, tag DependencyTag) {
if from.Module().Target().Os != android.Android {
// Host code is not restricted
return
}
// VNDK is cc.Module supported only for now.
if ccFrom, ok := from.(*Module); ok && from.UseVndk() {
// Though vendor code is limited by the vendor mutator,
// each vendor-available module needs to check
// link-type for VNDK.
if ccTo, ok := to.(*Module); ok {
if ccFrom.vndkdep != nil {
ccFrom.vndkdep.vndkCheckLinkType(ctx, ccTo, tag)
}
} else {
ctx.ModuleErrorf("Attempting to link VNDK cc.Module with unsupported module type")
}
return
}
if from.SdkVersion() == "" {
// Platform code can link to anything
return
}
if from.InRecovery() {
// Recovery code is not NDK
return
}
if to.ToolchainLibrary() {
// These are always allowed
return
}
if to.NdkPrebuiltStl() {
// These are allowed, but they don't set sdk_version
return
}
if to.StubDecorator() {
// These aren't real libraries, but are the stub shared libraries that are included in
// the NDK.
return
}
if strings.HasPrefix(ctx.ModuleName(), "libclang_rt.") && to.Module().Name() == "libc++" {
// Bug: http://b/121358700 - Allow libclang_rt.* shared libraries (with sdk_version)
// to link to libc++ (non-NDK and without sdk_version).
return
}
if to.SdkVersion() == "" {
// NDK code linking to platform code is never okay.
ctx.ModuleErrorf("depends on non-NDK-built library %q",
ctx.OtherModuleName(to.Module()))
return
}
// At this point we know we have two NDK libraries, but we need to
// check that we're not linking against anything built against a higher
// API level, as it is only valid to link against older or equivalent
// APIs.
// Current can link against anything.
if from.SdkVersion() != "current" {
// Otherwise we need to check.
if to.SdkVersion() == "current" {
// Current can't be linked against by anything else.
ctx.ModuleErrorf("links %q built against newer API version %q",
ctx.OtherModuleName(to.Module()), "current")
} else {
fromApi, err := strconv.Atoi(from.SdkVersion())
if err != nil {
ctx.PropertyErrorf("sdk_version",
"Invalid sdk_version value (must be int or current): %q",
from.SdkVersion())
}
toApi, err := strconv.Atoi(to.SdkVersion())
if err != nil {
ctx.PropertyErrorf("sdk_version",
"Invalid sdk_version value (must be int or current): %q",
to.SdkVersion())
}
if toApi > fromApi {
ctx.ModuleErrorf("links %q built against newer API version %q",
ctx.OtherModuleName(to.Module()), to.SdkVersion())
}
}
}
// Also check that the two STL choices are compatible.
fromStl := from.SelectedStl()
toStl := to.SelectedStl()
if fromStl == "" || toStl == "" {
// Libraries that don't use the STL are unrestricted.
} else if fromStl == "ndk_system" || toStl == "ndk_system" {
// We can be permissive with the system "STL" since it is only the C++
// ABI layer, but in the future we should make sure that everyone is
// using either libc++ or nothing.
} else if getNdkStlFamily(from) != getNdkStlFamily(to) {
ctx.ModuleErrorf("uses %q and depends on %q which uses incompatible %q",
from.SelectedStl(), ctx.OtherModuleName(to.Module()),
to.SelectedStl())
}
}
// Tests whether the dependent library is okay to be double loaded inside a single process.
// If a library has a vendor variant and is a (transitive) dependency of an LLNDK library,
// it is subject to be double loaded. Such lib should be explicitly marked as double_loadable: true
// or as vndk-sp (vndk: { enabled: true, support_system_process: true}).
func checkDoubleLoadableLibraries(ctx android.TopDownMutatorContext) {
check := func(child, parent android.Module) bool {
to, ok := child.(*Module)
if !ok {
// follow thru cc.Defaults, etc.
return true
}
if lib, ok := to.linker.(*libraryDecorator); !ok || !lib.shared() {
return false
}
// if target lib has no vendor variant, keep checking dependency graph
if !to.HasVendorVariant() {
return true
}
if to.isVndkSp() || to.isLlndk(ctx.Config()) || Bool(to.VendorProperties.Double_loadable) {
return false
}
var stringPath []string
for _, m := range ctx.GetWalkPath() {
stringPath = append(stringPath, m.Name())
}
ctx.ModuleErrorf("links a library %q which is not LL-NDK, "+
"VNDK-SP, or explicitly marked as 'double_loadable:true'. "+
"(dependency: %s)", ctx.OtherModuleName(to), strings.Join(stringPath, " -> "))
return false
}
if module, ok := ctx.Module().(*Module); ok {
if lib, ok := module.linker.(*libraryDecorator); ok && lib.shared() {
if module.isLlndk(ctx.Config()) || Bool(module.VendorProperties.Double_loadable) {
ctx.WalkDeps(check)
}
}
}
}
// Convert dependencies to paths. Returns a PathDeps containing paths
func (c *Module) depsToPaths(ctx android.ModuleContext) PathDeps {
var depPaths PathDeps
directStaticDeps := []LinkableInterface{}
directSharedDeps := []LinkableInterface{}
vendorPublicLibraries := vendorPublicLibraries(ctx.Config())
reexportExporter := func(exporter exportedFlagsProducer) {
depPaths.ReexportedDirs = append(depPaths.ReexportedDirs, exporter.exportedDirs()...)
depPaths.ReexportedSystemDirs = append(depPaths.ReexportedSystemDirs, exporter.exportedSystemDirs()...)
depPaths.ReexportedFlags = append(depPaths.ReexportedFlags, exporter.exportedFlags()...)
depPaths.ReexportedDeps = append(depPaths.ReexportedDeps, exporter.exportedDeps()...)
}
ctx.VisitDirectDeps(func(dep android.Module) {
depName := ctx.OtherModuleName(dep)
depTag := ctx.OtherModuleDependencyTag(dep)
ccDep, ok := dep.(LinkableInterface)
if !ok {
// handling for a few module types that aren't cc Module but that are also supported
switch depTag {
case genSourceDepTag:
if genRule, ok := dep.(genrule.SourceFileGenerator); ok {
depPaths.GeneratedSources = append(depPaths.GeneratedSources,
genRule.GeneratedSourceFiles()...)
} else {
ctx.ModuleErrorf("module %q is not a gensrcs or genrule", depName)
}
// Support exported headers from a generated_sources dependency
fallthrough
case genHeaderDepTag, genHeaderExportDepTag:
if genRule, ok := dep.(genrule.SourceFileGenerator); ok {
depPaths.GeneratedHeaders = append(depPaths.GeneratedHeaders,
genRule.GeneratedDeps()...)
dirs := genRule.GeneratedHeaderDirs()
depPaths.IncludeDirs = append(depPaths.IncludeDirs, dirs...)
if depTag == genHeaderExportDepTag {
depPaths.ReexportedDirs = append(depPaths.ReexportedDirs, dirs...)
depPaths.ReexportedDeps = append(depPaths.ReexportedDeps, genRule.GeneratedDeps()...)
// Add these re-exported flags to help header-abi-dumper to infer the abi exported by a library.
c.sabi.Properties.ReexportedIncludes = append(c.sabi.Properties.ReexportedIncludes, dirs.Strings()...)
}
} else {
ctx.ModuleErrorf("module %q is not a genrule", depName)
}
case linkerFlagsDepTag:
if genRule, ok := dep.(genrule.SourceFileGenerator); ok {
files := genRule.GeneratedSourceFiles()
if len(files) == 1 {
depPaths.LinkerFlagsFile = android.OptionalPathForPath(files[0])
} else if len(files) > 1 {
ctx.ModuleErrorf("module %q can only generate a single file if used for a linker flag file", depName)
}
} else {
ctx.ModuleErrorf("module %q is not a genrule", depName)
}
}
return
}
if depTag == android.ProtoPluginDepTag {
return
}
if dep.Target().Os != ctx.Os() {
ctx.ModuleErrorf("OS mismatch between %q and %q", ctx.ModuleName(), depName)
return
}
if dep.Target().Arch.ArchType != ctx.Arch().ArchType {
ctx.ModuleErrorf("Arch mismatch between %q and %q", ctx.ModuleName(), depName)
return
}
// re-exporting flags
if depTag == reuseObjTag {
// reusing objects only make sense for cc.Modules.
if ccReuseDep, ok := ccDep.(*Module); ok && ccDep.CcLibraryInterface() {
c.staticVariant = ccDep
objs, exporter := ccReuseDep.compiler.(libraryInterface).reuseObjs()
depPaths.Objs = depPaths.Objs.Append(objs)
reexportExporter(exporter)
return
}
}
if depTag == staticVariantTag {
// staticVariants are a cc.Module specific concept.
if _, ok := ccDep.(*Module); ok && ccDep.CcLibraryInterface() {
c.staticVariant = ccDep
return
}
}
// Extract ExplicitlyVersioned field from the depTag and reset it inside the struct.
// Otherwise, SharedDepTag and lateSharedDepTag with ExplicitlyVersioned set to true
// won't be matched to SharedDepTag and lateSharedDepTag.
explicitlyVersioned := false
if t, ok := depTag.(DependencyTag); ok {
explicitlyVersioned = t.ExplicitlyVersioned
t.ExplicitlyVersioned = false
depTag = t
}
if t, ok := depTag.(DependencyTag); ok && t.Library {
depIsStatic := false
switch depTag {
case StaticDepTag, staticExportDepTag, lateStaticDepTag, wholeStaticDepTag:
depIsStatic = true
}
if ccDep.CcLibrary() && !depIsStatic {
depIsStubs := ccDep.BuildStubs()
depHasStubs := ccDep.HasStubsVariants()
depInSameApex := android.DirectlyInApex(c.ApexName(), depName)
depInPlatform := !android.DirectlyInAnyApex(ctx, depName)
var useThisDep bool
if depIsStubs && explicitlyVersioned {
// Always respect dependency to the versioned stubs (i.e. libX#10)
useThisDep = true
} else if !depHasStubs {
// Use non-stub variant if that is the only choice
// (i.e. depending on a lib without stubs.version property)
useThisDep = true
} else if c.IsForPlatform() {
// If not building for APEX, use stubs only when it is from
// an APEX (and not from platform)
useThisDep = (depInPlatform != depIsStubs)
if c.InRecovery() || c.bootstrap() {
// However, for recovery or bootstrap modules,
// always link to non-stub variant
useThisDep = !depIsStubs
}
} else {
// If building for APEX, use stubs only when it is not from
// the same APEX
useThisDep = (depInSameApex != depIsStubs)
}
if !useThisDep {
return // stop processing this dep
}
}
// Exporting flags only makes sense for cc.Modules
if _, ok := ccDep.(*Module); ok {
if i, ok := ccDep.(*Module).linker.(exportedFlagsProducer); ok {
depPaths.IncludeDirs = append(depPaths.IncludeDirs, i.exportedDirs()...)
depPaths.SystemIncludeDirs = append(depPaths.SystemIncludeDirs, i.exportedSystemDirs()...)
depPaths.GeneratedHeaders = append(depPaths.GeneratedHeaders, i.exportedDeps()...)
depPaths.Flags = append(depPaths.Flags, i.exportedFlags()...)
if t.ReexportFlags {
reexportExporter(i)
// Add these re-exported flags to help header-abi-dumper to infer the abi exported by a library.
// Re-exported shared library headers must be included as well since they can help us with type information
// about template instantiations (instantiated from their headers).
// -isystem headers are not included since for bionic libraries, abi-filtering is taken care of by version
// scripts.
c.sabi.Properties.ReexportedIncludes = append(
c.sabi.Properties.ReexportedIncludes, i.exportedDirs().Strings()...)
}
}
}
checkLinkType(ctx, c, ccDep, t)
}
var ptr *android.Paths
var depPtr *android.Paths
linkFile := ccDep.OutputFile()
depFile := android.OptionalPath{}
switch depTag {
case ndkStubDepTag, SharedDepTag, sharedExportDepTag:
ptr = &depPaths.SharedLibs
depPtr = &depPaths.SharedLibsDeps
depFile = ccDep.Toc()
directSharedDeps = append(directSharedDeps, ccDep)
case earlySharedDepTag:
ptr = &depPaths.EarlySharedLibs
depPtr = &depPaths.EarlySharedLibsDeps
depFile = ccDep.Toc()
directSharedDeps = append(directSharedDeps, ccDep)
case lateSharedDepTag, ndkLateStubDepTag:
ptr = &depPaths.LateSharedLibs
depPtr = &depPaths.LateSharedLibsDeps
depFile = ccDep.Toc()
case StaticDepTag, staticExportDepTag:
ptr = nil
directStaticDeps = append(directStaticDeps, ccDep)
case lateStaticDepTag:
ptr = &depPaths.LateStaticLibs
case wholeStaticDepTag:
ptr = &depPaths.WholeStaticLibs
if !ccDep.CcLibraryInterface() || !ccDep.Static() {
ctx.ModuleErrorf("module %q not a static library", depName)
return
}
// Because the static library objects are included, this only makes sense
// in the context of proper cc.Modules.
if ccWholeStaticLib, ok := ccDep.(*Module); ok {
staticLib := ccWholeStaticLib.linker.(libraryInterface)
if missingDeps := staticLib.getWholeStaticMissingDeps(); missingDeps != nil {
postfix := " (required by " + ctx.OtherModuleName(dep) + ")"
for i := range missingDeps {
missingDeps[i] += postfix
}
ctx.AddMissingDependencies(missingDeps)
}
depPaths.WholeStaticLibObjs = depPaths.WholeStaticLibObjs.Append(staticLib.objs())
} else {
ctx.ModuleErrorf(
"non-cc.Modules cannot be included as whole static libraries.", depName)
return
}
case headerDepTag:
// Nothing
case objDepTag:
depPaths.Objs.objFiles = append(depPaths.Objs.objFiles, linkFile.Path())
case CrtBeginDepTag:
depPaths.CrtBegin = linkFile
case CrtEndDepTag:
depPaths.CrtEnd = linkFile
case dynamicLinkerDepTag:
depPaths.DynamicLinker = linkFile
}
switch depTag {
case StaticDepTag, staticExportDepTag, lateStaticDepTag:
if !ccDep.CcLibraryInterface() || !ccDep.Static() {
ctx.ModuleErrorf("module %q not a static library", depName)
return
}
// When combining coverage files for shared libraries and executables, coverage files
// in static libraries act as if they were whole static libraries. The same goes for
// source based Abi dump files.
// This should only be done for cc.Modules
if c, ok := ccDep.(*Module); ok {
staticLib := c.linker.(libraryInterface)
depPaths.StaticLibObjs.coverageFiles = append(depPaths.StaticLibObjs.coverageFiles,
staticLib.objs().coverageFiles...)
depPaths.StaticLibObjs.sAbiDumpFiles = append(depPaths.StaticLibObjs.sAbiDumpFiles,
staticLib.objs().sAbiDumpFiles...)
}
}
if ptr != nil {
if !linkFile.Valid() {
if !ctx.Config().AllowMissingDependencies() {
ctx.ModuleErrorf("module %q missing output file", depName)
} else {
ctx.AddMissingDependencies([]string{depName})
}
return
}
*ptr = append(*ptr, linkFile.Path())
}
if depPtr != nil {
dep := depFile
if !dep.Valid() {
dep = linkFile
}
*depPtr = append(*depPtr, dep.Path())
}
makeLibName := func(depName string) string {
libName := strings.TrimSuffix(depName, llndkLibrarySuffix)
libName = strings.TrimSuffix(libName, vendorPublicLibrarySuffix)
libName = strings.TrimPrefix(libName, "prebuilt_")
isLLndk := isLlndkLibrary(libName, ctx.Config())
isVendorPublicLib := inList(libName, *vendorPublicLibraries)
bothVendorAndCoreVariantsExist := ccDep.HasVendorVariant() || isLLndk
if ctx.DeviceConfig().VndkUseCoreVariant() && ccDep.IsVndk() && !ccDep.MustUseVendorVariant() && !c.InRecovery() {
// The vendor module is a no-vendor-variant VNDK library. Depend on the
// core module instead.
return libName
} else if c.UseVndk() && bothVendorAndCoreVariantsExist {
// The vendor module in Make will have been renamed to not conflict with the core
// module, so update the dependency name here accordingly.
ret := libName + vendorSuffix
vendorVersion := ctx.DeviceConfig().VndkVersion()
if vendorVersion == "current" {
vendorVersion = ctx.DeviceConfig().PlatformVndkVersion()
}
if c.Properties.VndkVersion != vendorVersion {
ret += "." + c.Properties.VndkVersion
}
return ret
} else if (ctx.Platform() || ctx.ProductSpecific()) && isVendorPublicLib {
return libName + vendorPublicLibrarySuffix
} else if ccDep.InRecovery() && !ccDep.OnlyInRecovery() {
return libName + recoverySuffix
} else if ccDep.Module().Target().NativeBridge == android.NativeBridgeEnabled {
return libName + nativeBridgeSuffix
} else {
return libName
}
}
// Export the shared libs to Make.
switch depTag {
case SharedDepTag, sharedExportDepTag, lateSharedDepTag, earlySharedDepTag:
if ccDep.CcLibrary() {
if ccDep.BuildStubs() && android.InAnyApex(depName) {
// Add the dependency to the APEX(es) providing the library so that
// m <module> can trigger building the APEXes as well.
for _, an := range android.GetApexesForModule(depName) {
c.Properties.ApexesProvidingSharedLibs = append(
c.Properties.ApexesProvidingSharedLibs, an)
}
}
}
// Note: the order of libs in this list is not important because
// they merely serve as Make dependencies and do not affect this lib itself.
c.Properties.AndroidMkSharedLibs = append(
c.Properties.AndroidMkSharedLibs, makeLibName(depName))
case ndkStubDepTag, ndkLateStubDepTag:
c.Properties.AndroidMkSharedLibs = append(
c.Properties.AndroidMkSharedLibs,
depName+"."+ccDep.ApiLevel())
case StaticDepTag, staticExportDepTag, lateStaticDepTag:
c.Properties.AndroidMkStaticLibs = append(
c.Properties.AndroidMkStaticLibs, makeLibName(depName))
case runtimeDepTag:
c.Properties.AndroidMkRuntimeLibs = append(
c.Properties.AndroidMkRuntimeLibs, makeLibName(depName))
case wholeStaticDepTag:
c.Properties.AndroidMkWholeStaticLibs = append(
c.Properties.AndroidMkWholeStaticLibs, makeLibName(depName))
}
})
// use the ordered dependencies as this module's dependencies
depPaths.StaticLibs = append(depPaths.StaticLibs, orderStaticModuleDeps(c, directStaticDeps, directSharedDeps)...)
// Dedup exported flags from dependencies
depPaths.Flags = android.FirstUniqueStrings(depPaths.Flags)
depPaths.IncludeDirs = android.FirstUniquePaths(depPaths.IncludeDirs)
depPaths.SystemIncludeDirs = android.FirstUniquePaths(depPaths.SystemIncludeDirs)
depPaths.GeneratedHeaders = android.FirstUniquePaths(depPaths.GeneratedHeaders)
depPaths.ReexportedDirs = android.FirstUniquePaths(depPaths.ReexportedDirs)
depPaths.ReexportedSystemDirs = android.FirstUniquePaths(depPaths.ReexportedSystemDirs)
depPaths.ReexportedFlags = android.FirstUniqueStrings(depPaths.ReexportedFlags)
depPaths.ReexportedDeps = android.FirstUniquePaths(depPaths.ReexportedDeps)
if c.sabi != nil {
c.sabi.Properties.ReexportedIncludes = android.FirstUniqueStrings(c.sabi.Properties.ReexportedIncludes)
}
return depPaths
}
func (c *Module) InstallInData() bool {
if c.installer == nil {
return false
}
return c.installer.inData()
}
func (c *Module) InstallInSanitizerDir() bool {
if c.installer == nil {
return false
}
if c.sanitize != nil && c.sanitize.inSanitizerDir() {
return true
}
return c.installer.inSanitizerDir()
}
func (c *Module) InstallInRecovery() bool {
return c.InRecovery()
}
func (c *Module) HostToolPath() android.OptionalPath {
if c.installer == nil {
return android.OptionalPath{}
}
return c.installer.hostToolPath()
}
func (c *Module) IntermPathForModuleOut() android.OptionalPath {
return c.outputFile
}
func (c *Module) OutputFiles(tag string) (android.Paths, error) {
switch tag {
case "":
if c.outputFile.Valid() {
return android.Paths{c.outputFile.Path()}, nil
}
return android.Paths{}, nil
default:
return nil, fmt.Errorf("unsupported module reference tag %q", tag)
}
}
func (c *Module) static() bool {
if static, ok := c.linker.(interface {
static() bool
}); ok {
return static.static()
}
return false
}
func (c *Module) staticBinary() bool {
if static, ok := c.linker.(interface {
staticBinary() bool
}); ok {
return static.staticBinary()
}
return false
}
func (c *Module) header() bool {
if h, ok := c.linker.(interface {
header() bool
}); ok {
return h.header()
}
return false
}
func (c *Module) getMakeLinkType(actx android.ModuleContext) string {
if c.UseVndk() {
if lib, ok := c.linker.(*llndkStubDecorator); ok {
if Bool(lib.Properties.Vendor_available) {
return "native:vndk"
}
return "native:vndk_private"
}
if c.IsVndk() && !c.isVndkExt() {
if Bool(c.VendorProperties.Vendor_available) {
return "native:vndk"
}
return "native:vndk_private"
}
return "native:vendor"
} else if c.InRecovery() {
return "native:recovery"
} else if c.Target().Os == android.Android && String(c.Properties.Sdk_version) != "" {
return "native:ndk:none:none"
// TODO(b/114741097): use the correct ndk stl once build errors have been fixed
//family, link := getNdkStlFamilyAndLinkType(c)
//return fmt.Sprintf("native:ndk:%s:%s", family, link)
} else if actx.DeviceConfig().VndkUseCoreVariant() && !c.MustUseVendorVariant() {
return "native:platform_vndk"
} else {
return "native:platform"
}
}
// Overrides ApexModule.IsInstallabeToApex()
// Only shared/runtime libraries and "test_per_src" tests are installable to APEX.
func (c *Module) IsInstallableToApex() bool {
if shared, ok := c.linker.(interface {
shared() bool
}); ok {
// Stub libs and prebuilt libs in a versioned SDK are not
// installable to APEX even though they are shared libs.
return shared.shared() && !c.IsStubs() && c.ContainingSdk().Unversioned()
} else if _, ok := c.linker.(testPerSrc); ok {
return true
}
return false
}
func (c *Module) AvailableFor(what string) bool {
if linker, ok := c.linker.(interface {
availableFor(string) bool
}); ok {
return c.ApexModuleBase.AvailableFor(what) || linker.availableFor(what)
} else {
return c.ApexModuleBase.AvailableFor(what)
}
}
func (c *Module) installable() bool {
return c.installer != nil && !c.Properties.PreventInstall && c.IsForPlatform() && c.outputFile.Valid()
}
func (c *Module) imageVariation() string {
if c.UseVndk() {
return vendorMode + "." + c.Properties.VndkVersion
} else if c.InRecovery() {
return recoveryMode
}
return coreMode
}
func (c *Module) IDEInfo(dpInfo *android.IdeInfo) {
outputFiles, err := c.OutputFiles("")
if err != nil {
panic(err)
}
dpInfo.Srcs = append(dpInfo.Srcs, outputFiles.Strings()...)
}
func (c *Module) AndroidMkWriteAdditionalDependenciesForSourceAbiDiff(w io.Writer) {
if c.linker != nil {
if library, ok := c.linker.(*libraryDecorator); ok {
library.androidMkWriteAdditionalDependenciesForSourceAbiDiff(w)
}
}
}
func (c *Module) DepIsInSameApex(ctx android.BaseModuleContext, dep android.Module) bool {
if depTag, ok := ctx.OtherModuleDependencyTag(dep).(DependencyTag); ok {
if cc, ok := dep.(*Module); ok && cc.IsStubs() && depTag.Shared {
// dynamic dep to a stubs lib crosses APEX boundary
return false
}
}
return true
}
//
// Defaults
//
type Defaults struct {
android.ModuleBase
android.DefaultsModuleBase
android.ApexModuleBase
}
// cc_defaults provides a set of properties that can be inherited by other cc
// modules. A module can use the properties from a cc_defaults using
// `defaults: ["<:default_module_name>"]`. Properties of both modules are
// merged (when possible) by prepending the default module's values to the
// depending module's values.
func defaultsFactory() android.Module {
return DefaultsFactory()
}
func DefaultsFactory(props ...interface{}) android.Module {
module := &Defaults{}
module.AddProperties(props...)
module.AddProperties(
&BaseProperties{},
&VendorProperties{},
&BaseCompilerProperties{},
&BaseLinkerProperties{},
&ObjectLinkerProperties{},
&LibraryProperties{},
&StaticProperties{},
&SharedProperties{},
&FlagExporterProperties{},
&BinaryLinkerProperties{},
&TestProperties{},
&TestBinaryProperties{},
&FuzzProperties{},
&StlProperties{},
&SanitizeProperties{},
&StripProperties{},
&InstallerProperties{},
&TidyProperties{},
&CoverageProperties{},
&SAbiProperties{},
&VndkProperties{},
&LTOProperties{},
&PgoProperties{},
&XomProperties{},
&android.ProtoProperties{},
)
android.InitDefaultsModule(module)
android.InitApexModule(module)
return module
}
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
const (
// coreMode is the variant used for framework-private libraries, or
// SDK libraries. (which framework-private libraries can use)
coreMode = "core"
// vendorMode is the variant prefix used for /vendor code that compiles
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
// against the VNDK.
vendorMode = "vendor"
recoveryMode = "recovery"
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
)
func squashVendorSrcs(m *Module) {
if lib, ok := m.compiler.(*libraryDecorator); ok {
lib.baseCompiler.Properties.Srcs = append(lib.baseCompiler.Properties.Srcs,
lib.baseCompiler.Properties.Target.Vendor.Srcs...)
lib.baseCompiler.Properties.Exclude_srcs = append(lib.baseCompiler.Properties.Exclude_srcs,
lib.baseCompiler.Properties.Target.Vendor.Exclude_srcs...)
}
}
func squashRecoverySrcs(m *Module) {
if lib, ok := m.compiler.(*libraryDecorator); ok {
lib.baseCompiler.Properties.Srcs = append(lib.baseCompiler.Properties.Srcs,
lib.baseCompiler.Properties.Target.Recovery.Srcs...)
lib.baseCompiler.Properties.Exclude_srcs = append(lib.baseCompiler.Properties.Exclude_srcs,
lib.baseCompiler.Properties.Target.Recovery.Exclude_srcs...)
}
}
func ImageMutator(mctx android.BottomUpMutatorContext) {
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
if mctx.Os() != android.Android {
return
}
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
if g, ok := mctx.Module().(*genrule.Module); ok {
if props, ok := g.Extra.(*GenruleExtraProperties); ok {
var coreVariantNeeded bool = false
var vendorVariantNeeded bool = false
var recoveryVariantNeeded bool = false
if mctx.DeviceConfig().VndkVersion() == "" {
coreVariantNeeded = true
} else if Bool(props.Vendor_available) {
coreVariantNeeded = true
vendorVariantNeeded = true
} else if mctx.SocSpecific() || mctx.DeviceSpecific() {
vendorVariantNeeded = true
} else {
coreVariantNeeded = true
}
if Bool(props.Recovery_available) {
recoveryVariantNeeded = true
}
if recoveryVariantNeeded {
primaryArch := mctx.Config().DevicePrimaryArchType()
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
moduleArch := g.Target().Arch.ArchType
if moduleArch != primaryArch {
recoveryVariantNeeded = false
}
}
var variants []string
if coreVariantNeeded {
variants = append(variants, coreMode)
}
if vendorVariantNeeded {
variants = append(variants, vendorMode+"."+mctx.DeviceConfig().PlatformVndkVersion())
if vndkVersion := mctx.DeviceConfig().VndkVersion(); vndkVersion != "current" {
variants = append(variants, vendorMode+"."+vndkVersion)
}
}
if recoveryVariantNeeded {
variants = append(variants, recoveryMode)
}
Add support for versioned stubs. A cc_library or cc_library_shared can be configured to have stubs variants of the lib. cc_library_shared { name: "libfoo", srcs: ["foo.cpp"], stubs: { symbol_file: "foo.map.txt", versions: ["1", "2", "3"], }, } then, stubs variants of libfoo for version 1, 2, and 3 are created from foo.map.txt. Each version has the symbols from the map file where each symbol is annotated with the version that the symbol was introduced via the 'introduced=<ver>' syntax. The versions don't need to be in sync with the platform versions (e.g., P for 28). The versions are local to the library. For another library or executable to use the versioned stubs lib, use the new 'name#ver' syntax to specify the version: cc_binary { name: "test", .... shared_libs: ["libFoo#2"], } Internally, a new mutator 'version' is applied to all cc.Module objects. By default, a variant named 'impl' is created for the non-stub version. If the versions property is set, additional variations are created per a version with the mutable property BuildStubs set as true, which lets the compiler and the linker to build a stubs lib from the symbol file instead from the source files. This feature will be used to enforce stable interfaces among APEXs. When a lib foo in an APEX is depending on a lib bar in another APEX, then bar should have stable interface (in C lang) and foo should be depending on one of the stubs libs of bar. Only libraries in the same APEX as foo can link against non-stub version of it. Bug: 112672359 Test: m (cc_test added) Change-Id: I2488be0b9d7b7b8d7761234dc1c9c0e3add8601c
2018-10-15 15:25:07 +02:00
mod := mctx.CreateVariations(variants...)
for i, v := range variants {
if v == recoveryMode {
m := mod[i].(*genrule.Module)
m.Extra.(*GenruleExtraProperties).InRecovery = true
}
}
}
}
//TODO When LinkableInterface supports VNDK, this should be mctx.Module().(LinkableInterface)
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
m, ok := mctx.Module().(*Module)
if !ok {
if linkable, ok := mctx.Module().(LinkableInterface); ok {
variations := []string{coreMode}
if linkable.InRecovery() {
variations = append(variations, recoveryMode)
}
mctx.CreateVariations(variations...)
}
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
return
}
// Sanity check
vendorSpecific := mctx.SocSpecific() || mctx.DeviceSpecific()
productSpecific := mctx.ProductSpecific()
if m.VendorProperties.Vendor_available != nil && vendorSpecific {
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
mctx.PropertyErrorf("vendor_available",
"doesn't make sense at the same time as `vendor: true`, `proprietary: true`, or `device_specific:true`")
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
return
}
if vndkdep := m.vndkdep; vndkdep != nil {
if vndkdep.isVndk() {
if productSpecific {
mctx.PropertyErrorf("product_specific",
"product_specific must not be true when `vndk: {enabled: true}`")
return
}
if vendorSpecific {
if !vndkdep.isVndkExt() {
mctx.PropertyErrorf("vndk",
"must set `extends: \"...\"` to vndk extension")
return
}
} else {
if vndkdep.isVndkExt() {
mctx.PropertyErrorf("vndk",
"must set `vendor: true` to set `extends: %q`",
m.getVndkExtendsModuleName())
return
}
if m.VendorProperties.Vendor_available == nil {
mctx.PropertyErrorf("vndk",
"vendor_available must be set to either true or false when `vndk: {enabled: true}`")
return
}
}
} else {
if vndkdep.isVndkSp() {
mctx.PropertyErrorf("vndk",
"must set `enabled: true` to set `support_system_process: true`")
return
}
if vndkdep.isVndkExt() {
mctx.PropertyErrorf("vndk",
"must set `enabled: true` to set `extends: %q`",
m.getVndkExtendsModuleName())
return
}
}
}
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
var coreVariantNeeded bool = false
var recoveryVariantNeeded bool = false
var vendorVariants []string
platformVndkVersion := mctx.DeviceConfig().PlatformVndkVersion()
deviceVndkVersion := mctx.DeviceConfig().VndkVersion()
if deviceVndkVersion == "current" {
deviceVndkVersion = platformVndkVersion
}
if mctx.DeviceConfig().VndkVersion() == "" {
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
// If the device isn't compiling against the VNDK, we always
// use the core mode.
coreVariantNeeded = true
} else if m.Target().NativeBridge == android.NativeBridgeEnabled {
// Skip creating vendor variants for natvie bridge modules
coreVariantNeeded = true
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
} else if _, ok := m.linker.(*llndkStubDecorator); ok {
// LL-NDK stubs only exist in the vendor variant, since the
// real libraries will be used in the core variant.
vendorVariants = append(vendorVariants,
platformVndkVersion,
deviceVndkVersion,
)
} else if _, ok := m.linker.(*llndkHeadersDecorator); ok {
// ... and LL-NDK headers as well
vendorVariants = append(vendorVariants,
platformVndkVersion,
deviceVndkVersion,
)
} else if lib, ok := m.linker.(*vndkPrebuiltLibraryDecorator); ok {
// Make vendor variants only for the versions in BOARD_VNDK_VERSION and
// PRODUCT_EXTRA_VNDK_VERSIONS.
vendorVariants = append(vendorVariants, lib.version())
} else if m.HasVendorVariant() && !vendorSpecific {
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
// This will be available in both /system and /vendor
// or a /system directory that is available to vendor.
coreVariantNeeded = true
vendorVariants = append(vendorVariants, platformVndkVersion)
// VNDK modules must not create BOARD_VNDK_VERSION variant because its
// code is PLATFORM_VNDK_VERSION.
// On the other hand, vendor_available modules which are not VNDK should
// also build BOARD_VNDK_VERSION because it's installed in /vendor.
if !m.IsVndk() {
vendorVariants = append(vendorVariants, deviceVndkVersion)
}
} else if vendorSpecific && String(m.Properties.Sdk_version) == "" {
// This will be available in /vendor (or /odm) only
vendorVariants = append(vendorVariants, deviceVndkVersion)
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
} else {
// This is either in /system (or similar: /data), or is a
// modules built with the NDK. Modules built with the NDK
// will be restricted using the existing link type checks.
coreVariantNeeded = true
}
if Bool(m.Properties.Recovery_available) {
recoveryVariantNeeded = true
}
if m.ModuleBase.InstallInRecovery() {
recoveryVariantNeeded = true
coreVariantNeeded = false
}
if recoveryVariantNeeded {
primaryArch := mctx.Config().DevicePrimaryArchType()
moduleArch := m.Target().Arch.ArchType
if moduleArch != primaryArch {
recoveryVariantNeeded = false
}
}
var variants []string
if coreVariantNeeded {
variants = append(variants, coreMode)
}
for _, variant := range android.FirstUniqueStrings(vendorVariants) {
variants = append(variants, vendorMode+"."+variant)
}
if recoveryVariantNeeded {
variants = append(variants, recoveryMode)
}
mod := mctx.CreateVariations(variants...)
for i, v := range variants {
if strings.HasPrefix(v, vendorMode+".") {
m := mod[i].(*Module)
m.Properties.VndkVersion = strings.TrimPrefix(v, vendorMode+".")
squashVendorSrcs(m)
} else if v == recoveryMode {
m := mod[i].(*Module)
m.Properties.InRecovery = true
m.MakeAsPlatform()
squashRecoverySrcs(m)
}
Split /system and /vendor modules, allow multi-installation Nothing changes if BOARD_VNDK_VERSION isn't set. When the VNDK is enabled (BOARD_VNDK_VERSION in Make), this will split /system and /vendor modules into two different variant spaces that can't link to each other. There are a few interfaces between the two variant spaces: The `llndk_library` stubs will be available in the /vendor variant, but won't be installed, so at runtime the /system variant will be used. Setting `vendor_available: true` will split a module into both variants. The /system (or "core") variant will compile just like today. The /vendor ("vendor") variant will compile against everything else in the vendor space (so LL-NDK instead of libc/liblog/etc). There will be two copies of these libraries installed onto the final device. Since the available runtime interfaces for vendor modules may be reduced, and your dependencies may not expose their private interfaces, we allow the vendor variants to reduce their compilation set, and export a different set of headers: cc_library { name: "libfoo", srcs: ["common.cpp", "private_impl.cpp"], export_include_dirs: ["include"], target: { vendor: { export_include_dirs: ["include_vndk"], exclude_srcs: ["private_impl.cpp"], srcs: ["vendor_only.cpp"], }, }, } So the "core" variant would compile with both "common.cpp" and "private_impl.cpp", and export "include". The "vendor" variant would compile "common.cpp" and "vendor_only.cpp", and export "include_vndk". Bug: 36426473 Bug: 36079834 Test: out/soong/build.ninja, out/soong/Android- only changes due to _core addition and .llndk -> .vendor Test: attempt to compile with BOARD_VNDK_VERSION:=current Change-Id: Idef28764043bf6c33dc0d2e7e2026c38867ff769
2017-04-06 21:43:22 +02:00
}
}
func getCurrentNdkPrebuiltVersion(ctx DepsContext) string {
if ctx.Config().PlatformSdkVersionInt() > config.NdkMaxPrebuiltVersionInt {
return strconv.Itoa(config.NdkMaxPrebuiltVersionInt)
}
return ctx.Config().PlatformSdkVersion()
}
Support source code cross-referencing for C++ and Java Use Kythe (https://kythe.io) to build cross reference for the Android source code. ~generate the input for it during the build. This is done on demand: if XREF_CORPUS environment variable is set, build emits a Ninja rule to generate Kythe input for each compilation rule. It also emits two consolidation rules (`xref_cxx` and `xref_java`), that depend on all Kythe input generation rules for C++ and Java. The value of the XREF_CORPUS environment variable is recorded in the generated files and thus passed to Kythe. For the AOSP master branch it is `android.googlesource.com/platform/superproject`, so the command to build all input for Kythe on that branch is: ``` XREF_CORPUS=android.googlesource.com/platform/superproject m xref_cxx xref_java ``` Each Kythe input generation rule generates a single file with .kzip extension. Individual .kzip files have a lot of common information, so there will be a post-build consolidation step run to combine them. The consolidated .kzip file is then passed to Kythe backend. The tools to generate .kzip files are provided by Kythe (it calls them 'extractors'). We are going to build them in toolbuilding branches (clang-tools and build-tools) and check them in as binaries into master and other PDK branches: For C++, `prebuilts/clang-tools/linux-x86/bin/cxx_extractor` for Java, `prebuilts/build-tools/common/framework/javac_extractor.jar` Bug: 121267023 Test: 1) When XREF_CORPUS is set, build generates Ninja rules to create .kzip files; 2) When XREF_CORPUS is set, building `xref_cxx`/`xref_java` creates .kzip files; 3) Unless XREF_CORPUS is set, build generates the same Ninja rules as before Change-Id: If957b35d7abc82dbfbb3665980e7c34afe7c789e
2018-11-06 01:49:08 +01:00
func kytheExtractAllFactory() android.Singleton {
return &kytheExtractAllSingleton{}
}
type kytheExtractAllSingleton struct {
}
func (ks *kytheExtractAllSingleton) GenerateBuildActions(ctx android.SingletonContext) {
var xrefTargets android.Paths
ctx.VisitAllModules(func(module android.Module) {
if ccModule, ok := module.(xref); ok {
xrefTargets = append(xrefTargets, ccModule.XrefCcFiles()...)
}
})
// TODO(asmundak): Perhaps emit a rule to output a warning if there were no xrefTargets
if len(xrefTargets) > 0 {
ctx.Build(pctx, android.BuildParams{
Rule: blueprint.Phony,
Output: android.PathForPhony(ctx, "xref_cxx"),
Inputs: xrefTargets,
//Default: true,
})
}
}
var Bool = proptools.Bool
var BoolDefault = proptools.BoolDefault
var BoolPtr = proptools.BoolPtr
var String = proptools.String
var StringPtr = proptools.StringPtr