platform_build_soong/sdk/update.go
Paul Duffin f88d8e032f Syntax check generated Android.bp snapshot
Checks the syntax of the Android.bp file generated for the sdk
snapshot. While this will not detect all possible problems with the
generated Android.bp file it will detect some and it is far better to
detect those issues during generation than when it is unpacked and
used.

Bug: 155628860
Test: m nothing
Change-Id: Ieec86a7a49fa2e3bd8b9f83aca540114232a3476
2020-05-12 09:52:41 +01:00

1526 lines
49 KiB
Go

// Copyright (C) 2019 The Android Open Source Project
//
// 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 sdk
import (
"fmt"
"reflect"
"sort"
"strings"
"android/soong/apex"
"android/soong/cc"
"github.com/google/blueprint"
"github.com/google/blueprint/proptools"
"android/soong/android"
)
var pctx = android.NewPackageContext("android/soong/sdk")
var (
repackageZip = pctx.AndroidStaticRule("SnapshotRepackageZip",
blueprint.RuleParams{
Command: `${config.Zip2ZipCmd} -i $in -o $out -x META-INF/**/* "**/*:$destdir"`,
CommandDeps: []string{
"${config.Zip2ZipCmd}",
},
},
"destdir")
zipFiles = pctx.AndroidStaticRule("SnapshotZipFiles",
blueprint.RuleParams{
Command: `${config.SoongZipCmd} -C $basedir -l $out.rsp -o $out`,
CommandDeps: []string{
"${config.SoongZipCmd}",
},
Rspfile: "$out.rsp",
RspfileContent: "$in",
},
"basedir")
mergeZips = pctx.AndroidStaticRule("SnapshotMergeZips",
blueprint.RuleParams{
Command: `${config.MergeZipsCmd} $out $in`,
CommandDeps: []string{
"${config.MergeZipsCmd}",
},
})
)
type generatedContents struct {
content strings.Builder
indentLevel int
}
// generatedFile abstracts operations for writing contents into a file and emit a build rule
// for the file.
type generatedFile struct {
generatedContents
path android.OutputPath
}
func newGeneratedFile(ctx android.ModuleContext, path ...string) *generatedFile {
return &generatedFile{
path: android.PathForModuleOut(ctx, path...).OutputPath,
}
}
func (gc *generatedContents) Indent() {
gc.indentLevel++
}
func (gc *generatedContents) Dedent() {
gc.indentLevel--
}
func (gc *generatedContents) Printfln(format string, args ...interface{}) {
fmt.Fprintf(&(gc.content), strings.Repeat(" ", gc.indentLevel)+format+"\n", args...)
}
func (gf *generatedFile) build(pctx android.PackageContext, ctx android.BuilderContext, implicits android.Paths) {
rb := android.NewRuleBuilder()
content := gf.content.String()
// ninja consumes newline characters in rspfile_content. Prevent it by
// escaping the backslash in the newline character. The extra backslash
// is removed when the rspfile is written to the actual script file
content = strings.ReplaceAll(content, "\n", "\\n")
rb.Command().
Implicits(implicits).
Text("echo").Text(proptools.ShellEscape(content)).
// convert \\n to \n
Text("| sed 's/\\\\n/\\n/g' >").Output(gf.path)
rb.Command().
Text("chmod a+x").Output(gf.path)
rb.Build(pctx, ctx, gf.path.Base(), "Build "+gf.path.Base())
}
// Collect all the members.
//
// Returns a list containing type (extracted from the dependency tag) and the variant
// plus the multilib usages.
func (s *sdk) collectMembers(ctx android.ModuleContext) {
s.multilibUsages = multilibNone
ctx.WalkDeps(func(child android.Module, parent android.Module) bool {
tag := ctx.OtherModuleDependencyTag(child)
if memberTag, ok := tag.(android.SdkMemberTypeDependencyTag); ok {
memberType := memberTag.SdkMemberType()
// Make sure that the resolved module is allowed in the member list property.
if !memberType.IsInstance(child) {
ctx.ModuleErrorf("module %q is not valid in property %s", ctx.OtherModuleName(child), memberType.SdkPropertyName())
}
// Keep track of which multilib variants are used by the sdk.
s.multilibUsages = s.multilibUsages.addArchType(child.Target().Arch.ArchType)
s.memberRefs = append(s.memberRefs, sdkMemberRef{memberType, child.(android.SdkAware)})
// If the member type supports transitive sdk members then recurse down into
// its dependencies, otherwise exit traversal.
return memberType.HasTransitiveSdkMembers()
}
return false
})
}
// Organize the members.
//
// The members are first grouped by type and then grouped by name. The order of
// the types is the order they are referenced in android.SdkMemberTypesRegistry.
// The names are in the order in which the dependencies were added.
//
// Returns the members as well as the multilib setting to use.
func (s *sdk) organizeMembers(ctx android.ModuleContext, memberRefs []sdkMemberRef) []*sdkMember {
byType := make(map[android.SdkMemberType][]*sdkMember)
byName := make(map[string]*sdkMember)
for _, memberRef := range memberRefs {
memberType := memberRef.memberType
variant := memberRef.variant
name := ctx.OtherModuleName(variant)
member := byName[name]
if member == nil {
member = &sdkMember{memberType: memberType, name: name}
byName[name] = member
byType[memberType] = append(byType[memberType], member)
}
// Only append new variants to the list. This is needed because a member can be both
// exported by the sdk and also be a transitive sdk member.
member.variants = appendUniqueVariants(member.variants, variant)
}
var members []*sdkMember
for _, memberListProperty := range s.memberListProperties() {
membersOfType := byType[memberListProperty.memberType]
members = append(members, membersOfType...)
}
return members
}
func appendUniqueVariants(variants []android.SdkAware, newVariant android.SdkAware) []android.SdkAware {
for _, v := range variants {
if v == newVariant {
return variants
}
}
return append(variants, newVariant)
}
// SDK directory structure
// <sdk_root>/
// Android.bp : definition of a 'sdk' module is here. This is a hand-made one.
// <api_ver>/ : below this directory are all auto-generated
// Android.bp : definition of 'sdk_snapshot' module is here
// aidl/
// frameworks/base/core/..../IFoo.aidl : an exported AIDL file
// java/
// <module_name>.jar : the stub jar for a java library 'module_name'
// include/
// bionic/libc/include/stdlib.h : an exported header file
// include_gen/
// <module_name>/com/android/.../IFoo.h : a generated header file
// <arch>/include/ : arch-specific exported headers
// <arch>/include_gen/ : arch-specific generated headers
// <arch>/lib/
// libFoo.so : a stub library
// A name that uniquely identifies a prebuilt SDK member for a version of SDK snapshot
// This isn't visible to users, so could be changed in future.
func versionedSdkMemberName(ctx android.ModuleContext, memberName string, version string) string {
return ctx.ModuleName() + "_" + memberName + string(android.SdkVersionSeparator) + version
}
// buildSnapshot is the main function in this source file. It creates rules to copy
// the contents (header files, stub libraries, etc) into the zip file.
func (s *sdk) buildSnapshot(ctx android.ModuleContext, sdkVariants []*sdk) android.OutputPath {
allMembersByName := make(map[string]struct{})
exportedMembersByName := make(map[string]struct{})
var memberRefs []sdkMemberRef
for _, sdkVariant := range sdkVariants {
memberRefs = append(memberRefs, sdkVariant.memberRefs...)
// Record the names of all the members, both explicitly specified and implicitly
// included.
for _, memberRef := range sdkVariant.memberRefs {
allMembersByName[memberRef.variant.Name()] = struct{}{}
}
// Merge the exported member sets from all sdk variants.
for key, _ := range sdkVariant.getExportedMembers() {
exportedMembersByName[key] = struct{}{}
}
}
snapshotDir := android.PathForModuleOut(ctx, "snapshot")
bp := newGeneratedFile(ctx, "snapshot", "Android.bp")
bpFile := &bpFile{
modules: make(map[string]*bpModule),
}
builder := &snapshotBuilder{
ctx: ctx,
sdk: s,
version: "current",
snapshotDir: snapshotDir.OutputPath,
copies: make(map[string]string),
filesToZip: []android.Path{bp.path},
bpFile: bpFile,
prebuiltModules: make(map[string]*bpModule),
allMembersByName: allMembersByName,
exportedMembersByName: exportedMembersByName,
}
s.builderForTests = builder
members := s.organizeMembers(ctx, memberRefs)
for _, member := range members {
memberType := member.memberType
memberCtx := &memberContext{ctx, builder, memberType, member.name}
prebuiltModule := memberType.AddPrebuiltModule(memberCtx, member)
s.createMemberSnapshot(memberCtx, member, prebuiltModule)
}
// Create a transformer that will transform an unversioned module into a versioned module.
unversionedToVersionedTransformer := unversionedToVersionedTransformation{builder: builder}
// Create a transformer that will transform an unversioned module by replacing any references
// to internal members with a unique module name and setting prefer: false.
unversionedTransformer := unversionedTransformation{builder: builder}
for _, unversioned := range builder.prebuiltOrder {
// Prune any empty property sets.
unversioned = unversioned.transform(pruneEmptySetTransformer{})
// Copy the unversioned module so it can be modified to make it versioned.
versioned := unversioned.deepCopy()
// Transform the unversioned module into a versioned one.
versioned.transform(unversionedToVersionedTransformer)
bpFile.AddModule(versioned)
// Transform the unversioned module to make it suitable for use in the snapshot.
unversioned.transform(unversionedTransformer)
bpFile.AddModule(unversioned)
}
// Create the snapshot module.
snapshotName := ctx.ModuleName() + string(android.SdkVersionSeparator) + builder.version
var snapshotModuleType string
if s.properties.Module_exports {
snapshotModuleType = "module_exports_snapshot"
} else {
snapshotModuleType = "sdk_snapshot"
}
snapshotModule := bpFile.newModule(snapshotModuleType)
snapshotModule.AddProperty("name", snapshotName)
// Make sure that the snapshot has the same visibility as the sdk.
visibility := android.EffectiveVisibilityRules(ctx, s)
if len(visibility) != 0 {
snapshotModule.AddProperty("visibility", visibility)
}
addHostDeviceSupportedProperties(s.ModuleBase.DeviceSupported(), s.ModuleBase.HostSupported(), snapshotModule)
var dynamicMemberPropertiesContainers []propertiesContainer
osTypeToMemberProperties := make(map[android.OsType]*sdk)
for _, sdkVariant := range sdkVariants {
properties := sdkVariant.dynamicMemberTypeListProperties
osTypeToMemberProperties[sdkVariant.Target().Os] = sdkVariant
dynamicMemberPropertiesContainers = append(dynamicMemberPropertiesContainers, &dynamicMemberPropertiesContainer{sdkVariant, properties})
}
// Extract the common lists of members into a separate struct.
commonDynamicMemberProperties := s.dynamicSdkMemberTypes.createMemberListProperties()
extractor := newCommonValueExtractor(commonDynamicMemberProperties)
extractCommonProperties(ctx, extractor, commonDynamicMemberProperties, dynamicMemberPropertiesContainers)
// Add properties common to all os types.
s.addMemberPropertiesToPropertySet(builder, snapshotModule, commonDynamicMemberProperties)
// Iterate over the os types in a fixed order.
targetPropertySet := snapshotModule.AddPropertySet("target")
for _, osType := range s.getPossibleOsTypes() {
if sdkVariant, ok := osTypeToMemberProperties[osType]; ok {
osPropertySet := targetPropertySet.AddPropertySet(sdkVariant.Target().Os.Name)
// Compile_multilib defaults to both and must always be set to both on the
// device and so only needs to be set when targeted at the host and is neither
// unspecified or both.
multilib := sdkVariant.multilibUsages
if (osType.Class == android.Host || osType.Class == android.HostCross) &&
multilib != multilibNone && multilib != multilibBoth {
osPropertySet.AddProperty("compile_multilib", multilib.String())
}
s.addMemberPropertiesToPropertySet(builder, osPropertySet, sdkVariant.dynamicMemberTypeListProperties)
}
}
// Prune any empty property sets.
snapshotModule.transform(pruneEmptySetTransformer{})
bpFile.AddModule(snapshotModule)
// generate Android.bp
bp = newGeneratedFile(ctx, "snapshot", "Android.bp")
generateBpContents(&bp.generatedContents, bpFile)
contents := bp.content.String()
syntaxCheckSnapshotBpFile(ctx, contents)
bp.build(pctx, ctx, nil)
filesToZip := builder.filesToZip
// zip them all
outputZipFile := android.PathForModuleOut(ctx, ctx.ModuleName()+"-current.zip").OutputPath
outputDesc := "Building snapshot for " + ctx.ModuleName()
// If there are no zips to merge then generate the output zip directly.
// Otherwise, generate an intermediate zip file into which other zips can be
// merged.
var zipFile android.OutputPath
var desc string
if len(builder.zipsToMerge) == 0 {
zipFile = outputZipFile
desc = outputDesc
} else {
zipFile = android.PathForModuleOut(ctx, ctx.ModuleName()+"-current.unmerged.zip").OutputPath
desc = "Building intermediate snapshot for " + ctx.ModuleName()
}
ctx.Build(pctx, android.BuildParams{
Description: desc,
Rule: zipFiles,
Inputs: filesToZip,
Output: zipFile,
Args: map[string]string{
"basedir": builder.snapshotDir.String(),
},
})
if len(builder.zipsToMerge) != 0 {
ctx.Build(pctx, android.BuildParams{
Description: outputDesc,
Rule: mergeZips,
Input: zipFile,
Inputs: builder.zipsToMerge,
Output: outputZipFile,
})
}
return outputZipFile
}
// Check the syntax of the generated Android.bp file contents and if they are
// invalid then log an error with the contents (tagged with line numbers) and the
// errors that were found so that it is easy to see where the problem lies.
func syntaxCheckSnapshotBpFile(ctx android.ModuleContext, contents string) {
errs := android.CheckBlueprintSyntax(ctx, "Android.bp", contents)
if len(errs) != 0 {
message := &strings.Builder{}
_, _ = fmt.Fprint(message, `errors in generated Android.bp snapshot:
Generated Android.bp contents
========================================================================
`)
for i, line := range strings.Split(contents, "\n") {
_, _ = fmt.Fprintf(message, "%6d: %s\n", i+1, line)
}
_, _ = fmt.Fprint(message, `
========================================================================
Errors found:
`)
for _, err := range errs {
_, _ = fmt.Fprintf(message, "%s\n", err.Error())
}
ctx.ModuleErrorf("%s", message.String())
}
}
func extractCommonProperties(ctx android.ModuleContext, extractor *commonValueExtractor, commonProperties interface{}, inputPropertiesSlice interface{}) {
err := extractor.extractCommonProperties(commonProperties, inputPropertiesSlice)
if err != nil {
ctx.ModuleErrorf("error extracting common properties: %s", err)
}
}
func (s *sdk) addMemberPropertiesToPropertySet(builder *snapshotBuilder, propertySet android.BpPropertySet, dynamicMemberTypeListProperties interface{}) {
for _, memberListProperty := range s.memberListProperties() {
names := memberListProperty.getter(dynamicMemberTypeListProperties)
if len(names) > 0 {
propertySet.AddProperty(memberListProperty.propertyName(), builder.versionedSdkMemberNames(names, false))
}
}
}
type propertyTag struct {
name string
}
// A BpPropertyTag to add to a property that contains references to other sdk members.
//
// This will cause the references to be rewritten to a versioned reference in the version
// specific instance of a snapshot module.
var requiredSdkMemberReferencePropertyTag = propertyTag{"requiredSdkMemberReferencePropertyTag"}
var optionalSdkMemberReferencePropertyTag = propertyTag{"optionalSdkMemberReferencePropertyTag"}
// A BpPropertyTag that indicates the property should only be present in the versioned
// module.
//
// This will cause the property to be removed from the unversioned instance of a
// snapshot module.
var sdkVersionedOnlyPropertyTag = propertyTag{"sdkVersionedOnlyPropertyTag"}
type unversionedToVersionedTransformation struct {
identityTransformation
builder *snapshotBuilder
}
func (t unversionedToVersionedTransformation) transformModule(module *bpModule) *bpModule {
// Use a versioned name for the module but remember the original name for the
// snapshot.
name := module.getValue("name").(string)
module.setProperty("name", t.builder.versionedSdkMemberName(name, true))
module.insertAfter("name", "sdk_member_name", name)
return module
}
func (t unversionedToVersionedTransformation) transformProperty(name string, value interface{}, tag android.BpPropertyTag) (interface{}, android.BpPropertyTag) {
if tag == requiredSdkMemberReferencePropertyTag || tag == optionalSdkMemberReferencePropertyTag {
required := tag == requiredSdkMemberReferencePropertyTag
return t.builder.versionedSdkMemberNames(value.([]string), required), tag
} else {
return value, tag
}
}
type unversionedTransformation struct {
identityTransformation
builder *snapshotBuilder
}
func (t unversionedTransformation) transformModule(module *bpModule) *bpModule {
// If the module is an internal member then use a unique name for it.
name := module.getValue("name").(string)
module.setProperty("name", t.builder.unversionedSdkMemberName(name, true))
// Set prefer: false - this is not strictly required as that is the default.
module.insertAfter("name", "prefer", false)
return module
}
func (t unversionedTransformation) transformProperty(name string, value interface{}, tag android.BpPropertyTag) (interface{}, android.BpPropertyTag) {
if tag == requiredSdkMemberReferencePropertyTag || tag == optionalSdkMemberReferencePropertyTag {
required := tag == requiredSdkMemberReferencePropertyTag
return t.builder.unversionedSdkMemberNames(value.([]string), required), tag
} else if tag == sdkVersionedOnlyPropertyTag {
// The property is not allowed in the unversioned module so remove it.
return nil, nil
} else {
return value, tag
}
}
type pruneEmptySetTransformer struct {
identityTransformation
}
var _ bpTransformer = (*pruneEmptySetTransformer)(nil)
func (t pruneEmptySetTransformer) transformPropertySetAfterContents(name string, propertySet *bpPropertySet, tag android.BpPropertyTag) (*bpPropertySet, android.BpPropertyTag) {
if len(propertySet.properties) == 0 {
return nil, nil
} else {
return propertySet, tag
}
}
func generateBpContents(contents *generatedContents, bpFile *bpFile) {
contents.Printfln("// This is auto-generated. DO NOT EDIT.")
for _, bpModule := range bpFile.order {
contents.Printfln("")
contents.Printfln("%s {", bpModule.moduleType)
outputPropertySet(contents, bpModule.bpPropertySet)
contents.Printfln("}")
}
}
func outputPropertySet(contents *generatedContents, set *bpPropertySet) {
contents.Indent()
// Output the properties first, followed by the nested sets. This ensures a
// consistent output irrespective of whether property sets are created before
// or after the properties. This simplifies the creation of the module.
for _, name := range set.order {
value := set.getValue(name)
switch v := value.(type) {
case []string:
length := len(v)
if length > 1 {
contents.Printfln("%s: [", name)
contents.Indent()
for i := 0; i < length; i = i + 1 {
contents.Printfln("%q,", v[i])
}
contents.Dedent()
contents.Printfln("],")
} else if length == 0 {
contents.Printfln("%s: [],", name)
} else {
contents.Printfln("%s: [%q],", name, v[0])
}
case bool:
contents.Printfln("%s: %t,", name, v)
case *bpPropertySet:
// Do not write property sets in the properties phase.
default:
contents.Printfln("%s: %q,", name, value)
}
}
for _, name := range set.order {
value := set.getValue(name)
// Only write property sets in the sets phase.
switch v := value.(type) {
case *bpPropertySet:
contents.Printfln("%s: {", name)
outputPropertySet(contents, v)
contents.Printfln("},")
}
}
contents.Dedent()
}
func (s *sdk) GetAndroidBpContentsForTests() string {
contents := &generatedContents{}
generateBpContents(contents, s.builderForTests.bpFile)
return contents.content.String()
}
type snapshotBuilder struct {
ctx android.ModuleContext
sdk *sdk
version string
snapshotDir android.OutputPath
bpFile *bpFile
// Map from destination to source of each copy - used to eliminate duplicates and
// detect conflicts.
copies map[string]string
filesToZip android.Paths
zipsToMerge android.Paths
prebuiltModules map[string]*bpModule
prebuiltOrder []*bpModule
// The set of all members by name.
allMembersByName map[string]struct{}
// The set of exported members by name.
exportedMembersByName map[string]struct{}
}
func (s *snapshotBuilder) CopyToSnapshot(src android.Path, dest string) {
if existing, ok := s.copies[dest]; ok {
if existing != src.String() {
s.ctx.ModuleErrorf("conflicting copy, %s copied from both %s and %s", dest, existing, src)
return
}
} else {
path := s.snapshotDir.Join(s.ctx, dest)
s.ctx.Build(pctx, android.BuildParams{
Rule: android.Cp,
Input: src,
Output: path,
})
s.filesToZip = append(s.filesToZip, path)
s.copies[dest] = src.String()
}
}
func (s *snapshotBuilder) UnzipToSnapshot(zipPath android.Path, destDir string) {
ctx := s.ctx
// Repackage the zip file so that the entries are in the destDir directory.
// This will allow the zip file to be merged into the snapshot.
tmpZipPath := android.PathForModuleOut(ctx, "tmp", destDir+".zip").OutputPath
ctx.Build(pctx, android.BuildParams{
Description: "Repackaging zip file " + destDir + " for snapshot " + ctx.ModuleName(),
Rule: repackageZip,
Input: zipPath,
Output: tmpZipPath,
Args: map[string]string{
"destdir": destDir,
},
})
// Add the repackaged zip file to the files to merge.
s.zipsToMerge = append(s.zipsToMerge, tmpZipPath)
}
func (s *snapshotBuilder) AddPrebuiltModule(member android.SdkMember, moduleType string) android.BpModule {
name := member.Name()
if s.prebuiltModules[name] != nil {
panic(fmt.Sprintf("Duplicate module detected, module %s has already been added", name))
}
m := s.bpFile.newModule(moduleType)
m.AddProperty("name", name)
variant := member.Variants()[0]
if s.isInternalMember(name) {
// An internal member is only referenced from the sdk snapshot which is in the
// same package so can be marked as private.
m.AddProperty("visibility", []string{"//visibility:private"})
} else {
// Extract visibility information from a member variant. All variants have the same
// visibility so it doesn't matter which one is used.
visibility := android.EffectiveVisibilityRules(s.ctx, variant)
if len(visibility) != 0 {
m.AddProperty("visibility", visibility)
}
}
deviceSupported := false
hostSupported := false
for _, variant := range member.Variants() {
osClass := variant.Target().Os.Class
if osClass == android.Host || osClass == android.HostCross {
hostSupported = true
} else if osClass == android.Device {
deviceSupported = true
}
}
addHostDeviceSupportedProperties(deviceSupported, hostSupported, m)
// Where available copy apex_available properties from the member.
if apexAware, ok := variant.(interface{ ApexAvailable() []string }); ok {
apexAvailable := apexAware.ApexAvailable()
// Add in any white listed apex available settings.
apexAvailable = append(apexAvailable, apex.WhitelistedApexAvailable(member.Name())...)
if len(apexAvailable) > 0 {
// Remove duplicates and sort.
apexAvailable = android.FirstUniqueStrings(apexAvailable)
sort.Strings(apexAvailable)
m.AddProperty("apex_available", apexAvailable)
}
}
// Disable installation in the versioned module of those modules that are ever installable.
if installable, ok := variant.(interface{ EverInstallable() bool }); ok {
if installable.EverInstallable() {
m.AddPropertyWithTag("installable", false, sdkVersionedOnlyPropertyTag)
}
}
s.prebuiltModules[name] = m
s.prebuiltOrder = append(s.prebuiltOrder, m)
return m
}
func addHostDeviceSupportedProperties(deviceSupported bool, hostSupported bool, bpModule *bpModule) {
if !deviceSupported {
bpModule.AddProperty("device_supported", false)
}
if hostSupported {
bpModule.AddProperty("host_supported", true)
}
}
func (s *snapshotBuilder) SdkMemberReferencePropertyTag(required bool) android.BpPropertyTag {
if required {
return requiredSdkMemberReferencePropertyTag
} else {
return optionalSdkMemberReferencePropertyTag
}
}
func (s *snapshotBuilder) OptionalSdkMemberReferencePropertyTag() android.BpPropertyTag {
return optionalSdkMemberReferencePropertyTag
}
// Get a versioned name appropriate for the SDK snapshot version being taken.
func (s *snapshotBuilder) versionedSdkMemberName(unversionedName string, required bool) string {
if _, ok := s.allMembersByName[unversionedName]; !ok {
if required {
s.ctx.ModuleErrorf("Required member reference %s is not a member of the sdk", unversionedName)
}
return unversionedName
}
return versionedSdkMemberName(s.ctx, unversionedName, s.version)
}
func (s *snapshotBuilder) versionedSdkMemberNames(members []string, required bool) []string {
var references []string = nil
for _, m := range members {
references = append(references, s.versionedSdkMemberName(m, required))
}
return references
}
// Get an internal name unique to the sdk.
func (s *snapshotBuilder) unversionedSdkMemberName(unversionedName string, required bool) string {
if _, ok := s.allMembersByName[unversionedName]; !ok {
if required {
s.ctx.ModuleErrorf("Required member reference %s is not a member of the sdk", unversionedName)
}
return unversionedName
}
if s.isInternalMember(unversionedName) {
return s.ctx.ModuleName() + "_" + unversionedName
} else {
return unversionedName
}
}
func (s *snapshotBuilder) unversionedSdkMemberNames(members []string, required bool) []string {
var references []string = nil
for _, m := range members {
references = append(references, s.unversionedSdkMemberName(m, required))
}
return references
}
func (s *snapshotBuilder) isInternalMember(memberName string) bool {
_, ok := s.exportedMembersByName[memberName]
return !ok
}
type sdkMemberRef struct {
memberType android.SdkMemberType
variant android.SdkAware
}
var _ android.SdkMember = (*sdkMember)(nil)
type sdkMember struct {
memberType android.SdkMemberType
name string
variants []android.SdkAware
}
func (m *sdkMember) Name() string {
return m.name
}
func (m *sdkMember) Variants() []android.SdkAware {
return m.variants
}
// Track usages of multilib variants.
type multilibUsage int
const (
multilibNone multilibUsage = 0
multilib32 multilibUsage = 1
multilib64 multilibUsage = 2
multilibBoth = multilib32 | multilib64
)
// Add the multilib that is used in the arch type.
func (m multilibUsage) addArchType(archType android.ArchType) multilibUsage {
multilib := archType.Multilib
switch multilib {
case "":
return m
case "lib32":
return m | multilib32
case "lib64":
return m | multilib64
default:
panic(fmt.Errorf("Unknown Multilib field in ArchType, expected 'lib32' or 'lib64', found %q", multilib))
}
}
func (m multilibUsage) String() string {
switch m {
case multilibNone:
return ""
case multilib32:
return "32"
case multilib64:
return "64"
case multilibBoth:
return "both"
default:
panic(fmt.Errorf("Unknown multilib value, found %b, expected one of %b, %b, %b or %b",
m, multilibNone, multilib32, multilib64, multilibBoth))
}
}
type baseInfo struct {
Properties android.SdkMemberProperties
}
func (b *baseInfo) optimizableProperties() interface{} {
return b.Properties
}
type osTypeSpecificInfo struct {
baseInfo
osType android.OsType
// The list of arch type specific info for this os type.
//
// Nil if there is one variant whose arch type is common
archInfos []*archTypeSpecificInfo
}
var _ propertiesContainer = (*osTypeSpecificInfo)(nil)
type variantPropertiesFactoryFunc func() android.SdkMemberProperties
// Create a new osTypeSpecificInfo for the specified os type and its properties
// structures populated with information from the variants.
func newOsTypeSpecificInfo(ctx android.SdkMemberContext, osType android.OsType, variantPropertiesFactory variantPropertiesFactoryFunc, osTypeVariants []android.Module) *osTypeSpecificInfo {
osInfo := &osTypeSpecificInfo{
osType: osType,
}
osSpecificVariantPropertiesFactory := func() android.SdkMemberProperties {
properties := variantPropertiesFactory()
properties.Base().Os = osType
return properties
}
// Create a structure into which properties common across the architectures in
// this os type will be stored.
osInfo.Properties = osSpecificVariantPropertiesFactory()
// Group the variants by arch type.
var variantsByArchName = make(map[string][]android.Module)
var archTypes []android.ArchType
for _, variant := range osTypeVariants {
archType := variant.Target().Arch.ArchType
archTypeName := archType.Name
if _, ok := variantsByArchName[archTypeName]; !ok {
archTypes = append(archTypes, archType)
}
variantsByArchName[archTypeName] = append(variantsByArchName[archTypeName], variant)
}
if commonVariants, ok := variantsByArchName["common"]; ok {
if len(osTypeVariants) != 1 {
panic("Expected to only have 1 variant when arch type is common but found " + string(len(osTypeVariants)))
}
// A common arch type only has one variant and its properties should be treated
// as common to the os type.
osInfo.Properties.PopulateFromVariant(ctx, commonVariants[0])
} else {
// Create an arch specific info for each supported architecture type.
for _, archType := range archTypes {
archTypeName := archType.Name
archVariants := variantsByArchName[archTypeName]
archInfo := newArchSpecificInfo(ctx, archType, osSpecificVariantPropertiesFactory, archVariants)
osInfo.archInfos = append(osInfo.archInfos, archInfo)
}
}
return osInfo
}
// Optimize the properties by extracting common properties from arch type specific
// properties into os type specific properties.
func (osInfo *osTypeSpecificInfo) optimizeProperties(ctx *memberContext, commonValueExtractor *commonValueExtractor) {
// Nothing to do if there is only a single common architecture.
if len(osInfo.archInfos) == 0 {
return
}
multilib := multilibNone
for _, archInfo := range osInfo.archInfos {
multilib = multilib.addArchType(archInfo.archType)
// Optimize the arch properties first.
archInfo.optimizeProperties(ctx, commonValueExtractor)
}
extractCommonProperties(ctx.sdkMemberContext, commonValueExtractor, osInfo.Properties, osInfo.archInfos)
// Choose setting for compile_multilib that is appropriate for the arch variants supplied.
osInfo.Properties.Base().Compile_multilib = multilib.String()
}
// Add the properties for an os to a property set.
//
// Maps the properties related to the os variants through to an appropriate
// module structure that will produce equivalent set of variants when it is
// processed in a build.
func (osInfo *osTypeSpecificInfo) addToPropertySet(ctx *memberContext, bpModule android.BpModule, targetPropertySet android.BpPropertySet) {
var osPropertySet android.BpPropertySet
var archPropertySet android.BpPropertySet
var archOsPrefix string
if osInfo.Properties.Base().Os_count == 1 {
// There is only one os type present in the variants so don't bother
// with adding target specific properties.
// Create a structure that looks like:
// module_type {
// name: "...",
// ...
// <common properties>
// ...
// <single os type specific properties>
//
// arch: {
// <arch specific sections>
// }
//
osPropertySet = bpModule
archPropertySet = osPropertySet.AddPropertySet("arch")
// Arch specific properties need to be added to an arch specific section
// within arch.
archOsPrefix = ""
} else {
// Create a structure that looks like:
// module_type {
// name: "...",
// ...
// <common properties>
// ...
// target: {
// <arch independent os specific sections, e.g. android>
// ...
// <arch and os specific sections, e.g. android_x86>
// }
//
osType := osInfo.osType
osPropertySet = targetPropertySet.AddPropertySet(osType.Name)
archPropertySet = targetPropertySet
// Arch specific properties need to be added to an os and arch specific
// section prefixed with <os>_.
archOsPrefix = osType.Name + "_"
}
// Add the os specific but arch independent properties to the module.
osInfo.Properties.AddToPropertySet(ctx, osPropertySet)
// Add arch (and possibly os) specific sections for each set of arch (and possibly
// os) specific properties.
//
// The archInfos list will be empty if the os contains variants for the common
// architecture.
for _, archInfo := range osInfo.archInfos {
archInfo.addToPropertySet(ctx, archPropertySet, archOsPrefix)
}
}
func (osInfo *osTypeSpecificInfo) isHostVariant() bool {
osClass := osInfo.osType.Class
return osClass == android.Host || osClass == android.HostCross
}
var _ isHostVariant = (*osTypeSpecificInfo)(nil)
func (osInfo *osTypeSpecificInfo) String() string {
return fmt.Sprintf("OsType{%s}", osInfo.osType)
}
type archTypeSpecificInfo struct {
baseInfo
archType android.ArchType
linkInfos []*linkTypeSpecificInfo
}
var _ propertiesContainer = (*archTypeSpecificInfo)(nil)
// Create a new archTypeSpecificInfo for the specified arch type and its properties
// structures populated with information from the variants.
func newArchSpecificInfo(ctx android.SdkMemberContext, archType android.ArchType, variantPropertiesFactory variantPropertiesFactoryFunc, archVariants []android.Module) *archTypeSpecificInfo {
// Create an arch specific info into which the variant properties can be copied.
archInfo := &archTypeSpecificInfo{archType: archType}
// Create the properties into which the arch type specific properties will be
// added.
archInfo.Properties = variantPropertiesFactory()
if len(archVariants) == 1 {
archInfo.Properties.PopulateFromVariant(ctx, archVariants[0])
} else {
// There is more than one variant for this arch type which must be differentiated
// by link type.
for _, linkVariant := range archVariants {
linkType := getLinkType(linkVariant)
if linkType == "" {
panic(fmt.Errorf("expected one arch specific variant as it is not identified by link type but found %d", len(archVariants)))
} else {
linkInfo := newLinkSpecificInfo(ctx, linkType, variantPropertiesFactory, linkVariant)
archInfo.linkInfos = append(archInfo.linkInfos, linkInfo)
}
}
}
return archInfo
}
func (archInfo *archTypeSpecificInfo) optimizableProperties() interface{} {
return archInfo.Properties
}
// Get the link type of the variant
//
// If the variant is not differentiated by link type then it returns "",
// otherwise it returns one of "static" or "shared".
func getLinkType(variant android.Module) string {
linkType := ""
if linkable, ok := variant.(cc.LinkableInterface); ok {
if linkable.Shared() && linkable.Static() {
panic(fmt.Errorf("expected variant %q to be either static or shared but was both", variant.String()))
} else if linkable.Shared() {
linkType = "shared"
} else if linkable.Static() {
linkType = "static"
} else {
panic(fmt.Errorf("expected variant %q to be either static or shared but was neither", variant.String()))
}
}
return linkType
}
// Optimize the properties by extracting common properties from link type specific
// properties into arch type specific properties.
func (archInfo *archTypeSpecificInfo) optimizeProperties(ctx *memberContext, commonValueExtractor *commonValueExtractor) {
if len(archInfo.linkInfos) == 0 {
return
}
extractCommonProperties(ctx.sdkMemberContext, commonValueExtractor, archInfo.Properties, archInfo.linkInfos)
}
// Add the properties for an arch type to a property set.
func (archInfo *archTypeSpecificInfo) addToPropertySet(ctx *memberContext, archPropertySet android.BpPropertySet, archOsPrefix string) {
archTypeName := archInfo.archType.Name
archTypePropertySet := archPropertySet.AddPropertySet(archOsPrefix + archTypeName)
archInfo.Properties.AddToPropertySet(ctx, archTypePropertySet)
for _, linkInfo := range archInfo.linkInfos {
linkPropertySet := archTypePropertySet.AddPropertySet(linkInfo.linkType)
linkInfo.Properties.AddToPropertySet(ctx, linkPropertySet)
}
}
func (archInfo *archTypeSpecificInfo) String() string {
return fmt.Sprintf("ArchType{%s}", archInfo.archType)
}
type linkTypeSpecificInfo struct {
baseInfo
linkType string
}
var _ propertiesContainer = (*linkTypeSpecificInfo)(nil)
// Create a new linkTypeSpecificInfo for the specified link type and its properties
// structures populated with information from the variant.
func newLinkSpecificInfo(ctx android.SdkMemberContext, linkType string, variantPropertiesFactory variantPropertiesFactoryFunc, linkVariant android.Module) *linkTypeSpecificInfo {
linkInfo := &linkTypeSpecificInfo{
baseInfo: baseInfo{
// Create the properties into which the link type specific properties will be
// added.
Properties: variantPropertiesFactory(),
},
linkType: linkType,
}
linkInfo.Properties.PopulateFromVariant(ctx, linkVariant)
return linkInfo
}
func (l *linkTypeSpecificInfo) String() string {
return fmt.Sprintf("LinkType{%s}", l.linkType)
}
type memberContext struct {
sdkMemberContext android.ModuleContext
builder *snapshotBuilder
memberType android.SdkMemberType
name string
}
func (m *memberContext) SdkModuleContext() android.ModuleContext {
return m.sdkMemberContext
}
func (m *memberContext) SnapshotBuilder() android.SnapshotBuilder {
return m.builder
}
func (m *memberContext) MemberType() android.SdkMemberType {
return m.memberType
}
func (m *memberContext) Name() string {
return m.name
}
func (s *sdk) createMemberSnapshot(ctx *memberContext, member *sdkMember, bpModule android.BpModule) {
memberType := member.memberType
// Group the variants by os type.
variantsByOsType := make(map[android.OsType][]android.Module)
variants := member.Variants()
for _, variant := range variants {
osType := variant.Target().Os
variantsByOsType[osType] = append(variantsByOsType[osType], variant)
}
osCount := len(variantsByOsType)
variantPropertiesFactory := func() android.SdkMemberProperties {
properties := memberType.CreateVariantPropertiesStruct()
base := properties.Base()
base.Os_count = osCount
return properties
}
osTypeToInfo := make(map[android.OsType]*osTypeSpecificInfo)
// The set of properties that are common across all architectures and os types.
commonProperties := variantPropertiesFactory()
commonProperties.Base().Os = android.CommonOS
// Create common value extractor that can be used to optimize the properties.
commonValueExtractor := newCommonValueExtractor(commonProperties)
// The list of property structures which are os type specific but common across
// architectures within that os type.
var osSpecificPropertiesContainers []*osTypeSpecificInfo
for osType, osTypeVariants := range variantsByOsType {
osInfo := newOsTypeSpecificInfo(ctx, osType, variantPropertiesFactory, osTypeVariants)
osTypeToInfo[osType] = osInfo
// Add the os specific properties to a list of os type specific yet architecture
// independent properties structs.
osSpecificPropertiesContainers = append(osSpecificPropertiesContainers, osInfo)
// Optimize the properties across all the variants for a specific os type.
osInfo.optimizeProperties(ctx, commonValueExtractor)
}
// Extract properties which are common across all architectures and os types.
extractCommonProperties(ctx.sdkMemberContext, commonValueExtractor, commonProperties, osSpecificPropertiesContainers)
// Add the common properties to the module.
commonProperties.AddToPropertySet(ctx, bpModule)
// Create a target property set into which target specific properties can be
// added.
targetPropertySet := bpModule.AddPropertySet("target")
// Iterate over the os types in a fixed order.
for _, osType := range s.getPossibleOsTypes() {
osInfo := osTypeToInfo[osType]
if osInfo == nil {
continue
}
osInfo.addToPropertySet(ctx, bpModule, targetPropertySet)
}
}
// Compute the list of possible os types that this sdk could support.
func (s *sdk) getPossibleOsTypes() []android.OsType {
var osTypes []android.OsType
for _, osType := range android.OsTypeList {
if s.DeviceSupported() {
if osType.Class == android.Device && osType != android.Fuchsia {
osTypes = append(osTypes, osType)
}
}
if s.HostSupported() {
if osType.Class == android.Host || osType.Class == android.HostCross {
osTypes = append(osTypes, osType)
}
}
}
sort.SliceStable(osTypes, func(i, j int) bool { return osTypes[i].Name < osTypes[j].Name })
return osTypes
}
// Given a set of properties (struct value), return the value of the field within that
// struct (or one of its embedded structs).
type fieldAccessorFunc func(structValue reflect.Value) reflect.Value
// Checks the metadata to determine whether the property should be ignored for the
// purposes of common value extraction or not.
type extractorMetadataPredicate func(metadata propertiesContainer) bool
// Indicates whether optimizable properties are provided by a host variant or
// not.
type isHostVariant interface {
isHostVariant() bool
}
// A property that can be optimized by the commonValueExtractor.
type extractorProperty struct {
// The name of the field for this property.
name string
// Filter that can use metadata associated with the properties being optimized
// to determine whether the field should be ignored during common value
// optimization.
filter extractorMetadataPredicate
// Retrieves the value on which common value optimization will be performed.
getter fieldAccessorFunc
// The empty value for the field.
emptyValue reflect.Value
// True if the property can support arch variants false otherwise.
archVariant bool
}
func (p extractorProperty) String() string {
return p.name
}
// Supports extracting common values from a number of instances of a properties
// structure into a separate common set of properties.
type commonValueExtractor struct {
// The properties that the extractor can optimize.
properties []extractorProperty
}
// Create a new common value extractor for the structure type for the supplied
// properties struct.
//
// The returned extractor can be used on any properties structure of the same type
// as the supplied set of properties.
func newCommonValueExtractor(propertiesStruct interface{}) *commonValueExtractor {
structType := getStructValue(reflect.ValueOf(propertiesStruct)).Type()
extractor := &commonValueExtractor{}
extractor.gatherFields(structType, nil)
return extractor
}
// Gather the fields from the supplied structure type from which common values will
// be extracted.
//
// This is recursive function. If it encounters an embedded field (no field name)
// that is a struct then it will recurse into that struct passing in the accessor
// for the field. That will then be used in the accessors for the fields in the
// embedded struct.
func (e *commonValueExtractor) gatherFields(structType reflect.Type, containingStructAccessor fieldAccessorFunc) {
for f := 0; f < structType.NumField(); f++ {
field := structType.Field(f)
if field.PkgPath != "" {
// Ignore unexported fields.
continue
}
// Ignore fields whose value should be kept.
if proptools.HasTag(field, "sdk", "keep") {
continue
}
var filter extractorMetadataPredicate
// Add a filter
if proptools.HasTag(field, "sdk", "ignored-on-host") {
filter = func(metadata propertiesContainer) bool {
if m, ok := metadata.(isHostVariant); ok {
if m.isHostVariant() {
return false
}
}
return true
}
}
// Save a copy of the field index for use in the function.
fieldIndex := f
name := field.Name
fieldGetter := func(value reflect.Value) reflect.Value {
if containingStructAccessor != nil {
// This is an embedded structure so first access the field for the embedded
// structure.
value = containingStructAccessor(value)
}
// Skip through interface and pointer values to find the structure.
value = getStructValue(value)
defer func() {
if r := recover(); r != nil {
panic(fmt.Errorf("%s for fieldIndex %d of field %s of value %#v", r, fieldIndex, name, value.Interface()))
}
}()
// Return the field.
return value.Field(fieldIndex)
}
if field.Type.Kind() == reflect.Struct && field.Anonymous {
// Gather fields from the embedded structure.
e.gatherFields(field.Type, fieldGetter)
} else {
property := extractorProperty{
name,
filter,
fieldGetter,
reflect.Zero(field.Type),
proptools.HasTag(field, "android", "arch_variant"),
}
e.properties = append(e.properties, property)
}
}
}
func getStructValue(value reflect.Value) reflect.Value {
foundStruct:
for {
kind := value.Kind()
switch kind {
case reflect.Interface, reflect.Ptr:
value = value.Elem()
case reflect.Struct:
break foundStruct
default:
panic(fmt.Errorf("expecting struct, interface or pointer, found %v of kind %s", value, kind))
}
}
return value
}
// A container of properties to be optimized.
//
// Allows additional information to be associated with the properties, e.g. for
// filtering.
type propertiesContainer interface {
fmt.Stringer
// Get the properties that need optimizing.
optimizableProperties() interface{}
}
// A wrapper for dynamic member properties to allow them to be optimized.
type dynamicMemberPropertiesContainer struct {
sdkVariant *sdk
dynamicMemberProperties interface{}
}
func (c dynamicMemberPropertiesContainer) optimizableProperties() interface{} {
return c.dynamicMemberProperties
}
func (c dynamicMemberPropertiesContainer) String() string {
return c.sdkVariant.String()
}
// Extract common properties from a slice of property structures of the same type.
//
// All the property structures must be of the same type.
// commonProperties - must be a pointer to the structure into which common properties will be added.
// inputPropertiesSlice - must be a slice of propertiesContainer interfaces.
//
// Iterates over each exported field (capitalized name) and checks to see whether they
// have the same value (using DeepEquals) across all the input properties. If it does not then no
// change is made. Otherwise, the common value is stored in the field in the commonProperties
// and the field in each of the input properties structure is set to its default value.
func (e *commonValueExtractor) extractCommonProperties(commonProperties interface{}, inputPropertiesSlice interface{}) error {
commonPropertiesValue := reflect.ValueOf(commonProperties)
commonStructValue := commonPropertiesValue.Elem()
sliceValue := reflect.ValueOf(inputPropertiesSlice)
for _, property := range e.properties {
fieldGetter := property.getter
filter := property.filter
if filter == nil {
filter = func(metadata propertiesContainer) bool {
return true
}
}
// Check to see if all the structures have the same value for the field. The commonValue
// is nil on entry to the loop and if it is nil on exit then there is no common value or
// all the values have been filtered out, otherwise it points to the common value.
var commonValue *reflect.Value
// Assume that all the values will be the same.
//
// While similar to this is not quite the same as commonValue == nil. If all the values
// have been filtered out then this will be false but commonValue == nil will be true.
valuesDiffer := false
for i := 0; i < sliceValue.Len(); i++ {
container := sliceValue.Index(i).Interface().(propertiesContainer)
itemValue := reflect.ValueOf(container.optimizableProperties())
fieldValue := fieldGetter(itemValue)
if !filter(container) {
expectedValue := property.emptyValue.Interface()
actualValue := fieldValue.Interface()
if !reflect.DeepEqual(expectedValue, actualValue) {
return fmt.Errorf("field %q is supposed to be ignored for %q but is set to %#v instead of %#v", property, container, actualValue, expectedValue)
}
continue
}
if commonValue == nil {
// Use the first value as the commonProperties value.
commonValue = &fieldValue
} else {
// If the value does not match the current common value then there is
// no value in common so break out.
if !reflect.DeepEqual(fieldValue.Interface(), commonValue.Interface()) {
commonValue = nil
valuesDiffer = true
break
}
}
}
// If the fields all have common value then store it in the common struct field
// and set the input struct's field to the empty value.
if commonValue != nil {
emptyValue := property.emptyValue
fieldGetter(commonStructValue).Set(*commonValue)
for i := 0; i < sliceValue.Len(); i++ {
container := sliceValue.Index(i).Interface().(propertiesContainer)
itemValue := reflect.ValueOf(container.optimizableProperties())
fieldValue := fieldGetter(itemValue)
fieldValue.Set(emptyValue)
}
}
if valuesDiffer && !property.archVariant {
// The values differ but the property does not support arch variants so it
// is an error.
var details strings.Builder
for i := 0; i < sliceValue.Len(); i++ {
container := sliceValue.Index(i).Interface().(propertiesContainer)
itemValue := reflect.ValueOf(container.optimizableProperties())
fieldValue := fieldGetter(itemValue)
_, _ = fmt.Fprintf(&details, "\n %q has value %q", container.String(), fieldValue.Interface())
}
return fmt.Errorf("field %q is not tagged as \"arch_variant\" but has arch specific properties:%s", property.String(), details.String())
}
}
return nil
}