// Copyright 2018 Google Inc. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package android import ( "fmt" "sort" "strconv" "strings" "sync" "github.com/google/blueprint" ) var ( // This is the sdk version when APEX was first introduced SdkVersion_Android10 = uncheckedFinalApiLevel(29) ) // ApexInfo describes the metadata about one or more apexBundles that an apex variant of a module is // part of. When an apex variant is created, the variant is associated with one apexBundle. But // when multiple apex variants are merged for deduping (see mergeApexVariations), this holds the // information about the apexBundles that are merged together. // Accessible via `ctx.Provider(android.ApexInfoProvider).(android.ApexInfo)` type ApexInfo struct { // Name of the apex variation that this module (i.e. the apex variant of the module) is // mutated into, or "" for a platform (i.e. non-APEX) variant. Note that a module can be // included in multiple APEXes, in which case, the module is mutated into one or more // variants, each of which is for an APEX. The variants then can later be deduped if they // don't need to be compiled differently. This is an optimization done in // mergeApexVariations. ApexVariationName string // Serialized ApiLevel that this module has to support at minimum. Should be accessed via // MinSdkVersion() method. Cannot be stored in its struct form because this is cloned into // properties structs, and ApiLevel has private members. MinSdkVersionStr string // True if this module comes from an updatable apexBundle. Updatable bool // The list of SDK modules that the containing apexBundle depends on. RequiredSdks SdkRefs // List of apexBundles that this apex variant of the module is associated with. Initially, // the size of this list is one because one apex variant is associated with one apexBundle. // When multiple apex variants are merged in mergeApexVariations, ApexInfo struct of the // merged variant holds the list of apexBundles that are merged together. InApexes []string // Pointers to the ApexContents struct each of which is for apexBundle modules that this // module is part of. The ApexContents gives information about which modules the apexBundle // has and whether a module became part of the apexBundle via a direct dependency or not. ApexContents []*ApexContents // True if this is for a prebuilt_apex. // // If true then this will customize the apex processing to make it suitable for handling // prebuilt_apex, e.g. it will prevent ApexInfos from being merged together. // // See Prebuilt.ApexInfoMutator for more information. ForPrebuiltApex bool } var ApexInfoProvider = blueprint.NewMutatorProvider(ApexInfo{}, "apex") // mergedName gives the name of the alias variation that will be used when multiple apex variations // of a module can be deduped into one variation. For example, if libfoo is included in both apex.a // and apex.b, and if the two APEXes have the same min_sdk_version (say 29), then libfoo doesn't // have to be built twice, but only once. In that case, the two apex variations apex.a and apex.b // are configured to have the same alias variation named apex29. func (i ApexInfo) mergedName(ctx PathContext) string { name := "apex" + strconv.Itoa(i.MinSdkVersion(ctx).FinalOrFutureInt()) for _, sdk := range i.RequiredSdks { name += "_" + sdk.Name + "_" + sdk.Version } return name } // MinSdkVersion gives the api level that this module has to support at minimum. This is from the // min_sdk_version property of the containing apexBundle. func (i ApexInfo) MinSdkVersion(ctx PathContext) ApiLevel { return ApiLevelOrPanic(ctx, i.MinSdkVersionStr) } // IsForPlatform tells whether this module is for the platform or not. If false is returned, it // means that this apex variant of the module is built for an APEX. func (i ApexInfo) IsForPlatform() bool { return i.ApexVariationName == "" } // InApex tells whether this apex variant of the module is part of the given apexBundle or not. func (i ApexInfo) InApex(apex string) bool { for _, a := range i.InApexes { if a == apex { return true } } return false } // InApexByBaseName tells whether this apex variant of the module is part of the given APEX or not, // where the APEX is specified by its canonical base name, i.e. typically beginning with // "com.android.". In particular this function doesn't differentiate between source and prebuilt // APEXes, where the latter may have "prebuilt_" prefixes. func (i ApexInfo) InApexByBaseName(apex string) bool { for _, a := range i.InApexes { if RemoveOptionalPrebuiltPrefix(a) == apex { return true } } return false } // ApexTestForInfo stores the contents of APEXes for which this module is a test - although this // module is not part of the APEX - and thus has access to APEX internals. type ApexTestForInfo struct { ApexContents []*ApexContents } var ApexTestForInfoProvider = blueprint.NewMutatorProvider(ApexTestForInfo{}, "apex_test_for") // DepIsInSameApex defines an interface that should be used to determine whether a given dependency // should be considered as part of the same APEX as the current module or not. Note: this was // extracted from ApexModule to make it easier to define custom subsets of the ApexModule interface // and improve code navigation within the IDE. type DepIsInSameApex interface { // DepIsInSameApex tests if the other module 'dep' is considered as part of the same APEX as // this module. For example, a static lib dependency usually returns true here, while a // shared lib dependency to a stub library returns false. DepIsInSameApex(ctx BaseModuleContext, dep Module) bool } // ApexModule is the interface that a module type is expected to implement if the module has to be // built differently depending on whether the module is destined for an APEX or not (i.e., installed // to one of the regular partitions). // // Native shared libraries are one such module type; when it is built for an APEX, it should depend // only on stable interfaces such as NDK, stable AIDL, or C APIs from other APEXes. // // A module implementing this interface will be mutated into multiple variations by apex.apexMutator // if it is directly or indirectly included in one or more APEXes. Specifically, if a module is // included in apex.foo and apex.bar then three apex variants are created: platform, apex.foo and // apex.bar. The platform variant is for the regular partitions (e.g., /system or /vendor, etc.) // while the other two are for the APEXs, respectively. The latter two variations can be merged (see // mergedName) when the two APEXes have the same min_sdk_version requirement. type ApexModule interface { Module DepIsInSameApex apexModuleBase() *ApexModuleBase // Marks that this module should be built for the specified APEX. Call this BEFORE // apex.apexMutator is run. BuildForApex(apex ApexInfo) // Returns true if this module is present in any APEX either directly or indirectly. Call // this after apex.apexMutator is run. InAnyApex() bool // Returns true if this module is directly in any APEX. Call this AFTER apex.apexMutator is // run. DirectlyInAnyApex() bool // NotInPlatform tells whether or not this module is included in an APEX and therefore // shouldn't be exposed to the platform (i.e. outside of the APEX) directly. A module is // considered to be included in an APEX either when there actually is an APEX that // explicitly has the module as its dependency or the module is not available to the // platform, which indicates that the module belongs to at least one or more other APEXes. NotInPlatform() bool // Tests if this module could have APEX variants. Even when a module type implements // ApexModule interface, APEX variants are created only for the module instances that return // true here. This is useful for not creating APEX variants for certain types of shared // libraries such as NDK stubs. CanHaveApexVariants() bool // Tests if this module can be installed to APEX as a file. For example, this would return // true for shared libs while return false for static libs because static libs are not // installable module (but it can still be mutated for APEX) IsInstallableToApex() bool // Tests if this module is available for the specified APEX or ":platform". This is from the // apex_available property of the module. AvailableFor(what string) bool // Returns true if this module is not available to platform (i.e. apex_available property // doesn't have "//apex_available:platform"), or shouldn't be available to platform, which // is the case when this module depends on other module that isn't available to platform. NotAvailableForPlatform() bool // Marks that this module is not available to platform. Set by the // check-platform-availability mutator in the apex package. SetNotAvailableForPlatform() // Returns the list of APEXes that this module is a test for. The module has access to the // private part of the listed APEXes even when it is not included in the APEXes. This by // default returns nil. A module type should override the default implementation. For // example, cc_test module type returns the value of test_for here. TestFor() []string // Returns nil (success) if this module should support the given sdk version. Returns an // error if not. No default implementation is provided for this method. A module type // implementing this interface should provide an implementation. A module supports an sdk // version when the module's min_sdk_version is equal to or less than the given sdk version. ShouldSupportSdkVersion(ctx BaseModuleContext, sdkVersion ApiLevel) error // Returns true if this module needs a unique variation per apex, effectively disabling the // deduping. This is turned on when, for example if use_apex_name_macro is set so that each // apex variant should be built with different macro definitions. UniqueApexVariations() bool } // Properties that are common to all module types implementing ApexModule interface. type ApexProperties struct { // Availability of this module in APEXes. Only the listed APEXes can contain this module. If // the module has stubs then other APEXes and the platform may access it through them // (subject to visibility). // // "//apex_available:anyapex" is a pseudo APEX name that matches to any APEX. // "//apex_available:platform" refers to non-APEX partitions like "system.img". // "com.android.gki.*" matches any APEX module name with the prefix "com.android.gki.". // Default is ["//apex_available:platform"]. Apex_available []string // See ApexModule.InAnyApex() InAnyApex bool `blueprint:"mutated"` // See ApexModule.DirectlyInAnyApex() DirectlyInAnyApex bool `blueprint:"mutated"` // AnyVariantDirectlyInAnyApex is true in the primary variant of a module if _any_ variant // of the module is directly in any apex. This includes host, arch, asan, etc. variants. It // is unused in any variant that is not the primary variant. Ideally this wouldn't be used, // as it incorrectly mixes arch variants if only one arch is in an apex, but a few places // depend on it, for example when an ASAN variant is created before the apexMutator. Call // this after apex.apexMutator is run. AnyVariantDirectlyInAnyApex bool `blueprint:"mutated"` // See ApexModule.NotAvailableForPlatform() NotAvailableForPlatform bool `blueprint:"mutated"` // See ApexModule.UniqueApexVariants() UniqueApexVariationsForDeps bool `blueprint:"mutated"` } // Marker interface that identifies dependencies that are excluded from APEX contents. type ExcludeFromApexContentsTag interface { blueprint.DependencyTag // Method that differentiates this interface from others. ExcludeFromApexContents() } // Marker interface that identifies dependencies that should inherit the DirectlyInAnyApex state // from the parent to the child. For example, stubs libraries are marked as DirectlyInAnyApex if // their implementation is in an apex. type CopyDirectlyInAnyApexTag interface { blueprint.DependencyTag // Method that differentiates this interface from others. CopyDirectlyInAnyApex() } // Interface that identifies dependencies to skip Apex dependency check type SkipApexAllowedDependenciesCheck interface { // Returns true to skip the Apex dependency check, which limits the allowed dependency in build. SkipApexAllowedDependenciesCheck() bool } // ApexModuleBase provides the default implementation for the ApexModule interface. APEX-aware // modules are expected to include this struct and call InitApexModule(). type ApexModuleBase struct { ApexProperties ApexProperties canHaveApexVariants bool apexInfos []ApexInfo apexInfosLock sync.Mutex // protects apexInfos during parallel apexInfoMutator } // Initializes ApexModuleBase struct. Not calling this (even when inheriting from ApexModuleBase) // prevents the module from being mutated for apexBundle. func InitApexModule(m ApexModule) { base := m.apexModuleBase() base.canHaveApexVariants = true m.AddProperties(&base.ApexProperties) } // Implements ApexModule func (m *ApexModuleBase) apexModuleBase() *ApexModuleBase { return m } // Implements ApexModule func (m *ApexModuleBase) ApexAvailable() []string { return m.ApexProperties.Apex_available } // Implements ApexModule func (m *ApexModuleBase) BuildForApex(apex ApexInfo) { m.apexInfosLock.Lock() defer m.apexInfosLock.Unlock() for _, v := range m.apexInfos { if v.ApexVariationName == apex.ApexVariationName { return } } m.apexInfos = append(m.apexInfos, apex) } // Implements ApexModule func (m *ApexModuleBase) InAnyApex() bool { return m.ApexProperties.InAnyApex } // Implements ApexModule func (m *ApexModuleBase) DirectlyInAnyApex() bool { return m.ApexProperties.DirectlyInAnyApex } // Implements ApexModule func (m *ApexModuleBase) NotInPlatform() bool { return m.ApexProperties.AnyVariantDirectlyInAnyApex || !m.AvailableFor(AvailableToPlatform) } // Implements ApexModule func (m *ApexModuleBase) CanHaveApexVariants() bool { return m.canHaveApexVariants } // Implements ApexModule func (m *ApexModuleBase) IsInstallableToApex() bool { // If needed, this will bel overridden by concrete types inheriting // ApexModuleBase return false } // Implements ApexModule func (m *ApexModuleBase) TestFor() []string { // If needed, this will be overridden by concrete types inheriting // ApexModuleBase return nil } // Implements ApexModule func (m *ApexModuleBase) UniqueApexVariations() bool { // If needed, this will bel overridden by concrete types inheriting // ApexModuleBase return false } // Implements ApexModule func (m *ApexModuleBase) DepIsInSameApex(ctx BaseModuleContext, dep Module) bool { // By default, if there is a dependency from A to B, we try to include both in the same // APEX, unless B is explicitly from outside of the APEX (i.e. a stubs lib). Thus, returning // true. This is overridden by some module types like apex.ApexBundle, cc.Module, // java.Module, etc. return true } const ( AvailableToPlatform = "//apex_available:platform" AvailableToAnyApex = "//apex_available:anyapex" AvailableToGkiApex = "com.android.gki.*" ) // CheckAvailableForApex provides the default algorithm for checking the apex availability. When the // availability is empty, it defaults to ["//apex_available:platform"] which means "available to the // platform but not available to any APEX". When the list is not empty, `what` is matched against // the list. If there is any matching element in the list, thus function returns true. The special // availability "//apex_available:anyapex" matches with anything except for // "//apex_available:platform". func CheckAvailableForApex(what string, apex_available []string) bool { if len(apex_available) == 0 { return what == AvailableToPlatform } return InList(what, apex_available) || (what != AvailableToPlatform && InList(AvailableToAnyApex, apex_available)) || (strings.HasPrefix(what, "com.android.gki.") && InList(AvailableToGkiApex, apex_available)) } // Implements ApexModule func (m *ApexModuleBase) AvailableFor(what string) bool { return CheckAvailableForApex(what, m.ApexProperties.Apex_available) } // Implements ApexModule func (m *ApexModuleBase) NotAvailableForPlatform() bool { return m.ApexProperties.NotAvailableForPlatform } // Implements ApexModule func (m *ApexModuleBase) SetNotAvailableForPlatform() { m.ApexProperties.NotAvailableForPlatform = true } // This function makes sure that the apex_available property is valid func (m *ApexModuleBase) checkApexAvailableProperty(mctx BaseModuleContext) { for _, n := range m.ApexProperties.Apex_available { if n == AvailableToPlatform || n == AvailableToAnyApex || n == AvailableToGkiApex { continue } if !mctx.OtherModuleExists(n) && !mctx.Config().AllowMissingDependencies() { mctx.PropertyErrorf("apex_available", "%q is not a valid module name", n) } } } type byApexName []ApexInfo func (a byApexName) Len() int { return len(a) } func (a byApexName) Swap(i, j int) { a[i], a[j] = a[j], a[i] } func (a byApexName) Less(i, j int) bool { return a[i].ApexVariationName < a[j].ApexVariationName } // mergeApexVariations deduplicates apex variations that would build identically into a common // variation. It returns the reduced list of variations and a list of aliases from the original // variation names to the new variation names. func mergeApexVariations(ctx PathContext, apexInfos []ApexInfo) (merged []ApexInfo, aliases [][2]string) { sort.Sort(byApexName(apexInfos)) seen := make(map[string]int) for _, apexInfo := range apexInfos { // If this is for a prebuilt apex then use the actual name of the apex variation to prevent this // from being merged with other ApexInfo. See Prebuilt.ApexInfoMutator for more information. if apexInfo.ForPrebuiltApex { merged = append(merged, apexInfo) continue } // Merge the ApexInfo together. If a compatible ApexInfo exists then merge the information from // this one into it, otherwise create a new merged ApexInfo from this one and save it away so // other ApexInfo instances can be merged into it. apexName := apexInfo.ApexVariationName mergedName := apexInfo.mergedName(ctx) if index, exists := seen[mergedName]; exists { // Variants having the same mergedName are deduped merged[index].InApexes = append(merged[index].InApexes, apexName) merged[index].ApexContents = append(merged[index].ApexContents, apexInfo.ApexContents...) merged[index].Updatable = merged[index].Updatable || apexInfo.Updatable } else { seen[mergedName] = len(merged) apexInfo.ApexVariationName = mergedName apexInfo.InApexes = CopyOf(apexInfo.InApexes) apexInfo.ApexContents = append([]*ApexContents(nil), apexInfo.ApexContents...) merged = append(merged, apexInfo) } aliases = append(aliases, [2]string{apexName, mergedName}) } return merged, aliases } // CreateApexVariations mutates a given module into multiple apex variants each of which is for an // apexBundle (and/or the platform) where the module is part of. func CreateApexVariations(mctx BottomUpMutatorContext, module ApexModule) []Module { base := module.apexModuleBase() // Shortcut if len(base.apexInfos) == 0 { return nil } // Do some validity checks. // TODO(jiyong): is this the right place? base.checkApexAvailableProperty(mctx) var apexInfos []ApexInfo var aliases [][2]string if !mctx.Module().(ApexModule).UniqueApexVariations() && !base.ApexProperties.UniqueApexVariationsForDeps { apexInfos, aliases = mergeApexVariations(mctx, base.apexInfos) } else { apexInfos = base.apexInfos } // base.apexInfos is only needed to propagate the list of apexes from apexInfoMutator to // apexMutator. It is no longer accurate after mergeApexVariations, and won't be copied to // all but the first created variant. Clear it so it doesn't accidentally get used later. base.apexInfos = nil sort.Sort(byApexName(apexInfos)) var inApex ApexMembership for _, a := range apexInfos { for _, apexContents := range a.ApexContents { inApex = inApex.merge(apexContents.contents[mctx.ModuleName()]) } } base.ApexProperties.InAnyApex = true base.ApexProperties.DirectlyInAnyApex = inApex == directlyInApex defaultVariation := "" mctx.SetDefaultDependencyVariation(&defaultVariation) variations := []string{defaultVariation} for _, a := range apexInfos { variations = append(variations, a.ApexVariationName) } modules := mctx.CreateVariations(variations...) for i, mod := range modules { platformVariation := i == 0 if platformVariation && !mctx.Host() && !mod.(ApexModule).AvailableFor(AvailableToPlatform) { // Do not install the module for platform, but still allow it to output // uninstallable AndroidMk entries in certain cases when they have side // effects. TODO(jiyong): move this routine to somewhere else mod.MakeUninstallable() } if !platformVariation { mctx.SetVariationProvider(mod, ApexInfoProvider, apexInfos[i-1]) } } for _, alias := range aliases { mctx.CreateAliasVariation(alias[0], alias[1]) } return modules } // UpdateUniqueApexVariationsForDeps sets UniqueApexVariationsForDeps if any dependencies that are // in the same APEX have unique APEX variations so that the module can link against the right // variant. func UpdateUniqueApexVariationsForDeps(mctx BottomUpMutatorContext, am ApexModule) { // anyInSameApex returns true if the two ApexInfo lists contain any values in an InApexes // list in common. It is used instead of DepIsInSameApex because it needs to determine if // the dep is in the same APEX due to being directly included, not only if it is included // _because_ it is a dependency. anyInSameApex := func(a, b []ApexInfo) bool { collectApexes := func(infos []ApexInfo) []string { var ret []string for _, info := range infos { ret = append(ret, info.InApexes...) } return ret } aApexes := collectApexes(a) bApexes := collectApexes(b) sort.Strings(bApexes) for _, aApex := range aApexes { index := sort.SearchStrings(bApexes, aApex) if index < len(bApexes) && bApexes[index] == aApex { return true } } return false } // If any of the dependencies requires unique apex variations, so does this module. mctx.VisitDirectDeps(func(dep Module) { if depApexModule, ok := dep.(ApexModule); ok { if anyInSameApex(depApexModule.apexModuleBase().apexInfos, am.apexModuleBase().apexInfos) && (depApexModule.UniqueApexVariations() || depApexModule.apexModuleBase().ApexProperties.UniqueApexVariationsForDeps) { am.apexModuleBase().ApexProperties.UniqueApexVariationsForDeps = true } } }) } // UpdateDirectlyInAnyApex uses the final module to store if any variant of this module is directly // in any APEX, and then copies the final value to all the modules. It also copies the // DirectlyInAnyApex value to any direct dependencies with a CopyDirectlyInAnyApexTag dependency // tag. func UpdateDirectlyInAnyApex(mctx BottomUpMutatorContext, am ApexModule) { base := am.apexModuleBase() // Copy DirectlyInAnyApex and InAnyApex from any direct dependencies with a // CopyDirectlyInAnyApexTag dependency tag. mctx.VisitDirectDeps(func(dep Module) { if _, ok := mctx.OtherModuleDependencyTag(dep).(CopyDirectlyInAnyApexTag); ok { depBase := dep.(ApexModule).apexModuleBase() base.ApexProperties.DirectlyInAnyApex = depBase.ApexProperties.DirectlyInAnyApex base.ApexProperties.InAnyApex = depBase.ApexProperties.InAnyApex } }) if base.ApexProperties.DirectlyInAnyApex { // Variants of a module are always visited sequentially in order, so it is safe to // write to another variant of this module. For a BottomUpMutator the // PrimaryModule() is visited first and FinalModule() is visited last. mctx.FinalModule().(ApexModule).apexModuleBase().ApexProperties.AnyVariantDirectlyInAnyApex = true } // If this is the FinalModule (last visited module) copy // AnyVariantDirectlyInAnyApex to all the other variants if am == mctx.FinalModule().(ApexModule) { mctx.VisitAllModuleVariants(func(variant Module) { variant.(ApexModule).apexModuleBase().ApexProperties.AnyVariantDirectlyInAnyApex = base.ApexProperties.AnyVariantDirectlyInAnyApex }) } } // ApexMembership tells how a module became part of an APEX. type ApexMembership int const ( notInApex ApexMembership = 0 indirectlyInApex = iota directlyInApex ) // ApexContents gives an information about member modules of an apexBundle. Each apexBundle has an // apexContents, and modules in that apex have a provider containing the apexContents of each // apexBundle they are part of. type ApexContents struct { // map from a module name to its membership in this apexBundle contents map[string]ApexMembership } // NewApexContents creates and initializes an ApexContents that is suitable // for use with an apex module. // * contents is a map from a module name to information about its membership within // the apex. func NewApexContents(contents map[string]ApexMembership) *ApexContents { return &ApexContents{ contents: contents, } } // Updates an existing membership by adding a new direct (or indirect) membership func (i ApexMembership) Add(direct bool) ApexMembership { if direct || i == directlyInApex { return directlyInApex } return indirectlyInApex } // Merges two membership into one. Merging is needed because a module can be a part of an apexBundle // in many different paths. For example, it could be dependend on by the apexBundle directly, but at // the same time, there might be an indirect dependency to the module. In that case, the more // specific dependency (the direct one) is chosen. func (i ApexMembership) merge(other ApexMembership) ApexMembership { if other == directlyInApex || i == directlyInApex { return directlyInApex } if other == indirectlyInApex || i == indirectlyInApex { return indirectlyInApex } return notInApex } // Tests whether a module named moduleName is directly included in the apexBundle where this // ApexContents is tagged. func (ac *ApexContents) DirectlyInApex(moduleName string) bool { return ac.contents[moduleName] == directlyInApex } // Tests whether a module named moduleName is included in the apexBundle where this ApexContent is // tagged. func (ac *ApexContents) InApex(moduleName string) bool { return ac.contents[moduleName] != notInApex } // Tests whether a module named moduleName is directly depended on by all APEXes in an ApexInfo. func DirectlyInAllApexes(apexInfo ApexInfo, moduleName string) bool { for _, contents := range apexInfo.ApexContents { if !contents.DirectlyInApex(moduleName) { return false } } return true } //////////////////////////////////////////////////////////////////////////////////////////////////// //Below are routines for extra safety checks. // // BuildDepsInfoLists is to flatten the dependency graph for an apexBundle into a text file // (actually two in slightly different formats). The files are mostly for debugging, for example to // see why a certain module is included in an APEX via which dependency path. // // CheckMinSdkVersion is to make sure that all modules in an apexBundle satisfy the min_sdk_version // requirement of the apexBundle. // A dependency info for a single ApexModule, either direct or transitive. type ApexModuleDepInfo struct { // Name of the dependency To string // List of dependencies To belongs to. Includes APEX itself, if a direct dependency. From []string // Whether the dependency belongs to the final compiled APEX. IsExternal bool // min_sdk_version of the ApexModule MinSdkVersion string } // A map of a dependency name to its ApexModuleDepInfo type DepNameToDepInfoMap map[string]ApexModuleDepInfo type ApexBundleDepsInfo struct { flatListPath OutputPath fullListPath OutputPath } type ApexBundleDepsInfoIntf interface { Updatable() bool FlatListPath() Path FullListPath() Path } func (d *ApexBundleDepsInfo) FlatListPath() Path { return d.flatListPath } func (d *ApexBundleDepsInfo) FullListPath() Path { return d.fullListPath } // Generate two module out files: // 1. FullList with transitive deps and their parents in the dep graph // 2. FlatList with a flat list of transitive deps func (d *ApexBundleDepsInfo) BuildDepsInfoLists(ctx ModuleContext, minSdkVersion string, depInfos DepNameToDepInfoMap) { var fullContent strings.Builder var flatContent strings.Builder fmt.Fprintf(&fullContent, "%s(minSdkVersion:%s):\n", ctx.ModuleName(), minSdkVersion) for _, key := range FirstUniqueStrings(SortedStringKeys(depInfos)) { info := depInfos[key] toName := fmt.Sprintf("%s(minSdkVersion:%s)", info.To, info.MinSdkVersion) if info.IsExternal { toName = toName + " (external)" } fmt.Fprintf(&fullContent, " %s <- %s\n", toName, strings.Join(SortedUniqueStrings(info.From), ", ")) fmt.Fprintf(&flatContent, "%s\n", toName) } d.fullListPath = PathForModuleOut(ctx, "depsinfo", "fulllist.txt").OutputPath WriteFileRule(ctx, d.fullListPath, fullContent.String()) d.flatListPath = PathForModuleOut(ctx, "depsinfo", "flatlist.txt").OutputPath WriteFileRule(ctx, d.flatListPath, flatContent.String()) ctx.Phony(fmt.Sprintf("%s-depsinfo", ctx.ModuleName()), d.fullListPath, d.flatListPath) } // TODO(b/158059172): remove minSdkVersion allowlist var minSdkVersionAllowlist = func(apiMap map[string]int) map[string]ApiLevel { list := make(map[string]ApiLevel, len(apiMap)) for name, finalApiInt := range apiMap { list[name] = uncheckedFinalApiLevel(finalApiInt) } return list }(map[string]int{ "adbd": 30, "android.net.ipsec.ike": 30, "apache-commons-compress": 29, "bouncycastle_ike_digests": 30, "brotli-java": 29, "captiveportal-lib": 28, "flatbuffer_headers": 30, "framework-permission": 30, "gemmlowp_headers": 30, "ike-internals": 30, "kotlinx-coroutines-android": 28, "kotlinx-coroutines-core": 28, "libadb_crypto": 30, "libadb_pairing_auth": 30, "libadb_pairing_connection": 30, "libadb_pairing_server": 30, "libadb_protos": 30, "libadb_tls_connection": 30, "libadbconnection_client": 30, "libadbconnection_server": 30, "libadbd_core": 30, "libadbd_services": 30, "libadbd": 30, "libapp_processes_protos_lite": 30, "libasyncio": 30, "libbrotli": 30, "libbuildversion": 30, "libcrypto_static": 30, "libcrypto_utils": 30, "libdiagnose_usb": 30, "libeigen": 30, "liblz4": 30, "libmdnssd": 30, "libneuralnetworks_common": 30, "libneuralnetworks_headers": 30, "libneuralnetworks": 30, "libprocpartition": 30, "libprotobuf-java-lite": 30, "libprotoutil": 30, "libqemu_pipe": 30, "libsync": 30, "libtextclassifier_hash_headers": 30, "libtextclassifier_hash_static": 30, "libtflite_kernel_utils": 30, "libwatchdog": 29, "libzstd": 30, "metrics-constants-protos": 28, "net-utils-framework-common": 29, "permissioncontroller-statsd": 28, "philox_random_headers": 30, "philox_random": 30, "service-permission": 30, "tensorflow_headers": 30, "xz-java": 29, }) // Function called while walking an APEX's payload dependencies. // // Return true if the `to` module should be visited, false otherwise. type PayloadDepsCallback func(ctx ModuleContext, from blueprint.Module, to ApexModule, externalDep bool) bool // UpdatableModule represents updatable APEX/APK type UpdatableModule interface { Module WalkPayloadDeps(ctx ModuleContext, do PayloadDepsCallback) } // CheckMinSdkVersion checks if every dependency of an updatable module sets min_sdk_version // accordingly func CheckMinSdkVersion(m UpdatableModule, ctx ModuleContext, minSdkVersion ApiLevel) { // do not enforce min_sdk_version for host if ctx.Host() { return } // do not enforce for coverage build if ctx.Config().IsEnvTrue("EMMA_INSTRUMENT") || ctx.DeviceConfig().NativeCoverageEnabled() || ctx.DeviceConfig().ClangCoverageEnabled() { return } // do not enforce deps.min_sdk_version if APEX/APK doesn't set min_sdk_version if minSdkVersion.IsNone() { return } m.WalkPayloadDeps(ctx, func(ctx ModuleContext, from blueprint.Module, to ApexModule, externalDep bool) bool { if externalDep { // external deps are outside the payload boundary, which is "stable" // interface. We don't have to check min_sdk_version for external // dependencies. return false } if am, ok := from.(DepIsInSameApex); ok && !am.DepIsInSameApex(ctx, to) { return false } if err := to.ShouldSupportSdkVersion(ctx, minSdkVersion); err != nil { toName := ctx.OtherModuleName(to) if ver, ok := minSdkVersionAllowlist[toName]; !ok || ver.GreaterThan(minSdkVersion) { ctx.OtherModuleErrorf(to, "should support min_sdk_version(%v) for %q: %v. Dependency path: %s", minSdkVersion, ctx.ModuleName(), err.Error(), ctx.GetPathString(false)) return false } } return true }) }