557 lines
26 KiB
Go
557 lines
26 KiB
Go
// Copyright 2020 Google Inc. All rights reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package dexpreopt
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import (
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"fmt"
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"sort"
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"strconv"
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"strings"
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"android/soong/android"
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)
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// This comment describes the following:
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// 1. the concept of class loader context (CLC) and its relation to classpath
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// 2. how PackageManager constructs CLC from shared libraries and their dependencies
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// 3. build-time vs. run-time CLC and why this matters for dexpreopt
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// 4. manifest fixer: a tool that adds missing <uses-library> tags to the manifests
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// 5. build system support for CLC
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//
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// 1. Class loader context
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// -----------------------
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//
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// Java libraries and apps that have run-time dependency on other libraries should list the used
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// libraries in their manifest (AndroidManifest.xml file). Each used library should be specified in
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// a <uses-library> tag that has the library name and an optional attribute specifying if the
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// library is optional or required. Required libraries are necessary for the library/app to run (it
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// will fail at runtime if the library cannot be loaded), and optional libraries are used only if
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// they are present (if not, the library/app can run without them).
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//
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// The libraries listed in <uses-library> tags are in the classpath of a library/app.
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//
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// Besides libraries, an app may also use another APK (for example in the case of split APKs), or
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// anything that gets added by the app dynamically. In general, it is impossible to know at build
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// time what the app may use at runtime. In the build system we focus on the known part: libraries.
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//
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// Class loader context (CLC) is a tree-like structure that describes class loader hierarchy. The
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// build system uses CLC in a more narrow sense: it is a tree of libraries that represents
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// transitive closure of all <uses-library> dependencies of a library/app. The top-level elements of
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// a CLC are the direct <uses-library> dependencies specified in the manifest (aka. classpath). Each
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// node of a CLC tree is a <uses-library> which may have its own <uses-library> sub-nodes.
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//
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// Because <uses-library> dependencies are, in general, a graph and not necessarily a tree, CLC may
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// contain subtrees for the same library multiple times. In other words, CLC is the dependency graph
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// "unfolded" to a tree. The duplication is only on a logical level, and the actual underlying class
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// loaders are not duplicated (at runtime there is a single class loader instance for each library).
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//
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// Example: A has <uses-library> tags B, C and D; C has <uses-library tags> B and D;
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// D has <uses-library> E; B and E have no <uses-library> dependencies. The CLC is:
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// A
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// ├── B
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// ├── C
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// │ ├── B
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// │ └── D
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// │ └── E
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// └── D
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// └── E
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//
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// CLC defines the lookup order of libraries when resolving Java classes used by the library/app.
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// The lookup order is important because libraries may contain duplicate classes, and the class is
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// resolved to the first match.
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//
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// 2. PackageManager and "shared" libraries
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// ----------------------------------------
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//
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// In order to load an APK at runtime, PackageManager (in frameworks/base) creates a CLC. It adds
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// the libraries listed in the <uses-library> tags in the app's manifest as top-level CLC elements.
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// For each of the used libraries PackageManager gets all its <uses-library> dependencies (specified
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// as tags in the manifest of that library) and adds a nested CLC for each dependency. This process
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// continues recursively until all leaf nodes of the constructed CLC tree are libraries that have no
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// <uses-library> dependencies.
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//
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// PackageManager is aware only of "shared" libraries. The definition of "shared" here differs from
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// its usual meaning (as in shared vs. static). In Android, Java "shared" libraries are those listed
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// in /system/etc/permissions/platform.xml file. This file is installed on device. Each entry in it
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// contains the name of a "shared" library, a path to its DEX jar file and a list of dependencies
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// (other "shared" libraries that this one uses at runtime and specifies them in <uses-library> tags
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// in its manifest).
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//
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// In other words, there are two sources of information that allow PackageManager to construct CLC
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// at runtime: <uses-library> tags in the manifests and "shared" library dependencies in
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// /system/etc/permissions/platform.xml.
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//
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// 3. Build-time and run-time CLC and dexpreopt
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// --------------------------------------------
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//
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// CLC is needed not only when loading a library/app, but also when compiling it. Compilation may
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// happen either on device (known as "dexopt") or during the build (known as "dexpreopt"). Since
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// dexopt takes place on device, it has the same information as PackageManager (manifests and
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// shared library dependencies). Dexpreopt, on the other hand, takes place on host and in a totally
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// different environment, and it has to get the same information from the build system (see the
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// section about build system support below).
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//
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// Thus, the build-time CLC used by dexpreopt and the run-time CLC used by PackageManager are
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// the same thing, but computed in two different ways.
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//
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// It is important that build-time and run-time CLCs coincide, otherwise the AOT-compiled code
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// created by dexpreopt will be rejected. In order to check the equality of build-time and
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// run-time CLCs, the dex2oat compiler records build-time CLC in the *.odex files (in the
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// "classpath" field of the OAT file header). To find the stored CLC, use the following command:
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// `oatdump --oat-file=<FILE> | grep '^classpath = '`.
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//
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// Mismatch between build-time and run-time CLC is reported in logcat during boot (search with
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// `logcat | grep -E 'ClassLoaderContext [a-z ]+ mismatch'`. Mismatch is bad for performance, as it
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// forces the library/app to either be dexopted, or to run without any optimizations (e.g. the app's
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// code may need to be extracted in memory from the APK, a very expensive operation).
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//
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// A <uses-library> can be either optional or required. From dexpreopt standpoint, required library
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// must be present at build time (its absence is a build error). An optional library may be either
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// present or absent at build time: if present, it will be added to the CLC, passed to dex2oat and
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// recorded in the *.odex file; otherwise, if the library is absent, it will be skipped and not
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// added to CLC. If there is a mismatch between built-time and run-time status (optional library is
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// present in one case, but not the other), then the build-time and run-time CLCs won't match and
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// the compiled code will be rejected. It is unknown at build time if the library will be present at
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// runtime, therefore either including or excluding it may cause CLC mismatch.
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//
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// 4. Manifest fixer
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// -----------------
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//
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// Sometimes <uses-library> tags are missing from the source manifest of a library/app. This may
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// happen for example if one of the transitive dependencies of the library/app starts using another
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// <uses-library>, and the library/app's manifest isn't updated to include it.
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//
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// Soong can compute some of the missing <uses-library> tags for a given library/app automatically
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// as SDK libraries in the transitive dependency closure of the library/app. The closure is needed
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// because a library/app may depend on a static library that may in turn depend on an SDK library,
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// (possibly transitively via another library).
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//
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// Not all <uses-library> tags can be computed in this way, because some of the <uses-library>
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// dependencies are not SDK libraries, or they are not reachable via transitive dependency closure.
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// But when possible, allowing Soong to calculate the manifest entries is less prone to errors and
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// simplifies maintenance. For example, consider a situation when many apps use some static library
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// that adds a new <uses-library> dependency -- all the apps will have to be updated. That is
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// difficult to maintain.
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//
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// Soong computes the libraries that need to be in the manifest as the top-level libraries in CLC.
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// These libraries are passed to the manifest_fixer.
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//
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// All libraries added to the manifest should be "shared" libraries, so that PackageManager can look
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// up their dependencies and reconstruct the nested subcontexts at runtime. There is no build check
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// to ensure this, it is an assumption.
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//
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// 5. Build system support
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// -----------------------
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//
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// In order to construct CLC for dexpreopt and manifest_fixer, the build system needs to know all
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// <uses-library> dependencies of the dexpreopted library/app (including transitive dependencies).
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// For each <uses-librarry> dependency it needs to know the following information:
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//
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// - the real name of the <uses-library> (it may be different from the module name)
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// - build-time (on host) and run-time (on device) paths to the DEX jar file of the library
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// - whether this library is optional or required
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// - all <uses-library> dependencies
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//
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// Since the build system doesn't have access to the manifest contents (it cannot read manifests at
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// the time of build rule generation), it is necessary to copy this information to the Android.bp
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// and Android.mk files. For blueprints, the relevant properties are `uses_libs` and
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// `optional_uses_libs`. For makefiles, relevant variables are `LOCAL_USES_LIBRARIES` and
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// `LOCAL_OPTIONAL_USES_LIBRARIES`. It is preferable to avoid specifying these properties explicilty
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// when they can be computed automatically by Soong (as the transitive closure of SDK library
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// dependencies).
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//
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// Some of the Java libraries that are used as <uses-library> are not SDK libraries (they are
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// defined as `java_library` rather than `java_sdk_library` in the Android.bp files). In order for
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// the build system to handle them automatically like SDK libraries, it is possible to set a
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// property `provides_uses_lib` or variable `LOCAL_PROVIDES_USES_LIBRARY` on the blueprint/makefile
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// module of such library. This property can also be used to specify real library name in cases
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// when it differs from the module name.
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//
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// Because the information from the manifests has to be duplicated in the Android.bp/Android.mk
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// files, there is a danger that it may get out of sync. To guard against that, the build system
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// generates a rule that checks the metadata in the build files against the contents of a manifest
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// (verify_uses_libraries). The manifest can be available as a source file, or as part of a prebuilt
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// APK. Note that reading the manifests at the Ninja stage of the build is fine, unlike the build
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// rule generation phase.
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//
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// ClassLoaderContext is a structure that represents CLC.
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//
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type ClassLoaderContext struct {
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// The name of the library.
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Name string
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// On-host build path to the library dex file (used in dex2oat argument --class-loader-context).
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Host android.Path
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// On-device install path (used in dex2oat argument --stored-class-loader-context).
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Device string
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// Nested sub-CLC for dependencies.
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Subcontexts []*ClassLoaderContext
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}
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// ClassLoaderContextMap is a map from SDK version to CLC. There is a special entry with key
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// AnySdkVersion that stores unconditional CLC that is added regardless of the target SDK version.
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//
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// Conditional CLC is for compatibility libraries which didn't exist prior to a certain SDK version
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// (say, N), but classes in them were in the bootclasspath jars, etc., and in version N they have
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// been separated into a standalone <uses-library>. Compatibility libraries should only be in the
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// CLC if the library/app that uses them has `targetSdkVersion` less than N in the manifest.
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//
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// Currently only apps (but not libraries) use conditional CLC.
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//
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// Target SDK version information is unavailable to the build system at rule generation time, so
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// the build system doesn't know whether conditional CLC is needed for a given app or not. So it
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// generates a build rule that includes conditional CLC for all versions, extracts the target SDK
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// version from the manifest, and filters the CLCs based on that version. Exact final CLC that is
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// passed to dex2oat is unknown to the build system, and gets known only at Ninja stage.
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//
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type ClassLoaderContextMap map[int][]*ClassLoaderContext
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// Compatibility libraries. Some are optional, and some are required: this is the default that
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// affects how they are handled by the Soong logic that automatically adds implicit SDK libraries
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// to the manifest_fixer, but an explicit `uses_libs`/`optional_uses_libs` can override this.
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var OrgApacheHttpLegacy = "org.apache.http.legacy"
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var AndroidTestBase = "android.test.base"
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var AndroidTestMock = "android.test.mock"
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var AndroidHidlBase = "android.hidl.base-V1.0-java"
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var AndroidHidlManager = "android.hidl.manager-V1.0-java"
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// Compatibility libraries grouped by version/optionality (for convenience, to avoid repeating the
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// same lists in multiple places).
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var OptionalCompatUsesLibs28 = []string{
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OrgApacheHttpLegacy,
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}
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var OptionalCompatUsesLibs30 = []string{
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AndroidTestBase,
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AndroidTestMock,
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}
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var CompatUsesLibs29 = []string{
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AndroidHidlManager,
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AndroidHidlBase,
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}
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var OptionalCompatUsesLibs = append(android.CopyOf(OptionalCompatUsesLibs28), OptionalCompatUsesLibs30...)
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var CompatUsesLibs = android.CopyOf(CompatUsesLibs29)
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const UnknownInstallLibraryPath = "error"
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// AnySdkVersion means that the class loader context is needed regardless of the targetSdkVersion
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// of the app. The numeric value affects the key order in the map and, as a result, the order of
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// arguments passed to construct_context.py (high value means that the unconditional context goes
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// last). We use the converntional "current" SDK level (10000), but any big number would do as well.
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const AnySdkVersion int = android.FutureApiLevelInt
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// Add class loader context for the given library to the map entry for the given SDK version.
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func (clcMap ClassLoaderContextMap) addContext(ctx android.ModuleInstallPathContext, sdkVer int, lib string,
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hostPath, installPath android.Path, nestedClcMap ClassLoaderContextMap) error {
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devicePath := UnknownInstallLibraryPath
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if installPath == nil {
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if android.InList(lib, CompatUsesLibs) || android.InList(lib, OptionalCompatUsesLibs) {
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// Assume that compatibility libraries are installed in /system/framework.
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installPath = android.PathForModuleInstall(ctx, "framework", lib+".jar")
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} else {
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// For some stub libraries the only known thing is the name of their implementation
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// library, but the library itself is unavailable (missing or part of a prebuilt). In
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// such cases we still need to add the library to <uses-library> tags in the manifest,
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// but we cannot use it for dexpreopt.
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}
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}
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if installPath != nil {
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devicePath = android.InstallPathToOnDevicePath(ctx, installPath.(android.InstallPath))
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}
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// Nested class loader context shouldn't have conditional part (it is allowed only at the top level).
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for ver, _ := range nestedClcMap {
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if ver != AnySdkVersion {
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clcStr, _ := ComputeClassLoaderContext(nestedClcMap)
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return fmt.Errorf("nested class loader context shouldn't have conditional part: %s", clcStr)
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}
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}
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subcontexts := nestedClcMap[AnySdkVersion]
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// If the library with this name is already present as one of the unconditional top-level
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// components, do not re-add it.
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for _, clc := range clcMap[sdkVer] {
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if clc.Name == lib {
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return nil
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}
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}
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clcMap[sdkVer] = append(clcMap[sdkVer], &ClassLoaderContext{
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Name: lib,
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Host: hostPath,
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Device: devicePath,
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Subcontexts: subcontexts,
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})
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return nil
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}
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// Add class loader context for the given SDK version. Don't fail on unknown build/install paths, as
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// libraries with unknown paths still need to be processed by manifest_fixer (which doesn't care
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// about paths). For the subset of libraries that are used in dexpreopt, their build/install paths
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// are validated later before CLC is used (in validateClassLoaderContext).
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func (clcMap ClassLoaderContextMap) AddContext(ctx android.ModuleInstallPathContext, sdkVer int,
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lib string, hostPath, installPath android.Path, nestedClcMap ClassLoaderContextMap) {
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err := clcMap.addContext(ctx, sdkVer, lib, hostPath, installPath, nestedClcMap)
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if err != nil {
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ctx.ModuleErrorf(err.Error())
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}
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}
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// Merge the other class loader context map into this one, do not override existing entries.
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// The implicitRootLib parameter is the name of the library for which the other class loader
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// context map was constructed. If the implicitRootLib is itself a <uses-library>, it should be
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// already present in the class loader context (with the other context as its subcontext) -- in
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// that case do not re-add the other context. Otherwise add the other context at the top-level.
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func (clcMap ClassLoaderContextMap) AddContextMap(otherClcMap ClassLoaderContextMap, implicitRootLib string) {
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if otherClcMap == nil {
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return
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}
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// If the implicit root of the merged map is already present as one of top-level subtrees, do
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// not merge it second time.
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for _, clc := range clcMap[AnySdkVersion] {
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if clc.Name == implicitRootLib {
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return
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}
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}
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for sdkVer, otherClcs := range otherClcMap {
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for _, otherClc := range otherClcs {
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alreadyHave := false
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for _, clc := range clcMap[sdkVer] {
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if clc.Name == otherClc.Name {
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alreadyHave = true
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break
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}
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}
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if !alreadyHave {
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clcMap[sdkVer] = append(clcMap[sdkVer], otherClc)
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}
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}
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}
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}
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// Returns top-level libraries in the CLC (conditional CLC, i.e. compatibility libraries are not
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// included). This is the list of libraries that should be in the <uses-library> tags in the
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// manifest. Some of them may be present in the source manifest, others are added by manifest_fixer.
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func (clcMap ClassLoaderContextMap) UsesLibs() (ulibs []string) {
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if clcMap != nil {
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clcs := clcMap[AnySdkVersion]
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ulibs = make([]string, 0, len(clcs))
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for _, clc := range clcs {
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ulibs = append(ulibs, clc.Name)
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}
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}
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return ulibs
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}
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// Now that the full unconditional context is known, reconstruct conditional context.
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// Apply filters for individual libraries, mirroring what the PackageManager does when it
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// constructs class loader context on device.
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//
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// TODO(b/132357300): remove "android.hidl.manager" and "android.hidl.base" for non-system apps.
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//
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func fixClassLoaderContext(clcMap ClassLoaderContextMap) {
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usesLibs := clcMap.UsesLibs()
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for sdkVer, clcs := range clcMap {
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if sdkVer == AnySdkVersion {
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continue
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}
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fixedClcs := []*ClassLoaderContext{}
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for _, clc := range clcs {
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if android.InList(clc.Name, usesLibs) {
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// skip compatibility libraries that are already included in unconditional context
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} else if clc.Name == AndroidTestMock && !android.InList("android.test.runner", usesLibs) {
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// android.test.mock is only needed as a compatibility library (in conditional class
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// loader context) if android.test.runner is used, otherwise skip it
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} else {
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fixedClcs = append(fixedClcs, clc)
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}
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clcMap[sdkVer] = fixedClcs
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}
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}
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}
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// Return true if all build/install library paths are valid (including recursive subcontexts),
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// otherwise return false. A build path is valid if it's not nil. An install path is valid if it's
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// not equal to a special "error" value.
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func validateClassLoaderContext(clcMap ClassLoaderContextMap) (bool, error) {
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for sdkVer, clcs := range clcMap {
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if valid, err := validateClassLoaderContextRec(sdkVer, clcs); !valid || err != nil {
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return valid, err
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}
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}
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return true, nil
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}
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// Helper function for validateClassLoaderContext() that handles recursion.
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func validateClassLoaderContextRec(sdkVer int, clcs []*ClassLoaderContext) (bool, error) {
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for _, clc := range clcs {
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if clc.Host == nil || clc.Device == UnknownInstallLibraryPath {
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if sdkVer == AnySdkVersion {
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// Return error if dexpreopt doesn't know paths to one of the <uses-library>
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// dependencies. In the future we may need to relax this and just disable dexpreopt.
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if clc.Host == nil {
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return false, fmt.Errorf("invalid build path for <uses-library> \"%s\"", clc.Name)
|
|
} else {
|
|
return false, fmt.Errorf("invalid install path for <uses-library> \"%s\"", clc.Name)
|
|
}
|
|
} else {
|
|
// No error for compatibility libraries, as Soong doesn't know if they are needed
|
|
// (this depends on the targetSdkVersion in the manifest), but the CLC is invalid.
|
|
return false, nil
|
|
}
|
|
}
|
|
if valid, err := validateClassLoaderContextRec(sdkVer, clc.Subcontexts); !valid || err != nil {
|
|
return valid, err
|
|
}
|
|
}
|
|
return true, nil
|
|
}
|
|
|
|
// Return the class loader context as a string, and a slice of build paths for all dependencies.
|
|
// Perform a depth-first preorder traversal of the class loader context tree for each SDK version.
|
|
// Return the resulting string and a slice of on-host build paths to all library dependencies.
|
|
func ComputeClassLoaderContext(clcMap ClassLoaderContextMap) (clcStr string, paths android.Paths) {
|
|
// CLC for different SDK versions should come in specific order that agrees with PackageManager.
|
|
// Since PackageManager processes SDK versions in ascending order and prepends compatibility
|
|
// libraries at the front, the required order is descending, except for AnySdkVersion that has
|
|
// numerically the largest order, but must be the last one. Example of correct order: [30, 29,
|
|
// 28, AnySdkVersion]. There are Soong tests to ensure that someone doesn't change this by
|
|
// accident, but there is no way to guard against changes in the PackageManager, except for
|
|
// grepping logcat on the first boot for absence of the following messages:
|
|
//
|
|
// `logcat | grep -E 'ClassLoaderContext [a-z ]+ mismatch`
|
|
//
|
|
versions := make([]int, 0, len(clcMap))
|
|
for ver, _ := range clcMap {
|
|
if ver != AnySdkVersion {
|
|
versions = append(versions, ver)
|
|
}
|
|
}
|
|
sort.Sort(sort.Reverse(sort.IntSlice(versions))) // descending order
|
|
versions = append(versions, AnySdkVersion)
|
|
|
|
for _, sdkVer := range versions {
|
|
sdkVerStr := fmt.Sprintf("%d", sdkVer)
|
|
if sdkVer == AnySdkVersion {
|
|
sdkVerStr = "any" // a special keyword that means any SDK version
|
|
}
|
|
hostClc, targetClc, hostPaths := computeClassLoaderContextRec(clcMap[sdkVer])
|
|
if hostPaths != nil {
|
|
clcStr += fmt.Sprintf(" --host-context-for-sdk %s %s", sdkVerStr, hostClc)
|
|
clcStr += fmt.Sprintf(" --target-context-for-sdk %s %s", sdkVerStr, targetClc)
|
|
}
|
|
paths = append(paths, hostPaths...)
|
|
}
|
|
return clcStr, android.FirstUniquePaths(paths)
|
|
}
|
|
|
|
// Helper function for ComputeClassLoaderContext() that handles recursion.
|
|
func computeClassLoaderContextRec(clcs []*ClassLoaderContext) (string, string, android.Paths) {
|
|
var paths android.Paths
|
|
var clcsHost, clcsTarget []string
|
|
|
|
for _, clc := range clcs {
|
|
subClcHost, subClcTarget, subPaths := computeClassLoaderContextRec(clc.Subcontexts)
|
|
if subPaths != nil {
|
|
subClcHost = "{" + subClcHost + "}"
|
|
subClcTarget = "{" + subClcTarget + "}"
|
|
}
|
|
|
|
clcsHost = append(clcsHost, "PCL["+clc.Host.String()+"]"+subClcHost)
|
|
clcsTarget = append(clcsTarget, "PCL["+clc.Device+"]"+subClcTarget)
|
|
|
|
paths = append(paths, clc.Host)
|
|
paths = append(paths, subPaths...)
|
|
}
|
|
|
|
clcHost := strings.Join(clcsHost, "#")
|
|
clcTarget := strings.Join(clcsTarget, "#")
|
|
|
|
return clcHost, clcTarget, paths
|
|
}
|
|
|
|
// Class loader contexts that come from Make via JSON dexpreopt.config. JSON CLC representation is
|
|
// the same as Soong representation except that SDK versions and paths are represented with strings.
|
|
type jsonClassLoaderContext struct {
|
|
Name string
|
|
Host string
|
|
Device string
|
|
Subcontexts []*jsonClassLoaderContext
|
|
}
|
|
|
|
// A map from SDK version (represented with a JSON string) to JSON CLCs.
|
|
type jsonClassLoaderContextMap map[string][]*jsonClassLoaderContext
|
|
|
|
// Convert JSON CLC map to Soong represenation.
|
|
func fromJsonClassLoaderContext(ctx android.PathContext, jClcMap jsonClassLoaderContextMap) ClassLoaderContextMap {
|
|
clcMap := make(ClassLoaderContextMap)
|
|
for sdkVerStr, clcs := range jClcMap {
|
|
sdkVer, ok := strconv.Atoi(sdkVerStr)
|
|
if ok != nil {
|
|
if sdkVerStr == "any" {
|
|
sdkVer = AnySdkVersion
|
|
} else {
|
|
android.ReportPathErrorf(ctx, "failed to parse SDK version in dexpreopt.config: '%s'", sdkVerStr)
|
|
}
|
|
}
|
|
clcMap[sdkVer] = fromJsonClassLoaderContextRec(ctx, clcs)
|
|
}
|
|
return clcMap
|
|
}
|
|
|
|
// Recursive helper for fromJsonClassLoaderContext.
|
|
func fromJsonClassLoaderContextRec(ctx android.PathContext, jClcs []*jsonClassLoaderContext) []*ClassLoaderContext {
|
|
clcs := make([]*ClassLoaderContext, 0, len(jClcs))
|
|
for _, clc := range jClcs {
|
|
clcs = append(clcs, &ClassLoaderContext{
|
|
Name: clc.Name,
|
|
Host: constructPath(ctx, clc.Host),
|
|
Device: clc.Device,
|
|
Subcontexts: fromJsonClassLoaderContextRec(ctx, clc.Subcontexts),
|
|
})
|
|
}
|
|
return clcs
|
|
}
|
|
|
|
// Convert Soong CLC map to JSON representation for Make.
|
|
func toJsonClassLoaderContext(clcMap ClassLoaderContextMap) jsonClassLoaderContextMap {
|
|
jClcMap := make(jsonClassLoaderContextMap)
|
|
for sdkVer, clcs := range clcMap {
|
|
sdkVerStr := fmt.Sprintf("%d", sdkVer)
|
|
jClcMap[sdkVerStr] = toJsonClassLoaderContextRec(clcs)
|
|
}
|
|
return jClcMap
|
|
}
|
|
|
|
// Recursive helper for toJsonClassLoaderContext.
|
|
func toJsonClassLoaderContextRec(clcs []*ClassLoaderContext) []*jsonClassLoaderContext {
|
|
jClcs := make([]*jsonClassLoaderContext, len(clcs))
|
|
for i, clc := range clcs {
|
|
jClcs[i] = &jsonClassLoaderContext{
|
|
Name: clc.Name,
|
|
Host: clc.Host.String(),
|
|
Device: clc.Device,
|
|
Subcontexts: toJsonClassLoaderContextRec(clc.Subcontexts),
|
|
}
|
|
}
|
|
return jClcs
|
|
}
|