| // Copyright (c) 2019, the R8 project authors. Please see the AUTHORS file |
| // for details. All rights reserved. Use of this source code is governed by a |
| // BSD-style license that can be found in the LICENSE file. |
| package com.android.tools.r8.shaking; |
| |
| import static com.android.tools.r8.graph.DexEncodedMethod.asProgramMethodOrNull; |
| import static com.android.tools.r8.graph.DexEncodedMethod.toMethodDefinitionOrNull; |
| import static com.android.tools.r8.graph.DexProgramClass.asProgramClassOrNull; |
| import static com.android.tools.r8.graph.ResolutionResult.SingleResolutionResult.isOverriding; |
| |
| import com.android.tools.r8.cf.CfVersion; |
| import com.android.tools.r8.features.ClassToFeatureSplitMap; |
| import com.android.tools.r8.graph.AppInfoWithClassHierarchy; |
| import com.android.tools.r8.graph.DexCallSite; |
| import com.android.tools.r8.graph.DexClass; |
| import com.android.tools.r8.graph.DexClassAndMethod; |
| import com.android.tools.r8.graph.DexClasspathClass; |
| import com.android.tools.r8.graph.DexDefinition; |
| import com.android.tools.r8.graph.DexDefinitionSupplier; |
| import com.android.tools.r8.graph.DexEncodedField; |
| import com.android.tools.r8.graph.DexEncodedMethod; |
| import com.android.tools.r8.graph.DexField; |
| import com.android.tools.r8.graph.DexMember; |
| import com.android.tools.r8.graph.DexMethod; |
| import com.android.tools.r8.graph.DexProgramClass; |
| import com.android.tools.r8.graph.DexReference; |
| import com.android.tools.r8.graph.DexType; |
| import com.android.tools.r8.graph.DirectMappedDexApplication; |
| import com.android.tools.r8.graph.FieldAccessInfo; |
| import com.android.tools.r8.graph.FieldAccessInfoCollection; |
| import com.android.tools.r8.graph.FieldAccessInfoCollectionImpl; |
| import com.android.tools.r8.graph.FieldResolutionResult; |
| import com.android.tools.r8.graph.GraphLens.NonIdentityGraphLens; |
| import com.android.tools.r8.graph.InstantiatedSubTypeInfo; |
| import com.android.tools.r8.graph.LookupResult.LookupResultSuccess; |
| import com.android.tools.r8.graph.LookupTarget; |
| import com.android.tools.r8.graph.MethodAccessInfoCollection; |
| import com.android.tools.r8.graph.ObjectAllocationInfoCollection; |
| import com.android.tools.r8.graph.ObjectAllocationInfoCollectionImpl; |
| import com.android.tools.r8.graph.ProgramField; |
| import com.android.tools.r8.graph.ProgramMethod; |
| import com.android.tools.r8.graph.PrunedItems; |
| import com.android.tools.r8.graph.ResolutionResult.SingleResolutionResult; |
| import com.android.tools.r8.graph.SubtypingInfo; |
| import com.android.tools.r8.ir.analysis.type.ClassTypeElement; |
| import com.android.tools.r8.ir.code.Invoke.Type; |
| import com.android.tools.r8.ir.desugar.DesugaredLibraryAPIConverter; |
| import com.android.tools.r8.ir.desugar.InterfaceMethodRewriter; |
| import com.android.tools.r8.ir.desugar.LambdaDescriptor; |
| import com.android.tools.r8.ir.desugar.TwrCloseResourceRewriter; |
| import com.android.tools.r8.synthesis.CommittedItems; |
| import com.android.tools.r8.utils.CollectionUtils; |
| import com.android.tools.r8.utils.InternalOptions; |
| import com.android.tools.r8.utils.ListUtils; |
| import com.android.tools.r8.utils.PredicateSet; |
| import com.android.tools.r8.utils.TraversalContinuation; |
| import com.android.tools.r8.utils.Visibility; |
| import com.android.tools.r8.utils.WorkList; |
| import com.android.tools.r8.utils.collections.ProgramMethodSet; |
| import com.android.tools.r8.utils.structural.Ordered; |
| import com.google.common.collect.Sets; |
| import it.unimi.dsi.fastutil.ints.Int2ReferenceMap; |
| import it.unimi.dsi.fastutil.objects.Object2BooleanMap; |
| import java.util.ArrayDeque; |
| import java.util.Collection; |
| import java.util.Collections; |
| import java.util.Deque; |
| import java.util.List; |
| import java.util.Map; |
| import java.util.Set; |
| import java.util.function.Consumer; |
| import java.util.stream.Collectors; |
| |
| /** Encapsulates liveness and reachability information for an application. */ |
| public class AppInfoWithLiveness extends AppInfoWithClassHierarchy |
| implements InstantiatedSubTypeInfo { |
| /** Set of reachable proto types that will be dead code eliminated. */ |
| private final Set<DexType> deadProtoTypes; |
| /** |
| * Set of types that are mentioned in the program. We at least need an empty abstract classitem |
| * for these. |
| */ |
| private final Set<DexType> liveTypes; |
| /** |
| * Set of methods that are the immediate target of an invoke. They might not actually be live but |
| * are required so that invokes can find the method. If such a method is not live (i.e. not |
| * contained in {@link #liveMethods}, it may be marked as abstract and its implementation may be |
| * removed. |
| */ |
| private final Set<DexMethod> targetedMethods; |
| |
| /** Set of targets that lead to resolution errors, such as non-existing or invalid targets. */ |
| private final Set<DexMethod> failedResolutionTargets; |
| |
| /** |
| * Set of program methods that are used as the bootstrap method for an invoke-dynamic instruction. |
| */ |
| private final Set<DexMethod> bootstrapMethods; |
| |
| /** Set of methods that are the immediate target of an invoke-dynamic. */ |
| private final Set<DexMethod> methodsTargetedByInvokeDynamic; |
| /** Set of virtual methods that are the immediate target of an invoke-direct. */ |
| private final Set<DexMethod> virtualMethodsTargetedByInvokeDirect; |
| /** |
| * Set of methods that belong to live classes and can be reached by invokes. These need to be |
| * kept. |
| */ |
| private final Set<DexMethod> liveMethods; |
| /** |
| * Information about all fields that are accessed by the program. The information includes whether |
| * a given field is read/written by the program, and it also includes all indirect accesses to |
| * each field. The latter is used, for example, during member rebinding. |
| */ |
| private FieldAccessInfoCollectionImpl fieldAccessInfoCollection; |
| /** Set of all methods referenced in invokes along with their calling contexts. */ |
| private final MethodAccessInfoCollection methodAccessInfoCollection; |
| /** Information about instantiated classes and their allocation sites. */ |
| private final ObjectAllocationInfoCollectionImpl objectAllocationInfoCollection; |
| /** |
| * Set of live call sites in the code. Note that if desugaring has taken place call site objects |
| * will have been removed from the code. |
| */ |
| public final Map<DexCallSite, ProgramMethodSet> callSites; |
| /** Collection of keep requirements for the program. */ |
| private final KeepInfoCollection keepInfo; |
| /** All items with assumemayhavesideeffects rule. */ |
| public final Map<DexReference, ProguardMemberRule> mayHaveSideEffects; |
| /** All items with assumenosideeffects rule. */ |
| public final Map<DexMember<?, ?>, ProguardMemberRule> noSideEffects; |
| /** All items with assumevalues rule. */ |
| public final Map<DexMember<?, ?>, ProguardMemberRule> assumedValues; |
| /** All methods that should be inlined if possible due to a configuration directive. */ |
| private final Set<DexMethod> alwaysInline; |
| /** All methods that *must* be inlined due to a configuration directive (testing only). */ |
| private final Set<DexMethod> forceInline; |
| /** All methods that *must* never be inlined due to a configuration directive (testing only). */ |
| private final Set<DexMethod> neverInline; |
| /** |
| * All methods that *must* never be inlined as a result of having a single caller due to a |
| * configuration directive (testing only). |
| */ |
| private final Set<DexMethod> neverInlineDueToSingleCaller; |
| /** Items for which to print inlining decisions for (testing only). */ |
| private final Set<DexMethod> whyAreYouNotInlining; |
| /** All methods that may not have any parameters with a constant value removed. */ |
| private final Set<DexMethod> keepConstantArguments; |
| /** All methods that may not have any unused arguments removed. */ |
| private final Set<DexMethod> keepUnusedArguments; |
| /** All methods that must be reprocessed (testing only). */ |
| private final Set<DexMethod> reprocess; |
| /** All methods that must not be reprocessed (testing only). */ |
| private final Set<DexMethod> neverReprocess; |
| /** All types that should be inlined if possible due to a configuration directive. */ |
| public final PredicateSet<DexType> alwaysClassInline; |
| /** All types that *must* never be inlined due to a configuration directive (testing only). */ |
| private final Set<DexType> neverClassInline; |
| |
| private final Set<DexType> noClassMerging; |
| private final Set<DexType> noHorizontalClassMerging; |
| private final Set<DexType> noVerticalClassMerging; |
| private final Set<DexType> noStaticClassMerging; |
| |
| /** |
| * Set of lock candidates (i.e., types whose class reference may flow to a monitor instruction). |
| */ |
| private final Set<DexType> lockCandidates; |
| /** |
| * A map from seen init-class references to the minimum required visibility of the corresponding |
| * static field. |
| */ |
| public final Map<DexType, Visibility> initClassReferences; |
| /** |
| * All methods and fields whose value *must* never be propagated due to a configuration directive. |
| * (testing only). |
| */ |
| private final Set<DexReference> neverPropagateValue; |
| /** |
| * All items with -identifiernamestring rule. Bound boolean value indicates the rule is explicitly |
| * specified by users (<code>true</code>) or not, i.e., implicitly added by R8 (<code>false</code> |
| * ). |
| */ |
| public final Object2BooleanMap<DexReference> identifierNameStrings; |
| /** A set of types that have been removed by the {@link TreePruner}. */ |
| final Set<DexType> prunedTypes; |
| /** A map from switchmap class types to their corresponding switchmaps. */ |
| final Map<DexField, Int2ReferenceMap<DexField>> switchMaps; |
| |
| /* A cache to improve the lookup performance of lookupSingleVirtualTarget */ |
| private final SingleTargetLookupCache singleTargetLookupCache = new SingleTargetLookupCache(); |
| |
| // TODO(zerny): Clean up the constructors so we have just one. |
| AppInfoWithLiveness( |
| CommittedItems syntheticItems, |
| ClassToFeatureSplitMap classToFeatureSplitMap, |
| MainDexClasses mainDexClasses, |
| Set<DexType> deadProtoTypes, |
| MissingClasses missingClasses, |
| Set<DexType> liveTypes, |
| Set<DexMethod> targetedMethods, |
| Set<DexMethod> failedResolutionTargets, |
| Set<DexMethod> bootstrapMethods, |
| Set<DexMethod> methodsTargetedByInvokeDynamic, |
| Set<DexMethod> virtualMethodsTargetedByInvokeDirect, |
| Set<DexMethod> liveMethods, |
| FieldAccessInfoCollectionImpl fieldAccessInfoCollection, |
| MethodAccessInfoCollection methodAccessInfoCollection, |
| ObjectAllocationInfoCollectionImpl objectAllocationInfoCollection, |
| Map<DexCallSite, ProgramMethodSet> callSites, |
| KeepInfoCollection keepInfo, |
| Map<DexReference, ProguardMemberRule> mayHaveSideEffects, |
| Map<DexMember<?, ?>, ProguardMemberRule> noSideEffects, |
| Map<DexMember<?, ?>, ProguardMemberRule> assumedValues, |
| Set<DexMethod> alwaysInline, |
| Set<DexMethod> forceInline, |
| Set<DexMethod> neverInline, |
| Set<DexMethod> neverInlineDueToSingleCaller, |
| Set<DexMethod> whyAreYouNotInlining, |
| Set<DexMethod> keepConstantArguments, |
| Set<DexMethod> keepUnusedArguments, |
| Set<DexMethod> reprocess, |
| Set<DexMethod> neverReprocess, |
| PredicateSet<DexType> alwaysClassInline, |
| Set<DexType> neverClassInline, |
| Set<DexType> noClassMerging, |
| Set<DexType> noVerticalClassMerging, |
| Set<DexType> noHorizontalClassMerging, |
| Set<DexType> noStaticClassMerging, |
| Set<DexReference> neverPropagateValue, |
| Object2BooleanMap<DexReference> identifierNameStrings, |
| Set<DexType> prunedTypes, |
| Map<DexField, Int2ReferenceMap<DexField>> switchMaps, |
| Set<DexType> lockCandidates, |
| Map<DexType, Visibility> initClassReferences) { |
| super(syntheticItems, classToFeatureSplitMap, mainDexClasses, missingClasses); |
| this.deadProtoTypes = deadProtoTypes; |
| this.liveTypes = liveTypes; |
| this.targetedMethods = targetedMethods; |
| this.failedResolutionTargets = failedResolutionTargets; |
| this.bootstrapMethods = bootstrapMethods; |
| this.methodsTargetedByInvokeDynamic = methodsTargetedByInvokeDynamic; |
| this.virtualMethodsTargetedByInvokeDirect = virtualMethodsTargetedByInvokeDirect; |
| this.liveMethods = liveMethods; |
| this.fieldAccessInfoCollection = fieldAccessInfoCollection; |
| this.methodAccessInfoCollection = methodAccessInfoCollection; |
| this.objectAllocationInfoCollection = objectAllocationInfoCollection; |
| this.keepInfo = keepInfo; |
| this.mayHaveSideEffects = mayHaveSideEffects; |
| this.noSideEffects = noSideEffects; |
| this.assumedValues = assumedValues; |
| this.callSites = callSites; |
| this.alwaysInline = alwaysInline; |
| this.forceInline = forceInline; |
| this.neverInline = neverInline; |
| this.neverInlineDueToSingleCaller = neverInlineDueToSingleCaller; |
| this.whyAreYouNotInlining = whyAreYouNotInlining; |
| this.keepConstantArguments = keepConstantArguments; |
| this.keepUnusedArguments = keepUnusedArguments; |
| this.reprocess = reprocess; |
| this.neverReprocess = neverReprocess; |
| this.alwaysClassInline = alwaysClassInline; |
| this.neverClassInline = neverClassInline; |
| this.noClassMerging = noClassMerging; |
| this.noVerticalClassMerging = noVerticalClassMerging; |
| this.noHorizontalClassMerging = noHorizontalClassMerging; |
| this.noStaticClassMerging = noStaticClassMerging; |
| this.neverPropagateValue = neverPropagateValue; |
| this.identifierNameStrings = identifierNameStrings; |
| this.prunedTypes = prunedTypes; |
| this.switchMaps = switchMaps; |
| this.lockCandidates = lockCandidates; |
| this.initClassReferences = initClassReferences; |
| verify(); |
| } |
| |
| private AppInfoWithLiveness(AppInfoWithLiveness previous, CommittedItems committedItems) { |
| this( |
| committedItems, |
| previous.getClassToFeatureSplitMap(), |
| previous.getMainDexClasses(), |
| previous.deadProtoTypes, |
| previous.getMissingClasses(), |
| CollectionUtils.mergeSets(previous.liveTypes, committedItems.getCommittedTypes()), |
| previous.targetedMethods, |
| previous.failedResolutionTargets, |
| previous.bootstrapMethods, |
| previous.methodsTargetedByInvokeDynamic, |
| previous.virtualMethodsTargetedByInvokeDirect, |
| previous.liveMethods, |
| previous.fieldAccessInfoCollection, |
| previous.methodAccessInfoCollection, |
| previous.objectAllocationInfoCollection, |
| previous.callSites, |
| previous.keepInfo, |
| previous.mayHaveSideEffects, |
| previous.noSideEffects, |
| previous.assumedValues, |
| previous.alwaysInline, |
| previous.forceInline, |
| previous.neverInline, |
| previous.neverInlineDueToSingleCaller, |
| previous.whyAreYouNotInlining, |
| previous.keepConstantArguments, |
| previous.keepUnusedArguments, |
| previous.reprocess, |
| previous.neverReprocess, |
| previous.alwaysClassInline, |
| previous.neverClassInline, |
| previous.noClassMerging, |
| previous.noVerticalClassMerging, |
| previous.noHorizontalClassMerging, |
| previous.noStaticClassMerging, |
| previous.neverPropagateValue, |
| previous.identifierNameStrings, |
| previous.prunedTypes, |
| previous.switchMaps, |
| previous.lockCandidates, |
| previous.initClassReferences); |
| } |
| |
| private AppInfoWithLiveness(AppInfoWithLiveness previous, PrunedItems prunedItems) { |
| this( |
| previous.getSyntheticItems().commitPrunedItems(prunedItems), |
| previous.getClassToFeatureSplitMap().withoutPrunedItems(prunedItems), |
| previous.getMainDexClasses().withoutPrunedItems(prunedItems), |
| previous.deadProtoTypes, |
| previous.getMissingClasses(), |
| prunedItems.hasRemovedClasses() |
| ? Sets.difference(previous.liveTypes, prunedItems.getRemovedClasses()) |
| : previous.liveTypes, |
| previous.targetedMethods, |
| previous.failedResolutionTargets, |
| previous.bootstrapMethods, |
| previous.methodsTargetedByInvokeDynamic, |
| previous.virtualMethodsTargetedByInvokeDirect, |
| previous.liveMethods, |
| previous.fieldAccessInfoCollection, |
| previous.methodAccessInfoCollection, |
| previous.objectAllocationInfoCollection, |
| previous.callSites, |
| extendPinnedItems(previous, prunedItems.getAdditionalPinnedItems()), |
| previous.mayHaveSideEffects, |
| previous.noSideEffects, |
| previous.assumedValues, |
| previous.alwaysInline, |
| previous.forceInline, |
| previous.neverInline, |
| previous.neverInlineDueToSingleCaller, |
| previous.whyAreYouNotInlining, |
| previous.keepConstantArguments, |
| previous.keepUnusedArguments, |
| previous.reprocess, |
| previous.neverReprocess, |
| previous.alwaysClassInline, |
| previous.neverClassInline, |
| previous.noClassMerging, |
| previous.noVerticalClassMerging, |
| previous.noHorizontalClassMerging, |
| previous.noStaticClassMerging, |
| previous.neverPropagateValue, |
| previous.identifierNameStrings, |
| prunedItems.hasRemovedClasses() |
| ? CollectionUtils.mergeSets(previous.prunedTypes, prunedItems.getRemovedClasses()) |
| : previous.prunedTypes, |
| previous.switchMaps, |
| previous.lockCandidates, |
| previous.initClassReferences); |
| } |
| |
| private void verify() { |
| assert keepInfo.verifyPinnedTypesAreLive(liveTypes); |
| assert objectAllocationInfoCollection.verifyAllocatedTypesAreLive( |
| liveTypes, getMissingClasses(), this); |
| } |
| |
| private static KeepInfoCollection extendPinnedItems( |
| AppInfoWithLiveness previous, Collection<? extends DexReference> additionalPinnedItems) { |
| if (additionalPinnedItems == null || additionalPinnedItems.isEmpty()) { |
| return previous.keepInfo; |
| } |
| return previous.keepInfo.mutate( |
| collection -> { |
| for (DexReference reference : additionalPinnedItems) { |
| if (reference.isDexType()) { |
| DexProgramClass clazz = |
| asProgramClassOrNull(previous.definitionFor(reference.asDexType())); |
| if (clazz != null) { |
| collection.pinClass(clazz); |
| } |
| } else if (reference.isDexMethod()) { |
| DexMethod method = reference.asDexMethod(); |
| DexProgramClass clazz = asProgramClassOrNull(previous.definitionFor(method.holder)); |
| if (clazz != null) { |
| ProgramMethod definition = clazz.lookupProgramMethod(method); |
| if (definition != null) { |
| collection.pinMethod(definition); |
| } |
| } |
| } else { |
| DexField field = reference.asDexField(); |
| DexProgramClass clazz = asProgramClassOrNull(previous.definitionFor(field.holder)); |
| if (clazz != null) { |
| ProgramField definition = clazz.lookupProgramField(field); |
| if (definition != null) { |
| collection.pinField(definition); |
| } |
| } |
| } |
| } |
| }); |
| } |
| |
| public AppInfoWithLiveness( |
| AppInfoWithLiveness previous, Map<DexField, Int2ReferenceMap<DexField>> switchMaps) { |
| super( |
| previous.getSyntheticItems().commit(previous.app()), |
| previous.getClassToFeatureSplitMap(), |
| previous.getMainDexClasses(), |
| previous.getMissingClasses()); |
| this.deadProtoTypes = previous.deadProtoTypes; |
| this.liveTypes = previous.liveTypes; |
| this.targetedMethods = previous.targetedMethods; |
| this.failedResolutionTargets = previous.failedResolutionTargets; |
| this.bootstrapMethods = previous.bootstrapMethods; |
| this.methodsTargetedByInvokeDynamic = previous.methodsTargetedByInvokeDynamic; |
| this.virtualMethodsTargetedByInvokeDirect = previous.virtualMethodsTargetedByInvokeDirect; |
| this.liveMethods = previous.liveMethods; |
| this.fieldAccessInfoCollection = previous.fieldAccessInfoCollection; |
| this.methodAccessInfoCollection = previous.methodAccessInfoCollection; |
| this.objectAllocationInfoCollection = previous.objectAllocationInfoCollection; |
| this.keepInfo = previous.keepInfo; |
| this.mayHaveSideEffects = previous.mayHaveSideEffects; |
| this.noSideEffects = previous.noSideEffects; |
| this.assumedValues = previous.assumedValues; |
| this.callSites = previous.callSites; |
| this.alwaysInline = previous.alwaysInline; |
| this.forceInline = previous.forceInline; |
| this.neverInline = previous.neverInline; |
| this.neverInlineDueToSingleCaller = previous.neverInlineDueToSingleCaller; |
| this.whyAreYouNotInlining = previous.whyAreYouNotInlining; |
| this.keepConstantArguments = previous.keepConstantArguments; |
| this.keepUnusedArguments = previous.keepUnusedArguments; |
| this.reprocess = previous.reprocess; |
| this.neverReprocess = previous.neverReprocess; |
| this.alwaysClassInline = previous.alwaysClassInline; |
| this.neverClassInline = previous.neverClassInline; |
| this.noClassMerging = previous.noClassMerging; |
| this.noVerticalClassMerging = previous.noVerticalClassMerging; |
| this.noHorizontalClassMerging = previous.noHorizontalClassMerging; |
| this.noStaticClassMerging = previous.noStaticClassMerging; |
| this.neverPropagateValue = previous.neverPropagateValue; |
| this.identifierNameStrings = previous.identifierNameStrings; |
| this.prunedTypes = previous.prunedTypes; |
| this.switchMaps = switchMaps; |
| this.lockCandidates = previous.lockCandidates; |
| this.initClassReferences = previous.initClassReferences; |
| previous.markObsolete(); |
| verify(); |
| } |
| |
| public static AppInfoWithLivenessModifier modifier() { |
| return new AppInfoWithLivenessModifier(); |
| } |
| |
| @Override |
| public DexClass definitionFor(DexType type) { |
| DexClass definition = super.definitionFor(type); |
| assert definition != null |
| || deadProtoTypes.contains(type) |
| || getMissingClasses().contains(type) |
| // TODO(b/150693139): Remove these exceptions once fixed. |
| || InterfaceMethodRewriter.isCompanionClassType(type) |
| || InterfaceMethodRewriter.hasDispatchClassSuffix(type) |
| || InterfaceMethodRewriter.isEmulatedLibraryClassType(type) |
| || type.toDescriptorString().startsWith("Lj$/$r8$retargetLibraryMember$") |
| || TwrCloseResourceRewriter.isUtilityClassDescriptor(type) |
| // TODO(b/150736225): Not sure how to remove these. |
| || DesugaredLibraryAPIConverter.isVivifiedType(type) |
| : "Failed lookup of non-missing type: " + type; |
| return definition; |
| } |
| |
| private CfVersion largestInputCfVersion = null; |
| |
| public boolean canUseConstClassInstructions(InternalOptions options) { |
| if (!options.isGeneratingClassFiles()) { |
| return true; |
| } |
| if (largestInputCfVersion == null) { |
| computeLargestCfVersion(); |
| } |
| return options.canUseConstClassInstructions(largestInputCfVersion); |
| } |
| |
| private synchronized void computeLargestCfVersion() { |
| if (largestInputCfVersion != null) { |
| return; |
| } |
| for (DexProgramClass clazz : classes()) { |
| // Skip synthetic classes which may not have a specified version. |
| if (clazz.hasClassFileVersion()) { |
| largestInputCfVersion = |
| Ordered.maxIgnoreNull(largestInputCfVersion, clazz.getInitialClassFileVersion()); |
| } |
| } |
| assert largestInputCfVersion != null; |
| } |
| |
| public boolean isLiveProgramClass(DexProgramClass clazz) { |
| return liveTypes.contains(clazz.type); |
| } |
| |
| public boolean isLiveProgramType(DexType type) { |
| DexClass clazz = definitionFor(type); |
| return clazz != null && clazz.isProgramClass() && isLiveProgramClass(clazz.asProgramClass()); |
| } |
| |
| public boolean isNonProgramTypeOrLiveProgramType(DexType type) { |
| if (liveTypes.contains(type)) { |
| return true; |
| } |
| if (prunedTypes.contains(type)) { |
| return false; |
| } |
| DexClass clazz = definitionFor(type); |
| return clazz == null || !clazz.isProgramClass(); |
| } |
| |
| public boolean isLiveMethod(DexMethod method) { |
| return liveMethods.contains(method); |
| } |
| |
| public boolean isTargetedMethod(DexMethod method) { |
| return targetedMethods.contains(method); |
| } |
| |
| public boolean isFailedResolutionTarget(DexMethod method) { |
| return failedResolutionTargets.contains(method); |
| } |
| |
| public Set<DexMethod> getFailedResolutionTargets() { |
| return failedResolutionTargets; |
| } |
| |
| public boolean isBootstrapMethod(DexMethod method) { |
| return bootstrapMethods.contains(method); |
| } |
| |
| public boolean isMethodTargetedByInvokeDynamic(DexMethod method) { |
| return methodsTargetedByInvokeDynamic.contains(method); |
| } |
| |
| public Set<DexMethod> getVirtualMethodsTargetedByInvokeDirect() { |
| return virtualMethodsTargetedByInvokeDirect; |
| } |
| |
| public boolean isAlwaysInlineMethod(DexMethod method) { |
| return alwaysInline.contains(method); |
| } |
| |
| public boolean hasNoAlwaysInlineMethods() { |
| return alwaysInline.isEmpty(); |
| } |
| |
| public boolean isForceInlineMethod(DexMethod method) { |
| return forceInline.contains(method); |
| } |
| |
| public boolean hasNoForceInlineMethods() { |
| return forceInline.isEmpty(); |
| } |
| |
| public boolean isNeverInlineMethod(DexMethod method) { |
| return neverInline.contains(method); |
| } |
| |
| public boolean isNeverInlineDueToSingleCallerMethod(ProgramMethod method) { |
| return neverInlineDueToSingleCaller.contains(method.getReference()); |
| } |
| |
| public boolean isWhyAreYouNotInliningMethod(DexMethod method) { |
| return whyAreYouNotInlining.contains(method); |
| } |
| |
| public boolean hasNoWhyAreYouNotInliningMethods() { |
| return whyAreYouNotInlining.isEmpty(); |
| } |
| |
| public boolean isKeepConstantArgumentsMethod(DexMethod method) { |
| return keepConstantArguments.contains(method); |
| } |
| |
| public boolean isKeepUnusedArgumentsMethod(DexMethod method) { |
| return keepUnusedArguments.contains(method); |
| } |
| |
| public boolean isNeverReprocessMethod(DexMethod method) { |
| return neverReprocess.contains(method); |
| } |
| |
| public Set<DexMethod> getReprocessMethods() { |
| return reprocess; |
| } |
| |
| public Collection<DexClass> computeReachableInterfaces() { |
| Set<DexClass> interfaces = Sets.newIdentityHashSet(); |
| WorkList<DexType> worklist = WorkList.newIdentityWorkList(); |
| worklist.addIfNotSeen(objectAllocationInfoCollection.getInstantiatedLambdaInterfaces()); |
| for (DexProgramClass clazz : classes()) { |
| worklist.addIfNotSeen(clazz.type); |
| } |
| while (worklist.hasNext()) { |
| DexType type = worklist.next(); |
| DexClass definition = definitionFor(type); |
| if (definition == null) { |
| continue; |
| } |
| if (definition.isInterface()) { |
| interfaces.add(definition); |
| } |
| if (definition.superType != null) { |
| worklist.addIfNotSeen(definition.superType); |
| } |
| worklist.addIfNotSeen(definition.interfaces.values); |
| } |
| return interfaces; |
| } |
| |
| /** |
| * Resolve the methods implemented by the lambda expression that created the {@code callSite}. |
| * |
| * <p>If {@code callSite} was not created as a result of a lambda expression (i.e. the metafactory |
| * is not {@code LambdaMetafactory}), the empty set is returned. |
| * |
| * <p>If the metafactory is neither {@code LambdaMetafactory} nor {@code StringConcatFactory}, a |
| * warning is issued. |
| * |
| * <p>The returned set of methods all have {@code callSite.methodName} as the method name. |
| * |
| * @param callSite Call site to resolve. |
| * @return Methods implemented by the lambda expression that created the {@code callSite}. |
| */ |
| public Set<DexEncodedMethod> lookupLambdaImplementedMethods(DexCallSite callSite) { |
| assert checkIfObsolete(); |
| List<DexType> callSiteInterfaces = LambdaDescriptor.getInterfaces(callSite, this); |
| if (callSiteInterfaces == null || callSiteInterfaces.isEmpty()) { |
| return Collections.emptySet(); |
| } |
| Set<DexEncodedMethod> result = Sets.newIdentityHashSet(); |
| Deque<DexType> worklist = new ArrayDeque<>(callSiteInterfaces); |
| Set<DexType> visited = Sets.newIdentityHashSet(); |
| while (!worklist.isEmpty()) { |
| DexType iface = worklist.removeFirst(); |
| if (!visited.add(iface)) { |
| // Already visited previously. May happen due to "diamond shapes" in the interface |
| // hierarchy. |
| continue; |
| } |
| DexClass clazz = definitionFor(iface); |
| if (clazz == null) { |
| // Skip this interface. If the lambda only implements missing library interfaces and not any |
| // program interfaces, then minification and tree shaking are not interested in this |
| // DexCallSite anyway, so skipping this interface is harmless. On the other hand, if |
| // minification is run on a program with a lambda interface that implements both a missing |
| // library interface and a present program interface, then we might minify the method name |
| // on the program interface even though it should be kept the same as the (missing) library |
| // interface method. That is a shame, but minification is not suited for incomplete programs |
| // anyway. |
| continue; |
| } |
| assert clazz.isInterface(); |
| for (DexEncodedMethod method : clazz.virtualMethods()) { |
| if (method.method.name == callSite.methodName && method.accessFlags.isAbstract()) { |
| result.add(method); |
| } |
| } |
| Collections.addAll(worklist, clazz.interfaces.values); |
| } |
| return result; |
| } |
| |
| /** |
| * Const-classes is a conservative set of types that may be lock-candidates and cannot be merged. |
| * When using synchronized blocks, we cannot ensure that const-class locks will not flow in. This |
| * can potentially cause incorrect behavior when merging classes. A conservative choice is to not |
| * merge any const-class classes. More info at b/142438687. |
| */ |
| public boolean isLockCandidate(DexType type) { |
| return lockCandidates.contains(type); |
| } |
| |
| public Set<DexType> getDeadProtoTypes() { |
| return deadProtoTypes; |
| } |
| |
| public Int2ReferenceMap<DexField> getSwitchMap(DexField field) { |
| assert checkIfObsolete(); |
| return switchMaps.get(field); |
| } |
| |
| /** This method provides immutable access to `fieldAccessInfoCollection`. */ |
| public FieldAccessInfoCollection<? extends FieldAccessInfo> getFieldAccessInfoCollection() { |
| return fieldAccessInfoCollection; |
| } |
| |
| FieldAccessInfoCollectionImpl getMutableFieldAccessInfoCollection() { |
| return fieldAccessInfoCollection; |
| } |
| |
| /** This method provides immutable access to `methodAccessInfoCollection`. */ |
| public MethodAccessInfoCollection getMethodAccessInfoCollection() { |
| return methodAccessInfoCollection; |
| } |
| |
| /** This method provides immutable access to `objectAllocationInfoCollection`. */ |
| public ObjectAllocationInfoCollection getObjectAllocationInfoCollection() { |
| return objectAllocationInfoCollection; |
| } |
| |
| void mutateObjectAllocationInfoCollection( |
| Consumer<ObjectAllocationInfoCollectionImpl.Builder> mutator) { |
| objectAllocationInfoCollection.mutate(mutator, this); |
| } |
| |
| void removeFromSingleTargetLookupCache(DexClass clazz) { |
| singleTargetLookupCache.removeInstantiatedType(clazz.type, this); |
| } |
| |
| private boolean isInstantiatedDirectly(DexProgramClass clazz) { |
| assert checkIfObsolete(); |
| DexType type = clazz.type; |
| return |
| // TODO(b/165224388): Synthetic classes should be represented in the allocation info. |
| getSyntheticItems().isSyntheticClass(clazz) |
| || (!clazz.isInterface() && objectAllocationInfoCollection.isInstantiatedDirectly(clazz)) |
| // TODO(b/145344105): Model annotations in the object allocation info. |
| || (clazz.isAnnotation() && liveTypes.contains(type)); |
| } |
| |
| public boolean isInstantiatedIndirectly(DexProgramClass clazz) { |
| assert checkIfObsolete(); |
| return objectAllocationInfoCollection.hasInstantiatedStrictSubtype(clazz); |
| } |
| |
| public boolean isInstantiatedDirectlyOrIndirectly(DexProgramClass clazz) { |
| assert checkIfObsolete(); |
| return isInstantiatedDirectly(clazz) || isInstantiatedIndirectly(clazz); |
| } |
| |
| public boolean isFieldRead(DexEncodedField encodedField) { |
| assert checkIfObsolete(); |
| DexField field = encodedField.field; |
| FieldAccessInfo info = getFieldAccessInfoCollection().get(field); |
| if (info != null && info.isRead()) { |
| return true; |
| } |
| if (keepInfo.isPinned(field, this)) { |
| return true; |
| } |
| // Fields in the class that is synthesized by D8/R8 would be used soon. |
| // TODO(b/165229577): Do we need this special handling of synthetics? |
| if (getSyntheticItems().isSyntheticClass(field.holder)) { |
| return true; |
| } |
| // For library classes we don't know whether a field is read. |
| return isLibraryOrClasspathField(encodedField); |
| } |
| |
| public boolean isFieldWritten(DexEncodedField encodedField) { |
| assert checkIfObsolete(); |
| return isFieldWrittenByFieldPutInstruction(encodedField) || isPinned(encodedField.field); |
| } |
| |
| public boolean isFieldWrittenByFieldPutInstruction(DexEncodedField encodedField) { |
| assert checkIfObsolete(); |
| DexField field = encodedField.field; |
| FieldAccessInfo info = getFieldAccessInfoCollection().get(field); |
| if (info != null && info.isWritten()) { |
| // The field is written directly by the program itself. |
| return true; |
| } |
| // TODO(b/165229577): Do we need this special handling of synthetics? |
| if (getSyntheticItems().isSyntheticClass(field.holder)) { |
| return true; |
| } |
| // For library classes we don't know whether a field is rewritten. |
| return isLibraryOrClasspathField(encodedField); |
| } |
| |
| public boolean isFieldOnlyWrittenInMethod(DexEncodedField field, DexEncodedMethod method) { |
| assert checkIfObsolete(); |
| assert isFieldWritten(field) : "Expected field `" + field.toSourceString() + "` to be written"; |
| if (isPinned(field.field)) { |
| return false; |
| } |
| return isFieldOnlyWrittenInMethodIgnoringPinning(field, method); |
| } |
| |
| public boolean isFieldOnlyWrittenInMethodIgnoringPinning( |
| DexEncodedField field, DexEncodedMethod method) { |
| assert checkIfObsolete(); |
| assert isFieldWritten(field) : "Expected field `" + field.toSourceString() + "` to be written"; |
| FieldAccessInfo fieldAccessInfo = getFieldAccessInfoCollection().get(field.field); |
| return fieldAccessInfo != null |
| && fieldAccessInfo.isWritten() |
| && !fieldAccessInfo.isWrittenOutside(method); |
| } |
| |
| public boolean isInstanceFieldWrittenOnlyInInstanceInitializers(DexEncodedField field) { |
| assert checkIfObsolete(); |
| assert isFieldWritten(field) : "Expected field `" + field.toSourceString() + "` to be written"; |
| if (isPinned(field.field)) { |
| return false; |
| } |
| FieldAccessInfo fieldAccessInfo = getFieldAccessInfoCollection().get(field.field); |
| if (fieldAccessInfo == null || !fieldAccessInfo.isWritten()) { |
| return false; |
| } |
| DexType holder = field.getHolderType(); |
| return fieldAccessInfo.isWrittenOnlyInMethodSatisfying( |
| method -> |
| method.getHolderType() == holder |
| && method |
| .getDefinition() |
| .isOrWillBeInlinedIntoInstanceInitializer(dexItemFactory())); |
| } |
| |
| public boolean isStaticFieldWrittenOnlyInEnclosingStaticInitializer(DexEncodedField field) { |
| assert checkIfObsolete(); |
| assert isFieldWritten(field) : "Expected field `" + field.toSourceString() + "` to be written"; |
| DexEncodedMethod staticInitializer = |
| definitionFor(field.getHolderType()).asProgramClass().getClassInitializer(); |
| return staticInitializer != null && isFieldOnlyWrittenInMethod(field, staticInitializer); |
| } |
| |
| public boolean mayPropagateArgumentsTo(ProgramMethod method) { |
| DexMethod reference = method.getReference(); |
| return method.getDefinition().hasCode() |
| && !method.getDefinition().isLibraryMethodOverride().isPossiblyTrue() |
| && !neverReprocess.contains(reference) |
| && !keepInfo.getMethodInfo(method).isPinned(); |
| } |
| |
| public boolean mayPropagateValueFor(DexMember<?, ?> reference) { |
| assert checkIfObsolete(); |
| return reference.apply(this::mayPropagateValueFor, this::mayPropagateValueFor); |
| } |
| |
| public boolean mayPropagateValueFor(DexField field) { |
| assert checkIfObsolete(); |
| if (!options().enableValuePropagation || neverPropagateValue.contains(field)) { |
| return false; |
| } |
| if (isPinned(field) && !field.getType().isAlwaysNull(this)) { |
| return false; |
| } |
| return true; |
| } |
| |
| public boolean mayPropagateValueFor(DexMethod method) { |
| assert checkIfObsolete(); |
| if (!options().enableValuePropagation || neverPropagateValue.contains(method)) { |
| return false; |
| } |
| if (isPinned(method) && !method.getReturnType().isAlwaysNull(this)) { |
| return false; |
| } |
| return true; |
| } |
| |
| private boolean isLibraryOrClasspathField(DexEncodedField field) { |
| DexClass holder = definitionFor(field.getHolderType()); |
| return holder == null || holder.isLibraryClass() || holder.isClasspathClass(); |
| } |
| |
| public boolean isInstantiatedInterface(DexProgramClass clazz) { |
| assert checkIfObsolete(); |
| return objectAllocationInfoCollection.isInterfaceWithUnknownSubtypeHierarchy(clazz); |
| } |
| |
| @Override |
| public boolean hasLiveness() { |
| assert checkIfObsolete(); |
| return true; |
| } |
| |
| @Override |
| public AppInfoWithLiveness withLiveness() { |
| assert checkIfObsolete(); |
| return this; |
| } |
| |
| public boolean isClassInliningAllowed(DexProgramClass clazz) { |
| return !isPinned(clazz) && !neverClassInline.contains(clazz.getType()); |
| } |
| |
| public boolean isMinificationAllowed(DexReference reference) { |
| return options().isMinificationEnabled() |
| && keepInfo.getInfo(reference, this).isMinificationAllowed(options()); |
| } |
| |
| public boolean isAccessModificationAllowed(DexReference reference) { |
| assert options().getProguardConfiguration().isAccessModificationAllowed(); |
| return keepInfo.getInfo(reference, this).isAccessModificationAllowed(options()); |
| } |
| |
| public boolean isRepackagingAllowed(DexProgramClass clazz) { |
| if (!options().isRepackagingEnabled()) { |
| return false; |
| } |
| if (!keepInfo.getInfo(clazz).isRepackagingAllowed(options())) { |
| return false; |
| } |
| return clazz |
| .traverseProgramMembers( |
| member -> { |
| if (keepInfo.getInfo(member).isRepackagingAllowed(options())) { |
| return TraversalContinuation.CONTINUE; |
| } |
| return TraversalContinuation.BREAK; |
| }) |
| .shouldContinue(); |
| } |
| |
| public boolean isPinned(DexReference reference) { |
| assert checkIfObsolete(); |
| return keepInfo.isPinned(reference, this); |
| } |
| |
| public boolean isPinned(DexDefinition definition) { |
| assert definition != null; |
| return isPinned(definition.getReference()); |
| } |
| |
| public boolean hasPinnedInstanceInitializer(DexType type) { |
| assert type.isClassType(); |
| DexProgramClass clazz = asProgramClassOrNull(definitionFor(type)); |
| if (clazz != null) { |
| for (DexEncodedMethod method : clazz.directMethods()) { |
| if (method.isInstanceInitializer() && isPinned(method.method)) { |
| return true; |
| } |
| } |
| } |
| return false; |
| } |
| |
| public KeepInfoCollection getKeepInfo() { |
| return keepInfo; |
| } |
| |
| /** |
| * Returns a copy of this AppInfoWithLiveness where the set of classes is pruned using the given |
| * DexApplication object. |
| */ |
| @Override |
| public AppInfoWithLiveness prunedCopyFrom(PrunedItems prunedItems) { |
| assert getClass() == AppInfoWithLiveness.class; |
| assert checkIfObsolete(); |
| if (prunedItems.isEmpty()) { |
| assert app() == prunedItems.getPrunedApp(); |
| return this; |
| } |
| if (prunedItems.hasRemovedClasses()) { |
| // Rebuild the hierarchy. |
| objectAllocationInfoCollection.mutate( |
| mutator -> mutator.removeAllocationsForPrunedItems(prunedItems), this); |
| keepInfo.mutate( |
| keepInfo -> keepInfo.removeKeepInfoForPrunedItems(prunedItems.getRemovedClasses())); |
| } |
| return new AppInfoWithLiveness(this, prunedItems); |
| } |
| |
| public AppInfoWithLiveness rebuildWithLiveness(CommittedItems committedItems) { |
| return new AppInfoWithLiveness(this, committedItems); |
| } |
| |
| public AppInfoWithLiveness rewrittenWithLens( |
| DirectMappedDexApplication application, NonIdentityGraphLens lens) { |
| assert checkIfObsolete(); |
| |
| // Switchmap classes should never be affected by renaming. |
| assert lens.assertDefinitionsNotModified( |
| switchMaps.keySet().stream() |
| .map(this::resolveField) |
| .filter(FieldResolutionResult::isSuccessfulResolution) |
| .map(FieldResolutionResult::getResolvedField) |
| .collect(Collectors.toList())); |
| |
| CommittedItems committedItems = getSyntheticItems().commitRewrittenWithLens(application, lens); |
| DexDefinitionSupplier definitionSupplier = application.getDefinitionsSupplier(committedItems); |
| return new AppInfoWithLiveness( |
| committedItems, |
| getClassToFeatureSplitMap().rewrittenWithLens(lens), |
| getMainDexClasses().rewrittenWithLens(lens), |
| deadProtoTypes, |
| getMissingClasses().commitSyntheticItems(committedItems), |
| lens.rewriteTypes(liveTypes), |
| lens.rewriteMethods(targetedMethods), |
| lens.rewriteMethods(failedResolutionTargets), |
| lens.rewriteMethods(bootstrapMethods), |
| lens.rewriteMethods(methodsTargetedByInvokeDynamic), |
| lens.rewriteMethods(virtualMethodsTargetedByInvokeDirect), |
| lens.rewriteMethods(liveMethods), |
| fieldAccessInfoCollection.rewrittenWithLens(definitionSupplier, lens), |
| methodAccessInfoCollection.rewrittenWithLens(definitionSupplier, lens), |
| objectAllocationInfoCollection.rewrittenWithLens(definitionSupplier, lens), |
| lens.rewriteCallSites(callSites, definitionSupplier), |
| keepInfo.rewrite(lens, application.options), |
| lens.rewriteReferenceKeys(mayHaveSideEffects), |
| lens.rewriteReferenceKeys(noSideEffects), |
| lens.rewriteReferenceKeys(assumedValues), |
| lens.rewriteMethods(alwaysInline), |
| lens.rewriteMethods(forceInline), |
| lens.rewriteMethods(neverInline), |
| lens.rewriteMethods(neverInlineDueToSingleCaller), |
| lens.rewriteMethods(whyAreYouNotInlining), |
| lens.rewriteMethods(keepConstantArguments), |
| lens.rewriteMethods(keepUnusedArguments), |
| lens.rewriteMethods(reprocess), |
| lens.rewriteMethods(neverReprocess), |
| alwaysClassInline.rewriteItems(lens::lookupType), |
| lens.rewriteTypes(neverClassInline), |
| lens.rewriteTypes(noClassMerging), |
| lens.rewriteTypes(noVerticalClassMerging), |
| lens.rewriteTypes(noHorizontalClassMerging), |
| lens.rewriteTypes(noStaticClassMerging), |
| lens.rewriteReferences(neverPropagateValue), |
| lens.rewriteReferenceKeys(identifierNameStrings), |
| // Don't rewrite pruned types - the removed types are identified by their original name. |
| prunedTypes, |
| lens.rewriteFieldKeys(switchMaps), |
| lens.rewriteTypes(lockCandidates), |
| lens.rewriteTypeKeys(initClassReferences)); |
| } |
| |
| /** |
| * Returns true if the given type was part of the original program but has been removed during |
| * tree shaking. |
| */ |
| public boolean wasPruned(DexType type) { |
| assert checkIfObsolete(); |
| return prunedTypes.contains(type); |
| } |
| |
| public Set<DexType> getPrunedTypes() { |
| assert checkIfObsolete(); |
| return prunedTypes; |
| } |
| |
| public DexEncodedMethod lookupSingleTarget( |
| Type type, |
| DexMethod target, |
| ProgramMethod context, |
| LibraryModeledPredicate modeledPredicate) { |
| assert checkIfObsolete(); |
| DexType holder = target.holder; |
| if (!holder.isClassType()) { |
| return null; |
| } |
| switch (type) { |
| case VIRTUAL: |
| return lookupSingleVirtualTarget(target, context, false, modeledPredicate); |
| case INTERFACE: |
| return lookupSingleVirtualTarget(target, context, true, modeledPredicate); |
| case DIRECT: |
| return lookupDirectTarget(target, context); |
| case STATIC: |
| return lookupStaticTarget(target, context); |
| case SUPER: |
| return toMethodDefinitionOrNull(lookupSuperTarget(target, context)); |
| default: |
| return null; |
| } |
| } |
| |
| public ProgramMethod lookupSingleProgramTarget( |
| Type type, |
| DexMethod target, |
| ProgramMethod context, |
| LibraryModeledPredicate modeledPredicate) { |
| return asProgramMethodOrNull(lookupSingleTarget(type, target, context, modeledPredicate), this); |
| } |
| |
| /** For mapping invoke virtual instruction to single target method. */ |
| public DexEncodedMethod lookupSingleVirtualTarget( |
| DexMethod method, ProgramMethod context, boolean isInterface) { |
| assert checkIfObsolete(); |
| return lookupSingleVirtualTarget( |
| method, context, isInterface, type -> false, method.holder, null); |
| } |
| |
| /** For mapping invoke virtual instruction to single target method. */ |
| public DexEncodedMethod lookupSingleVirtualTarget( |
| DexMethod method, |
| ProgramMethod context, |
| boolean isInterface, |
| LibraryModeledPredicate modeledPredicate) { |
| assert checkIfObsolete(); |
| return lookupSingleVirtualTarget( |
| method, context, isInterface, modeledPredicate, method.holder, null); |
| } |
| |
| public DexEncodedMethod lookupSingleVirtualTarget( |
| DexMethod method, |
| ProgramMethod context, |
| boolean isInterface, |
| LibraryModeledPredicate modeledPredicate, |
| DexType refinedReceiverType, |
| ClassTypeElement receiverLowerBoundType) { |
| assert checkIfObsolete(); |
| assert refinedReceiverType != null; |
| if (!refinedReceiverType.isClassType()) { |
| // The refined receiver is not of class type and we will not be able to find a single target |
| // (it is either primitive or array). |
| return null; |
| } |
| DexClass initialResolutionHolder = definitionFor(method.holder); |
| if (initialResolutionHolder == null || initialResolutionHolder.isInterface() != isInterface) { |
| return null; |
| } |
| DexClass refinedReceiverClass = definitionFor(refinedReceiverType); |
| if (refinedReceiverClass == null) { |
| // The refined receiver is not defined in the program and we cannot determine the target. |
| return null; |
| } |
| if (receiverLowerBoundType == null |
| && singleTargetLookupCache.hasCachedItem(refinedReceiverType, method)) { |
| DexEncodedMethod cachedItem = |
| singleTargetLookupCache.getCachedItem(refinedReceiverType, method); |
| return cachedItem; |
| } |
| SingleResolutionResult resolution = |
| resolveMethodOn(initialResolutionHolder, method).asSingleResolution(); |
| if (resolution == null |
| || resolution.isAccessibleForVirtualDispatchFrom(context.getHolder(), this).isFalse()) { |
| return null; |
| } |
| // If the method is modeled, return the resolution. |
| DexEncodedMethod resolvedMethod = resolution.getResolvedMethod(); |
| if (modeledPredicate.isModeled(resolution.getResolvedHolder().type)) { |
| if (resolution.getResolvedHolder().isFinal() |
| || (resolvedMethod.isFinal() && resolvedMethod.accessFlags.isPublic())) { |
| singleTargetLookupCache.addToCache(refinedReceiverType, method, resolvedMethod); |
| return resolvedMethod; |
| } |
| } |
| DexEncodedMethod exactTarget = |
| getMethodTargetFromExactRuntimeInformation( |
| refinedReceiverType, receiverLowerBoundType, resolution, refinedReceiverClass); |
| if (exactTarget != null) { |
| // We are not caching single targets here because the cache does not include the |
| // lower bound dimension. |
| return exactTarget == DexEncodedMethod.SENTINEL ? null : exactTarget; |
| } |
| if (refinedReceiverClass.isNotProgramClass()) { |
| // The refined receiver is not defined in the program and we cannot determine the target. |
| singleTargetLookupCache.addToCache(refinedReceiverType, method, null); |
| return null; |
| } |
| DexClass resolvedHolder = resolution.getResolvedHolder(); |
| // TODO(b/148769279): Disable lookup single target on lambda's for now. |
| if (resolvedHolder.isInterface() |
| && resolvedHolder.isProgramClass() |
| && objectAllocationInfoCollection.isImmediateInterfaceOfInstantiatedLambda( |
| resolvedHolder.asProgramClass())) { |
| singleTargetLookupCache.addToCache(refinedReceiverType, method, null); |
| return null; |
| } |
| DexEncodedMethod singleMethodTarget = null; |
| DexProgramClass refinedLowerBound = null; |
| if (receiverLowerBoundType != null) { |
| DexClass refinedLowerBoundClass = definitionFor(receiverLowerBoundType.getClassType()); |
| if (refinedLowerBoundClass != null) { |
| refinedLowerBound = refinedLowerBoundClass.asProgramClass(); |
| // TODO(b/154822960): Check if the lower bound is a subtype of the upper bound. |
| if (refinedLowerBound != null && !isSubtype(refinedLowerBound.type, refinedReceiverType)) { |
| refinedLowerBound = null; |
| } |
| } |
| } |
| LookupResultSuccess lookupResult = |
| resolution |
| .lookupVirtualDispatchTargets( |
| context.getHolder(), this, refinedReceiverClass.asProgramClass(), refinedLowerBound) |
| .asLookupResultSuccess(); |
| if (lookupResult != null && !lookupResult.isIncomplete()) { |
| LookupTarget singleTarget = lookupResult.getSingleLookupTarget(); |
| if (singleTarget != null && singleTarget.isMethodTarget()) { |
| singleMethodTarget = singleTarget.asMethodTarget().getDefinition(); |
| } |
| } |
| if (receiverLowerBoundType == null) { |
| singleTargetLookupCache.addToCache(refinedReceiverType, method, singleMethodTarget); |
| } |
| return singleMethodTarget; |
| } |
| |
| private DexEncodedMethod getMethodTargetFromExactRuntimeInformation( |
| DexType refinedReceiverType, |
| ClassTypeElement receiverLowerBoundType, |
| SingleResolutionResult resolution, |
| DexClass refinedReceiverClass) { |
| // If the lower-bound on the receiver type is the same as the upper-bound, then we have exact |
| // runtime type information. In this case, the invoke will dispatch to the resolution result |
| // from the runtime type of the receiver. |
| if (receiverLowerBoundType != null |
| && receiverLowerBoundType.getClassType() == refinedReceiverType) { |
| if (refinedReceiverClass.isProgramClass()) { |
| DexClassAndMethod clazzAndMethod = |
| resolution.lookupVirtualDispatchTarget(refinedReceiverClass.asProgramClass(), this); |
| if (clazzAndMethod == null || isPinned(clazzAndMethod.getDefinition().method)) { |
| // TODO(b/150640456): We should maybe only consider program methods. |
| return DexEncodedMethod.SENTINEL; |
| } |
| return clazzAndMethod.getDefinition(); |
| } else { |
| // TODO(b/150640456): We should maybe only consider program methods. |
| // If we resolved to a method on the refined receiver in the library, then we report the |
| // method as a single target as well. This is a bit iffy since the library could change |
| // implementation, but we use this for library modelling. |
| DexEncodedMethod resolvedMethod = resolution.getResolvedMethod(); |
| DexEncodedMethod targetOnReceiver = |
| refinedReceiverClass.lookupVirtualMethod(resolvedMethod.method); |
| if (targetOnReceiver != null && isOverriding(resolvedMethod, targetOnReceiver)) { |
| return targetOnReceiver; |
| } |
| return DexEncodedMethod.SENTINEL; |
| } |
| } |
| return null; |
| } |
| |
| public AppInfoWithLiveness withSwitchMaps(Map<DexField, Int2ReferenceMap<DexField>> switchMaps) { |
| assert checkIfObsolete(); |
| assert this.switchMaps.isEmpty(); |
| return new AppInfoWithLiveness(this, switchMaps); |
| } |
| |
| /** |
| * Visit all class definitions of classpath classes that are referenced in the compilation unit. |
| * |
| * <p>TODO(b/139464956): Only traverse the classpath types referenced from the live program. |
| * Conservatively traces all classpath classes for now. |
| */ |
| public void forEachReferencedClasspathClass(Consumer<DexClasspathClass> fn) { |
| app().asDirect().classpathClasses().forEach(fn); |
| } |
| |
| /** |
| * Visits all class definitions that are a live program type or a type above it in the hierarchy. |
| * |
| * <p>Any given definition will be visited at most once. No guarantees are places on the order. |
| */ |
| public void forEachTypeInHierarchyOfLiveProgramClasses(Consumer<DexClass> fn) { |
| forEachTypeInHierarchyOfLiveProgramClasses( |
| fn, |
| ListUtils.map(liveTypes, t -> definitionFor(t).asProgramClass()), |
| objectAllocationInfoCollection.getInstantiatedLambdaInterfaces(), |
| this); |
| } |
| |
| // Split in a static method so it can be used during construction. |
| static void forEachTypeInHierarchyOfLiveProgramClasses( |
| Consumer<DexClass> fn, |
| Collection<DexProgramClass> liveProgramClasses, |
| Set<DexType> lambdaInterfaces, |
| AppInfoWithClassHierarchy appInfo) { |
| Set<DexType> seen = Sets.newIdentityHashSet(); |
| liveProgramClasses.forEach(c -> seen.add(c.type)); |
| Deque<DexType> worklist = new ArrayDeque<>(lambdaInterfaces); |
| for (DexProgramClass liveProgramClass : liveProgramClasses) { |
| fn.accept(liveProgramClass); |
| DexType superType = liveProgramClass.superType; |
| if (superType != null && seen.add(superType)) { |
| worklist.add(superType); |
| } |
| for (DexType iface : liveProgramClass.interfaces.values) { |
| if (seen.add(iface)) { |
| worklist.add(iface); |
| } |
| } |
| } |
| while (!worklist.isEmpty()) { |
| DexType type = worklist.pop(); |
| DexClass clazz = appInfo.definitionFor(type); |
| if (clazz != null) { |
| fn.accept(clazz); |
| if (clazz.superType != null && seen.add(clazz.superType)) { |
| worklist.add(clazz.superType); |
| } |
| for (DexType iface : clazz.interfaces.values) { |
| if (seen.add(iface)) { |
| worklist.add(iface); |
| } |
| } |
| } |
| } |
| } |
| |
| @Override |
| public void forEachInstantiatedSubType( |
| DexType type, |
| Consumer<DexProgramClass> subTypeConsumer, |
| Consumer<LambdaDescriptor> callSiteConsumer) { |
| objectAllocationInfoCollection.forEachInstantiatedSubType( |
| type, subTypeConsumer, callSiteConsumer, this); |
| } |
| |
| public void forEachInstantiatedSubTypeInChain( |
| DexProgramClass refinedReceiverUpperBound, |
| DexProgramClass refinedReceiverLowerBound, |
| Consumer<DexProgramClass> subTypeConsumer, |
| Consumer<LambdaDescriptor> callSiteConsumer) { |
| List<DexProgramClass> subTypes = |
| computeProgramClassRelationChain(refinedReceiverLowerBound, refinedReceiverUpperBound); |
| for (DexProgramClass subType : subTypes) { |
| if (isInstantiatedOrPinned(subType)) { |
| subTypeConsumer.accept(subType); |
| } |
| } |
| } |
| |
| private boolean isInstantiatedOrPinned(DexProgramClass clazz) { |
| return isInstantiatedDirectly(clazz) || isPinned(clazz.type) || isInstantiatedInterface(clazz); |
| } |
| |
| public boolean isPinnedNotProgramOrLibraryOverride(DexDefinition definition) { |
| if (isPinned(definition.getReference())) { |
| return true; |
| } |
| if (definition.isDexEncodedMethod()) { |
| DexEncodedMethod method = definition.asDexEncodedMethod(); |
| return !method.isProgramMethod(this) || method.isLibraryMethodOverride().isPossiblyTrue(); |
| } |
| assert definition.isDexClass(); |
| DexClass clazz = definition.asDexClass(); |
| return clazz.isNotProgramClass() || isInstantiatedInterface(clazz.asProgramClass()); |
| } |
| |
| public SubtypingInfo computeSubtypingInfo() { |
| return new SubtypingInfo(this); |
| } |
| |
| public boolean mayHaveFinalizeMethodDirectlyOrIndirectly(ClassTypeElement type) { |
| // Special case for java.lang.Object. |
| if (type.getClassType() == dexItemFactory().objectType) { |
| if (type.getInterfaces().isEmpty()) { |
| // The type java.lang.Object could be any instantiated type. Assume a finalizer exists. |
| return true; |
| } |
| for (DexType iface : type.getInterfaces()) { |
| if (mayHaveFinalizer(iface)) { |
| return true; |
| } |
| } |
| return false; |
| } |
| return mayHaveFinalizer(type.getClassType()); |
| } |
| |
| private boolean mayHaveFinalizer(DexType type) { |
| // A type may have an active finalizer if any derived instance has a finalizer. |
| return objectAllocationInfoCollection |
| .traverseInstantiatedSubtypes( |
| type, |
| clazz -> { |
| if (objectAllocationInfoCollection.isInterfaceWithUnknownSubtypeHierarchy(clazz)) { |
| return TraversalContinuation.BREAK; |
| } else { |
| SingleResolutionResult resolution = |
| resolveMethodOn(clazz, dexItemFactory().objectMembers.finalize) |
| .asSingleResolution(); |
| if (resolution != null && resolution.getResolvedHolder().isProgramClass()) { |
| return TraversalContinuation.BREAK; |
| } |
| } |
| return TraversalContinuation.CONTINUE; |
| }, |
| lambda -> { |
| // Lambda classes do not have finalizers. |
| return TraversalContinuation.CONTINUE; |
| }, |
| this) |
| .shouldBreak(); |
| } |
| |
| /** Predicate on types that *must* never be merged horizontally. */ |
| public boolean isNoHorizontalClassMergingOfType(DexType type) { |
| return noClassMerging.contains(type) || noHorizontalClassMerging.contains(type); |
| } |
| |
| /** Predicate on types that *must* never be merged vertically. */ |
| public boolean isNoVerticalClassMergingOfType(DexType type) { |
| return noClassMerging.contains(type) || noVerticalClassMerging.contains(type); |
| } |
| |
| /** |
| * All types that *must* never be merged by the static class merger due to a configuration |
| * directive (testing only). |
| */ |
| public Set<DexType> getNoStaticClassMergingSet() { |
| return noStaticClassMerging; |
| } |
| } |