/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "android-base/strings.h" #include "art_method-inl.h" #include "base/unix_file/fd_file.h" #include "base/utils.h" #include "common_runtime_test.h" #include "dex/descriptors_names.h" #include "dex/type_reference.h" #include "exec_utils.h" #include "linear_alloc.h" #include "mirror/class-inl.h" #include "obj_ptr-inl.h" #include "profile/profile_compilation_info.h" #include "profile_assistant.h" #include "scoped_thread_state_change-inl.h" namespace art { using Hotness = ProfileCompilationInfo::MethodHotness; using TypeReferenceSet = std::set; static constexpr size_t kMaxMethodIds = 65535; class ProfileAssistantTest : public CommonRuntimeTest { public: void PostRuntimeCreate() override { allocator_.reset(new ArenaAllocator(Runtime::Current()->GetArenaPool())); } protected: void SetupProfile(const std::string& id, uint32_t checksum, uint16_t number_of_methods, uint16_t number_of_classes, const ScratchFile& profile, ProfileCompilationInfo* info, uint16_t start_method_index = 0, bool reverse_dex_write_order = false) { std::string dex_location1 = "location1" + id; uint32_t dex_location_checksum1 = checksum; std::string dex_location2 = "location2" + id; uint32_t dex_location_checksum2 = 10 * checksum; SetupProfile(dex_location1, dex_location_checksum1, dex_location2, dex_location_checksum2, number_of_methods, number_of_classes, profile, info, start_method_index, reverse_dex_write_order); } void SetupProfile(const std::string& dex_location1, uint32_t dex_location_checksum1, const std::string& dex_location2, uint32_t dex_location_checksum2, uint16_t number_of_methods, uint16_t number_of_classes, const ScratchFile& profile, ProfileCompilationInfo* info, uint16_t start_method_index = 0, bool reverse_dex_write_order = false, uint32_t number_of_methods1 = kMaxMethodIds, uint32_t number_of_methods2 = kMaxMethodIds) { for (uint16_t i = start_method_index; i < start_method_index + number_of_methods; i++) { // reverse_dex_write_order controls the order in which the dex files will be added to // the profile and thus written to disk. ProfileCompilationInfo::OfflineProfileMethodInfo pmi = GetOfflineProfileMethodInfo(dex_location1, dex_location_checksum1, dex_location2, dex_location_checksum2, number_of_methods1, number_of_methods2); Hotness::Flag flags = Hotness::kFlagPostStartup; if (reverse_dex_write_order) { ASSERT_TRUE(info->AddMethod( dex_location2, dex_location_checksum2, i, number_of_methods2, pmi, flags)); ASSERT_TRUE(info->AddMethod( dex_location1, dex_location_checksum1, i, number_of_methods1, pmi, flags)); } else { ASSERT_TRUE(info->AddMethod( dex_location1, dex_location_checksum1, i, number_of_methods1, pmi, flags)); ASSERT_TRUE(info->AddMethod( dex_location2, dex_location_checksum2, i, number_of_methods2, pmi, flags)); } } for (uint16_t i = 0; i < number_of_classes; i++) { ASSERT_TRUE(info->AddClassIndex(ProfileCompilationInfo::GetProfileDexFileKey(dex_location1), dex_location_checksum1, dex::TypeIndex(i), number_of_methods1)); } ASSERT_TRUE(info->Save(GetFd(profile))); ASSERT_EQ(0, profile.GetFile()->Flush()); ASSERT_TRUE(profile.GetFile()->ResetOffset()); } void SetupBasicProfile(const std::string& id, uint32_t checksum, uint16_t number_of_methods, const std::vector& hot_methods, const std::vector& startup_methods, const std::vector& post_startup_methods, const ScratchFile& profile, ProfileCompilationInfo* info) { std::string dex_location = "location1" + id; for (uint32_t idx : hot_methods) { info->AddMethodIndex(Hotness::kFlagHot, dex_location, checksum, idx, number_of_methods); } for (uint32_t idx : startup_methods) { info->AddMethodIndex(Hotness::kFlagStartup, dex_location, checksum, idx, number_of_methods); } for (uint32_t idx : post_startup_methods) { info->AddMethodIndex(Hotness::kFlagPostStartup, dex_location, checksum, idx, number_of_methods); } ASSERT_TRUE(info->Save(GetFd(profile))); ASSERT_EQ(0, profile.GetFile()->Flush()); ASSERT_TRUE(profile.GetFile()->ResetOffset()); } // Creates an inline cache which will be destructed at the end of the test. ProfileCompilationInfo::InlineCacheMap* CreateInlineCacheMap() { used_inline_caches.emplace_back(new ProfileCompilationInfo::InlineCacheMap( std::less(), allocator_->Adapter(kArenaAllocProfile))); return used_inline_caches.back().get(); } ProfileCompilationInfo::OfflineProfileMethodInfo GetOfflineProfileMethodInfo( const std::string& dex_location1, uint32_t dex_checksum1, const std::string& dex_location2, uint32_t dex_checksum2, uint32_t number_of_methods1 = kMaxMethodIds, uint32_t number_of_methods2 = kMaxMethodIds) { ProfileCompilationInfo::InlineCacheMap* ic_map = CreateInlineCacheMap(); ProfileCompilationInfo::OfflineProfileMethodInfo pmi(ic_map); pmi.dex_references.emplace_back(dex_location1, dex_checksum1, number_of_methods1); pmi.dex_references.emplace_back(dex_location2, dex_checksum2, number_of_methods2); // Monomorphic for (uint16_t dex_pc = 0; dex_pc < 11; dex_pc++) { ProfileCompilationInfo::DexPcData dex_pc_data(allocator_.get()); dex_pc_data.AddClass(0, dex::TypeIndex(0)); ic_map->Put(dex_pc, dex_pc_data); } // Polymorphic for (uint16_t dex_pc = 11; dex_pc < 22; dex_pc++) { ProfileCompilationInfo::DexPcData dex_pc_data(allocator_.get()); dex_pc_data.AddClass(0, dex::TypeIndex(0)); dex_pc_data.AddClass(1, dex::TypeIndex(1)); ic_map->Put(dex_pc, dex_pc_data); } // Megamorphic for (uint16_t dex_pc = 22; dex_pc < 33; dex_pc++) { ProfileCompilationInfo::DexPcData dex_pc_data(allocator_.get()); dex_pc_data.SetIsMegamorphic(); ic_map->Put(dex_pc, dex_pc_data); } // Missing types for (uint16_t dex_pc = 33; dex_pc < 44; dex_pc++) { ProfileCompilationInfo::DexPcData dex_pc_data(allocator_.get()); dex_pc_data.SetIsMissingTypes(); ic_map->Put(dex_pc, dex_pc_data); } return pmi; } int GetFd(const ScratchFile& file) const { return static_cast(file.GetFd()); } void CheckProfileInfo(ScratchFile& file, const ProfileCompilationInfo& info) { ProfileCompilationInfo file_info; ASSERT_TRUE(file.GetFile()->ResetOffset()); ASSERT_TRUE(file_info.Load(GetFd(file))); ASSERT_TRUE(file_info.Equals(info)); } std::string GetProfmanCmd() { std::string file_path = GetTestAndroidRoot(); file_path += "/bin/profman"; if (kIsDebugBuild) { file_path += "d"; } EXPECT_TRUE(OS::FileExists(file_path.c_str())) << file_path << " should be a valid file path"; return file_path; } // Runs test with given arguments. int ProcessProfiles(const std::vector& profiles_fd, int reference_profile_fd) { std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); for (size_t k = 0; k < profiles_fd.size(); k++) { argv_str.push_back("--profile-file-fd=" + std::to_string(profiles_fd[k])); } argv_str.push_back("--reference-profile-file-fd=" + std::to_string(reference_profile_fd)); std::string error; return ExecAndReturnCode(argv_str, &error); } bool GenerateTestProfile(const std::string& filename) { std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--generate-test-profile=" + filename); std::string error; return ExecAndReturnCode(argv_str, &error); } bool GenerateTestProfileWithInputDex(const std::string& filename) { std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--generate-test-profile=" + filename); argv_str.push_back("--generate-test-profile-seed=0"); argv_str.push_back("--apk=" + GetLibCoreDexFileNames()[0]); argv_str.push_back("--dex-location=" + GetLibCoreDexFileNames()[0]); std::string error; return ExecAndReturnCode(argv_str, &error); } bool CreateProfile(const std::string& profile_file_contents, const std::string& filename, const std::string& dex_location) { ScratchFile class_names_file; File* file = class_names_file.GetFile(); EXPECT_TRUE(file->WriteFully(profile_file_contents.c_str(), profile_file_contents.length())); EXPECT_EQ(0, file->Flush()); EXPECT_TRUE(file->ResetOffset()); std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--create-profile-from=" + class_names_file.GetFilename()); argv_str.push_back("--reference-profile-file=" + filename); argv_str.push_back("--apk=" + dex_location); argv_str.push_back("--dex-location=" + dex_location); std::string error; EXPECT_EQ(ExecAndReturnCode(argv_str, &error), 0); return true; } bool RunProfman(const std::string& filename, std::vector& extra_args, std::string* output) { ScratchFile output_file; std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.insert(argv_str.end(), extra_args.begin(), extra_args.end()); argv_str.push_back("--profile-file=" + filename); argv_str.push_back("--apk=" + GetLibCoreDexFileNames()[0]); argv_str.push_back("--dex-location=" + GetLibCoreDexFileNames()[0]); argv_str.push_back("--dump-output-to-fd=" + std::to_string(GetFd(output_file))); std::string error; EXPECT_EQ(ExecAndReturnCode(argv_str, &error), 0); File* file = output_file.GetFile(); EXPECT_EQ(0, file->Flush()); EXPECT_TRUE(file->ResetOffset()); int64_t length = file->GetLength(); std::unique_ptr buf(new char[length]); EXPECT_EQ(file->Read(buf.get(), length, 0), length); *output = std::string(buf.get(), length); return true; } bool DumpClassesAndMethods(const std::string& filename, std::string* file_contents) { std::vector extra_args; extra_args.push_back("--dump-classes-and-methods"); return RunProfman(filename, extra_args, file_contents); } bool DumpOnly(const std::string& filename, std::string* file_contents) { std::vector extra_args; extra_args.push_back("--dump-only"); return RunProfman(filename, extra_args, file_contents); } bool CreateAndDump(const std::string& input_file_contents, std::string* output_file_contents) { ScratchFile profile_file; EXPECT_TRUE(CreateProfile(input_file_contents, profile_file.GetFilename(), GetLibCoreDexFileNames()[0])); profile_file.GetFile()->ResetOffset(); EXPECT_TRUE(DumpClassesAndMethods(profile_file.GetFilename(), output_file_contents)); return true; } ObjPtr GetClass(ScopedObjectAccess& soa, jobject class_loader, const std::string& clazz) REQUIRES_SHARED(Locks::mutator_lock_) { ClassLinker* class_linker = Runtime::Current()->GetClassLinker(); StackHandleScope<1> hs(soa.Self()); Handle h_loader(hs.NewHandle( ObjPtr::DownCast(soa.Self()->DecodeJObject(class_loader)))); return class_linker->FindClass(soa.Self(), clazz.c_str(), h_loader); } ArtMethod* GetVirtualMethod(jobject class_loader, const std::string& clazz, const std::string& name) { ScopedObjectAccess soa(Thread::Current()); ObjPtr klass = GetClass(soa, class_loader, clazz); ClassLinker* class_linker = Runtime::Current()->GetClassLinker(); const auto pointer_size = class_linker->GetImagePointerSize(); ArtMethod* method = nullptr; for (auto& m : klass->GetVirtualMethods(pointer_size)) { if (name == m.GetName()) { EXPECT_TRUE(method == nullptr); method = &m; } } return method; } static TypeReference MakeTypeReference(ObjPtr klass) REQUIRES_SHARED(Locks::mutator_lock_) { return TypeReference(&klass->GetDexFile(), klass->GetDexTypeIndex()); } // Verify that given method has the expected inline caches and nothing else. void AssertInlineCaches(ArtMethod* method, const TypeReferenceSet& expected_clases, const ProfileCompilationInfo& info, bool is_megamorphic, bool is_missing_types) REQUIRES_SHARED(Locks::mutator_lock_) { std::unique_ptr pmi = info.GetMethod(method->GetDexFile()->GetLocation(), method->GetDexFile()->GetLocationChecksum(), method->GetDexMethodIndex()); ASSERT_TRUE(pmi != nullptr); ASSERT_EQ(pmi->inline_caches->size(), 1u); const ProfileCompilationInfo::DexPcData& dex_pc_data = pmi->inline_caches->begin()->second; ASSERT_EQ(dex_pc_data.is_megamorphic, is_megamorphic); ASSERT_EQ(dex_pc_data.is_missing_types, is_missing_types); ASSERT_EQ(expected_clases.size(), dex_pc_data.classes.size()); size_t found = 0; for (const TypeReference& type_ref : expected_clases) { for (const auto& class_ref : dex_pc_data.classes) { ProfileCompilationInfo::DexReference dex_ref = pmi->dex_references[class_ref.dex_profile_index]; if (dex_ref.MatchesDex(type_ref.dex_file) && class_ref.type_index == type_ref.TypeIndex()) { found++; } } } ASSERT_EQ(expected_clases.size(), found); } int CheckCompilationMethodPercentChange(uint16_t methods_in_cur_profile, uint16_t methods_in_ref_profile) { ScratchFile profile; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile)}); int reference_profile_fd = GetFd(reference_profile); std::vector hot_methods_cur; std::vector hot_methods_ref; std::vector empty_vector; for (size_t i = 0; i < methods_in_cur_profile; ++i) { hot_methods_cur.push_back(i); } for (size_t i = 0; i < methods_in_ref_profile; ++i) { hot_methods_ref.push_back(i); } ProfileCompilationInfo info1; uint16_t methods_in_profile = std::max(methods_in_cur_profile, methods_in_ref_profile); SetupBasicProfile("p1", 1, methods_in_profile, hot_methods_cur, empty_vector, empty_vector, profile, &info1); ProfileCompilationInfo info2; SetupBasicProfile("p1", 1, methods_in_profile, hot_methods_ref, empty_vector, empty_vector, reference_profile, &info2); return ProcessProfiles(profile_fds, reference_profile_fd); } int CheckCompilationClassPercentChange(uint16_t classes_in_cur_profile, uint16_t classes_in_ref_profile) { ScratchFile profile; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile)}); int reference_profile_fd = GetFd(reference_profile); ProfileCompilationInfo info1; SetupProfile("p1", 1, 0, classes_in_cur_profile, profile, &info1); ProfileCompilationInfo info2; SetupProfile("p1", 1, 0, classes_in_ref_profile, reference_profile, &info2); return ProcessProfiles(profile_fds, reference_profile_fd); } std::unique_ptr allocator_; // Cache of inline caches generated during tests. // This makes it easier to pass data between different utilities and ensure that // caches are destructed at the end of the test. std::vector> used_inline_caches; }; TEST_F(ProfileAssistantTest, AdviseCompilationEmptyReferences) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1), GetFd(profile2)}); int reference_profile_fd = GetFd(reference_profile); const uint16_t kNumberOfMethodsToEnableCompilation = 100; ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1); ProfileCompilationInfo info2; SetupProfile("p2", 2, kNumberOfMethodsToEnableCompilation, 0, profile2, &info2); // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, ProcessProfiles(profile_fds, reference_profile_fd)); // The resulting compilation info must be equal to the merge of the inputs. ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile_fd)); ProfileCompilationInfo expected; ASSERT_TRUE(expected.MergeWith(info1)); ASSERT_TRUE(expected.MergeWith(info2)); ASSERT_TRUE(expected.Equals(result)); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); CheckProfileInfo(profile2, info2); } // TODO(calin): Add more tests for classes. TEST_F(ProfileAssistantTest, AdviseCompilationEmptyReferencesBecauseOfClasses) { ScratchFile profile1; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1)}); int reference_profile_fd = GetFd(reference_profile); const uint16_t kNumberOfClassesToEnableCompilation = 100; ProfileCompilationInfo info1; SetupProfile("p1", 1, 0, kNumberOfClassesToEnableCompilation, profile1, &info1); // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, ProcessProfiles(profile_fds, reference_profile_fd)); // The resulting compilation info must be equal to the merge of the inputs. ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile_fd)); ProfileCompilationInfo expected; ASSERT_TRUE(expected.MergeWith(info1)); ASSERT_TRUE(expected.Equals(result)); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); } TEST_F(ProfileAssistantTest, AdviseCompilationNonEmptyReferences) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1), GetFd(profile2)}); int reference_profile_fd = GetFd(reference_profile); // The new profile info will contain the methods with indices 0-100. const uint16_t kNumberOfMethodsToEnableCompilation = 100; ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1); ProfileCompilationInfo info2; SetupProfile("p2", 2, kNumberOfMethodsToEnableCompilation, 0, profile2, &info2); // The reference profile info will contain the methods with indices 50-150. const uint16_t kNumberOfMethodsAlreadyCompiled = 100; ProfileCompilationInfo reference_info; SetupProfile("p1", 1, kNumberOfMethodsAlreadyCompiled, 0, reference_profile, &reference_info, kNumberOfMethodsToEnableCompilation / 2); // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, ProcessProfiles(profile_fds, reference_profile_fd)); // The resulting compilation info must be equal to the merge of the inputs ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile_fd)); ProfileCompilationInfo expected; ASSERT_TRUE(expected.MergeWith(info1)); ASSERT_TRUE(expected.MergeWith(info2)); ASSERT_TRUE(expected.MergeWith(reference_info)); ASSERT_TRUE(expected.Equals(result)); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); CheckProfileInfo(profile2, info2); } TEST_F(ProfileAssistantTest, DoNotAdviseCompilation) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1), GetFd(profile2)}); int reference_profile_fd = GetFd(reference_profile); const uint16_t kNumberOfMethodsToSkipCompilation = 24; // Threshold is 100. ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToSkipCompilation, 0, profile1, &info1); ProfileCompilationInfo info2; SetupProfile("p2", 2, kNumberOfMethodsToSkipCompilation, 0, profile2, &info2); // We should not advise compilation. ASSERT_EQ(ProfileAssistant::kSkipCompilation, ProcessProfiles(profile_fds, reference_profile_fd)); // The information from profiles must remain the same. ProfileCompilationInfo file_info1; ASSERT_TRUE(profile1.GetFile()->ResetOffset()); ASSERT_TRUE(file_info1.Load(GetFd(profile1))); ASSERT_TRUE(file_info1.Equals(info1)); ProfileCompilationInfo file_info2; ASSERT_TRUE(profile2.GetFile()->ResetOffset()); ASSERT_TRUE(file_info2.Load(GetFd(profile2))); ASSERT_TRUE(file_info2.Equals(info2)); // Reference profile files must remain empty. ASSERT_EQ(0, reference_profile.GetFile()->GetLength()); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); CheckProfileInfo(profile2, info2); } TEST_F(ProfileAssistantTest, DoNotAdviseCompilationMethodPercentage) { const uint16_t kNumberOfMethodsInRefProfile = 6000; const uint16_t kNumberOfMethodsInCurProfile = 6100; // Threshold is 2%. // We should not advise compilation. ASSERT_EQ(ProfileAssistant::kSkipCompilation, CheckCompilationMethodPercentChange(kNumberOfMethodsInCurProfile, kNumberOfMethodsInRefProfile)); } TEST_F(ProfileAssistantTest, ShouldAdviseCompilationMethodPercentage) { const uint16_t kNumberOfMethodsInRefProfile = 6000; const uint16_t kNumberOfMethodsInCurProfile = 6200; // Threshold is 2%. // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, CheckCompilationMethodPercentChange(kNumberOfMethodsInCurProfile, kNumberOfMethodsInRefProfile)); } TEST_F(ProfileAssistantTest, DoNotdviseCompilationClassPercentage) { const uint16_t kNumberOfClassesInRefProfile = 6000; const uint16_t kNumberOfClassesInCurProfile = 6110; // Threshold is 2%. // We should not advise compilation. ASSERT_EQ(ProfileAssistant::kSkipCompilation, CheckCompilationClassPercentChange(kNumberOfClassesInCurProfile, kNumberOfClassesInRefProfile)); } TEST_F(ProfileAssistantTest, ShouldAdviseCompilationClassPercentage) { const uint16_t kNumberOfClassesInRefProfile = 6000; const uint16_t kNumberOfClassesInCurProfile = 6120; // Threshold is 2%. // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, CheckCompilationClassPercentChange(kNumberOfClassesInCurProfile, kNumberOfClassesInRefProfile)); } TEST_F(ProfileAssistantTest, FailProcessingBecauseOfProfiles) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1), GetFd(profile2)}); int reference_profile_fd = GetFd(reference_profile); const uint16_t kNumberOfMethodsToEnableCompilation = 100; // Assign different hashes for the same dex file. This will make merging of information to fail. ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1); ProfileCompilationInfo info2; SetupProfile("p1", 2, kNumberOfMethodsToEnableCompilation, 0, profile2, &info2); // We should fail processing. ASSERT_EQ(ProfileAssistant::kErrorBadProfiles, ProcessProfiles(profile_fds, reference_profile_fd)); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); CheckProfileInfo(profile2, info2); // Reference profile files must still remain empty. ASSERT_EQ(0, reference_profile.GetFile()->GetLength()); } TEST_F(ProfileAssistantTest, FailProcessingBecauseOfReferenceProfiles) { ScratchFile profile1; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1)}); int reference_profile_fd = GetFd(reference_profile); const uint16_t kNumberOfMethodsToEnableCompilation = 100; // Assign different hashes for the same dex file. This will make merging of information to fail. ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1); ProfileCompilationInfo reference_info; SetupProfile("p1", 2, kNumberOfMethodsToEnableCompilation, 0, reference_profile, &reference_info); // We should not advise compilation. ASSERT_TRUE(profile1.GetFile()->ResetOffset()); ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_EQ(ProfileAssistant::kErrorBadProfiles, ProcessProfiles(profile_fds, reference_profile_fd)); // The information from profiles must remain the same. CheckProfileInfo(profile1, info1); } TEST_F(ProfileAssistantTest, TestProfileGeneration) { ScratchFile profile; // Generate a test profile. GenerateTestProfile(profile.GetFilename()); // Verify that the generated profile is valid and can be loaded. ASSERT_TRUE(profile.GetFile()->ResetOffset()); ProfileCompilationInfo info; ASSERT_TRUE(info.Load(GetFd(profile))); } TEST_F(ProfileAssistantTest, TestProfileGenerationWithIndexDex) { ScratchFile profile; // Generate a test profile passing in a dex file as reference. GenerateTestProfileWithInputDex(profile.GetFilename()); // Verify that the generated profile is valid and can be loaded. ASSERT_TRUE(profile.GetFile()->ResetOffset()); ProfileCompilationInfo info; ASSERT_TRUE(info.Load(GetFd(profile))); } TEST_F(ProfileAssistantTest, TestProfileCreationAllMatch) { // Class names put here need to be in sorted order. std::vector class_names = { "HLjava/lang/Object;->()V", "Ljava/lang/Comparable;", "Ljava/lang/Math;", "Ljava/lang/Object;", "SPLjava/lang/Comparable;->compareTo(Ljava/lang/Object;)I", }; std::string file_contents; for (std::string& class_name : class_names) { file_contents += class_name + std::string("\n"); } std::string output_file_contents; ASSERT_TRUE(CreateAndDump(file_contents, &output_file_contents)); ASSERT_EQ(output_file_contents, file_contents); } TEST_F(ProfileAssistantTest, TestProfileCreationGenerateMethods) { // Class names put here need to be in sorted order. std::vector class_names = { "Ljava/lang/Math;->*", }; std::string input_file_contents; std::string expected_contents; for (std::string& class_name : class_names) { input_file_contents += class_name + std::string("\n"); expected_contents += DescriptorToDot(class_name.c_str()) + std::string("\n"); } std::string output_file_contents; ScratchFile profile_file; EXPECT_TRUE(CreateProfile(input_file_contents, profile_file.GetFilename(), GetLibCoreDexFileNames()[0])); ProfileCompilationInfo info; profile_file.GetFile()->ResetOffset(); ASSERT_TRUE(info.Load(GetFd(profile_file))); // Verify that the profile has matching methods. ScopedObjectAccess soa(Thread::Current()); ObjPtr klass = GetClass(soa, /* class_loader= */ nullptr, "Ljava/lang/Math;"); ASSERT_TRUE(klass != nullptr); size_t method_count = 0; for (ArtMethod& method : klass->GetMethods(kRuntimePointerSize)) { if (!method.IsCopied() && method.GetCodeItem() != nullptr) { ++method_count; std::unique_ptr pmi = info.GetMethod(method.GetDexFile()->GetLocation(), method.GetDexFile()->GetLocationChecksum(), method.GetDexMethodIndex()); ASSERT_TRUE(pmi != nullptr) << method.PrettyMethod(); } } EXPECT_GT(method_count, 0u); } TEST_F(ProfileAssistantTest, TestBootImageProfile) { const std::string core_dex = GetLibCoreDexFileNames()[0]; std::vector profiles; // In image with enough clean occurrences. const std::string kCleanClass = "Ljava/lang/CharSequence;"; // In image with enough dirty occurrences. const std::string kDirtyClass = "Ljava/lang/Object;"; // Not in image becauseof not enough occurrences. const std::string kUncommonCleanClass = "Ljava/lang/Process;"; const std::string kUncommonDirtyClass = "Ljava/lang/Package;"; // Method that is hot. // Also adds the class through inference since it is in each dex. const std::string kHotMethod = "Ljava/lang/Comparable;->compareTo(Ljava/lang/Object;)I"; // Method that doesn't add the class since its only in one profile. Should still show up in the // boot profile. const std::string kOtherMethod = "Ljava/util/HashMap;->()V"; // Method that gets marked as hot since it's in multiple profiles. const std::string kMultiMethod = "Ljava/util/ArrayList;->clear()V"; // Thresholds for this test. static const size_t kDirtyThreshold = 3; static const size_t kCleanThreshold = 2; static const size_t kMethodThreshold = 2; // Create a bunch of boot profiles. std::string dex1 = kCleanClass + "\n" + kDirtyClass + "\n" + kUncommonCleanClass + "\n" + "H" + kHotMethod + "\n" + kUncommonDirtyClass; profiles.emplace_back(ScratchFile()); EXPECT_TRUE(CreateProfile( dex1, profiles.back().GetFilename(), core_dex)); // Create a bunch of boot profiles. std::string dex2 = kCleanClass + "\n" + kDirtyClass + "\n" + "P" + kHotMethod + "\n" + "P" + kMultiMethod + "\n" + kUncommonDirtyClass; profiles.emplace_back(ScratchFile()); EXPECT_TRUE(CreateProfile( dex2, profiles.back().GetFilename(), core_dex)); // Create a bunch of boot profiles. std::string dex3 = "S" + kHotMethod + "\n" + "P" + kOtherMethod + "\n" + "P" + kMultiMethod + "\n" + kDirtyClass + "\n"; profiles.emplace_back(ScratchFile()); EXPECT_TRUE(CreateProfile( dex3, profiles.back().GetFilename(), core_dex)); // Generate the boot profile. ScratchFile out_profile; std::vector args; args.push_back(GetProfmanCmd()); args.push_back("--generate-boot-image-profile"); args.push_back("--boot-image-class-threshold=" + std::to_string(kDirtyThreshold)); args.push_back("--boot-image-clean-class-threshold=" + std::to_string(kCleanThreshold)); args.push_back("--boot-image-sampled-method-threshold=" + std::to_string(kMethodThreshold)); args.push_back("--reference-profile-file=" + out_profile.GetFilename()); args.push_back("--apk=" + core_dex); args.push_back("--dex-location=" + core_dex); for (const ScratchFile& profile : profiles) { args.push_back("--profile-file=" + profile.GetFilename()); } std::string error; EXPECT_EQ(ExecAndReturnCode(args, &error), 0) << error; ASSERT_EQ(0, out_profile.GetFile()->Flush()); ASSERT_TRUE(out_profile.GetFile()->ResetOffset()); // Verify the boot profile contents. std::string output_file_contents; EXPECT_TRUE(DumpClassesAndMethods(out_profile.GetFilename(), &output_file_contents)); // Common classes, should be in the classes of the profile. EXPECT_NE(output_file_contents.find(kCleanClass + "\n"), std::string::npos) << output_file_contents; EXPECT_NE(output_file_contents.find(kDirtyClass + "\n"), std::string::npos) << output_file_contents; // Uncommon classes, should not fit preloaded class criteria and should not be in the profile. EXPECT_EQ(output_file_contents.find(kUncommonCleanClass + "\n"), std::string::npos) << output_file_contents; EXPECT_EQ(output_file_contents.find(kUncommonDirtyClass + "\n"), std::string::npos) << output_file_contents; // Inferred class from a method common to all three profiles. EXPECT_NE(output_file_contents.find("Ljava/lang/Comparable;\n"), std::string::npos) << output_file_contents; // Aggregated methods hotness information. EXPECT_NE(output_file_contents.find("HSP" + kHotMethod), std::string::npos) << output_file_contents; EXPECT_NE(output_file_contents.find("P" + kOtherMethod), std::string::npos) << output_file_contents; // Not inferred class, method is only in one profile. EXPECT_EQ(output_file_contents.find("Ljava/util/HashMap;\n"), std::string::npos) << output_file_contents; // Test the sampled methods that became hot. // Other method is in only one profile, it should not become hot. EXPECT_EQ(output_file_contents.find("HP" + kOtherMethod), std::string::npos) << output_file_contents; // Multi method is in at least two profiles, it should become hot. EXPECT_NE(output_file_contents.find("HP" + kMultiMethod), std::string::npos) << output_file_contents; } TEST_F(ProfileAssistantTest, TestProfileCreationOneNotMatched) { // Class names put here need to be in sorted order. std::vector class_names = { "Ldoesnt/match/this/one;", "Ljava/lang/Comparable;", "Ljava/lang/Object;" }; std::string input_file_contents; for (std::string& class_name : class_names) { input_file_contents += class_name + std::string("\n"); } std::string output_file_contents; ASSERT_TRUE(CreateAndDump(input_file_contents, &output_file_contents)); std::string expected_contents = class_names[1] + std::string("\n") + class_names[2] + std::string("\n"); ASSERT_EQ(output_file_contents, expected_contents); } TEST_F(ProfileAssistantTest, TestProfileCreationNoneMatched) { // Class names put here need to be in sorted order. std::vector class_names = { "Ldoesnt/match/this/one;", "Ldoesnt/match/this/one/either;", "Lnor/this/one;" }; std::string input_file_contents; for (std::string& class_name : class_names) { input_file_contents += class_name + std::string("\n"); } std::string output_file_contents; ASSERT_TRUE(CreateAndDump(input_file_contents, &output_file_contents)); std::string expected_contents(""); ASSERT_EQ(output_file_contents, expected_contents); } TEST_F(ProfileAssistantTest, TestProfileCreateInlineCache) { // Create the profile content. std::vector methods = { "LTestInline;->inlineMonomorphic(LSuper;)I+LSubA;", "LTestInline;->inlinePolymorphic(LSuper;)I+LSubA;,LSubB;,LSubC;", "LTestInline;->inlineMegamorphic(LSuper;)I+LSubA;,LSubB;,LSubC;,LSubD;,LSubE;", "LTestInline;->inlineMissingTypes(LSuper;)I+missing_types", "LTestInline;->noInlineCache(LSuper;)I" }; std::string input_file_contents; for (std::string& m : methods) { input_file_contents += m + std::string("\n"); } // Create the profile and save it to disk. ScratchFile profile_file; ASSERT_TRUE(CreateProfile(input_file_contents, profile_file.GetFilename(), GetTestDexFileName("ProfileTestMultiDex"))); // Load the profile from disk. ProfileCompilationInfo info; profile_file.GetFile()->ResetOffset(); ASSERT_TRUE(info.Load(GetFd(profile_file))); // Load the dex files and verify that the profile contains the expected methods info. ScopedObjectAccess soa(Thread::Current()); jobject class_loader = LoadDex("ProfileTestMultiDex"); ASSERT_NE(class_loader, nullptr); StackHandleScope<3> hs(soa.Self()); Handle sub_a = hs.NewHandle(GetClass(soa, class_loader, "LSubA;")); Handle sub_b = hs.NewHandle(GetClass(soa, class_loader, "LSubB;")); Handle sub_c = hs.NewHandle(GetClass(soa, class_loader, "LSubC;")); ASSERT_TRUE(sub_a != nullptr); ASSERT_TRUE(sub_b != nullptr); ASSERT_TRUE(sub_c != nullptr); { // Verify that method inlineMonomorphic has the expected inline caches and nothing else. ArtMethod* inline_monomorphic = GetVirtualMethod(class_loader, "LTestInline;", "inlineMonomorphic"); ASSERT_TRUE(inline_monomorphic != nullptr); TypeReferenceSet expected_monomorphic; expected_monomorphic.insert(MakeTypeReference(sub_a.Get())); AssertInlineCaches(inline_monomorphic, expected_monomorphic, info, /*is_megamorphic=*/false, /*is_missing_types=*/false); } { // Verify that method inlinePolymorphic has the expected inline caches and nothing else. ArtMethod* inline_polymorhic = GetVirtualMethod(class_loader, "LTestInline;", "inlinePolymorphic"); ASSERT_TRUE(inline_polymorhic != nullptr); TypeReferenceSet expected_polymorphic; expected_polymorphic.insert(MakeTypeReference(sub_a.Get())); expected_polymorphic.insert(MakeTypeReference(sub_b.Get())); expected_polymorphic.insert(MakeTypeReference(sub_c.Get())); AssertInlineCaches(inline_polymorhic, expected_polymorphic, info, /*is_megamorphic=*/false, /*is_missing_types=*/false); } { // Verify that method inlineMegamorphic has the expected inline caches and nothing else. ArtMethod* inline_megamorphic = GetVirtualMethod(class_loader, "LTestInline;", "inlineMegamorphic"); ASSERT_TRUE(inline_megamorphic != nullptr); TypeReferenceSet expected_megamorphic; AssertInlineCaches(inline_megamorphic, expected_megamorphic, info, /*is_megamorphic=*/true, /*is_missing_types=*/false); } { // Verify that method inlineMegamorphic has the expected inline caches and nothing else. ArtMethod* inline_missing_types = GetVirtualMethod(class_loader, "LTestInline;", "inlineMissingTypes"); ASSERT_TRUE(inline_missing_types != nullptr); TypeReferenceSet expected_missing_Types; AssertInlineCaches(inline_missing_types, expected_missing_Types, info, /*is_megamorphic=*/false, /*is_missing_types=*/true); } { // Verify that method noInlineCache has no inline caches in the profile. ArtMethod* no_inline_cache = GetVirtualMethod(class_loader, "LTestInline;", "noInlineCache"); ASSERT_TRUE(no_inline_cache != nullptr); std::unique_ptr pmi_no_inline_cache = info.GetMethod(no_inline_cache->GetDexFile()->GetLocation(), no_inline_cache->GetDexFile()->GetLocationChecksum(), no_inline_cache->GetDexMethodIndex()); ASSERT_TRUE(pmi_no_inline_cache != nullptr); ASSERT_TRUE(pmi_no_inline_cache->inline_caches->empty()); } } TEST_F(ProfileAssistantTest, MergeProfilesWithDifferentDexOrder) { ScratchFile profile1; ScratchFile reference_profile; std::vector profile_fds({GetFd(profile1)}); int reference_profile_fd = GetFd(reference_profile); // The new profile info will contain the methods with indices 0-100. const uint16_t kNumberOfMethodsToEnableCompilation = 100; ProfileCompilationInfo info1; SetupProfile("p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1, /*start_method_index=*/0, /*reverse_dex_write_order=*/false); // The reference profile info will contain the methods with indices 50-150. // When setting up the profile reverse the order in which the dex files // are added to the profile. This will verify that profman merges profiles // with a different dex order correctly. const uint16_t kNumberOfMethodsAlreadyCompiled = 100; ProfileCompilationInfo reference_info; SetupProfile("p1", 1, kNumberOfMethodsAlreadyCompiled, 0, reference_profile, &reference_info, kNumberOfMethodsToEnableCompilation / 2, /*reverse_dex_write_order=*/true); // We should advise compilation. ASSERT_EQ(ProfileAssistant::kCompile, ProcessProfiles(profile_fds, reference_profile_fd)); // The resulting compilation info must be equal to the merge of the inputs. ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile_fd)); ProfileCompilationInfo expected; ASSERT_TRUE(expected.MergeWith(reference_info)); ASSERT_TRUE(expected.MergeWith(info1)); ASSERT_TRUE(expected.Equals(result)); // The information from profile must remain the same. CheckProfileInfo(profile1, info1); } TEST_F(ProfileAssistantTest, TestProfileCreateWithInvalidData) { // Create the profile content. std::vector profile_methods = { "LTestInline;->inlineMonomorphic(LSuper;)I+invalid_class", "LTestInline;->invalid_method", "invalid_class" }; std::string input_file_contents; for (std::string& m : profile_methods) { input_file_contents += m + std::string("\n"); } // Create the profile and save it to disk. ScratchFile profile_file; std::string dex_filename = GetTestDexFileName("ProfileTestMultiDex"); ASSERT_TRUE(CreateProfile(input_file_contents, profile_file.GetFilename(), dex_filename)); // Load the profile from disk. ProfileCompilationInfo info; profile_file.GetFile()->ResetOffset(); ASSERT_TRUE(info.Load(GetFd(profile_file))); // Load the dex files and verify that the profile contains the expected methods info. ScopedObjectAccess soa(Thread::Current()); jobject class_loader = LoadDex("ProfileTestMultiDex"); ASSERT_NE(class_loader, nullptr); ArtMethod* inline_monomorphic = GetVirtualMethod(class_loader, "LTestInline;", "inlineMonomorphic"); const DexFile* dex_file = inline_monomorphic->GetDexFile(); // Verify that the inline cache contains the invalid type. std::unique_ptr pmi = info.GetMethod(dex_file->GetLocation(), dex_file->GetLocationChecksum(), inline_monomorphic->GetDexMethodIndex()); ASSERT_TRUE(pmi != nullptr); ASSERT_EQ(pmi->inline_caches->size(), 1u); const ProfileCompilationInfo::DexPcData& dex_pc_data = pmi->inline_caches->begin()->second; dex::TypeIndex invalid_class_index(std::numeric_limits::max() - 1); ASSERT_EQ(1u, dex_pc_data.classes.size()); ASSERT_EQ(invalid_class_index, dex_pc_data.classes.begin()->type_index); // Verify that the start-up classes contain the invalid class. std::set classes; std::set hot_methods; std::set startup_methods; std::set post_start_methods; ASSERT_TRUE(info.GetClassesAndMethods(*dex_file, &classes, &hot_methods, &startup_methods, &post_start_methods)); ASSERT_EQ(1u, classes.size()); ASSERT_TRUE(classes.find(invalid_class_index) != classes.end()); // Verify that the invalid method did not get in the profile. ASSERT_EQ(1u, hot_methods.size()); uint16_t invalid_method_index = std::numeric_limits::max() - 1; ASSERT_FALSE(hot_methods.find(invalid_method_index) != hot_methods.end()); } TEST_F(ProfileAssistantTest, DumpOnly) { ScratchFile profile; const uint32_t kNumberOfMethods = 64; std::vector hot_methods; std::vector startup_methods; std::vector post_startup_methods; for (size_t i = 0; i < kNumberOfMethods; ++i) { if (i % 2 == 0) { hot_methods.push_back(i); } if (i % 3 == 1) { startup_methods.push_back(i); } if (i % 4 == 2) { post_startup_methods.push_back(i); } } EXPECT_GT(hot_methods.size(), 0u); EXPECT_GT(startup_methods.size(), 0u); EXPECT_GT(post_startup_methods.size(), 0u); ProfileCompilationInfo info1; SetupBasicProfile("p1", 1, kNumberOfMethods, hot_methods, startup_methods, post_startup_methods, profile, &info1); std::string output; DumpOnly(profile.GetFilename(), &output); const size_t hot_offset = output.find("hot methods:"); const size_t startup_offset = output.find("startup methods:"); const size_t post_startup_offset = output.find("post startup methods:"); const size_t classes_offset = output.find("classes:"); ASSERT_NE(hot_offset, std::string::npos); ASSERT_NE(startup_offset, std::string::npos); ASSERT_NE(post_startup_offset, std::string::npos); ASSERT_LT(hot_offset, startup_offset); ASSERT_LT(startup_offset, post_startup_offset); // Check the actual contents of the dump by looking at the offsets of the methods. for (uint32_t m : hot_methods) { const size_t pos = output.find(std::to_string(m) + "[],", hot_offset); ASSERT_NE(pos, std::string::npos) << output; EXPECT_LT(pos, startup_offset) << output; } for (uint32_t m : startup_methods) { const size_t pos = output.find(std::to_string(m) + ",", startup_offset); ASSERT_NE(pos, std::string::npos) << output; EXPECT_LT(pos, post_startup_offset) << output; } for (uint32_t m : post_startup_methods) { const size_t pos = output.find(std::to_string(m) + ",", post_startup_offset); ASSERT_NE(pos, std::string::npos) << output; EXPECT_LT(pos, classes_offset) << output; } } TEST_F(ProfileAssistantTest, MergeProfilesWithFilter) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; std::vector profile_fds({ GetFd(profile1), GetFd(profile2)}); int reference_profile_fd = GetFd(reference_profile); // Use a real dex file to generate profile test data. // The file will be used during merging to filter unwanted data. std::vector> dex_files = OpenTestDexFiles("ProfileTestMultiDex"); const DexFile& d1 = *dex_files[0]; const DexFile& d2 = *dex_files[1]; // The new profile info will contain the methods with indices 0-100. const uint16_t kNumberOfMethodsToEnableCompilation = 100; ProfileCompilationInfo info1; SetupProfile(d1.GetLocation(), d1.GetLocationChecksum(), "p1", 1, kNumberOfMethodsToEnableCompilation, 0, profile1, &info1); ProfileCompilationInfo info2; SetupProfile(d2.GetLocation(), d2.GetLocationChecksum(), "p2", 2, kNumberOfMethodsToEnableCompilation, 0, profile2, &info2); // The reference profile info will contain the methods with indices 50-150. const uint16_t kNumberOfMethodsAlreadyCompiled = 100; ProfileCompilationInfo reference_info; SetupProfile(d1.GetLocation(), d1.GetLocationChecksum(), "p1", 1, kNumberOfMethodsAlreadyCompiled, 0, reference_profile, &reference_info, kNumberOfMethodsToEnableCompilation / 2); // Run profman and pass the dex file with --apk-fd. android::base::unique_fd apk_fd( open(GetTestDexFileName("ProfileTestMultiDex").c_str(), O_RDONLY)); // NOLINT ASSERT_GE(apk_fd.get(), 0); std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--profile-file-fd=" + std::to_string(profile1.GetFd())); argv_str.push_back("--profile-file-fd=" + std::to_string(profile2.GetFd())); argv_str.push_back("--reference-profile-file-fd=" + std::to_string(reference_profile.GetFd())); argv_str.push_back("--apk-fd=" + std::to_string(apk_fd.get())); std::string error; EXPECT_EQ(ExecAndReturnCode(argv_str, &error), 0) << error; // Verify that we can load the result. ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile_fd)); ASSERT_TRUE(profile1.GetFile()->ResetOffset()); ASSERT_TRUE(profile2.GetFile()->ResetOffset()); ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); // Verify that the result filtered out data not belonging to the dex file. // This is equivalent to checking that the result is equal to the merging of // all profiles while filtering out data not belonging to the dex file. ProfileCompilationInfo::ProfileLoadFilterFn filter_fn = [&d1, &d2](const std::string& dex_location, uint32_t checksum) -> bool { return (dex_location == ProfileCompilationInfo::GetProfileDexFileKey(d1.GetLocation()) && checksum == d1.GetLocationChecksum()) || (dex_location == ProfileCompilationInfo::GetProfileDexFileKey(d2.GetLocation()) && checksum == d2.GetLocationChecksum()); }; ProfileCompilationInfo info1_filter; ProfileCompilationInfo info2_filter; ProfileCompilationInfo expected; info2_filter.Load(profile1.GetFd(), /*merge_classes=*/ true, filter_fn); info2_filter.Load(profile2.GetFd(), /*merge_classes=*/ true, filter_fn); expected.Load(reference_profile.GetFd(), /*merge_classes=*/ true, filter_fn); ASSERT_TRUE(expected.MergeWith(info1_filter)); ASSERT_TRUE(expected.MergeWith(info2_filter)); ASSERT_TRUE(expected.Equals(result)); } TEST_F(ProfileAssistantTest, CopyAndUpdateProfileKey) { ScratchFile profile1; ScratchFile reference_profile; // Use a real dex file to generate profile test data. During the copy-and-update the // matching is done based on checksum so we have to match with the real thing. std::vector> dex_files = OpenTestDexFiles("ProfileTestMultiDex"); const DexFile& d1 = *dex_files[0]; const DexFile& d2 = *dex_files[1]; ProfileCompilationInfo info1; uint16_t num_methods_to_add = std::min(d1.NumMethodIds(), d2.NumMethodIds()); SetupProfile("fake-location1", d1.GetLocationChecksum(), "fake-location2", d2.GetLocationChecksum(), num_methods_to_add, /*number_of_classes=*/ 0, profile1, &info1, /*start_method_index=*/ 0, /*reverse_dex_write_order=*/ false, /*number_of_methods1=*/ d1.NumMethodIds(), /*number_of_methods2=*/ d2.NumMethodIds()); // Run profman and pass the dex file with --apk-fd. android::base::unique_fd apk_fd( open(GetTestDexFileName("ProfileTestMultiDex").c_str(), O_RDONLY)); // NOLINT ASSERT_GE(apk_fd.get(), 0); std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--profile-file-fd=" + std::to_string(profile1.GetFd())); argv_str.push_back("--reference-profile-file-fd=" + std::to_string(reference_profile.GetFd())); argv_str.push_back("--apk-fd=" + std::to_string(apk_fd.get())); argv_str.push_back("--copy-and-update-profile-key"); std::string error; ASSERT_EQ(ExecAndReturnCode(argv_str, &error), 0) << error; // Verify that we can load the result. ProfileCompilationInfo result; ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile.GetFd())); // Verify that the renaming was done. for (uint16_t i = 0; i < num_methods_to_add; i ++) { std::unique_ptr pmi; ASSERT_TRUE(result.GetMethod(d1.GetLocation(), d1.GetLocationChecksum(), i) != nullptr) << i; ASSERT_TRUE(result.GetMethod(d2.GetLocation(), d2.GetLocationChecksum(), i) != nullptr) << i; ASSERT_TRUE(result.GetMethod("fake-location1", d1.GetLocationChecksum(), i) == nullptr); ASSERT_TRUE(result.GetMethod("fake-location2", d2.GetLocationChecksum(), i) == nullptr); } } TEST_F(ProfileAssistantTest, MergeProfilesWithCounters) { ScratchFile profile1; ScratchFile profile2; ScratchFile reference_profile; // The new profile info will contain methods with indices 0-100. const uint16_t kNumberOfMethodsToEnableCompilation = 100; const uint16_t kNumberOfClasses = 50; std::vector> dex_files = OpenTestDexFiles("ProfileTestMultiDex"); const DexFile& d1 = *dex_files[0]; const DexFile& d2 = *dex_files[1]; ProfileCompilationInfo info1; SetupProfile( d1.GetLocation(), d1.GetLocationChecksum(), d2.GetLocation(), d2.GetLocationChecksum(), kNumberOfMethodsToEnableCompilation, kNumberOfClasses, profile1, &info1); ProfileCompilationInfo info2; SetupProfile( d1.GetLocation(), d1.GetLocationChecksum(), d2.GetLocation(), d2.GetLocationChecksum(), kNumberOfMethodsToEnableCompilation, kNumberOfClasses, profile2, &info2); std::string profman_cmd = GetProfmanCmd(); std::vector argv_str; argv_str.push_back(profman_cmd); argv_str.push_back("--profile-file-fd=" + std::to_string(profile1.GetFd())); argv_str.push_back("--profile-file-fd=" + std::to_string(profile2.GetFd())); argv_str.push_back("--reference-profile-file-fd=" + std::to_string(reference_profile.GetFd())); argv_str.push_back("--store-aggregation-counters"); std::string error; EXPECT_EQ(ExecAndReturnCode(argv_str, &error), 0) << error; // Verify that we can load the result and that the counters are in place. ProfileCompilationInfo result; result.PrepareForAggregationCounters(); ASSERT_TRUE(reference_profile.GetFile()->ResetOffset()); ASSERT_TRUE(result.Load(reference_profile.GetFd())); ASSERT_TRUE(result.StoresAggregationCounters()); ASSERT_EQ(2, result.GetAggregationCounter()); for (uint16_t i = 0; i < kNumberOfMethodsToEnableCompilation; i++) { ASSERT_EQ(1, result.GetMethodAggregationCounter(MethodReference(&d1, i))); ASSERT_EQ(1, result.GetMethodAggregationCounter(MethodReference(&d2, i))); } for (uint16_t i = 0; i < kNumberOfClasses; i++) { ASSERT_EQ(1, result.GetClassAggregationCounter(TypeReference(&d1, dex::TypeIndex(i)))); } } } // namespace art