/* * 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. */ // Test is in compiler, as it uses compiler related code. #include "verifier/verifier_deps.h" #include "class_linker.h" #include "compiler/common_compiler_test.h" #include "compiler/driver/compiler_options.h" #include "compiler/driver/compiler_driver.h" #include "compiler_callbacks.h" #include "dex_file.h" #include "dex_file_types.h" #include "handle_scope-inl.h" #include "verifier/method_verifier-inl.h" #include "mirror/class_loader.h" #include "runtime.h" #include "thread.h" #include "scoped_thread_state_change-inl.h" namespace art { namespace verifier { class VerifierDepsCompilerCallbacks : public CompilerCallbacks { public: explicit VerifierDepsCompilerCallbacks() : CompilerCallbacks(CompilerCallbacks::CallbackMode::kCompileApp), deps_(nullptr) {} void MethodVerified(verifier::MethodVerifier* verifier ATTRIBUTE_UNUSED) OVERRIDE {} void ClassRejected(ClassReference ref ATTRIBUTE_UNUSED) OVERRIDE {} bool IsRelocationPossible() OVERRIDE { return false; } verifier::VerifierDeps* GetVerifierDeps() const OVERRIDE { return deps_; } void SetVerifierDeps(verifier::VerifierDeps* deps) { deps_ = deps; } private: verifier::VerifierDeps* deps_; }; class VerifierDepsTest : public CommonCompilerTest { public: void SetUpRuntimeOptions(RuntimeOptions* options) { CommonCompilerTest::SetUpRuntimeOptions(options); callbacks_.reset(new VerifierDepsCompilerCallbacks()); } mirror::Class* FindClassByName(const std::string& name, ScopedObjectAccess* soa) REQUIRES_SHARED(Locks::mutator_lock_) { StackHandleScope<1> hs(Thread::Current()); Handle class_loader_handle( hs.NewHandle(soa->Decode(class_loader_))); mirror::Class* klass = class_linker_->FindClass(Thread::Current(), name.c_str(), class_loader_handle); if (klass == nullptr) { DCHECK(Thread::Current()->IsExceptionPending()); Thread::Current()->ClearException(); } return klass; } void SetupCompilerDriver() { compiler_options_->boot_image_ = false; compiler_driver_->InitializeThreadPools(); } void VerifyWithCompilerDriver(verifier::VerifierDeps* deps) { TimingLogger timings("Verify", false, false); // The compiler driver handles the verifier deps in the callbacks, so // remove what this class did for unit testing. verifier_deps_.reset(nullptr); callbacks_->SetVerifierDeps(nullptr); compiler_driver_->Verify(class_loader_, dex_files_, deps, &timings); // The compiler driver may have updated the VerifierDeps in the callback object. verifier_deps_.reset(callbacks_->GetVerifierDeps()); } void SetVerifierDeps(const std::vector& dex_files) { verifier_deps_.reset(new verifier::VerifierDeps(dex_files)); VerifierDepsCompilerCallbacks* callbacks = reinterpret_cast(callbacks_.get()); callbacks->SetVerifierDeps(verifier_deps_.get()); } void LoadDexFile(ScopedObjectAccess* soa, const char* name1, const char* name2 = nullptr) REQUIRES_SHARED(Locks::mutator_lock_) { class_loader_ = (name2 == nullptr) ? LoadDex(name1) : LoadMultiDex(name1, name2); dex_files_ = GetDexFiles(class_loader_); primary_dex_file_ = dex_files_.front(); SetVerifierDeps(dex_files_); StackHandleScope<1> hs(soa->Self()); Handle loader = hs.NewHandle(soa->Decode(class_loader_)); for (const DexFile* dex_file : dex_files_) { class_linker_->RegisterDexFile(*dex_file, loader.Get()); } } void LoadDexFile(ScopedObjectAccess* soa) REQUIRES_SHARED(Locks::mutator_lock_) { LoadDexFile(soa, "VerifierDeps"); CHECK_EQ(dex_files_.size(), 1u); klass_Main_ = FindClassByName("LMain;", soa); CHECK(klass_Main_ != nullptr); } bool VerifyMethod(const std::string& method_name) { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa); StackHandleScope<2> hs(soa.Self()); Handle class_loader_handle( hs.NewHandle(soa.Decode(class_loader_))); Handle dex_cache_handle(hs.NewHandle(klass_Main_->GetDexCache())); const DexFile::ClassDef* class_def = klass_Main_->GetClassDef(); const uint8_t* class_data = primary_dex_file_->GetClassData(*class_def); CHECK(class_data != nullptr); ClassDataItemIterator it(*primary_dex_file_, class_data); while (it.HasNextStaticField() || it.HasNextInstanceField()) { it.Next(); } ArtMethod* method = nullptr; while (it.HasNextDirectMethod()) { ArtMethod* resolved_method = class_linker_->ResolveMethod( *primary_dex_file_, it.GetMemberIndex(), dex_cache_handle, class_loader_handle, nullptr, it.GetMethodInvokeType(*class_def)); CHECK(resolved_method != nullptr); if (method_name == resolved_method->GetName()) { method = resolved_method; break; } it.Next(); } CHECK(method != nullptr); MethodVerifier verifier(Thread::Current(), primary_dex_file_, dex_cache_handle, class_loader_handle, *class_def, it.GetMethodCodeItem(), it.GetMemberIndex(), method, it.GetMethodAccessFlags(), true /* can_load_classes */, true /* allow_soft_failures */, true /* need_precise_constants */, false /* verify to dump */, true /* allow_thread_suspension */); verifier.Verify(); return !verifier.HasFailures(); } void VerifyDexFile(const char* multidex = nullptr) { { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa, "VerifierDeps", multidex); } SetupCompilerDriver(); VerifyWithCompilerDriver(/* verifier_deps */ nullptr); } bool TestAssignabilityRecording(const std::string& dst, const std::string& src, bool is_strict, bool is_assignable) { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa); mirror::Class* klass_dst = FindClassByName(dst, &soa); DCHECK(klass_dst != nullptr); mirror::Class* klass_src = FindClassByName(src, &soa); DCHECK(klass_src != nullptr); verifier_deps_->AddAssignability(*primary_dex_file_, klass_dst, klass_src, is_strict, is_assignable); return true; } // Check that the status of classes in `class_loader_` match the // expected status in `deps`. void VerifyClassStatus(const verifier::VerifierDeps& deps) { ScopedObjectAccess soa(Thread::Current()); StackHandleScope<2> hs(soa.Self()); Handle class_loader_handle( hs.NewHandle(soa.Decode(class_loader_))); MutableHandle cls(hs.NewHandle(nullptr)); for (const DexFile* dex_file : dex_files_) { const std::vector& unverified_classes = deps.GetUnverifiedClasses(*dex_file); std::set set(unverified_classes.begin(), unverified_classes.end()); for (uint32_t i = 0; i < dex_file->NumClassDefs(); ++i) { const DexFile::ClassDef& class_def = dex_file->GetClassDef(i); const char* descriptor = dex_file->GetClassDescriptor(class_def); cls.Assign(class_linker_->FindClass(soa.Self(), descriptor, class_loader_handle)); if (cls.Get() == nullptr) { CHECK(soa.Self()->IsExceptionPending()); soa.Self()->ClearException(); } else if (set.find(class_def.class_idx_) == set.end()) { ASSERT_EQ(cls->GetStatus(), mirror::Class::kStatusVerified); } else { ASSERT_LT(cls->GetStatus(), mirror::Class::kStatusVerified); } } } } bool HasUnverifiedClass(const std::string& cls) { const DexFile::TypeId* type_id = primary_dex_file_->FindTypeId(cls.c_str()); DCHECK(type_id != nullptr); dex::TypeIndex index = primary_dex_file_->GetIndexForTypeId(*type_id); MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); for (const auto& dex_dep : verifier_deps_->dex_deps_) { for (dex::TypeIndex entry : dex_dep.second->unverified_classes_) { if (index == entry) { return true; } } } return false; } // Iterates over all assignability records and tries to find an entry which // matches the expected destination/source pair. bool HasAssignable(const std::string& expected_destination, const std::string& expected_source, bool expected_is_assignable) { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); for (auto& dex_dep : verifier_deps_->dex_deps_) { const DexFile& dex_file = *dex_dep.first; auto& storage = expected_is_assignable ? dex_dep.second->assignable_types_ : dex_dep.second->unassignable_types_; for (auto& entry : storage) { std::string actual_destination = verifier_deps_->GetStringFromId(dex_file, entry.GetDestination()); std::string actual_source = verifier_deps_->GetStringFromId(dex_file, entry.GetSource()); if ((expected_destination == actual_destination) && (expected_source == actual_source)) { return true; } } } return false; } // Iterates over all class resolution records, finds an entry which matches // the given class descriptor and tests its properties. bool HasClass(const std::string& expected_klass, bool expected_resolved, const std::string& expected_access_flags = "") { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); for (auto& dex_dep : verifier_deps_->dex_deps_) { for (auto& entry : dex_dep.second->classes_) { if (expected_resolved != entry.IsResolved()) { continue; } std::string actual_klass = dex_dep.first->StringByTypeIdx(entry.GetDexTypeIndex()); if (expected_klass != actual_klass) { continue; } if (expected_resolved) { // Test access flags. Note that PrettyJavaAccessFlags always appends // a space after the modifiers. Add it to the expected access flags. std::string actual_access_flags = PrettyJavaAccessFlags(entry.GetAccessFlags()); if (expected_access_flags + " " != actual_access_flags) { continue; } } return true; } } return false; } // Iterates over all field resolution records, finds an entry which matches // the given field class+name+type and tests its properties. bool HasField(const std::string& expected_klass, const std::string& expected_name, const std::string& expected_type, bool expected_resolved, const std::string& expected_access_flags = "", const std::string& expected_decl_klass = "") { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); for (auto& dex_dep : verifier_deps_->dex_deps_) { for (auto& entry : dex_dep.second->fields_) { if (expected_resolved != entry.IsResolved()) { continue; } const DexFile::FieldId& field_id = dex_dep.first->GetFieldId(entry.GetDexFieldIndex()); std::string actual_klass = dex_dep.first->StringByTypeIdx(field_id.class_idx_); if (expected_klass != actual_klass) { continue; } std::string actual_name = dex_dep.first->StringDataByIdx(field_id.name_idx_); if (expected_name != actual_name) { continue; } std::string actual_type = dex_dep.first->StringByTypeIdx(field_id.type_idx_); if (expected_type != actual_type) { continue; } if (expected_resolved) { // Test access flags. Note that PrettyJavaAccessFlags always appends // a space after the modifiers. Add it to the expected access flags. std::string actual_access_flags = PrettyJavaAccessFlags(entry.GetAccessFlags()); if (expected_access_flags + " " != actual_access_flags) { continue; } std::string actual_decl_klass = verifier_deps_->GetStringFromId( *dex_dep.first, entry.GetDeclaringClassIndex()); if (expected_decl_klass != actual_decl_klass) { continue; } } return true; } } return false; } // Iterates over all method resolution records, finds an entry which matches // the given field kind+class+name+signature and tests its properties. bool HasMethod(const std::string& expected_kind, const std::string& expected_klass, const std::string& expected_name, const std::string& expected_signature, bool expected_resolved, const std::string& expected_access_flags = "", const std::string& expected_decl_klass = "") { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); for (auto& dex_dep : verifier_deps_->dex_deps_) { auto& storage = (expected_kind == "direct") ? dex_dep.second->direct_methods_ : (expected_kind == "virtual") ? dex_dep.second->virtual_methods_ : dex_dep.second->interface_methods_; for (auto& entry : storage) { if (expected_resolved != entry.IsResolved()) { continue; } const DexFile::MethodId& method_id = dex_dep.first->GetMethodId(entry.GetDexMethodIndex()); std::string actual_klass = dex_dep.first->StringByTypeIdx(method_id.class_idx_); if (expected_klass != actual_klass) { continue; } std::string actual_name = dex_dep.first->StringDataByIdx(method_id.name_idx_); if (expected_name != actual_name) { continue; } std::string actual_signature = dex_dep.first->GetMethodSignature(method_id).ToString(); if (expected_signature != actual_signature) { continue; } if (expected_resolved) { // Test access flags. Note that PrettyJavaAccessFlags always appends // a space after the modifiers. Add it to the expected access flags. std::string actual_access_flags = PrettyJavaAccessFlags(entry.GetAccessFlags()); if (expected_access_flags + " " != actual_access_flags) { continue; } std::string actual_decl_klass = verifier_deps_->GetStringFromId( *dex_dep.first, entry.GetDeclaringClassIndex()); if (expected_decl_klass != actual_decl_klass) { continue; } } return true; } } return false; } size_t NumberOfCompiledDexFiles() { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); return verifier_deps_->dex_deps_.size(); } size_t HasEachKindOfRecord() { MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); bool has_strings = false; bool has_assignability = false; bool has_classes = false; bool has_fields = false; bool has_methods = false; bool has_unverified_classes = false; for (auto& entry : verifier_deps_->dex_deps_) { has_strings |= !entry.second->strings_.empty(); has_assignability |= !entry.second->assignable_types_.empty(); has_assignability |= !entry.second->unassignable_types_.empty(); has_classes |= !entry.second->classes_.empty(); has_fields |= !entry.second->fields_.empty(); has_methods |= !entry.second->direct_methods_.empty(); has_methods |= !entry.second->virtual_methods_.empty(); has_methods |= !entry.second->interface_methods_.empty(); has_unverified_classes |= !entry.second->unverified_classes_.empty(); } return has_strings && has_assignability && has_classes && has_fields && has_methods && has_unverified_classes; } static std::set* GetMethods( VerifierDeps::DexFileDeps* deps, MethodResolutionKind resolution_kind) { if (resolution_kind == kDirectMethodResolution) { return &deps->direct_methods_; } else if (resolution_kind == kVirtualMethodResolution) { return &deps->virtual_methods_; } else { DCHECK_EQ(resolution_kind, kInterfaceMethodResolution); return &deps->interface_methods_; } } std::unique_ptr verifier_deps_; std::vector dex_files_; const DexFile* primary_dex_file_; jobject class_loader_; mirror::Class* klass_Main_; }; TEST_F(VerifierDepsTest, StringToId) { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa); MutexLock mu(Thread::Current(), *Locks::verifier_deps_lock_); uint32_t id_Main1 = verifier_deps_->GetIdFromString(*primary_dex_file_, "LMain;"); ASSERT_LT(id_Main1, primary_dex_file_->NumStringIds()); ASSERT_EQ("LMain;", verifier_deps_->GetStringFromId(*primary_dex_file_, id_Main1)); uint32_t id_Main2 = verifier_deps_->GetIdFromString(*primary_dex_file_, "LMain;"); ASSERT_LT(id_Main2, primary_dex_file_->NumStringIds()); ASSERT_EQ("LMain;", verifier_deps_->GetStringFromId(*primary_dex_file_, id_Main2)); uint32_t id_Lorem1 = verifier_deps_->GetIdFromString(*primary_dex_file_, "Lorem ipsum"); ASSERT_GE(id_Lorem1, primary_dex_file_->NumStringIds()); ASSERT_EQ("Lorem ipsum", verifier_deps_->GetStringFromId(*primary_dex_file_, id_Lorem1)); uint32_t id_Lorem2 = verifier_deps_->GetIdFromString(*primary_dex_file_, "Lorem ipsum"); ASSERT_GE(id_Lorem2, primary_dex_file_->NumStringIds()); ASSERT_EQ("Lorem ipsum", verifier_deps_->GetStringFromId(*primary_dex_file_, id_Lorem2)); ASSERT_EQ(id_Main1, id_Main2); ASSERT_EQ(id_Lorem1, id_Lorem2); ASSERT_NE(id_Main1, id_Lorem1); } TEST_F(VerifierDepsTest, Assignable_BothInBoot) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/util/TimeZone;", /* src */ "Ljava/util/SimpleTimeZone;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/util/TimeZone;", "Ljava/util/SimpleTimeZone;", true)); } TEST_F(VerifierDepsTest, Assignable_DestinationInBoot1) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/net/Socket;", /* src */ "LMySSLSocket;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/net/Socket;", "LMySSLSocket;", true)); } TEST_F(VerifierDepsTest, Assignable_DestinationInBoot2) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/util/TimeZone;", /* src */ "LMySimpleTimeZone;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/util/TimeZone;", "LMySimpleTimeZone;", true)); } TEST_F(VerifierDepsTest, Assignable_DestinationInBoot3) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/util/Collection;", /* src */ "LMyThreadSet;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/util/Collection;", "LMyThreadSet;", true)); } TEST_F(VerifierDepsTest, Assignable_BothArrays_Resolved) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "[[Ljava/util/TimeZone;", /* src */ "[[Ljava/util/SimpleTimeZone;", /* is_strict */ true, /* is_assignable */ true)); // If the component types of both arrays are resolved, we optimize the list of // dependencies by recording a dependency on the component types. ASSERT_FALSE(HasAssignable("[[Ljava/util/TimeZone;", "[[Ljava/util/SimpleTimeZone;", true)); ASSERT_FALSE(HasAssignable("[Ljava/util/TimeZone;", "[Ljava/util/SimpleTimeZone;", true)); ASSERT_TRUE(HasAssignable("Ljava/util/TimeZone;", "Ljava/util/SimpleTimeZone;", true)); } TEST_F(VerifierDepsTest, Assignable_BothArrays_Erroneous) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "[[Ljava/util/TimeZone;", /* src */ "[[LMyErroneousTimeZone;", /* is_strict */ true, /* is_assignable */ true)); // If the component type of an array is erroneous, we record the dependency on // the array type. ASSERT_FALSE(HasAssignable("[[Ljava/util/TimeZone;", "[[LMyErroneousTimeZone;", true)); ASSERT_TRUE(HasAssignable("[Ljava/util/TimeZone;", "[LMyErroneousTimeZone;", true)); ASSERT_FALSE(HasAssignable("Ljava/util/TimeZone;", "LMyErroneousTimeZone;", true)); } // We test that VerifierDeps does not try to optimize by storing assignability // of the component types. This is due to the fact that the component type may // be an erroneous class, even though the array type has resolved status. TEST_F(VerifierDepsTest, Assignable_ArrayToInterface1) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/io/Serializable;", /* src */ "[Ljava/util/TimeZone;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/io/Serializable;", "[Ljava/util/TimeZone;", true)); } TEST_F(VerifierDepsTest, Assignable_ArrayToInterface2) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/io/Serializable;", /* src */ "[LMyThreadSet;", /* is_strict */ true, /* is_assignable */ true)); ASSERT_TRUE(HasAssignable("Ljava/io/Serializable;", "[LMyThreadSet;", true)); } TEST_F(VerifierDepsTest, NotAssignable_BothInBoot) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/lang/Exception;", /* src */ "Ljava/util/SimpleTimeZone;", /* is_strict */ true, /* is_assignable */ false)); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "Ljava/util/SimpleTimeZone;", false)); } TEST_F(VerifierDepsTest, NotAssignable_DestinationInBoot1) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/lang/Exception;", /* src */ "LMySSLSocket;", /* is_strict */ true, /* is_assignable */ false)); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "LMySSLSocket;", false)); } TEST_F(VerifierDepsTest, NotAssignable_DestinationInBoot2) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "Ljava/lang/Exception;", /* src */ "LMySimpleTimeZone;", /* is_strict */ true, /* is_assignable */ false)); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "LMySimpleTimeZone;", false)); } TEST_F(VerifierDepsTest, NotAssignable_BothArrays) { ASSERT_TRUE(TestAssignabilityRecording(/* dst */ "[Ljava/lang/Exception;", /* src */ "[Ljava/util/SimpleTimeZone;", /* is_strict */ true, /* is_assignable */ false)); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "Ljava/util/SimpleTimeZone;", false)); } TEST_F(VerifierDepsTest, ArgumentType_ResolvedClass) { ASSERT_TRUE(VerifyMethod("ArgumentType_ResolvedClass")); ASSERT_TRUE(HasClass("Ljava/lang/Thread;", true, "public")); } TEST_F(VerifierDepsTest, ArgumentType_ResolvedReferenceArray) { ASSERT_TRUE(VerifyMethod("ArgumentType_ResolvedReferenceArray")); ASSERT_TRUE(HasClass("[Ljava/lang/Thread;", true, "public final abstract")); } TEST_F(VerifierDepsTest, ArgumentType_ResolvedPrimitiveArray) { ASSERT_TRUE(VerifyMethod("ArgumentType_ResolvedPrimitiveArray")); ASSERT_TRUE(HasClass("[B", true, "public final abstract")); } TEST_F(VerifierDepsTest, ArgumentType_UnresolvedClass) { ASSERT_TRUE(VerifyMethod("ArgumentType_UnresolvedClass")); ASSERT_TRUE(HasClass("LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, ArgumentType_UnresolvedSuper) { ASSERT_TRUE(VerifyMethod("ArgumentType_UnresolvedSuper")); ASSERT_TRUE(HasClass("LMySetWithUnresolvedSuper;", false)); } TEST_F(VerifierDepsTest, ReturnType_Reference) { ASSERT_TRUE(VerifyMethod("ReturnType_Reference")); ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/lang/IllegalStateException;", true)); } TEST_F(VerifierDepsTest, ReturnType_Array) { ASSERT_FALSE(VerifyMethod("ReturnType_Array")); ASSERT_TRUE(HasAssignable("Ljava/lang/Integer;", "Ljava/lang/IllegalStateException;", false)); } TEST_F(VerifierDepsTest, InvokeArgumentType) { ASSERT_TRUE(VerifyMethod("InvokeArgumentType")); ASSERT_TRUE(HasClass("Ljava/text/SimpleDateFormat;", true, "public")); ASSERT_TRUE(HasClass("Ljava/util/SimpleTimeZone;", true, "public")); ASSERT_TRUE(HasMethod("virtual", "Ljava/text/SimpleDateFormat;", "setTimeZone", "(Ljava/util/TimeZone;)V", true, "public", "Ljava/text/DateFormat;")); ASSERT_TRUE(HasAssignable("Ljava/util/TimeZone;", "Ljava/util/SimpleTimeZone;", true)); } TEST_F(VerifierDepsTest, MergeTypes_RegisterLines) { ASSERT_TRUE(VerifyMethod("MergeTypes_RegisterLines")); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "LMySocketTimeoutException;", true)); ASSERT_TRUE(HasAssignable( "Ljava/lang/Exception;", "Ljava/util/concurrent/TimeoutException;", true)); } TEST_F(VerifierDepsTest, MergeTypes_IfInstanceOf) { ASSERT_TRUE(VerifyMethod("MergeTypes_IfInstanceOf")); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "Ljava/net/SocketTimeoutException;", true)); ASSERT_TRUE(HasAssignable( "Ljava/lang/Exception;", "Ljava/util/concurrent/TimeoutException;", true)); ASSERT_TRUE(HasAssignable("Ljava/net/SocketTimeoutException;", "Ljava/lang/Exception;", false)); } TEST_F(VerifierDepsTest, MergeTypes_Unresolved) { ASSERT_TRUE(VerifyMethod("MergeTypes_Unresolved")); ASSERT_TRUE(HasAssignable("Ljava/lang/Exception;", "Ljava/net/SocketTimeoutException;", true)); ASSERT_TRUE(HasAssignable( "Ljava/lang/Exception;", "Ljava/util/concurrent/TimeoutException;", true)); } TEST_F(VerifierDepsTest, ConstClass_Resolved) { ASSERT_TRUE(VerifyMethod("ConstClass_Resolved")); ASSERT_TRUE(HasClass("Ljava/lang/IllegalStateException;", true, "public")); } TEST_F(VerifierDepsTest, ConstClass_Unresolved) { ASSERT_TRUE(VerifyMethod("ConstClass_Unresolved")); ASSERT_TRUE(HasClass("LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, CheckCast_Resolved) { ASSERT_TRUE(VerifyMethod("CheckCast_Resolved")); ASSERT_TRUE(HasClass("Ljava/lang/IllegalStateException;", true, "public")); } TEST_F(VerifierDepsTest, CheckCast_Unresolved) { ASSERT_TRUE(VerifyMethod("CheckCast_Unresolved")); ASSERT_TRUE(HasClass("LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, InstanceOf_Resolved) { ASSERT_TRUE(VerifyMethod("InstanceOf_Resolved")); ASSERT_TRUE(HasClass("Ljava/lang/IllegalStateException;", true, "public")); } TEST_F(VerifierDepsTest, InstanceOf_Unresolved) { ASSERT_TRUE(VerifyMethod("InstanceOf_Unresolved")); ASSERT_TRUE(HasClass("LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, NewInstance_Resolved) { ASSERT_TRUE(VerifyMethod("NewInstance_Resolved")); ASSERT_TRUE(HasClass("Ljava/lang/IllegalStateException;", true, "public")); } TEST_F(VerifierDepsTest, NewInstance_Unresolved) { ASSERT_TRUE(VerifyMethod("NewInstance_Unresolved")); ASSERT_TRUE(HasClass("LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, NewArray_Resolved) { ASSERT_TRUE(VerifyMethod("NewArray_Resolved")); ASSERT_TRUE(HasClass("[Ljava/lang/IllegalStateException;", true, "public final abstract")); } TEST_F(VerifierDepsTest, NewArray_Unresolved) { ASSERT_TRUE(VerifyMethod("NewArray_Unresolved")); ASSERT_TRUE(HasClass("[LUnresolvedClass;", false)); } TEST_F(VerifierDepsTest, Throw) { ASSERT_TRUE(VerifyMethod("Throw")); ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/lang/IllegalStateException;", true)); } TEST_F(VerifierDepsTest, MoveException_Resolved) { ASSERT_TRUE(VerifyMethod("MoveException_Resolved")); ASSERT_TRUE(HasClass("Ljava/io/InterruptedIOException;", true, "public")); ASSERT_TRUE(HasClass("Ljava/net/SocketTimeoutException;", true, "public")); ASSERT_TRUE(HasClass("Ljava/util/zip/ZipException;", true, "public")); // Testing that all exception types are assignable to Throwable. ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/io/InterruptedIOException;", true)); ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/net/SocketTimeoutException;", true)); ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/util/zip/ZipException;", true)); // Testing that the merge type is assignable to Throwable. ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "Ljava/io/IOException;", true)); // Merging of exception types. ASSERT_TRUE(HasAssignable("Ljava/io/IOException;", "Ljava/io/InterruptedIOException;", true)); ASSERT_TRUE(HasAssignable("Ljava/io/IOException;", "Ljava/util/zip/ZipException;", true)); ASSERT_TRUE(HasAssignable( "Ljava/io/InterruptedIOException;", "Ljava/net/SocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, MoveException_Unresolved) { ASSERT_FALSE(VerifyMethod("MoveException_Unresolved")); ASSERT_TRUE(HasClass("LUnresolvedException;", false)); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/lang/System;", true, "public final")); ASSERT_TRUE(HasField("Ljava/lang/System;", "out", "Ljava/io/PrintStream;", true, "public final static", "Ljava/lang/System;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInSuperclass1) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInSuperclass1")); ASSERT_TRUE(HasClass("Ljava/util/SimpleTimeZone;", true, "public")); ASSERT_TRUE(HasField( "Ljava/util/SimpleTimeZone;", "LONG", "I", true, "public final static", "Ljava/util/TimeZone;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInSuperclass2) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInSuperclass2")); ASSERT_TRUE(HasField( "LMySimpleTimeZone;", "SHORT", "I", true, "public final static", "Ljava/util/TimeZone;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInInterface1) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInInterface1")); ASSERT_TRUE(HasClass("Ljavax/xml/transform/dom/DOMResult;", true, "public")); ASSERT_TRUE(HasField("Ljavax/xml/transform/dom/DOMResult;", "PI_ENABLE_OUTPUT_ESCAPING", "Ljava/lang/String;", true, "public final static", "Ljavax/xml/transform/Result;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInInterface2) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInInterface2")); ASSERT_TRUE(HasField("LMyDOMResult;", "PI_ENABLE_OUTPUT_ESCAPING", "Ljava/lang/String;", true, "public final static", "Ljavax/xml/transform/Result;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInInterface3) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInInterface3")); ASSERT_TRUE(HasField("LMyResult;", "PI_ENABLE_OUTPUT_ESCAPING", "Ljava/lang/String;", true, "public final static", "Ljavax/xml/transform/Result;")); } TEST_F(VerifierDepsTest, StaticField_Resolved_DeclaredInInterface4) { ASSERT_TRUE(VerifyMethod("StaticField_Resolved_DeclaredInInterface4")); ASSERT_TRUE(HasField("LMyDocument;", "ELEMENT_NODE", "S", true, "public final static", "Lorg/w3c/dom/Node;")); } TEST_F(VerifierDepsTest, StaticField_Unresolved_ReferrerInBoot) { ASSERT_TRUE(VerifyMethod("StaticField_Unresolved_ReferrerInBoot")); ASSERT_TRUE(HasClass("Ljava/util/TimeZone;", true, "public abstract")); ASSERT_TRUE(HasField("Ljava/util/TimeZone;", "x", "I", false)); } TEST_F(VerifierDepsTest, StaticField_Unresolved_ReferrerInDex) { ASSERT_TRUE(VerifyMethod("StaticField_Unresolved_ReferrerInDex")); ASSERT_TRUE(HasField("LMyThreadSet;", "x", "I", false)); } TEST_F(VerifierDepsTest, InstanceField_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("InstanceField_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/io/InterruptedIOException;", true, "public")); ASSERT_TRUE(HasField("Ljava/io/InterruptedIOException;", "bytesTransferred", "I", true, "public", "Ljava/io/InterruptedIOException;")); ASSERT_TRUE(HasAssignable( "Ljava/io/InterruptedIOException;", "LMySocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, InstanceField_Resolved_DeclaredInSuperclass1) { ASSERT_TRUE(VerifyMethod("InstanceField_Resolved_DeclaredInSuperclass1")); ASSERT_TRUE(HasClass("Ljava/net/SocketTimeoutException;", true, "public")); ASSERT_TRUE(HasField("Ljava/net/SocketTimeoutException;", "bytesTransferred", "I", true, "public", "Ljava/io/InterruptedIOException;")); ASSERT_TRUE(HasAssignable( "Ljava/io/InterruptedIOException;", "LMySocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, InstanceField_Resolved_DeclaredInSuperclass2) { ASSERT_TRUE(VerifyMethod("InstanceField_Resolved_DeclaredInSuperclass2")); ASSERT_TRUE(HasField("LMySocketTimeoutException;", "bytesTransferred", "I", true, "public", "Ljava/io/InterruptedIOException;")); ASSERT_TRUE(HasAssignable( "Ljava/io/InterruptedIOException;", "LMySocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, InstanceField_Unresolved_ReferrerInBoot) { ASSERT_TRUE(VerifyMethod("InstanceField_Unresolved_ReferrerInBoot")); ASSERT_TRUE(HasClass("Ljava/io/InterruptedIOException;", true, "public")); ASSERT_TRUE(HasField("Ljava/io/InterruptedIOException;", "x", "I", false)); } TEST_F(VerifierDepsTest, InstanceField_Unresolved_ReferrerInDex) { ASSERT_TRUE(VerifyMethod("InstanceField_Unresolved_ReferrerInDex")); ASSERT_TRUE(HasField("LMyThreadSet;", "x", "I", false)); } TEST_F(VerifierDepsTest, InvokeStatic_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("InvokeStatic_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/net/Socket;", true, "public")); ASSERT_TRUE(HasMethod("direct", "Ljava/net/Socket;", "setSocketImplFactory", "(Ljava/net/SocketImplFactory;)V", true, "public static", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeStatic_Resolved_DeclaredInSuperclass1) { ASSERT_TRUE(VerifyMethod("InvokeStatic_Resolved_DeclaredInSuperclass1")); ASSERT_TRUE(HasClass("Ljavax/net/ssl/SSLSocket;", true, "public abstract")); ASSERT_TRUE(HasMethod("direct", "Ljavax/net/ssl/SSLSocket;", "setSocketImplFactory", "(Ljava/net/SocketImplFactory;)V", true, "public static", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeStatic_Resolved_DeclaredInSuperclass2) { ASSERT_TRUE(VerifyMethod("InvokeStatic_Resolved_DeclaredInSuperclass2")); ASSERT_TRUE(HasMethod("direct", "LMySSLSocket;", "setSocketImplFactory", "(Ljava/net/SocketImplFactory;)V", true, "public static", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeStatic_DeclaredInInterface1) { ASSERT_TRUE(VerifyMethod("InvokeStatic_DeclaredInInterface1")); ASSERT_TRUE(HasClass("Ljava/util/Map$Entry;", true, "public abstract interface")); ASSERT_TRUE(HasMethod("direct", "Ljava/util/Map$Entry;", "comparingByKey", "()Ljava/util/Comparator;", true, "public static", "Ljava/util/Map$Entry;")); } TEST_F(VerifierDepsTest, InvokeStatic_DeclaredInInterface2) { ASSERT_FALSE(VerifyMethod("InvokeStatic_DeclaredInInterface2")); ASSERT_TRUE(HasClass("Ljava/util/AbstractMap$SimpleEntry;", true, "public")); ASSERT_TRUE(HasMethod("direct", "Ljava/util/AbstractMap$SimpleEntry;", "comparingByKey", "()Ljava/util/Comparator;", false)); } TEST_F(VerifierDepsTest, InvokeStatic_Unresolved1) { ASSERT_FALSE(VerifyMethod("InvokeStatic_Unresolved1")); ASSERT_TRUE(HasClass("Ljavax/net/ssl/SSLSocket;", true, "public abstract")); ASSERT_TRUE(HasMethod("direct", "Ljavax/net/ssl/SSLSocket;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeStatic_Unresolved2) { ASSERT_FALSE(VerifyMethod("InvokeStatic_Unresolved2")); ASSERT_TRUE(HasMethod("direct", "LMySSLSocket;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeDirect_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("InvokeDirect_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/net/Socket;", true, "public")); ASSERT_TRUE(HasMethod( "direct", "Ljava/net/Socket;", "", "()V", true, "public", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeDirect_Resolved_DeclaredInSuperclass1) { ASSERT_FALSE(VerifyMethod("InvokeDirect_Resolved_DeclaredInSuperclass1")); ASSERT_TRUE(HasClass("Ljavax/net/ssl/SSLSocket;", true, "public abstract")); ASSERT_TRUE(HasMethod("direct", "Ljavax/net/ssl/SSLSocket;", "checkOldImpl", "()V", true, "private", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeDirect_Resolved_DeclaredInSuperclass2) { ASSERT_FALSE(VerifyMethod("InvokeDirect_Resolved_DeclaredInSuperclass2")); ASSERT_TRUE(HasMethod( "direct", "LMySSLSocket;", "checkOldImpl", "()V", true, "private", "Ljava/net/Socket;")); } TEST_F(VerifierDepsTest, InvokeDirect_Unresolved1) { ASSERT_FALSE(VerifyMethod("InvokeDirect_Unresolved1")); ASSERT_TRUE(HasClass("Ljavax/net/ssl/SSLSocket;", true, "public abstract")); ASSERT_TRUE(HasMethod("direct", "Ljavax/net/ssl/SSLSocket;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeDirect_Unresolved2) { ASSERT_FALSE(VerifyMethod("InvokeDirect_Unresolved2")); ASSERT_TRUE(HasMethod("direct", "LMySSLSocket;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeVirtual_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("InvokeVirtual_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/lang/Throwable;", true, "public")); ASSERT_TRUE(HasMethod("virtual", "Ljava/lang/Throwable;", "getMessage", "()Ljava/lang/String;", true, "public", "Ljava/lang/Throwable;")); // Type dependency on `this` argument. ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "LMySocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, InvokeVirtual_Resolved_DeclaredInSuperclass1) { ASSERT_TRUE(VerifyMethod("InvokeVirtual_Resolved_DeclaredInSuperclass1")); ASSERT_TRUE(HasClass("Ljava/io/InterruptedIOException;", true, "public")); ASSERT_TRUE(HasMethod("virtual", "Ljava/io/InterruptedIOException;", "getMessage", "()Ljava/lang/String;", true, "public", "Ljava/lang/Throwable;")); // Type dependency on `this` argument. ASSERT_TRUE(HasAssignable("Ljava/lang/Throwable;", "LMySocketTimeoutException;", true)); } TEST_F(VerifierDepsTest, InvokeVirtual_Resolved_DeclaredInSuperclass2) { ASSERT_TRUE(VerifyMethod("InvokeVirtual_Resolved_DeclaredInSuperclass2")); ASSERT_TRUE(HasMethod("virtual", "LMySocketTimeoutException;", "getMessage", "()Ljava/lang/String;", true, "public", "Ljava/lang/Throwable;")); } TEST_F(VerifierDepsTest, InvokeVirtual_Resolved_DeclaredInSuperinterface) { ASSERT_TRUE(VerifyMethod("InvokeVirtual_Resolved_DeclaredInSuperinterface")); ASSERT_TRUE(HasMethod("virtual", "LMyThreadSet;", "size", "()I", true, "public abstract", "Ljava/util/Set;")); } TEST_F(VerifierDepsTest, InvokeVirtual_Unresolved1) { ASSERT_FALSE(VerifyMethod("InvokeVirtual_Unresolved1")); ASSERT_TRUE(HasClass("Ljava/io/InterruptedIOException;", true, "public")); ASSERT_TRUE(HasMethod("virtual", "Ljava/io/InterruptedIOException;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeVirtual_Unresolved2) { ASSERT_FALSE(VerifyMethod("InvokeVirtual_Unresolved2")); ASSERT_TRUE(HasMethod("virtual", "LMySocketTimeoutException;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeVirtual_ActuallyDirect) { ASSERT_FALSE(VerifyMethod("InvokeVirtual_ActuallyDirect")); ASSERT_TRUE(HasMethod("virtual", "LMyThread;", "activeCount", "()I", false)); ASSERT_TRUE(HasMethod("direct", "LMyThread;", "activeCount", "()I", true, "public static", "Ljava/lang/Thread;")); } TEST_F(VerifierDepsTest, InvokeInterface_Resolved_DeclaredInReferenced) { ASSERT_TRUE(VerifyMethod("InvokeInterface_Resolved_DeclaredInReferenced")); ASSERT_TRUE(HasClass("Ljava/lang/Runnable;", true, "public abstract interface")); ASSERT_TRUE(HasMethod("interface", "Ljava/lang/Runnable;", "run", "()V", true, "public abstract", "Ljava/lang/Runnable;")); } TEST_F(VerifierDepsTest, InvokeInterface_Resolved_DeclaredInSuperclass) { ASSERT_FALSE(VerifyMethod("InvokeInterface_Resolved_DeclaredInSuperclass")); ASSERT_TRUE(HasMethod("interface", "LMyThread;", "join", "()V", false)); } TEST_F(VerifierDepsTest, InvokeInterface_Resolved_DeclaredInSuperinterface1) { ASSERT_FALSE(VerifyMethod("InvokeInterface_Resolved_DeclaredInSuperinterface1")); ASSERT_TRUE(HasMethod("interface", "LMyThreadSet;", "run", "()V", true, "public abstract", "Ljava/lang/Runnable;")); } TEST_F(VerifierDepsTest, InvokeInterface_Resolved_DeclaredInSuperinterface2) { ASSERT_FALSE(VerifyMethod("InvokeInterface_Resolved_DeclaredInSuperinterface2")); ASSERT_TRUE(HasMethod("interface", "LMyThreadSet;", "isEmpty", "()Z", true, "public abstract", "Ljava/util/Set;")); } TEST_F(VerifierDepsTest, InvokeInterface_Unresolved1) { ASSERT_FALSE(VerifyMethod("InvokeInterface_Unresolved1")); ASSERT_TRUE(HasClass("Ljava/lang/Runnable;", true, "public abstract interface")); ASSERT_TRUE(HasMethod("interface", "Ljava/lang/Runnable;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeInterface_Unresolved2) { ASSERT_FALSE(VerifyMethod("InvokeInterface_Unresolved2")); ASSERT_TRUE(HasMethod("interface", "LMyThreadSet;", "x", "()V", false)); } TEST_F(VerifierDepsTest, InvokeSuper_ThisAssignable) { ASSERT_TRUE(VerifyMethod("InvokeSuper_ThisAssignable")); ASSERT_TRUE(HasClass("Ljava/lang/Runnable;", true, "public abstract interface")); ASSERT_TRUE(HasAssignable("Ljava/lang/Runnable;", "LMain;", true)); ASSERT_TRUE(HasMethod("interface", "Ljava/lang/Runnable;", "run", "()V", true, "public abstract", "Ljava/lang/Runnable;")); } TEST_F(VerifierDepsTest, InvokeSuper_ThisNotAssignable) { ASSERT_FALSE(VerifyMethod("InvokeSuper_ThisNotAssignable")); ASSERT_TRUE(HasClass("Ljava/lang/Integer;", true, "public final")); ASSERT_TRUE(HasAssignable("Ljava/lang/Integer;", "LMain;", false)); ASSERT_TRUE(HasMethod( "virtual", "Ljava/lang/Integer;", "intValue", "()I", true, "public", "Ljava/lang/Integer;")); } TEST_F(VerifierDepsTest, EncodeDecode) { VerifyDexFile(); ASSERT_EQ(1u, NumberOfCompiledDexFiles()); ASSERT_TRUE(HasEachKindOfRecord()); std::vector buffer; verifier_deps_->Encode(dex_files_, &buffer); ASSERT_FALSE(buffer.empty()); VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); ASSERT_TRUE(verifier_deps_->Equals(decoded_deps)); } TEST_F(VerifierDepsTest, EncodeDecodeMulti) { VerifyDexFile("MultiDex"); ASSERT_GT(NumberOfCompiledDexFiles(), 1u); std::vector buffer; verifier_deps_->Encode(dex_files_, &buffer); ASSERT_FALSE(buffer.empty()); // Create new DexFile, to mess with std::map order: the verifier deps used // to iterate over the map, which doesn't guarantee insertion order. We fixed // this by passing the expected order when encoding/decoding. std::vector> first_dex_files = OpenTestDexFiles("VerifierDeps"); std::vector> second_dex_files = OpenTestDexFiles("MultiDex"); std::vector dex_files; for (auto& dex_file : first_dex_files) { dex_files.push_back(dex_file.get()); } for (auto& dex_file : second_dex_files) { dex_files.push_back(dex_file.get()); } // Dump the new verifier deps to ensure it can properly read the data. VerifierDeps decoded_deps(dex_files, ArrayRef(buffer)); std::ostringstream stream; VariableIndentationOutputStream os(&stream); decoded_deps.Dump(&os); } TEST_F(VerifierDepsTest, UnverifiedClasses) { VerifyDexFile(); ASSERT_FALSE(HasUnverifiedClass("LMyThread;")); // Test that a class with a soft failure is recorded. ASSERT_TRUE(HasUnverifiedClass("LMain;")); // Test that a class with hard failure is recorded. ASSERT_TRUE(HasUnverifiedClass("LMyVerificationFailure;")); // Test that a class with unresolved super is recorded. ASSERT_FALSE(HasUnverifiedClass("LMyClassWithNoSuper;")); // Test that a class with unresolved super and hard failure is recorded. ASSERT_TRUE(HasUnverifiedClass("LMyClassWithNoSuperButFailures;")); } // Returns the next resolution kind in the enum. static MethodResolutionKind GetNextResolutionKind(MethodResolutionKind resolution_kind) { if (resolution_kind == kDirectMethodResolution) { return kVirtualMethodResolution; } else if (resolution_kind == kVirtualMethodResolution) { return kInterfaceMethodResolution; } else { DCHECK_EQ(resolution_kind, kInterfaceMethodResolution); return kDirectMethodResolution; } } TEST_F(VerifierDepsTest, VerifyDeps) { VerifyDexFile(); ASSERT_EQ(1u, NumberOfCompiledDexFiles()); ASSERT_TRUE(HasEachKindOfRecord()); // When validating, we create a new class loader, as // the existing `class_loader_` may contain erroneous classes, // that ClassLinker::FindClass won't return. ScopedObjectAccess soa(Thread::Current()); StackHandleScope<1> hs(soa.Self()); MutableHandle new_class_loader(hs.NewHandle(nullptr)); { new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_TRUE(verifier_deps_->ValidateDependencies(new_class_loader, soa.Self())); } std::vector buffer; verifier_deps_->Encode(dex_files_, &buffer); ASSERT_FALSE(buffer.empty()); { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_TRUE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } // Fiddle with the dependencies to make sure we catch any change and fail to verify. { // Mess up with the assignable_types. VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); deps->assignable_types_.insert(*deps->unassignable_types_.begin()); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { // Mess up with the unassignable_types. VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); deps->unassignable_types_.insert(*deps->assignable_types_.begin()); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } // Mess up with classes. { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->classes_) { if (entry.IsResolved()) { deps->classes_.insert(VerifierDeps::ClassResolution( entry.GetDexTypeIndex(), VerifierDeps::kUnresolvedMarker)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->classes_) { if (!entry.IsResolved()) { deps->classes_.insert(VerifierDeps::ClassResolution( entry.GetDexTypeIndex(), VerifierDeps::kUnresolvedMarker - 1)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->classes_) { if (entry.IsResolved()) { deps->classes_.insert(VerifierDeps::ClassResolution( entry.GetDexTypeIndex(), entry.GetAccessFlags() - 1)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } // Mess up with fields. { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->fields_) { if (entry.IsResolved()) { deps->fields_.insert(VerifierDeps::FieldResolution(entry.GetDexFieldIndex(), VerifierDeps::kUnresolvedMarker, entry.GetDeclaringClassIndex())); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->fields_) { if (!entry.IsResolved()) { deps->fields_.insert(VerifierDeps::FieldResolution(0 /* we know there is a field there */, VerifierDeps::kUnresolvedMarker - 1, 0 /* we know there is a class there */)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->fields_) { if (entry.IsResolved()) { deps->fields_.insert(VerifierDeps::FieldResolution(entry.GetDexFieldIndex(), entry.GetAccessFlags() - 1, entry.GetDeclaringClassIndex())); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->fields_) { static constexpr uint32_t kNewTypeIndex = 0; if (entry.GetDeclaringClassIndex() != kNewTypeIndex) { deps->fields_.insert(VerifierDeps::FieldResolution(entry.GetDexFieldIndex(), entry.GetAccessFlags(), kNewTypeIndex)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } // Mess up with methods. for (MethodResolutionKind resolution_kind : { kDirectMethodResolution, kVirtualMethodResolution, kInterfaceMethodResolution }) { { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { if (entry.IsResolved()) { methods->insert(VerifierDeps::MethodResolution(entry.GetDexMethodIndex(), VerifierDeps::kUnresolvedMarker, entry.GetDeclaringClassIndex())); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { if (!entry.IsResolved()) { methods->insert(VerifierDeps::MethodResolution(0 /* we know there is a method there */, VerifierDeps::kUnresolvedMarker - 1, 0 /* we know there is a class there */)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { if (entry.IsResolved()) { methods->insert(VerifierDeps::MethodResolution(entry.GetDexMethodIndex(), entry.GetAccessFlags() - 1, entry.GetDeclaringClassIndex())); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { static constexpr uint32_t kNewTypeIndex = 0; if (entry.IsResolved() && entry.GetDeclaringClassIndex() != kNewTypeIndex) { methods->insert(VerifierDeps::MethodResolution(entry.GetDexMethodIndex(), entry.GetAccessFlags(), kNewTypeIndex)); found = true; break; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { if (entry.IsResolved()) { GetMethods(deps, GetNextResolutionKind(resolution_kind))->insert( VerifierDeps::MethodResolution(entry.GetDexMethodIndex(), entry.GetAccessFlags(), entry.GetDeclaringClassIndex())); found = true; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } { VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; std::set* methods = GetMethods(deps, resolution_kind); for (const auto& entry : *methods) { if (entry.IsResolved()) { GetMethods(deps, GetNextResolutionKind(GetNextResolutionKind(resolution_kind)))->insert( VerifierDeps::MethodResolution(entry.GetDexMethodIndex(), entry.GetAccessFlags(), entry.GetDeclaringClassIndex())); found = true; } } ASSERT_TRUE(found); new_class_loader.Assign(soa.Decode(LoadDex("VerifierDeps"))); ASSERT_FALSE(decoded_deps.ValidateDependencies(new_class_loader, soa.Self())); } } } TEST_F(VerifierDepsTest, CompilerDriver) { SetupCompilerDriver(); // Test both multi-dex and single-dex configuration. for (const char* multi : { "MultiDex", static_cast(nullptr) }) { // Test that the compiler driver behaves as expected when the dependencies // verify and when they don't verify. for (bool verify_failure : { false, true }) { { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa, "VerifierDeps", multi); } VerifyWithCompilerDriver(/* verifier_deps */ nullptr); std::vector buffer; verifier_deps_->Encode(dex_files_, &buffer); { ScopedObjectAccess soa(Thread::Current()); LoadDexFile(&soa, "VerifierDeps", multi); } verifier::VerifierDeps decoded_deps(dex_files_, ArrayRef(buffer)); if (verify_failure) { // Just taint the decoded VerifierDeps with one invalid entry. VerifierDeps::DexFileDeps* deps = decoded_deps.GetDexFileDeps(*primary_dex_file_); bool found = false; for (const auto& entry : deps->classes_) { if (entry.IsResolved()) { deps->classes_.insert(VerifierDeps::ClassResolution( entry.GetDexTypeIndex(), VerifierDeps::kUnresolvedMarker)); found = true; break; } } ASSERT_TRUE(found); } VerifyWithCompilerDriver(&decoded_deps); if (verify_failure) { ASSERT_FALSE(verifier_deps_ == nullptr); ASSERT_FALSE(verifier_deps_->Equals(decoded_deps)); } else { ASSERT_TRUE(verifier_deps_ == nullptr); VerifyClassStatus(decoded_deps); } } } } } // namespace verifier } // namespace art