/* * Copyright (C) 2011 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. */ #ifndef ART_RUNTIME_MIRROR_CLASS_INL_H_ #define ART_RUNTIME_MIRROR_CLASS_INL_H_ #include "class.h" #include "art_field.h" #include "art_method.h" #include "base/array_slice.h" #include "base/iteration_range.h" #include "base/length_prefixed_array.h" #include "base/stride_iterator.h" #include "base/utils.h" #include "class_linker.h" #include "class_loader.h" #include "common_throws.h" #include "dex/dex_file-inl.h" #include "dex/invoke_type.h" #include "dex_cache.h" #include "hidden_api.h" #include "iftable-inl.h" #include "imtable.h" #include "object-inl.h" #include "read_barrier-inl.h" #include "runtime.h" #include "string.h" #include "subtype_check.h" #include "thread-current-inl.h" namespace art HIDDEN { namespace mirror { template inline uint32_t Class::GetObjectSize() { // Note: Extra parentheses to avoid the comma being interpreted as macro parameter separator. DCHECK((!IsVariableSize())) << "class=" << PrettyTypeOf(); return GetField32(ObjectSizeOffset()); } template inline uint32_t Class::GetObjectSizeAllocFastPath() { // Note: Extra parentheses to avoid the comma being interpreted as macro parameter separator. DCHECK((!IsVariableSize())) << "class=" << PrettyTypeOf(); return GetField32(ObjectSizeAllocFastPathOffset()); } template inline ObjPtr Class::GetSuperClass() { // Can only get super class for loaded classes (hack for when runtime is // initializing) DCHECK(IsLoaded() || IsErroneous() || !Runtime::Current()->IsStarted()) << IsLoaded(); return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, super_class_)); } inline void Class::SetSuperClass(ObjPtr new_super_class) { // Super class is assigned once, except during class linker initialization. if (kIsDebugBuild) { ObjPtr old_super_class = GetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, super_class_)); DCHECK(old_super_class == nullptr || old_super_class == new_super_class); } DCHECK(new_super_class != nullptr); SetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, super_class_), new_super_class); } inline bool Class::HasSuperClass() { // No read barrier is needed for comparing with null. See ReadBarrierOption. return GetSuperClass() != nullptr; } template inline ObjPtr Class::GetClassLoader() { return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, class_loader_)); } template inline ObjPtr Class::GetExtData() { return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, ext_data_)); } template inline ObjPtr Class::GetDexCache() { return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, dex_cache_)); } inline uint32_t Class::GetCopiedMethodsStartOffset() { // Object::GetFieldShort returns an int16_t value, but // Class::copied_methods_offset_ is an uint16_t value; cast the // latter to uint16_t before returning it as an uint32_t value, so // that uint16_t values between 2^15 and 2^16-1 are correctly // handled. return static_cast( GetFieldShort(OFFSET_OF_OBJECT_MEMBER(Class, copied_methods_offset_))); } inline uint32_t Class::GetDirectMethodsStartOffset() { return 0; } inline uint32_t Class::GetVirtualMethodsStartOffset() { // Object::GetFieldShort returns an int16_t value, but // Class::virtual_method_offset_ is an uint16_t value; cast the // latter to uint16_t before returning it as an uint32_t value, so // that uint16_t values between 2^15 and 2^16-1 are correctly // handled. return static_cast( GetFieldShort(OFFSET_OF_OBJECT_MEMBER(Class, virtual_methods_offset_))); } template inline ArraySlice Class::GetDirectMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()) << GetStatus(); return GetDirectMethodsSliceUnchecked(pointer_size); } inline ArraySlice Class::GetDirectMethodsSliceUnchecked(PointerSize pointer_size) { return GetMethodsSliceRangeUnchecked(GetMethodsPtr(), pointer_size, GetDirectMethodsStartOffset(), GetVirtualMethodsStartOffset()); } template inline ArraySlice Class::GetDeclaredMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()) << GetStatus(); return GetDeclaredMethodsSliceUnchecked(pointer_size); } inline ArraySlice Class::GetDeclaredMethodsSliceUnchecked(PointerSize pointer_size) { return GetMethodsSliceRangeUnchecked(GetMethodsPtr(), pointer_size, GetDirectMethodsStartOffset(), GetCopiedMethodsStartOffset()); } template inline ArraySlice Class::GetDeclaredVirtualMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()) << GetStatus(); return GetDeclaredVirtualMethodsSliceUnchecked(pointer_size); } inline ArraySlice Class::GetDeclaredVirtualMethodsSliceUnchecked( PointerSize pointer_size) { return GetMethodsSliceRangeUnchecked(GetMethodsPtr(), pointer_size, GetVirtualMethodsStartOffset(), GetCopiedMethodsStartOffset()); } template inline ArraySlice Class::GetVirtualMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()); return GetVirtualMethodsSliceUnchecked(pointer_size); } inline ArraySlice Class::GetVirtualMethodsSliceUnchecked(PointerSize pointer_size) { LengthPrefixedArray* methods = GetMethodsPtr(); return GetMethodsSliceRangeUnchecked(methods, pointer_size, GetVirtualMethodsStartOffset(), NumMethods(methods)); } template inline ArraySlice Class::GetCopiedMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()); return GetCopiedMethodsSliceUnchecked(pointer_size); } inline ArraySlice Class::GetCopiedMethodsSliceUnchecked(PointerSize pointer_size) { LengthPrefixedArray* methods = GetMethodsPtr(); return GetMethodsSliceRangeUnchecked(methods, pointer_size, GetCopiedMethodsStartOffset(), NumMethods(methods)); } inline LengthPrefixedArray* Class::GetMethodsPtr() { return reinterpret_cast*>( static_cast(GetField64(OFFSET_OF_OBJECT_MEMBER(Class, methods_)))); } template inline ArraySlice Class::GetMethodsSlice(PointerSize pointer_size) { DCHECK(IsLoaded() || IsErroneous()); LengthPrefixedArray* methods = GetMethodsPtr(); return GetMethodsSliceRangeUnchecked(methods, pointer_size, 0, NumMethods(methods)); } inline ArraySlice Class::GetMethodsSliceRangeUnchecked( LengthPrefixedArray* methods, PointerSize pointer_size, uint32_t start_offset, uint32_t end_offset) { DCHECK_LE(start_offset, end_offset); DCHECK_LE(end_offset, NumMethods(methods)); uint32_t size = end_offset - start_offset; if (size == 0u) { return ArraySlice(); } DCHECK(methods != nullptr); DCHECK_LE(end_offset, methods->size()); size_t method_size = ArtMethod::Size(pointer_size); size_t method_alignment = ArtMethod::Alignment(pointer_size); ArraySlice slice(&methods->At(0u, method_size, method_alignment), methods->size(), method_size); return slice.SubArray(start_offset, size); } inline uint32_t Class::NumMethods() { return NumMethods(GetMethodsPtr()); } inline uint32_t Class::NumMethods(LengthPrefixedArray* methods) { return (methods == nullptr) ? 0 : methods->size(); } inline ArtMethod* Class::GetDirectMethodUnchecked(size_t i, PointerSize pointer_size) { CheckPointerSize(pointer_size); return &GetDirectMethodsSliceUnchecked(pointer_size)[i]; } inline ArtMethod* Class::GetDirectMethod(size_t i, PointerSize pointer_size) { CheckPointerSize(pointer_size); return &GetDirectMethodsSlice(pointer_size)[i]; } inline void Class::SetMethodsPtr(LengthPrefixedArray* new_methods, uint32_t num_direct, uint32_t num_virtual) { DCHECK(GetMethodsPtr() == nullptr); SetMethodsPtrUnchecked(new_methods, num_direct, num_virtual); } inline void Class::SetMethodsPtrUnchecked(LengthPrefixedArray* new_methods, uint32_t num_direct, uint32_t num_virtual) { DCHECK_LE(num_direct + num_virtual, (new_methods == nullptr) ? 0 : new_methods->size()); SetField64(OFFSET_OF_OBJECT_MEMBER(Class, methods_), static_cast(reinterpret_cast(new_methods))); SetFieldShort(OFFSET_OF_OBJECT_MEMBER(Class, copied_methods_offset_), dchecked_integral_cast(num_direct + num_virtual)); SetFieldShort(OFFSET_OF_OBJECT_MEMBER(Class, virtual_methods_offset_), dchecked_integral_cast(num_direct)); } template inline ArtMethod* Class::GetVirtualMethod(size_t i, PointerSize pointer_size) { CheckPointerSize(pointer_size); DCHECK(IsResolved() || IsErroneous()) << Class::PrettyClass() << " status=" << GetStatus(); return GetVirtualMethodUnchecked(i, pointer_size); } inline ArtMethod* Class::GetVirtualMethodDuringLinking(size_t i, PointerSize pointer_size) { CheckPointerSize(pointer_size); DCHECK(IsLoaded() || IsErroneous()); return GetVirtualMethodUnchecked(i, pointer_size); } inline ArtMethod* Class::GetVirtualMethodUnchecked(size_t i, PointerSize pointer_size) { CheckPointerSize(pointer_size); return &GetVirtualMethodsSliceUnchecked(pointer_size)[i]; } template inline ObjPtr Class::GetVTable() { DCHECK(IsLoaded() || IsErroneous()); return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, vtable_)); } inline ObjPtr Class::GetVTableDuringLinking() { DCHECK(IsLoaded() || IsErroneous()); return GetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, vtable_)); } inline void Class::SetVTable(ObjPtr new_vtable) { SetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, vtable_), new_vtable); } template inline bool Class::ShouldHaveImt() { return ShouldHaveEmbeddedVTable(); } template inline bool Class::ShouldHaveEmbeddedVTable() { return IsInstantiable(); } inline bool Class::HasVTable() { // No read barrier is needed for comparing with null. See ReadBarrierOption. return GetVTable() != nullptr || ShouldHaveEmbeddedVTable(); } template inline int32_t Class::GetVTableLength() { if (ShouldHaveEmbeddedVTable()) { return GetEmbeddedVTableLength(); } // We do not need a read barrier here as the length is constant, // both from-space and to-space vtables shall yield the same result. ObjPtr vtable = GetVTable(); return vtable != nullptr ? vtable->GetLength() : 0; } template inline ArtMethod* Class::GetVTableEntry(uint32_t i, PointerSize pointer_size) { if (ShouldHaveEmbeddedVTable()) { return GetEmbeddedVTableEntry(i, pointer_size); } ObjPtr vtable = GetVTable(); DCHECK(vtable != nullptr); return vtable->GetElementPtrSize(i, pointer_size); } template inline int32_t Class::GetEmbeddedVTableLength() { return GetField32(MemberOffset(EmbeddedVTableLengthOffset())); } inline void Class::SetEmbeddedVTableLength(int32_t len) { SetField32( MemberOffset(EmbeddedVTableLengthOffset()), len); } inline ImTable* Class::GetImt(PointerSize pointer_size) { return GetFieldPtrWithSize(ImtPtrOffset(pointer_size), pointer_size); } inline void Class::SetImt(ImTable* imt, PointerSize pointer_size) { return SetFieldPtrWithSize( ImtPtrOffset(pointer_size), imt, pointer_size); } inline MemberOffset Class::EmbeddedVTableEntryOffset(uint32_t i, PointerSize pointer_size) { return MemberOffset( EmbeddedVTableOffset(pointer_size).Uint32Value() + i * VTableEntrySize(pointer_size)); } inline ArtMethod* Class::GetEmbeddedVTableEntry(uint32_t i, PointerSize pointer_size) { return GetFieldPtrWithSize(EmbeddedVTableEntryOffset(i, pointer_size), pointer_size); } inline void Class::SetEmbeddedVTableEntryUnchecked( uint32_t i, ArtMethod* method, PointerSize pointer_size) { SetFieldPtrWithSize( EmbeddedVTableEntryOffset(i, pointer_size), method, pointer_size); } inline void Class::SetEmbeddedVTableEntry(uint32_t i, ArtMethod* method, PointerSize pointer_size) { ObjPtr vtable = GetVTableDuringLinking(); CHECK_EQ(method, vtable->GetElementPtrSize(i, pointer_size)); SetEmbeddedVTableEntryUnchecked(i, method, pointer_size); } inline bool Class::Implements(ObjPtr klass) { DCHECK(klass != nullptr); DCHECK(klass->IsInterface()) << PrettyClass(); // All interfaces implemented directly and by our superclass, and // recursively all super-interfaces of those interfaces, are listed // in iftable_, so we can just do a linear scan through that. int32_t iftable_count = GetIfTableCount(); ObjPtr iftable = GetIfTable(); for (int32_t i = 0; i < iftable_count; i++) { if (iftable->GetInterface(i) == klass) { return true; } } return false; } template inline bool Class::IsVariableSize() { // Classes, arrays, and strings vary in size, and so the object_size_ field cannot // be used to Get their instance size return IsClassClass() || IsArrayClass() || IsStringClass(); } inline void Class::SetObjectSize(uint32_t new_object_size) { DCHECK(!IsVariableSize()); // Not called within a transaction. return SetField32(OFFSET_OF_OBJECT_MEMBER(Class, object_size_), new_object_size); } template inline bool Class::IsDiscoverable(bool public_only, const hiddenapi::AccessContext& access_context, T* member) { if (public_only && ((member->GetAccessFlags() & kAccPublic) == 0)) { return false; } return !hiddenapi::ShouldDenyAccessToMember( member, access_context, hiddenapi::AccessMethod::kNone); } // Determine whether "this" is assignable from "src", where both of these // are array classes. // // Consider an array class, e.g. Y[][], where Y is a subclass of X. // Y[][] = Y[][] --> true (identity) // X[][] = Y[][] --> true (element superclass) // Y = Y[][] --> false // Y[] = Y[][] --> false // Object = Y[][] --> true (everything is an object) // Object[] = Y[][] --> true // Object[][] = Y[][] --> true // Object[][][] = Y[][] --> false (too many []s) // Serializable = Y[][] --> true (all arrays are Serializable) // Serializable[] = Y[][] --> true // Serializable[][] = Y[][] --> false (unless Y is Serializable) // // Don't forget about primitive types. // Object[] = int[] --> false // inline bool Class::IsArrayAssignableFromArray(ObjPtr src) { DCHECK(IsArrayClass()) << PrettyClass(); DCHECK(src->IsArrayClass()) << src->PrettyClass(); return GetComponentType()->IsAssignableFrom(src->GetComponentType()); } inline bool Class::IsAssignableFromArray(ObjPtr src) { DCHECK(!IsInterface()) << PrettyClass(); // handled first in IsAssignableFrom DCHECK(src->IsArrayClass()) << src->PrettyClass(); if (!IsArrayClass()) { // If "this" is not also an array, it must be Object. // src's super should be java_lang_Object, since it is an array. ObjPtr java_lang_Object = src->GetSuperClass(); DCHECK(java_lang_Object != nullptr) << src->PrettyClass(); DCHECK(java_lang_Object->GetSuperClass() == nullptr) << src->PrettyClass(); return this == java_lang_Object; } return IsArrayAssignableFromArray(src); } template inline bool Class::ResolvedFieldAccessTest(ObjPtr access_to, ArtField* field, ObjPtr dex_cache, uint32_t field_idx) { DCHECK(dex_cache != nullptr); if (UNLIKELY(!this->CanAccess(access_to))) { // The referrer class can't access the field's declaring class but may still be able // to access the field if the FieldId specifies an accessible subclass of the declaring // class rather than the declaring class itself. dex::TypeIndex class_idx = dex_cache->GetDexFile()->GetFieldId(field_idx).class_idx_; // The referenced class has already been resolved with the field, but may not be in the dex // cache. Use LookupResolveType here to search the class table if it is not in the dex cache. // should be no thread suspension due to the class being resolved. ObjPtr dex_access_to = Runtime::Current()->GetClassLinker()->LookupResolvedType( class_idx, dex_cache, GetClassLoader()); DCHECK(dex_access_to != nullptr); if (UNLIKELY(!this->CanAccess(dex_access_to))) { if (throw_on_failure) { ThrowIllegalAccessErrorClass(this, dex_access_to); } return false; } } if (LIKELY(this->CanAccessMember(access_to, field->GetAccessFlags()))) { return true; } if (throw_on_failure) { ThrowIllegalAccessErrorField(this, field); } return false; } inline bool Class::CanAccessResolvedField(ObjPtr access_to, ArtField* field, ObjPtr dex_cache, uint32_t field_idx) { return ResolvedFieldAccessTest(access_to, field, dex_cache, field_idx); } inline bool Class::CheckResolvedFieldAccess(ObjPtr access_to, ArtField* field, ObjPtr dex_cache, uint32_t field_idx) { return ResolvedFieldAccessTest(access_to, field, dex_cache, field_idx); } inline bool Class::IsObsoleteVersionOf(ObjPtr klass) { DCHECK(!klass->IsObsoleteObject()) << klass->PrettyClass() << " is obsolete!"; if (LIKELY(!IsObsoleteObject())) { return false; } ObjPtr current(klass); do { if (UNLIKELY(current == this)) { return true; } else { current = current->GetObsoleteClass(); } } while (!current.IsNull()); return false; } inline bool Class::IsSubClass(ObjPtr klass) { // Since the SubtypeCheck::IsSubtypeOf needs to lookup the Depth, // it is always O(Depth) in terms of speed to do the check. // // So always do the "slow" linear scan in normal release builds. // // Future note: If we could have the depth in O(1) we could use the 'fast' // method instead as it avoids a loop and a read barrier. bool result = false; DCHECK(!IsInterface()) << PrettyClass(); DCHECK(!IsArrayClass()) << PrettyClass(); ObjPtr current = this; do { if (current == klass) { result = true; break; } current = current->GetSuperClass(); } while (current != nullptr); if (kIsDebugBuild && kBitstringSubtypeCheckEnabled) { ObjPtr dis(this); SubtypeCheckInfo::Result sc_result = SubtypeCheck>::IsSubtypeOf(dis, klass); if (sc_result != SubtypeCheckInfo::kUnknownSubtypeOf) { // Note: The "kUnknownSubTypeOf" can be avoided if and only if: // SubtypeCheck::EnsureInitialized(source) // happens-before source.IsSubClass(target) // SubtypeCheck::EnsureAssigned(target).GetState() == Assigned // happens-before source.IsSubClass(target) // // When code generated by optimizing compiler executes this operation, both // happens-before are guaranteed, so there is no fallback code there. SubtypeCheckInfo::Result expected_result = result ? SubtypeCheckInfo::kSubtypeOf : SubtypeCheckInfo::kNotSubtypeOf; DCHECK_EQ(expected_result, sc_result) << "source: " << PrettyClass() << "target: " << klass->PrettyClass(); } } return result; } inline ArtMethod* Class::FindVirtualMethodForInterface(ArtMethod* method, PointerSize pointer_size) { ObjPtr declaring_class = method->GetDeclaringClass(); DCHECK(declaring_class != nullptr) << PrettyClass(); if (UNLIKELY(!declaring_class->IsInterface())) { DCHECK(declaring_class->IsObjectClass()) << method->PrettyMethod(); DCHECK(method->IsPublic() && !method->IsStatic()); return FindVirtualMethodForVirtual(method, pointer_size); } DCHECK(!method->IsCopied()); // TODO cache to improve lookup speed const int32_t iftable_count = GetIfTableCount(); ObjPtr iftable = GetIfTable(); for (int32_t i = 0; i < iftable_count; i++) { if (iftable->GetInterface(i) == declaring_class) { return iftable->GetMethodArray(i)->GetElementPtrSize( method->GetMethodIndex(), pointer_size); } } return nullptr; } inline ArtMethod* Class::FindVirtualMethodForVirtual(ArtMethod* method, PointerSize pointer_size) { // Only miranda or default methods may come from interfaces and be used as a virtual. DCHECK(!method->GetDeclaringClass()->IsInterface() || method->IsDefault() || method->IsMiranda()); DCHECK(method->GetDeclaringClass()->IsAssignableFrom(this)) << "Method " << method->PrettyMethod() << " is not declared in " << PrettyDescriptor() << " or its super classes"; // The argument method may from a super class. // Use the index to a potentially overridden one for this instance's class. return GetVTableEntry(method->GetMethodIndex(), pointer_size); } inline ArtMethod* Class::FindVirtualMethodForSuper(ArtMethod* method, PointerSize pointer_size) { DCHECK(!method->GetDeclaringClass()->IsInterface()); DCHECK(method->GetDeclaringClass()->IsAssignableFrom(this)) << "Method " << method->PrettyMethod() << " is not declared in " << PrettyDescriptor() << " or its super classes"; return GetSuperClass()->GetVTableEntry(method->GetMethodIndex(), pointer_size); } inline ArtMethod* Class::FindVirtualMethodForVirtualOrInterface(ArtMethod* method, PointerSize pointer_size) { if (method->IsDirect()) { return method; } if (method->GetDeclaringClass()->IsInterface() && !method->IsCopied()) { return FindVirtualMethodForInterface(method, pointer_size); } return FindVirtualMethodForVirtual(method, pointer_size); } template inline ObjPtr Class::GetIfTable() { ObjPtr ret = GetFieldObject(IfTableOffset()); DCHECK(ret != nullptr) << PrettyClass(this); return ret; } template inline int32_t Class::GetIfTableCount() { // We do not need a read barrier here as the length is constant, // both from-space and to-space iftables shall yield the same result. return GetIfTable()->Count(); } inline void Class::SetIfTable(ObjPtr new_iftable) { DCHECK(new_iftable != nullptr) << PrettyClass(this); SetFieldObject( IfTableOffset(), new_iftable); } inline LengthPrefixedArray* Class::GetIFieldsPtr() { DCHECK(IsLoaded() || IsErroneous()) << GetStatus(); return GetFieldPtr*>(OFFSET_OF_OBJECT_MEMBER(Class, ifields_)); } template inline MemberOffset Class::GetFirstReferenceInstanceFieldOffset() { ObjPtr super_class = GetSuperClass(); return (super_class != nullptr) ? MemberOffset(RoundUp(super_class->GetObjectSize(), kHeapReferenceSize)) : ClassOffset(); } template inline MemberOffset Class::GetFirstReferenceStaticFieldOffset(PointerSize pointer_size) { DCHECK(IsResolved()); uint32_t base = sizeof(Class); // Static fields come after the class. if (ShouldHaveEmbeddedVTable()) { // Static fields come after the embedded tables. base = Class::ComputeClassSize( true, GetEmbeddedVTableLength(), 0, 0, 0, 0, 0, 0, pointer_size); } return MemberOffset(base); } inline MemberOffset Class::GetFirstReferenceStaticFieldOffsetDuringLinking( PointerSize pointer_size) { DCHECK(IsLoaded()); uint32_t base = sizeof(Class); // Static fields come after the class. if (ShouldHaveEmbeddedVTable()) { // Static fields come after the embedded tables. base = Class::ComputeClassSize( true, GetVTableDuringLinking()->GetLength(), 0, 0, 0, 0, 0, 0, pointer_size); } return MemberOffset(base); } inline void Class::SetIFieldsPtr(LengthPrefixedArray* new_ifields) { DCHECK(GetIFieldsPtrUnchecked() == nullptr); return SetFieldPtr(OFFSET_OF_OBJECT_MEMBER(Class, ifields_), new_ifields); } inline void Class::SetIFieldsPtrUnchecked(LengthPrefixedArray* new_ifields) { SetFieldPtr(OFFSET_OF_OBJECT_MEMBER(Class, ifields_), new_ifields); } inline LengthPrefixedArray* Class::GetSFieldsPtrUnchecked() { return GetFieldPtr*>(OFFSET_OF_OBJECT_MEMBER(Class, sfields_)); } inline LengthPrefixedArray* Class::GetIFieldsPtrUnchecked() { return GetFieldPtr*>(OFFSET_OF_OBJECT_MEMBER(Class, ifields_)); } inline LengthPrefixedArray* Class::GetSFieldsPtr() { DCHECK(IsLoaded() || IsErroneous()) << GetStatus(); return GetSFieldsPtrUnchecked(); } inline void Class::SetSFieldsPtr(LengthPrefixedArray* new_sfields) { DCHECK((IsRetired() && new_sfields == nullptr) || GetFieldPtr(OFFSET_OF_OBJECT_MEMBER(Class, sfields_)) == nullptr); SetFieldPtr(OFFSET_OF_OBJECT_MEMBER(Class, sfields_), new_sfields); } inline void Class::SetSFieldsPtrUnchecked(LengthPrefixedArray* new_sfields) { SetFieldPtr(OFFSET_OF_OBJECT_MEMBER(Class, sfields_), new_sfields); } inline ArtField* Class::GetStaticField(uint32_t i) { return &GetSFieldsPtr()->At(i); } inline ArtField* Class::GetInstanceField(uint32_t i) { return &GetIFieldsPtr()->At(i); } template inline uint32_t Class::GetReferenceInstanceOffsets() { DCHECK(IsResolved() || IsErroneous()); return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, reference_instance_offsets_)); } inline void Class::SetClinitThreadId(pid_t new_clinit_thread_id) { SetField32Transaction(OFFSET_OF_OBJECT_MEMBER(Class, clinit_thread_id_), new_clinit_thread_id); } template inline ObjPtr Class::GetName() { return GetFieldObject( OFFSET_OF_OBJECT_MEMBER(Class, name_)); } inline void Class::SetName(ObjPtr name) { SetFieldObjectTransaction(OFFSET_OF_OBJECT_MEMBER(Class, name_), name); } template inline Primitive::Type Class::GetPrimitiveType() { static_assert(sizeof(Primitive::Type) == sizeof(int32_t), "art::Primitive::Type and int32_t have different sizes."); int32_t v32 = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, primitive_type_)); Primitive::Type type = static_cast(v32 & kPrimitiveTypeMask); DCHECK_EQ(static_cast(v32 >> kPrimitiveTypeSizeShiftShift), Primitive::ComponentSizeShift(type)); return type; } template inline size_t Class::GetPrimitiveTypeSizeShift() { static_assert(sizeof(Primitive::Type) == sizeof(int32_t), "art::Primitive::Type and int32_t have different sizes."); int32_t v32 = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, primitive_type_)); size_t size_shift = static_cast(v32 >> kPrimitiveTypeSizeShiftShift); DCHECK_EQ(size_shift, Primitive::ComponentSizeShift(static_cast(v32 & kPrimitiveTypeMask))); return size_shift; } template inline void Class::VerifyOverflowReferenceBitmap() { // Can't reliably access super-classes during CMC compaction. if (Runtime::Current() != nullptr && Runtime::Current()->GetHeap() != nullptr && Runtime::Current()->GetHeap()->IsPerformingUffdCompaction()) { return; } CHECK(!IsVariableSize()); ObjPtr klass; ObjPtr super_class; size_t num_bits = (RoundUp(GetObjectSize(), sizeof(mirror::HeapReference)) - mirror::kObjectHeaderSize) / sizeof(mirror::HeapReference); std::vector check_bitmap(num_bits, false); for (klass = this; klass != nullptr; klass = super_class) { super_class = klass->GetSuperClass(); if (klass->NumReferenceInstanceFields() != 0) { break; } } if (super_class != nullptr) { std::vector> klasses; for (; klass != nullptr; klass = super_class) { super_class = klass->GetSuperClass(); if (super_class != nullptr) { klasses.push_back(klass); } } for (auto iter = klasses.rbegin(); iter != klasses.rend(); iter++) { klass = *iter; size_t idx = (klass->GetFirstReferenceInstanceFieldOffset() .Uint32Value() - mirror::kObjectHeaderSize) / sizeof(mirror::HeapReference); uint32_t num_refs = klass->NumReferenceInstanceFields(); for (uint32_t i = 0; i < num_refs; i++) { check_bitmap[idx++] = true; } CHECK_LE(idx, num_bits) << PrettyClass(); } } uint32_t ref_offsets = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, reference_instance_offsets_)); CHECK_NE(ref_offsets, 0u) << PrettyClass(); CHECK((ref_offsets & kVisitReferencesSlowpathMask) != 0) << PrettyClass(); uint32_t bitmap_num_words = ref_offsets & ~kVisitReferencesSlowpathMask; uint32_t* overflow_bitmap = reinterpret_cast( reinterpret_cast(this) + (GetClassSize() - bitmap_num_words * sizeof(uint32_t))); for (uint32_t i = 0, field_offset = 0; i < bitmap_num_words; i++, field_offset += 32) { ref_offsets = overflow_bitmap[i]; uint32_t check_bitmap_idx = field_offset; // Confirm that all the bits in check_bitmap that ought to be set, are set. while (ref_offsets != 0) { if ((ref_offsets & 1) != 0) { CHECK(check_bitmap[check_bitmap_idx]) << PrettyClass() << " i:" << i << " field_offset:" << field_offset << " check_bitmap_idx:" << check_bitmap_idx << " bitmap_word:" << overflow_bitmap[i]; check_bitmap[check_bitmap_idx] = false; } ref_offsets >>= 1; check_bitmap_idx++; } } // Confirm that there is no other bit set. std::ostringstream oss; bool found = false; for (size_t i = 0; i < check_bitmap.size(); i++) { if (check_bitmap[i]) { if (!found) { DumpClass(oss, kDumpClassFullDetail); oss << " set-bits:"; } found = true; oss << i << ","; } } if (found) { oss << " stored-bitmap:"; for (size_t i = 0; i < bitmap_num_words; i++) { oss << overflow_bitmap[i] << ":"; } LOG(FATAL) << oss.str(); } } inline size_t Class::AdjustClassSizeForReferenceOffsetBitmapDuringLinking(ObjPtr klass, size_t class_size) { if (klass->IsInstantiable()) { // Find the first class with non-zero instance field count and its super-class' // object-size together will tell us the required size. for (ObjPtr k = klass; k != nullptr; k = k->GetSuperClass()) { size_t num_reference_fields = k->NumReferenceInstanceFieldsDuringLinking(); if (num_reference_fields != 0) { ObjPtr super = k->GetSuperClass(); // Leave it for mirror::Object (the class field is handled specially). if (super != nullptr) { // All of the fields that contain object references are guaranteed to be grouped in // memory starting at an appropriately aligned address after super class object data. uint32_t start_offset = RoundUp(super->GetObjectSize(), sizeof(mirror::HeapReference)); uint32_t start_bit = (start_offset - mirror::kObjectHeaderSize) / sizeof(mirror::HeapReference); if (start_bit + num_reference_fields > 31) { // Alignment that maybe required at the end of static fields smaller than 32-bit. class_size = RoundUp(class_size, sizeof(uint32_t)); // 32-bit words required for the overflow bitmap. class_size += RoundUp(start_bit + num_reference_fields, 32) / 32 * sizeof(uint32_t); } } break; } } } return class_size; } inline uint32_t Class::ComputeClassSize(bool has_embedded_vtable, uint32_t num_vtable_entries, uint32_t num_8bit_static_fields, uint32_t num_16bit_static_fields, uint32_t num_32bit_static_fields, uint32_t num_64bit_static_fields, uint32_t num_ref_static_fields, uint32_t num_ref_bitmap_entries, PointerSize pointer_size) { // Space used by java.lang.Class and its instance fields. uint32_t size = sizeof(Class); // Space used by embedded tables. if (has_embedded_vtable) { size = RoundUp(size + sizeof(uint32_t), static_cast(pointer_size)); size += static_cast(pointer_size); // size of pointer to IMT size += num_vtable_entries * VTableEntrySize(pointer_size); } // Space used by reference statics. size += num_ref_static_fields * kHeapReferenceSize; if (!IsAligned<8>(size) && num_64bit_static_fields > 0) { uint32_t gap = 8 - (size & 0x7); size += gap; // will be padded // Shuffle 4-byte fields forward. while (gap >= sizeof(uint32_t) && num_32bit_static_fields != 0) { --num_32bit_static_fields; gap -= sizeof(uint32_t); } // Shuffle 2-byte fields forward. while (gap >= sizeof(uint16_t) && num_16bit_static_fields != 0) { --num_16bit_static_fields; gap -= sizeof(uint16_t); } // Shuffle byte fields forward. while (gap >= sizeof(uint8_t) && num_8bit_static_fields != 0) { --num_8bit_static_fields; gap -= sizeof(uint8_t); } } // Guaranteed to be at least 4 byte aligned. No need for further alignments. // Space used for primitive static fields. size += num_8bit_static_fields * sizeof(uint8_t) + num_16bit_static_fields * sizeof(uint16_t) + num_32bit_static_fields * sizeof(uint32_t) + num_64bit_static_fields * sizeof(uint64_t); // Space used by reference-offset bitmap. if (num_ref_bitmap_entries > 0) { size = RoundUp(size, sizeof(uint32_t)); size += num_ref_bitmap_entries * sizeof(uint32_t); } return size; } template inline bool Class::IsClassClass() { // OK to look at from-space copies since java.lang.Class.class is non-moveable // (even when running without boot image, see ClassLinker::InitWithoutImage()) // and we're reading it for comparison only. See ReadBarrierOption. ObjPtr java_lang_Class = GetClass(); return this == java_lang_Class; } inline const DexFile& Class::GetDexFile() { // From-space version is the same as the to-space version since the dex file never changes. // Avoiding the read barrier here is important to prevent recursive AssertToSpaceInvariant issues // from PrettyTypeOf. return *GetDexCache()->GetDexFile(); } inline std::string_view Class::GetDescriptorView() { DCHECK(!IsArrayClass()); DCHECK(!IsPrimitive()); DCHECK(!IsProxyClass()); return GetDexFile().GetTypeDescriptorView(GetDexTypeIndex()); } inline bool Class::DescriptorEquals(std::string_view match) { ObjPtr klass = this; while (klass->IsArrayClass()) { if (UNLIKELY(match.empty()) || match[0] != '[') { return false; } match.remove_prefix(1u); // No read barrier needed, we're reading a chain of constant references for comparison // with null. Then we follow up below with reading constant references to read constant // primitive data in both proxy and non-proxy paths. See ReadBarrierOption. klass = klass->GetComponentType(); } if (klass->IsPrimitive()) { return match.length() == 1u && match[0] == Primitive::Descriptor(klass->GetPrimitiveType())[0]; } else if (UNLIKELY(klass->IsProxyClass())) { return klass->ProxyDescriptorEquals(match); } else { const DexFile& dex_file = klass->GetDexFile(); const dex::TypeId& type_id = dex_file.GetTypeId(klass->GetDexTypeIndex()); return dex_file.GetTypeDescriptorView(type_id) == match; } } inline uint32_t Class::DescriptorHash() { // No read barriers needed, we're reading a chain of constant references for comparison with null // and retrieval of constant primitive data. See `ReadBarrierOption` and `Class::GetDescriptor()`. ObjPtr klass = this; uint32_t hash = StartModifiedUtf8Hash(); while (klass->IsArrayClass()) { klass = klass->GetComponentType(); hash = UpdateModifiedUtf8Hash(hash, '['); } if (UNLIKELY(klass->IsProxyClass())) { hash = UpdateHashForProxyClass(hash, klass); } else if (klass->IsPrimitive()) { hash = UpdateModifiedUtf8Hash(hash, Primitive::Descriptor(klass->GetPrimitiveType())[0]); } else { const DexFile& dex_file = klass->GetDexFile(); const dex::TypeId& type_id = dex_file.GetTypeId(klass->GetDexTypeIndex()); std::string_view descriptor = dex_file.GetTypeDescriptorView(type_id); hash = UpdateModifiedUtf8Hash(hash, descriptor); } if (kIsDebugBuild) { std::string temp; CHECK_EQ(hash, ComputeModifiedUtf8Hash(GetDescriptor(&temp))); } return hash; } inline void Class::AssertInitializedOrInitializingInThread(Thread* self) { if (kIsDebugBuild && !IsInitialized()) { CHECK(IsInitializing()) << PrettyClass() << " is not initializing: " << GetStatus(); CHECK_EQ(GetClinitThreadId(), self->GetTid()) << PrettyClass() << " is initializing in a different thread"; } } inline ObjPtr> Class::GetProxyInterfaces() { CHECK(IsProxyClass()); // First static field. ArtField* field = GetStaticField(0); DCHECK_STREQ(field->GetName(), "interfaces"); MemberOffset field_offset = field->GetOffset(); return GetFieldObject>(field_offset); } inline ObjPtr>> Class::GetProxyThrows() { CHECK(IsProxyClass()); // Second static field. ArtField* field = GetStaticField(1); DCHECK_STREQ(field->GetName(), "throws"); MemberOffset field_offset = field->GetOffset(); return GetFieldObject>>(field_offset); } inline bool Class::IsBootStrapClassLoaded() { // No read barrier is needed for comparing with null. See ReadBarrierOption. return GetClassLoader() == nullptr; } inline void Class::InitializeClassVisitor::operator()(ObjPtr