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gerrit-public.fairphone.software / platform / art / c151f90d7e31a59675e118c5aff20c8d3ad50ad0 / . / src / object.h
blob: c1e46671e93c814b503c333cda0abc5b9d1fdfa9 [file] [log] [blame]
/*
* 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_SRC_OBJECT_H_
#define ART_SRC_OBJECT_H_
#include <iosfwd>
#include <vector>
#include "UniquePtr.h"
#include "atomic.h"
#include "casts.h"
#include "globals.h"
#include "heap.h"
#include "logging.h"
#include "macros.h"
#include "offsets.h"
#include "primitive.h"
#include "runtime.h"
#include "stringpiece.h"
#include "thread.h"
#include "utf.h"
namespace art {
class Array;
class Class;
class ClassLoader;
class CodeAndDirectMethods;
class DexCache;
class Field;
class InterfaceEntry;
class Monitor;
class Method;
class Object;
class StaticStorageBase;
class String;
template<class T> class ObjectArray;
template<class T> class PrimitiveArray;
typedef PrimitiveArray<uint8_t> BooleanArray;
typedef PrimitiveArray<int8_t> ByteArray;
typedef PrimitiveArray<uint16_t> CharArray;
typedef PrimitiveArray<double> DoubleArray;
typedef PrimitiveArray<float> FloatArray;
typedef PrimitiveArray<int32_t> IntArray;
typedef PrimitiveArray<int64_t> LongArray;
typedef PrimitiveArray<int16_t> ShortArray;
union JValue {
// We default initialize JValue instances to all-zeros.
JValue() : j(0) {}
int8_t GetB() const { return b; }
void SetB(int8_t new_b) {
i = ((static_cast<int32_t>(new_b) << 24) >> 24); // Sign-extend.
}
uint16_t GetC() const { return c; }
void SetC(uint16_t new_c) { c = new_c; }
double GetD() const { return d; }
void SetD(double new_d) { d = new_d; }
float GetF() const { return f; }
void SetF(float new_f) { f = new_f; }
int32_t GetI() const { return i; }
void SetI(int32_t new_i) { i = new_i; }
int64_t GetJ() const { return j; }
void SetJ(int64_t new_j) { j = new_j; }
Object* GetL() const { return l; }
void SetL(Object* new_l) { l = new_l; }
int16_t GetS() const { return s; }
void SetS(int16_t new_s) {
i = ((static_cast<int32_t>(new_s) << 16) >> 16); // Sign-extend.
}
uint8_t GetZ() const { return z; }
void SetZ(uint8_t new_z) { z = new_z; }
private:
uint8_t z;
int8_t b;
uint16_t c;
int16_t s;
int32_t i;
int64_t j;
float f;
double d;
Object* l;
};
#if defined(ART_USE_LLVM_COMPILER)
namespace compiler_llvm {
class InferredRegCategoryMap;
} // namespace compiler_llvm
#endif
static const uint32_t kAccPublic = 0x0001; // class, field, method, ic
static const uint32_t kAccPrivate = 0x0002; // field, method, ic
static const uint32_t kAccProtected = 0x0004; // field, method, ic
static const uint32_t kAccStatic = 0x0008; // field, method, ic
static const uint32_t kAccFinal = 0x0010; // class, field, method, ic
static const uint32_t kAccSynchronized = 0x0020; // method (only allowed on natives)
static const uint32_t kAccSuper = 0x0020; // class (not used in dex)
static const uint32_t kAccVolatile = 0x0040; // field
static const uint32_t kAccBridge = 0x0040; // method (1.5)
static const uint32_t kAccTransient = 0x0080; // field
static const uint32_t kAccVarargs = 0x0080; // method (1.5)
static const uint32_t kAccNative = 0x0100; // method
static const uint32_t kAccInterface = 0x0200; // class, ic
static const uint32_t kAccAbstract = 0x0400; // class, method, ic
static const uint32_t kAccStrict = 0x0800; // method
static const uint32_t kAccSynthetic = 0x1000; // field, method, ic
static const uint32_t kAccAnnotation = 0x2000; // class, ic (1.5)
static const uint32_t kAccEnum = 0x4000; // class, field, ic (1.5)
static const uint32_t kAccMiranda = 0x8000; // method
static const uint32_t kAccJavaFlagsMask = 0xffff; // bits set from Java sources (low 16)
static const uint32_t kAccConstructor = 0x00010000; // method (dex only)
static const uint32_t kAccDeclaredSynchronized = 0x00020000; // method (dex only)
static const uint32_t kAccClassIsProxy = 0x00040000; // class (dex only)
static const uint32_t kAccWritable = 0x80000000; // method (dex only)
// Special runtime-only flags.
// Note: if only kAccClassIsReference is set, we have a soft reference.
static const uint32_t kAccClassIsFinalizable = 0x80000000; // class/ancestor overrides finalize()
static const uint32_t kAccClassIsReference = 0x08000000; // class is a soft/weak/phantom ref
static const uint32_t kAccClassIsWeakReference = 0x04000000; // class is a weak reference
static const uint32_t kAccClassIsFinalizerReference = 0x02000000; // class is a finalizer reference
static const uint32_t kAccClassIsPhantomReference = 0x01000000; // class is a phantom reference
static const uint32_t kAccReferenceFlagsMask = (kAccClassIsReference
| kAccClassIsWeakReference
| kAccClassIsFinalizerReference
| kAccClassIsPhantomReference);
/*
* Definitions for packing refOffsets in Class.
*/
/*
* A magic value for refOffsets. Ignore the bits and walk the super
* chain when this is the value.
* [This is an unlikely "natural" value, since it would be 30 non-ref instance
* fields followed by 2 ref instance fields.]
*/
#define CLASS_WALK_SUPER ((unsigned int)(3))
#define CLASS_BITS_PER_WORD (sizeof(unsigned long int) * 8)
#define CLASS_OFFSET_ALIGNMENT 4
#define CLASS_HIGH_BIT ((unsigned int)1 << (CLASS_BITS_PER_WORD - 1))
/*
* Given an offset, return the bit number which would encode that offset.
* Local use only.
*/
#define _CLASS_BIT_NUMBER_FROM_OFFSET(byteOffset) \
((unsigned int)(byteOffset) / \
CLASS_OFFSET_ALIGNMENT)
/*
* Is the given offset too large to be encoded?
*/
#define CLASS_CAN_ENCODE_OFFSET(byteOffset) \
(_CLASS_BIT_NUMBER_FROM_OFFSET(byteOffset) < CLASS_BITS_PER_WORD)
/*
* Return a single bit, encoding the offset.
* Undefined if the offset is too large, as defined above.
*/
#define CLASS_BIT_FROM_OFFSET(byteOffset) \
(CLASS_HIGH_BIT >> _CLASS_BIT_NUMBER_FROM_OFFSET(byteOffset))
/*
* Return an offset, given a bit number as returned from CLZ.
*/
#define CLASS_OFFSET_FROM_CLZ(rshift) \
MemberOffset((static_cast<int>(rshift) * CLASS_OFFSET_ALIGNMENT))
#define OFFSET_OF_OBJECT_MEMBER(type, field) \
MemberOffset(OFFSETOF_MEMBER(type, field))
// Classes shared with the managed side of the world need to be packed
// so that they don't have extra platform specific padding.
#define MANAGED PACKED
// C++ mirror of java.lang.Object
class MANAGED Object {
public:
static MemberOffset ClassOffset() {
return OFFSET_OF_OBJECT_MEMBER(Object, klass_);
}
Class* GetClass() const {
return GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Object, klass_), false);
}
void SetClass(Class* new_klass);
bool InstanceOf(const Class* klass) const;
size_t SizeOf() const;
Object* Clone();
static MemberOffset MonitorOffset() {
return OFFSET_OF_OBJECT_MEMBER(Object, monitor_);
}
volatile int32_t* GetRawLockWordAddress() {
byte* raw_addr = reinterpret_cast<byte*>(this) + OFFSET_OF_OBJECT_MEMBER(Object, monitor_).Int32Value();
int32_t* word_addr = reinterpret_cast<int32_t*>(raw_addr);
return const_cast<volatile int32_t*>(word_addr);
}
uint32_t GetThinLockId();
void MonitorEnter(Thread* thread);
bool MonitorExit(Thread* thread);
void Notify();
void NotifyAll();
void Wait(int64_t timeout);
void Wait(int64_t timeout, int32_t nanos);
bool IsClass() const;
Class* AsClass() {
DCHECK(IsClass());
return down_cast<Class*>(this);
}
const Class* AsClass() const {
DCHECK(IsClass());
return down_cast<const Class*>(this);
}
bool IsObjectArray() const;
template<class T>
ObjectArray<T>* AsObjectArray();
template<class T>
const ObjectArray<T>* AsObjectArray() const;
bool IsArrayInstance() const;
Array* AsArray() {
DCHECK(IsArrayInstance());
return down_cast<Array*>(this);
}
const Array* AsArray() const {
DCHECK(IsArrayInstance());
return down_cast<const Array*>(this);
}
String* AsString();
bool IsMethod() const;
Method* AsMethod() {
DCHECK(IsMethod());
return down_cast<Method*>(this);
}
const Method* AsMethod() const {
DCHECK(IsMethod());
return down_cast<const Method*>(this);
}
bool IsField() const;
Field* AsField() {
DCHECK(IsField());
return down_cast<Field*>(this);
}
const Field* AsField() const {
DCHECK(IsField());
return down_cast<const Field*>(this);
}
bool IsReferenceInstance() const;
bool IsWeakReferenceInstance() const;
bool IsSoftReferenceInstance() const;
bool IsFinalizerReferenceInstance() const;
bool IsPhantomReferenceInstance() const;
// Accessors for Java type fields
template<class T>
T GetFieldObject(MemberOffset field_offset, bool is_volatile) const {
DCHECK(Thread::Current() == NULL || Thread::Current()->CanAccessDirectReferences());
T result = reinterpret_cast<T>(GetField32(field_offset, is_volatile));
Runtime::Current()->GetHeap()->VerifyObject(result);
return result;
}
void SetFieldObject(MemberOffset field_offset, const Object* new_value, bool is_volatile, bool this_is_valid = true) {
Runtime::Current()->GetHeap()->VerifyObject(new_value);
SetField32(field_offset, reinterpret_cast<uint32_t>(new_value), is_volatile, this_is_valid);
if (new_value != NULL) {
Runtime::Current()->GetHeap()->WriteBarrierField(this, field_offset, new_value);
}
}
uint32_t GetField32(MemberOffset field_offset, bool is_volatile) const {
Runtime::Current()->GetHeap()->VerifyObject(this);
const byte* raw_addr = reinterpret_cast<const byte*>(this) + field_offset.Int32Value();
const int32_t* word_addr = reinterpret_cast<const int32_t*>(raw_addr);
if (UNLIKELY(is_volatile)) {
return android_atomic_acquire_load(word_addr);
} else {
return *word_addr;
}
}
void SetField32(MemberOffset field_offset, uint32_t new_value, bool is_volatile, bool this_is_valid = true) {
if (this_is_valid) {
Runtime::Current()->GetHeap()->VerifyObject(this);
}
byte* raw_addr = reinterpret_cast<byte*>(this) + field_offset.Int32Value();
uint32_t* word_addr = reinterpret_cast<uint32_t*>(raw_addr);
if (UNLIKELY(is_volatile)) {
/*
* TODO: add an android_atomic_synchronization_store() function and
* use it in the 32-bit volatile set handlers. On some platforms we
* can use a fast atomic instruction and avoid the barriers.
*/
ANDROID_MEMBAR_STORE();
*word_addr = new_value;
ANDROID_MEMBAR_FULL();
} else {
*word_addr = new_value;
}
}
uint64_t GetField64(MemberOffset field_offset, bool is_volatile) const {
Runtime::Current()->GetHeap()->VerifyObject(this);
const byte* raw_addr = reinterpret_cast<const byte*>(this) + field_offset.Int32Value();
const int64_t* addr = reinterpret_cast<const int64_t*>(raw_addr);
if (UNLIKELY(is_volatile)) {
uint64_t result = QuasiAtomic::Read64(addr);
ANDROID_MEMBAR_FULL();
return result;
} else {
return *addr;
}
}
void SetField64(MemberOffset field_offset, uint64_t new_value, bool is_volatile) {
Runtime::Current()->GetHeap()->VerifyObject(this);
byte* raw_addr = reinterpret_cast<byte*>(this) + field_offset.Int32Value();
int64_t* addr = reinterpret_cast<int64_t*>(raw_addr);
if (UNLIKELY(is_volatile)) {
ANDROID_MEMBAR_STORE();
QuasiAtomic::Swap64(new_value, addr);
// Post-store barrier not required due to use of atomic op or mutex.
} else {
*addr = new_value;
}
}
protected:
// Accessors for non-Java type fields
template<class T>
T GetFieldPtr(MemberOffset field_offset, bool is_volatile) const {
return reinterpret_cast<T>(GetField32(field_offset, is_volatile));
}
template<typename T>
void SetFieldPtr(MemberOffset field_offset, T new_value, bool is_volatile, bool this_is_valid = true) {
SetField32(field_offset, reinterpret_cast<uint32_t>(new_value), is_volatile, this_is_valid);
}
private:
Class* klass_;
uint32_t monitor_;
friend class ImageWriter; // for abusing monitor_ directly
friend struct ObjectOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Object);
};
struct ObjectIdentityHash {
size_t operator()(const Object* const& obj) const {
#ifdef MOVING_GARBAGE_COLLECTOR
// TODO: we'll need to use the Object's internal concept of identity
UNIMPLEMENTED(FATAL);
#endif
return reinterpret_cast<size_t>(obj);
}
};
// C++ mirror of java.lang.reflect.Field
class MANAGED Field : public Object {
public:
Class* GetDeclaringClass() const;
void SetDeclaringClass(Class *new_declaring_class);
uint32_t GetAccessFlags() const;
void SetAccessFlags(uint32_t new_access_flags) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Field, access_flags_), new_access_flags, false);
}
bool IsPublic() const {
return (GetAccessFlags() & kAccPublic) != 0;
}
bool IsStatic() const {
return (GetAccessFlags() & kAccStatic) != 0;
}
bool IsFinal() const {
return (GetAccessFlags() & kAccFinal) != 0;
}
uint32_t GetDexFieldIndex() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Field, field_dex_idx_), false);
}
void SetDexFieldIndex(uint32_t new_idx) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Field, field_dex_idx_), new_idx, false);
}
// Offset to field within an Object
MemberOffset GetOffset() const;
static MemberOffset OffsetOffset() {
return MemberOffset(OFFSETOF_MEMBER(Field, offset_));
}
MemberOffset GetOffsetDuringLinking() const;
void SetOffset(MemberOffset num_bytes);
// field access, null object for static fields
bool GetBoolean(const Object* object) const;
void SetBoolean(Object* object, bool z) const;
int8_t GetByte(const Object* object) const;
void SetByte(Object* object, int8_t b) const;
uint16_t GetChar(const Object* object) const;
void SetChar(Object* object, uint16_t c) const;
int16_t GetShort(const Object* object) const;
void SetShort(Object* object, int16_t s) const;
int32_t GetInt(const Object* object) const;
void SetInt(Object* object, int32_t i) const;
int64_t GetLong(const Object* object) const;
void SetLong(Object* object, int64_t j) const;
float GetFloat(const Object* object) const;
void SetFloat(Object* object, float f) const;
double GetDouble(const Object* object) const;
void SetDouble(Object* object, double d) const;
Object* GetObject(const Object* object) const;
void SetObject(Object* object, const Object* l) const;
// raw field accesses
uint32_t Get32(const Object* object) const;
void Set32(Object* object, uint32_t new_value) const;
uint64_t Get64(const Object* object) const;
void Set64(Object* object, uint64_t new_value) const;
Object* GetObj(const Object* object) const;
void SetObj(Object* object, const Object* new_value) const;
static Class* GetJavaLangReflectField() {
DCHECK(java_lang_reflect_Field_ != NULL);
return java_lang_reflect_Field_;
}
static void SetClass(Class* java_lang_reflect_Field);
static void ResetClass();
bool IsVolatile() const {
return (GetAccessFlags() & kAccVolatile) != 0;
}
private:
// Field order required by test "ValidateFieldOrderOfJavaCppUnionClasses".
// The class we are a part of
Class* declaring_class_;
uint32_t access_flags_;
// Dex cache index of field id
uint32_t field_dex_idx_;
// Offset of field within an instance or in the Class' static fields
uint32_t offset_;
static Class* java_lang_reflect_Field_;
friend struct FieldOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Field);
};
// C++ mirror of java.lang.reflect.Method and java.lang.reflect.Constructor
class MANAGED Method : public Object {
public:
// An function that invokes a method with an array of its arguments.
typedef void InvokeStub(const Method* method,
Object* obj,
Thread* thread,
JValue* args,
JValue* result);
Class* GetDeclaringClass() const;
void SetDeclaringClass(Class *new_declaring_class);
static MemberOffset DeclaringClassOffset() {
return MemberOffset(OFFSETOF_MEMBER(Method, declaring_class_));
}
uint32_t GetAccessFlags() const;
void SetAccessFlags(uint32_t new_access_flags) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, access_flags_), new_access_flags, false);
}
// Returns true if the method is declared public.
bool IsPublic() const {
return (GetAccessFlags() & kAccPublic) != 0;
}
// Returns true if the method is declared private.
bool IsPrivate() const {
return (GetAccessFlags() & kAccPrivate) != 0;
}
// Returns true if the method is declared static.
bool IsStatic() const {
return (GetAccessFlags() & kAccStatic) != 0;
}
// Returns true if the method is a constructor.
bool IsConstructor() const {
return (GetAccessFlags() & kAccConstructor) != 0;
}
// Returns true if the method is static, private, or a constructor.
bool IsDirect() const {
return IsDirect(GetAccessFlags());
}
static bool IsDirect(uint32_t access_flags) {
return (access_flags & (kAccStatic | kAccPrivate | kAccConstructor)) != 0;
}
// Returns true if the method is declared synchronized.
bool IsSynchronized() const {
uint32_t synchonized = kAccSynchronized | kAccDeclaredSynchronized;
return (GetAccessFlags() & synchonized) != 0;
}
bool IsFinal() const {
return (GetAccessFlags() & kAccFinal) != 0;
}
bool IsMiranda() const {
return (GetAccessFlags() & kAccMiranda) != 0;
}
bool IsNative() const {
return (GetAccessFlags() & kAccNative) != 0;
}
bool IsAbstract() const {
return (GetAccessFlags() & kAccAbstract) != 0;
}
bool IsSynthetic() const {
return (GetAccessFlags() & kAccSynthetic) != 0;
}
bool IsProxyMethod() const;
uint16_t GetMethodIndex() const;
size_t GetVtableIndex() const {
return GetMethodIndex();
}
void SetMethodIndex(uint16_t new_method_index) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, method_index_), new_method_index, false);
}
static MemberOffset MethodIndexOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, method_index_);
}
uint32_t GetCodeItemOffset() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, code_item_offset_), false);
}
void SetCodeItemOffset(uint32_t new_code_off) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, code_item_offset_), new_code_off, false);
}
// Number of 32bit registers that would be required to hold all the arguments
static size_t NumArgRegisters(const StringPiece& shorty);
uint32_t GetDexMethodIndex() const;
void SetDexMethodIndex(uint32_t new_idx) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, method_dex_index_), new_idx, false);
}
ObjectArray<String>* GetDexCacheStrings() const;
void SetDexCacheStrings(ObjectArray<String>* new_dex_cache_strings);
static MemberOffset DexCacheStringsOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, dex_cache_strings_);
}
static MemberOffset DexCacheResolvedMethodsOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, dex_cache_resolved_methods_);
}
static MemberOffset DexCacheResolvedTypesOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, dex_cache_resolved_types_);
}
static MemberOffset DexCacheInitializedStaticStorageOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method,
dex_cache_initialized_static_storage_);
}
ObjectArray<Method>* GetDexCacheResolvedMethods() const;
void SetDexCacheResolvedMethods(ObjectArray<Method>* new_dex_cache_methods);
ObjectArray<Class>* GetDexCacheResolvedTypes() const;
void SetDexCacheResolvedTypes(ObjectArray<Class>* new_dex_cache_types);
ObjectArray<StaticStorageBase>* GetDexCacheInitializedStaticStorage() const;
void SetDexCacheInitializedStaticStorage(ObjectArray<StaticStorageBase>* new_value);
// Find the method that this method overrides
Method* FindOverriddenMethod() const;
void Invoke(Thread* self, Object* receiver, JValue* args, JValue* result) const;
const void* GetCode() const {
return GetFieldPtr<const void*>(OFFSET_OF_OBJECT_MEMBER(Method, code_), false);
}
void SetCode(const void* code) {
SetFieldPtr<const void*>(OFFSET_OF_OBJECT_MEMBER(Method, code_), code, false);
}
uint32_t GetCodeSize() const {
DCHECK(!IsRuntimeMethod() && !IsProxyMethod()) << PrettyMethod(this);
uintptr_t code = reinterpret_cast<uintptr_t>(GetCode());
if (code == 0) {
return 0;
}
// TODO: make this Thumb2 specific
code &= ~0x1;
return reinterpret_cast<uint32_t*>(code)[-1];
}
bool IsWithinCode(uintptr_t pc) const {
uintptr_t code = reinterpret_cast<uintptr_t>(GetCode());
if (code == 0) {
return pc == 0;
}
return (code <= pc && pc < code + GetCodeSize());
}
void AssertPcIsWithinCode(uintptr_t pc) const;
uint32_t GetOatCodeOffset() const {
DCHECK(!Runtime::Current()->IsStarted());
return reinterpret_cast<uint32_t>(GetCode());
}
void SetOatCodeOffset(uint32_t code_offset) {
DCHECK(!Runtime::Current()->IsStarted());
SetCode(reinterpret_cast<void*>(code_offset));
}
static MemberOffset GetCodeOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, code_);
}
const uint32_t* GetMappingTable() const {
const uint32_t* map = GetMappingTableRaw();
if (map == NULL) {
return map;
}
return map + 1;
}
uint32_t GetMappingTableLength() const {
const uint32_t* map = GetMappingTableRaw();
if (map == NULL) {
return 0;
}
return *map;
}
const uint32_t* GetMappingTableRaw() const {
return GetFieldPtr<const uint32_t*>(OFFSET_OF_OBJECT_MEMBER(Method, mapping_table_), false);
}
void SetMappingTable(const uint32_t* mapping_table) {
SetFieldPtr<const uint32_t*>(OFFSET_OF_OBJECT_MEMBER(Method, mapping_table_),
mapping_table, false);
}
uint32_t GetOatMappingTableOffset() const {
DCHECK(!Runtime::Current()->IsStarted());
return reinterpret_cast<uint32_t>(GetMappingTableRaw());
}
void SetOatMappingTableOffset(uint32_t mapping_table_offset) {
DCHECK(!Runtime::Current()->IsStarted());
SetMappingTable(reinterpret_cast<const uint32_t*>(mapping_table_offset));
}
// Callers should wrap the uint16_t* in a VmapTable instance for convenient access.
const uint16_t* GetVmapTableRaw() const {
return GetFieldPtr<const uint16_t*>(OFFSET_OF_OBJECT_MEMBER(Method, vmap_table_), false);
}
void SetVmapTable(const uint16_t* vmap_table) {
SetFieldPtr<const uint16_t*>(OFFSET_OF_OBJECT_MEMBER(Method, vmap_table_), vmap_table, false);
}
uint32_t GetOatVmapTableOffset() const {
DCHECK(!Runtime::Current()->IsStarted());
return reinterpret_cast<uint32_t>(GetVmapTableRaw());
}
void SetOatVmapTableOffset(uint32_t vmap_table_offset) {
DCHECK(!Runtime::Current()->IsStarted());
SetVmapTable(reinterpret_cast<uint16_t*>(vmap_table_offset));
}
const uint8_t* GetGcMap() const {
const uint8_t* gc_map_raw = GetGcMapRaw();
if (gc_map_raw == NULL) {
return gc_map_raw;
}
return gc_map_raw + sizeof(uint32_t);
}
uint32_t GetGcMapLength() const {
const uint8_t* gc_map_raw = GetGcMapRaw();
if (gc_map_raw == NULL) {
return 0;
}
return static_cast<uint32_t>((gc_map_raw[0] << 24) |
(gc_map_raw[1] << 16) |
(gc_map_raw[2] << 8) |
(gc_map_raw[3] << 0));
}
const uint8_t* GetGcMapRaw() const {
return GetFieldPtr<uint8_t*>(OFFSET_OF_OBJECT_MEMBER(Method, gc_map_), false);
}
void SetGcMap(const uint8_t* data) {
SetFieldPtr<const uint8_t*>(OFFSET_OF_OBJECT_MEMBER(Method, gc_map_), data, false);
}
uint32_t GetOatGcMapOffset() const {
DCHECK(!Runtime::Current()->IsStarted());
return reinterpret_cast<uint32_t>(GetGcMapRaw());
}
void SetOatGcMapOffset(uint32_t gc_map_offset) {
DCHECK(!Runtime::Current()->IsStarted());
SetGcMap(reinterpret_cast<uint8_t*>(gc_map_offset));
}
size_t GetFrameSizeInBytes() const {
DCHECK_EQ(sizeof(size_t), sizeof(uint32_t));
size_t result = GetField32(OFFSET_OF_OBJECT_MEMBER(Method, frame_size_in_bytes_), false);
DCHECK_LE(static_cast<size_t>(kStackAlignment), result);
return result;
}
void SetFrameSizeInBytes(size_t new_frame_size_in_bytes) {
DCHECK_EQ(sizeof(size_t), sizeof(uint32_t));
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, frame_size_in_bytes_),
new_frame_size_in_bytes, false);
}
size_t GetReturnPcOffsetInBytes() const {
return GetFrameSizeInBytes() - kPointerSize;
}
bool IsRegistered() const;
void RegisterNative(Thread* self, const void* native_method);
void UnregisterNative(Thread* self);
static MemberOffset NativeMethodOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, native_method_);
}
const void* GetNativeMethod() const {
return reinterpret_cast<const void*>(GetField32(NativeMethodOffset(), false));
}
// Native to managed invocation stub entry point
const InvokeStub* GetInvokeStub() const {
InvokeStub* result = GetFieldPtr<InvokeStub*>(
OFFSET_OF_OBJECT_MEMBER(Method, invoke_stub_), false);
// TODO: DCHECK(result != NULL); should be ahead of time compiled
return result;
}
void SetInvokeStub(InvokeStub* invoke_stub) {
SetFieldPtr<const InvokeStub*>(OFFSET_OF_OBJECT_MEMBER(Method, invoke_stub_),
invoke_stub, false);
}
uint32_t GetInvokeStubSize() const {
const uint32_t* invoke_stub = reinterpret_cast<const uint32_t*>(GetInvokeStub());
if (invoke_stub == NULL) {
return 0;
}
return invoke_stub[-1];
}
uint32_t GetOatInvokeStubOffset() const {
DCHECK(!Runtime::Current()->IsStarted());
return reinterpret_cast<uint32_t>(GetInvokeStub());
}
void SetOatInvokeStubOffset(uint32_t invoke_stub_offset) {
DCHECK(!Runtime::Current()->IsStarted());
SetInvokeStub(reinterpret_cast<InvokeStub*>(invoke_stub_offset));
}
static MemberOffset GetInvokeStubOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, invoke_stub_);
}
static MemberOffset GetMethodIndexOffset() {
return OFFSET_OF_OBJECT_MEMBER(Method, method_index_);
}
uint32_t GetCoreSpillMask() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, core_spill_mask_), false);
}
void SetCoreSpillMask(uint32_t core_spill_mask) {
// Computed during compilation
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, core_spill_mask_), core_spill_mask, false);
}
uint32_t GetFpSpillMask() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, fp_spill_mask_), false);
}
void SetFpSpillMask(uint32_t fp_spill_mask) {
// Computed during compilation
SetField32(OFFSET_OF_OBJECT_MEMBER(Method, fp_spill_mask_), fp_spill_mask, false);
}
// Is this a CalleSaveMethod or ResolutionMethod and therefore doesn't adhere to normal
// conventions for a method of managed code.
bool IsRuntimeMethod() const {
return GetDexMethodIndex() == DexFile::kDexNoIndex16;
}
// Is this a hand crafted method used for something like describing callee saves?
bool IsCalleeSaveMethod() const {
if (!IsRuntimeMethod()) {
return false;
}
Runtime* runtime = Runtime::Current();
bool result = false;
for (int i = 0; i < Runtime::kLastCalleeSaveType; i++) {
if (this == runtime->GetCalleeSaveMethod(Runtime::CalleeSaveType(i))) {
result = true;
break;
}
}
return result;
}
bool IsResolutionMethod() const {
bool result = this == Runtime::Current()->GetResolutionMethod();
// Check that if we do think it is phony it looks like the resolution method
DCHECK(!result || GetDexMethodIndex() == DexFile::kDexNoIndex16);
return result;
}
// Converts a native PC to a dex PC. TODO: this is a no-op
// until we associate a PC mapping table with each method.
uint32_t ToDexPC(const uintptr_t pc) const;
// Converts a dex PC to a native PC. TODO: this is a no-op
// until we associate a PC mapping table with each method.
uintptr_t ToNativePC(const uint32_t dex_pc) const;
// Find the catch block for the given exception type and dex_pc
uint32_t FindCatchBlock(Class* exception_type, uint32_t dex_pc) const;
static void SetClasses(Class* java_lang_reflect_Constructor, Class* java_lang_reflect_Method);
static Class* GetConstructorClass() {
return java_lang_reflect_Constructor_;
}
static Class* GetMethodClass() {
return java_lang_reflect_Method_;
}
static void ResetClasses();
private:
// Field order required by test "ValidateFieldOrderOfJavaCppUnionClasses".
// The class we are a part of
Class* declaring_class_;
// short cuts to declaring_class_->dex_cache_ member for fast compiled code access
ObjectArray<StaticStorageBase>* dex_cache_initialized_static_storage_;
// short cuts to declaring_class_->dex_cache_ member for fast compiled code access
ObjectArray<Class>* dex_cache_resolved_methods_;
// short cuts to declaring_class_->dex_cache_ member for fast compiled code access
ObjectArray<Class>* dex_cache_resolved_types_;
// short cuts to declaring_class_->dex_cache_ member for fast compiled code access
ObjectArray<String>* dex_cache_strings_;
// Access flags; low 16 bits are defined by spec.
uint32_t access_flags_;
// Compiled code associated with this method for callers from managed code.
// May be compiled managed code or a bridge for invoking a native method.
const void* code_;
// Offset to the CodeItem.
uint32_t code_item_offset_;
// Architecture-dependent register spill mask
uint32_t core_spill_mask_;
// Architecture-dependent register spill mask
uint32_t fp_spill_mask_;
// Total size in bytes of the frame
size_t frame_size_in_bytes_;
// Garbage collection map
const uint8_t* gc_map_;
// Native invocation stub entry point for calling from native to managed code.
const InvokeStub* invoke_stub_;
// Mapping from native pc to dex pc
const uint32_t* mapping_table_;
// Index into method_ids of the dex file associated with this method
uint32_t method_dex_index_;
// For concrete virtual methods, this is the offset of the method in Class::vtable_.
//
// For abstract methods in an interface class, this is the offset of the method in
// "iftable_->Get(n)->GetMethodArray()".
//
// For static and direct methods this is the index in the direct methods table.
uint32_t method_index_;
// The target native method registered with this method
const void* native_method_;
// When a register is promoted into a register, the spill mask holds which registers hold dex
// registers. The first promoted register's corresponding dex register is vmap_table_[1], the Nth
// is vmap_table_[N]. vmap_table_[0] holds the length of the table.
const uint16_t* vmap_table_;
static Class* java_lang_reflect_Constructor_;
static Class* java_lang_reflect_Method_;
friend class ImageWriter; // for relocating code_ and invoke_stub_
friend struct MethodOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Method);
};
class MANAGED Array : public Object {
public:
// A convenience for code that doesn't know the component size,
// and doesn't want to have to work it out itself.
static Array* Alloc(Class* array_class, int32_t component_count);
static Array* Alloc(Class* array_class, int32_t component_count, size_t component_size);
size_t SizeOf() const;
int32_t GetLength() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Array, length_), false);
}
void SetLength(int32_t length) {
CHECK_GE(length, 0);
SetField32(OFFSET_OF_OBJECT_MEMBER(Array, length_), length, false);
}
static MemberOffset LengthOffset() {
return OFFSET_OF_OBJECT_MEMBER(Array, length_);
}
static MemberOffset DataOffset(size_t component_size) {
if (component_size != sizeof(int64_t)) {
return OFFSET_OF_OBJECT_MEMBER(Array, first_element_);
} else {
// Align longs and doubles.
return MemberOffset(OFFSETOF_MEMBER(Array, first_element_) + 4);
}
}
void* GetRawData(size_t component_size) {
intptr_t data = reinterpret_cast<intptr_t>(this) + DataOffset(component_size).Int32Value();
return reinterpret_cast<void*>(data);
}
const void* GetRawData(size_t component_size) const {
intptr_t data = reinterpret_cast<intptr_t>(this) + DataOffset(component_size).Int32Value();
return reinterpret_cast<const void*>(data);
}
protected:
bool IsValidIndex(int32_t index) const {
if (UNLIKELY(index < 0 || index >= length_)) {
return ThrowArrayIndexOutOfBoundsException(index);
}
return true;
}
protected:
bool ThrowArrayIndexOutOfBoundsException(int32_t index) const;
bool ThrowArrayStoreException(Object* object) const;
private:
// The number of array elements.
int32_t length_;
// Marker for the data (used by generated code)
uint32_t first_element_[0];
DISALLOW_IMPLICIT_CONSTRUCTORS(Array);
};
template<class T>
class MANAGED ObjectArray : public Array {
public:
static ObjectArray<T>* Alloc(Class* object_array_class, int32_t length);
T* Get(int32_t i) const;
void Set(int32_t i, T* object);
// Set element without bound and element type checks, to be used in limited
// circumstances, such as during boot image writing
void SetWithoutChecks(int32_t i, T* object);
T* GetWithoutChecks(int32_t i) const;
static void Copy(const ObjectArray<T>* src, int src_pos,
ObjectArray<T>* dst, int dst_pos,
size_t length);
ObjectArray<T>* CopyOf(int32_t new_length);
private:
DISALLOW_IMPLICIT_CONSTRUCTORS(ObjectArray);
};
template<class T>
ObjectArray<T>* ObjectArray<T>::Alloc(Class* object_array_class, int32_t length) {
Array* array = Array::Alloc(object_array_class, length, sizeof(Object*));
if (UNLIKELY(array == NULL)) {
return NULL;
} else {
return array->AsObjectArray<T>();
}
}
template<class T>
T* ObjectArray<T>::Get(int32_t i) const {
if (UNLIKELY(!IsValidIndex(i))) {
return NULL;
}
MemberOffset data_offset(DataOffset(sizeof(Object*)).Int32Value() + i * sizeof(Object*));
return GetFieldObject<T*>(data_offset, false);
}
template<class T>
ObjectArray<T>* ObjectArray<T>::CopyOf(int32_t new_length) {
ObjectArray<T>* new_array = Alloc(GetClass(), new_length);
Copy(this, 0, new_array, 0, std::min(GetLength(), new_length));
return new_array;
}
// Type for the InitializedStaticStorage table. Currently the Class
// provides the static storage. However, this might change to an Array
// to improve image sharing, so we use this type to avoid assumptions
// on the current storage.
class MANAGED StaticStorageBase : public Object {
};
// C++ mirror of java.lang.Class
class MANAGED Class : public StaticStorageBase {
public:
// Class Status
//
// kStatusNotReady: If a Class cannot be found in the class table by
// FindClass, it allocates an new one with AllocClass in the
// kStatusNotReady and calls LoadClass. Note if it does find a
// class, it may not be kStatusResolved and it will try to push it
// forward toward kStatusResolved.
//
// kStatusIdx: LoadClass populates with Class with information from
// the DexFile, moving the status to kStatusIdx, indicating that the
// Class value in super_class_ has not been populated. The new Class
// can then be inserted into the classes table.
//
// kStatusLoaded: After taking a lock on Class, the ClassLinker will
// attempt to move a kStatusIdx class forward to kStatusLoaded by
// using ResolveClass to initialize the super_class_ and ensuring the
// interfaces are resolved.
//
// kStatusResolved: Still holding the lock on Class, the ClassLinker
// shows linking is complete and fields of the Class populated by making
// it kStatusResolved. Java allows circularities of the form where a super
// class has a field that is of the type of the sub class. We need to be able
// to fully resolve super classes while resolving types for fields.
//
// kStatusRetryVerificationAtRuntime: The verifier sets a class to
// this state if it encounters a soft failure at compile time. This
// often happens when there are unresolved classes in other dex
// files, and this status marks a class as needing to be verified
// again at runtime.
//
// TODO: Explain the other states
enum Status {
kStatusError = -1,
kStatusNotReady = 0,
kStatusIdx = 1, // loaded, DEX idx in super_class_type_idx_ and interfaces_type_idx_
kStatusLoaded = 2, // DEX idx values resolved
kStatusResolved = 3, // part of linking
kStatusVerifying = 4, // in the process of being verified
kStatusRetryVerificationAtRuntime = 5, // compile time verification failed, retry at runtime
kStatusVerified = 6, // logically part of linking; done pre-init
kStatusInitializing = 7, // class init in progress
kStatusInitialized = 8, // ready to go
};
Status GetStatus() const {
DCHECK_EQ(sizeof(Status), sizeof(uint32_t));
return static_cast<Status>(GetField32(OFFSET_OF_OBJECT_MEMBER(Class, status_), false));
}
void SetStatus(Status new_status);
// Returns true if the class has failed to link.
bool IsErroneous() const {
return GetStatus() == kStatusError;
}
// Returns true if the class has been loaded.
bool IsIdxLoaded() const {
return GetStatus() >= kStatusIdx;
}
// Returns true if the class has been loaded.
bool IsLoaded() const {
return GetStatus() >= kStatusLoaded;
}
// Returns true if the class has been linked.
bool IsResolved() const {
return GetStatus() >= kStatusResolved;
}
// Returns true if the class was compile-time verified.
bool IsCompileTimeVerified() const {
return GetStatus() >= kStatusRetryVerificationAtRuntime;
}
// Returns true if the class has been verified.
bool IsVerified() const {
return GetStatus() >= kStatusVerified;
}
// Returns true if the class is initializing.
bool IsInitializing() const {
return GetStatus() >= kStatusInitializing;
}
// Returns true if the class is initialized.
bool IsInitialized() const {
return GetStatus() == kStatusInitialized;
}
uint32_t GetAccessFlags() const;
void SetAccessFlags(uint32_t new_access_flags) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, access_flags_), new_access_flags, false);
}
// Returns true if the class is an interface.
bool IsInterface() const {
return (GetAccessFlags() & kAccInterface) != 0;
}
// Returns true if the class is declared public.
bool IsPublic() const {
return (GetAccessFlags() & kAccPublic) != 0;
}
// Returns true if the class is declared final.
bool IsFinal() const {
return (GetAccessFlags() & kAccFinal) != 0;
}
bool IsFinalizable() const {
return (GetAccessFlags() & kAccClassIsFinalizable) != 0;
}
void SetFinalizable() {
uint32_t flags = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, access_flags_), false);
SetAccessFlags(flags | kAccClassIsFinalizable);
}
// Returns true if the class is abstract.
bool IsAbstract() const {
return (GetAccessFlags() & kAccAbstract) != 0;
}
// Returns true if the class is an annotation.
bool IsAnnotation() const {
return (GetAccessFlags() & kAccAnnotation) != 0;
}
// Returns true if the class is synthetic.
bool IsSynthetic() const {
return (GetAccessFlags() & kAccSynthetic) != 0;
}
bool IsReferenceClass() const {
return (GetAccessFlags() & kAccClassIsReference) != 0;
}
bool IsWeakReferenceClass() const {
return (GetAccessFlags() & kAccClassIsWeakReference) != 0;
}
bool IsSoftReferenceClass() const {
return (GetAccessFlags() & kAccReferenceFlagsMask) == kAccClassIsReference;
}
bool IsFinalizerReferenceClass() const {
return (GetAccessFlags() & kAccClassIsFinalizerReference) != 0;
}
bool IsPhantomReferenceClass() const {
return (GetAccessFlags() & kAccClassIsPhantomReference) != 0;
}
String* GetName() const; // Returns the cached name
void SetName(String* name); // Sets the cached name
String* ComputeName(); // Computes the name, then sets the cached value
bool IsProxyClass() const {
// Read access flags without using getter as whether something is a proxy can be check in
// any loaded state
// TODO: switch to a check if the super class is java.lang.reflect.Proxy?
uint32_t access_flags = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, access_flags_), false);
return (access_flags & kAccClassIsProxy) != 0;
}
Primitive::Type GetPrimitiveType() const {
DCHECK_EQ(sizeof(Primitive::Type), sizeof(int32_t));
return static_cast<Primitive::Type>(
GetField32(OFFSET_OF_OBJECT_MEMBER(Class, primitive_type_), false));
}
void SetPrimitiveType(Primitive::Type new_type) {
DCHECK_EQ(sizeof(Primitive::Type), sizeof(int32_t));
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, primitive_type_), new_type, false);
}
// Returns true if the class is a primitive type.
bool IsPrimitive() const {
return GetPrimitiveType() != Primitive::kPrimNot;
}
bool IsPrimitiveBoolean() const {
return GetPrimitiveType() == Primitive::kPrimBoolean;
}
bool IsPrimitiveByte() const {
return GetPrimitiveType() == Primitive::kPrimByte;
}
bool IsPrimitiveChar() const {
return GetPrimitiveType() == Primitive::kPrimChar;
}
bool IsPrimitiveShort() const {
return GetPrimitiveType() == Primitive::kPrimShort;
}
bool IsPrimitiveInt() const {
return GetPrimitiveType() == Primitive::kPrimInt;
}
bool IsPrimitiveLong() const {
return GetPrimitiveType() == Primitive::kPrimLong;
}
bool IsPrimitiveFloat() const {
return GetPrimitiveType() == Primitive::kPrimFloat;
}
bool IsPrimitiveDouble() const {
return GetPrimitiveType() == Primitive::kPrimDouble;
}
bool IsPrimitiveVoid() const {
return GetPrimitiveType() == Primitive::kPrimVoid;
}
// Depth of class from java.lang.Object
size_t Depth() {
size_t depth = 0;
for (Class* klass = this; klass->GetSuperClass() != NULL; klass = klass->GetSuperClass()) {
depth++;
}
return depth;
}
bool IsArrayClass() const {
return GetComponentType() != NULL;
}
bool IsClassClass() const;
bool IsStringClass() const;
bool IsThrowableClass() const;
Class* GetComponentType() const {
return GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Class, component_type_), false);
}
void SetComponentType(Class* new_component_type) {
DCHECK(GetComponentType() == NULL);
DCHECK(new_component_type != NULL);
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, component_type_), new_component_type, false);
}
size_t GetComponentSize() const {
return Primitive::ComponentSize(GetComponentType()->GetPrimitiveType());
}
bool IsObjectClass() const {
return !IsPrimitive() && GetSuperClass() == NULL;
}
bool IsInstantiable() const {
return !IsPrimitive() && !IsInterface() && !IsAbstract();
}
// Creates a raw object instance but does not invoke the default constructor.
Object* AllocObject();
bool IsVariableSize() const {
// Classes and arrays vary in size, and so the object_size_ field cannot
// be used to get their instance size
return IsClassClass() || IsArrayClass();
}
size_t SizeOf() const {
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, class_size_), false);
}
size_t GetClassSize() const {
DCHECK_EQ(sizeof(size_t), sizeof(uint32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, class_size_), false);
}
void SetClassSize(size_t new_class_size);
size_t GetObjectSize() const {
CHECK(!IsVariableSize()) << " class=" << PrettyTypeOf(this);
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
size_t result = GetField32(OFFSET_OF_OBJECT_MEMBER(Class, object_size_), false);
CHECK_GE(result, sizeof(Object)) << " class=" << PrettyTypeOf(this);
return result;
}
void SetObjectSize(size_t new_object_size) {
DCHECK(!IsVariableSize());
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return SetField32(OFFSET_OF_OBJECT_MEMBER(Class, object_size_), new_object_size, false);
}
// Returns true if this class is in the same packages as that class.
bool IsInSamePackage(const Class* that) const;
static bool IsInSamePackage(const StringPiece& descriptor1, const StringPiece& descriptor2);
// Returns true if this class can access that class.
bool CanAccess(Class* that) const {
return that->IsPublic() || this->IsInSamePackage(that);
}
// Can this class access a member in the provided class with the provided member access flags?
// Note that access to the class isn't checked in case the declaring class is protected and the
// method has been exposed by a public sub-class
bool CanAccessMember(Class* access_to, uint32_t member_flags) const {
// Classes can access all of their own members
if (this == access_to) {
return true;
}
// Public members are trivially accessible
if (member_flags & kAccPublic) {
return true;
}
// Private members are trivially not accessible
if (member_flags & kAccPrivate) {
return false;
}
// Check for protected access from a sub-class, which may or may not be in the same package.
if (member_flags & kAccProtected) {
if (this->IsSubClass(access_to)) {
return true;
}
}
// Allow protected access from other classes in the same package.
return this->IsInSamePackage(access_to);
}
bool IsSubClass(const Class* klass) const;
// Can src be assigned to this class? For example, String can be assigned to Object (by an
// upcast), however, an Object cannot be assigned to a String as a potentially exception throwing
// downcast would be necessary. Similarly for interfaces, a class that implements (or an interface
// that extends) another can be assigned to its parent, but not vice-versa. All Classes may assign
// to themselves. Classes for primitive types may not assign to each other.
bool IsAssignableFrom(const Class* src) const {
DCHECK(src != NULL);
if (this == src) {
// Can always assign to things of the same type
return true;
} else if (IsObjectClass()) {
// Can assign any reference to java.lang.Object
return !src->IsPrimitive();
} else if (IsInterface()) {
return src->Implements(this);
} else if (src->IsArrayClass()) {
return IsAssignableFromArray(src);
} else {
return !src->IsInterface() && src->IsSubClass(this);
}
}
Class* GetSuperClass() const {
// Can only get super class for loaded classes (hack for when runtime is
// initializing)
DCHECK(IsLoaded() || !Runtime::Current()->IsStarted()) << IsLoaded();
return GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Class, super_class_), false);
}
void SetSuperClass(Class *new_super_class) {
// super class is assigned once, except during class linker initialization
Class* old_super_class = GetFieldObject<Class*>(
OFFSET_OF_OBJECT_MEMBER(Class, super_class_), false);
DCHECK(old_super_class == NULL || old_super_class == new_super_class);
DCHECK(new_super_class != NULL);
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, super_class_), new_super_class, false);
}
bool HasSuperClass() const {
return GetSuperClass() != NULL;
}
static MemberOffset SuperClassOffset() {
return MemberOffset(OFFSETOF_MEMBER(Class, super_class_));
}
ClassLoader* GetClassLoader() const;
void SetClassLoader(const ClassLoader* new_cl);
static MemberOffset DexCacheOffset() {
return MemberOffset(OFFSETOF_MEMBER(Class, dex_cache_));
}
enum {
kDumpClassFullDetail = 1,
kDumpClassClassLoader = (1 << 1),
kDumpClassInitialized = (1 << 2),
};
void DumpClass(std::ostream& os, int flags) const;
DexCache* GetDexCache() const;
void SetDexCache(DexCache* new_dex_cache);
ObjectArray<Method>* GetDirectMethods() const {
DCHECK(IsLoaded() || IsErroneous());
return GetFieldObject<ObjectArray<Method>*>(
OFFSET_OF_OBJECT_MEMBER(Class, direct_methods_), false);
}
void SetDirectMethods(ObjectArray<Method>* new_direct_methods) {
DCHECK(NULL == GetFieldObject<ObjectArray<Method>*>(
OFFSET_OF_OBJECT_MEMBER(Class, direct_methods_), false));
DCHECK_NE(0, new_direct_methods->GetLength());
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, direct_methods_),
new_direct_methods, false);
}
Method* GetDirectMethod(int32_t i) const {
return GetDirectMethods()->Get(i);
}
void SetDirectMethod(uint32_t i, Method* f) { // TODO: uint16_t
ObjectArray<Method>* direct_methods =
GetFieldObject<ObjectArray<Method>*>(
OFFSET_OF_OBJECT_MEMBER(Class, direct_methods_), false);
direct_methods->Set(i, f);
}
// Returns the number of static, private, and constructor methods.
size_t NumDirectMethods() const {
return (GetDirectMethods() != NULL) ? GetDirectMethods()->GetLength() : 0;
}
ObjectArray<Method>* GetVirtualMethods() const {
DCHECK(IsLoaded() || IsErroneous());
return GetFieldObject<ObjectArray<Method>*>(
OFFSET_OF_OBJECT_MEMBER(Class, virtual_methods_), false);
}
void SetVirtualMethods(ObjectArray<Method>* new_virtual_methods) {
// TODO: we reassign virtual methods to grow the table for miranda
// methods.. they should really just be assigned once
DCHECK_NE(0, new_virtual_methods->GetLength());
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, virtual_methods_),
new_virtual_methods, false);
}
// Returns the number of non-inherited virtual methods.
size_t NumVirtualMethods() const {
return (GetVirtualMethods() != NULL) ? GetVirtualMethods()->GetLength() : 0;
}
Method* GetVirtualMethod(uint32_t i) const {
DCHECK(IsResolved() || IsErroneous());
return GetVirtualMethods()->Get(i);
}
Method* GetVirtualMethodDuringLinking(uint32_t i) const {
DCHECK(IsLoaded() || IsErroneous());
return GetVirtualMethods()->Get(i);
}
void SetVirtualMethod(uint32_t i, Method* f) { // TODO: uint16_t
ObjectArray<Method>* virtual_methods =
GetFieldObject<ObjectArray<Method>*>(
OFFSET_OF_OBJECT_MEMBER(Class, virtual_methods_), false);
virtual_methods->Set(i, f);
}
ObjectArray<Method>* GetVTable() const {
DCHECK(IsResolved() || IsErroneous());
return GetFieldObject<ObjectArray<Method>*>(OFFSET_OF_OBJECT_MEMBER(Class, vtable_), false);
}
ObjectArray<Method>* GetVTableDuringLinking() const {
DCHECK(IsLoaded() || IsErroneous());
return GetFieldObject<ObjectArray<Method>*>(OFFSET_OF_OBJECT_MEMBER(Class, vtable_), false);
}
void SetVTable(ObjectArray<Method>* new_vtable) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, vtable_), new_vtable, false);
}
static MemberOffset VTableOffset() {
return OFFSET_OF_OBJECT_MEMBER(Class, vtable_);
}
// Given a method implemented by this class but potentially from a
// super class, return the specific implementation
// method for this class.
Method* FindVirtualMethodForVirtual(Method* method) {
DCHECK(!method->GetDeclaringClass()->IsInterface());
// The argument method may from a super class.
// Use the index to a potentially overridden one for this instance's class.
return GetVTable()->Get(method->GetMethodIndex());
}
// Given a method implemented by this class, but potentially from a
// super class or interface, return the specific implementation
// method for this class.
Method* FindVirtualMethodForInterface(Method* method);
Method* FindInterfaceMethod(const StringPiece& name, const StringPiece& descriptor) const;
Method* FindInterfaceMethod(const DexCache* dex_cache, uint32_t dex_method_idx) const;
Method* FindVirtualMethodForVirtualOrInterface(Method* method) {
if (method->IsDirect()) {
return method;
}
if (method->GetDeclaringClass()->IsInterface()) {
return FindVirtualMethodForInterface(method);
}
return FindVirtualMethodForVirtual(method);
}
Method* FindDeclaredVirtualMethod(const StringPiece& name, const StringPiece& signature) const;
Method* FindDeclaredVirtualMethod(const DexCache* dex_cache, uint32_t dex_method_idx) const;
Method* FindVirtualMethod(const StringPiece& name, const StringPiece& descriptor) const;
Method* FindVirtualMethod(const DexCache* dex_cache, uint32_t dex_method_idx) const;
Method* FindDeclaredDirectMethod(const StringPiece& name, const StringPiece& signature) const;
Method* FindDeclaredDirectMethod(const DexCache* dex_cache, uint32_t dex_method_idx) const;
Method* FindDirectMethod(const StringPiece& name, const StringPiece& signature) const;
Method* FindDirectMethod(const DexCache* dex_cache, uint32_t dex_method_idx) const;
int32_t GetIfTableCount() const {
ObjectArray<InterfaceEntry>* iftable = GetIfTable();
if (iftable == NULL) {
return 0;
}
return iftable->GetLength();
}
ObjectArray<InterfaceEntry>* GetIfTable() const {
DCHECK(IsResolved() || IsErroneous());
return GetFieldObject<ObjectArray<InterfaceEntry>*>(
OFFSET_OF_OBJECT_MEMBER(Class, iftable_), false);
}
void SetIfTable(ObjectArray<InterfaceEntry>* new_iftable) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, iftable_), new_iftable, false);
}
// Get instance fields of the class (See also GetSFields).
ObjectArray<Field>* GetIFields() const {
DCHECK(IsLoaded() || IsErroneous());
return GetFieldObject<ObjectArray<Field>*>(OFFSET_OF_OBJECT_MEMBER(Class, ifields_), false);
}
void SetIFields(ObjectArray<Field>* new_ifields) {
DCHECK(NULL == GetFieldObject<ObjectArray<Field>*>(
OFFSET_OF_OBJECT_MEMBER(Class, ifields_), false));
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, ifields_), new_ifields, false);
}
size_t NumInstanceFields() const {
return (GetIFields() != NULL) ? GetIFields()->GetLength() : 0;
}
Field* GetInstanceField(uint32_t i) const { // TODO: uint16_t
DCHECK_NE(NumInstanceFields(), 0U);
return GetIFields()->Get(i);
}
void SetInstanceField(uint32_t i, Field* f) { // TODO: uint16_t
ObjectArray<Field>* ifields= GetFieldObject<ObjectArray<Field>*>(
OFFSET_OF_OBJECT_MEMBER(Class, ifields_), false);
ifields->Set(i, f);
}
// Returns the number of instance fields containing reference types.
size_t NumReferenceInstanceFields() const {
DCHECK(IsResolved() || IsErroneous());
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_instance_fields_), false);
}
size_t NumReferenceInstanceFieldsDuringLinking() const {
DCHECK(IsLoaded() || IsErroneous());
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_instance_fields_), false);
}
void SetNumReferenceInstanceFields(size_t new_num) {
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_instance_fields_), new_num, false);
}
uint32_t GetReferenceInstanceOffsets() const {
DCHECK(IsResolved() || IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, reference_instance_offsets_), false);
}
void SetReferenceInstanceOffsets(uint32_t new_reference_offsets);
// Beginning of static field data
static MemberOffset FieldsOffset() {
return OFFSET_OF_OBJECT_MEMBER(Class, fields_);
}
// Returns the number of static fields containing reference types.
size_t NumReferenceStaticFields() const {
DCHECK(IsResolved() || IsErroneous());
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_static_fields_), false);
}
size_t NumReferenceStaticFieldsDuringLinking() const {
DCHECK(IsLoaded() || IsErroneous());
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_static_fields_), false);
}
void SetNumReferenceStaticFields(size_t new_num) {
DCHECK_EQ(sizeof(size_t), sizeof(int32_t));
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, num_reference_static_fields_), new_num, false);
}
// Gets the static fields of the class.
ObjectArray<Field>* GetSFields() const {
DCHECK(IsLoaded() || IsErroneous());
return GetFieldObject<ObjectArray<Field>*>(OFFSET_OF_OBJECT_MEMBER(Class, sfields_), false);
}
void SetSFields(ObjectArray<Field>* new_sfields) {
DCHECK(NULL == GetFieldObject<ObjectArray<Field>*>(
OFFSET_OF_OBJECT_MEMBER(Class, sfields_), false));
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, sfields_), new_sfields, false);
}
size_t NumStaticFields() const {
return (GetSFields() != NULL) ? GetSFields()->GetLength() : 0;
}
Field* GetStaticField(uint32_t i) const { // TODO: uint16_t
return GetSFields()->Get(i);
}
void SetStaticField(uint32_t i, Field* f) { // TODO: uint16_t
ObjectArray<Field>* sfields= GetFieldObject<ObjectArray<Field>*>(
OFFSET_OF_OBJECT_MEMBER(Class, sfields_), false);
sfields->Set(i, f);
}
uint32_t GetReferenceStaticOffsets() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, reference_static_offsets_), false);
}
void SetReferenceStaticOffsets(uint32_t new_reference_offsets);
// Find a static or instance field using the JLS resolution order
Field* FindField(const StringPiece& name, const StringPiece& type);
// Finds the given instance field in this class or a superclass.
Field* FindInstanceField(const StringPiece& name, const StringPiece& type);
// Finds the given instance field in this class or a superclass, only searches classes that
// have the same dex cache.
Field* FindInstanceField(const DexCache* dex_cache, uint32_t dex_field_idx);
Field* FindDeclaredInstanceField(const StringPiece& name, const StringPiece& type);
Field* FindDeclaredInstanceField(const DexCache* dex_cache, uint32_t dex_field_idx);
// Finds the given static field in this class or a superclass.
Field* FindStaticField(const StringPiece& name, const StringPiece& type);
// Finds the given static field in this class or superclass, only searches classes that
// have the same dex cache.
Field* FindStaticField(const DexCache* dex_cache, uint32_t dex_field_idx);
Field* FindDeclaredStaticField(const StringPiece& name, const StringPiece& type);
Field* FindDeclaredStaticField(const DexCache* dex_cache, uint32_t dex_field_idx);
pid_t GetClinitThreadId() const {
DCHECK(IsIdxLoaded() || IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, clinit_thread_id_), false);
}
void SetClinitThreadId(pid_t new_clinit_thread_id) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, clinit_thread_id_), new_clinit_thread_id, false);
}
Class* GetVerifyErrorClass() const {
// DCHECK(IsErroneous());
return GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Class, verify_error_class_), false);
}
uint16_t GetDexTypeIndex() const {
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, dex_type_idx_), false);
}
void SetDexTypeIndex(uint16_t type_idx) {
SetField32(OFFSET_OF_OBJECT_MEMBER(Class, dex_type_idx_), type_idx, false);
}
private:
void SetVerifyErrorClass(Class* klass) {
CHECK(klass != NULL) << PrettyClass(this);
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, verify_error_class_), klass, false);
}
bool Implements(const Class* klass) const;
bool IsArrayAssignableFromArray(const Class* klass) const;
bool IsAssignableFromArray(const Class* klass) const;
// defining class loader, or NULL for the "bootstrap" system loader
ClassLoader* class_loader_;
// For array classes, the component class object for instanceof/checkcast
// (for String[][][], this will be String[][]). NULL for non-array classes.
Class* component_type_;
// DexCache of resolved constant pool entries (will be NULL for classes generated by the
// runtime such as arrays and primitive classes).
DexCache* dex_cache_;
// static, private, and <init> methods
ObjectArray<Method>* direct_methods_;
// instance fields
//
// These describe the layout of the contents of an Object.
// Note that only the fields directly declared by this class are
// listed in ifields; fields declared by a superclass are listed in
// the superclass's Class.ifields.
//
// All instance fields that refer to objects are guaranteed to be at
// the beginning of the field list. num_reference_instance_fields_
// specifies the number of reference fields.
ObjectArray<Field>* ifields_;
// Interface table (iftable_), one entry per interface supported by
// this class. That means one entry for each interface we support
// directly, indirectly via superclass, or indirectly via
// superinterface. This will be null if neither we nor our
// superclass implement any interfaces.
//
// Why we need this: given "class Foo implements Face", declare
// "Face faceObj = new Foo()". Invoke faceObj.blah(), where "blah"
// is part of the Face interface. We can't easily use a single
// vtable.
//
// For every interface a concrete class implements, we create an array
// of the concrete vtable_ methods for the methods in the interface.
ObjectArray<InterfaceEntry>* iftable_;
// descriptor for the class such as "java.lang.Class" or "[C". Lazily initialized by ComputeName
String* name_;
// Static fields
ObjectArray<Field>* sfields_;
// The superclass, or NULL if this is java.lang.Object, an interface or primitive type.
Class* super_class_;
// If class verify fails, we must return same error on subsequent tries.
Class* verify_error_class_;
// virtual methods defined in this class; invoked through vtable
ObjectArray<Method>* virtual_methods_;
// Virtual method table (vtable), for use by "invoke-virtual". The vtable from the superclass is
// copied in, and virtual methods from our class either replace those from the super or are
// appended. For abstract classes, methods may be created in the vtable that aren't in
// virtual_ methods_ for miranda methods.
ObjectArray<Method>* vtable_;
// access flags; low 16 bits are defined by VM spec
uint32_t access_flags_;
// Total size of the Class instance; used when allocating storage on gc heap.
// See also object_size_.
size_t class_size_;
// tid used to check for recursive <clinit> invocation
pid_t clinit_thread_id_;
// type index from dex file
// TODO: really 16bits
uint32_t dex_type_idx_;
// number of instance fields that are object refs
size_t num_reference_instance_fields_;
// number of static fields that are object refs
size_t num_reference_static_fields_;
// Total object size; used when allocating storage on gc heap.
// (For interfaces and abstract classes this will be zero.)
// See also class_size_.
size_t object_size_;
// primitive type value, or Primitive::kPrimNot (0); set for generated prim classes
Primitive::Type primitive_type_;
// Bitmap of offsets of ifields.
uint32_t reference_instance_offsets_;
// Bitmap of offsets of sfields.
uint32_t reference_static_offsets_;
// state of class initialization
Status status_;
// TODO: ?
// initiating class loader list
// NOTE: for classes with low serialNumber, these are unused, and the
// values are kept in a table in gDvm.
// InitiatingLoaderList initiating_loader_list_;
// Location of first static field.
uint32_t fields_[0];
friend struct ClassOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Class);
};
std::ostream& operator<<(std::ostream& os, const Class::Status& rhs);
inline void Object::SetClass(Class* new_klass) {
// new_klass may be NULL prior to class linker initialization
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Object, klass_), new_klass, false, false);
}
inline bool Object::InstanceOf(const Class* klass) const {
DCHECK(klass != NULL);
DCHECK(GetClass() != NULL);
return klass->IsAssignableFrom(GetClass());
}
inline bool Object::IsClass() const {
Class* java_lang_Class = GetClass()->GetClass();
return GetClass() == java_lang_Class;
}
inline bool Object::IsObjectArray() const {
return IsArrayInstance() && !GetClass()->GetComponentType()->IsPrimitive();
}
template<class T>
inline ObjectArray<T>* Object::AsObjectArray() {
DCHECK(IsObjectArray());
return down_cast<ObjectArray<T>*>(this);
}
template<class T>
inline const ObjectArray<T>* Object::AsObjectArray() const {
DCHECK(IsObjectArray());
return down_cast<const ObjectArray<T>*>(this);
}
inline bool Object::IsArrayInstance() const {
return GetClass()->IsArrayClass();
}
inline bool Object::IsField() const {
Class* java_lang_Class = klass_->klass_;
Class* java_lang_reflect_Field =
java_lang_Class->GetInstanceField(0)->GetClass();
return GetClass() == java_lang_reflect_Field;
}
inline bool Object::IsMethod() const {
Class* c = GetClass();
return c == Method::GetMethodClass() || c == Method::GetConstructorClass();
}
inline bool Object::IsReferenceInstance() const {
return GetClass()->IsReferenceClass();
}
inline bool Object::IsWeakReferenceInstance() const {
return GetClass()->IsWeakReferenceClass();
}
inline bool Object::IsSoftReferenceInstance() const {
return GetClass()->IsSoftReferenceClass();
}
inline bool Object::IsFinalizerReferenceInstance() const {
return GetClass()->IsFinalizerReferenceClass();
}
inline bool Object::IsPhantomReferenceInstance() const {
return GetClass()->IsPhantomReferenceClass();
}
inline size_t Object::SizeOf() const {
size_t result;
if (IsArrayInstance()) {
result = AsArray()->SizeOf();
} else if (IsClass()) {
result = AsClass()->SizeOf();
} else {
result = GetClass()->GetObjectSize();
}
DCHECK(!IsField() || result == sizeof(Field));
DCHECK(!IsMethod() || result == sizeof(Method));
return result;
}
inline Class* Field::GetDeclaringClass() const {
Class* result = GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Field, declaring_class_), false);
DCHECK(result != NULL);
DCHECK(result->IsLoaded() || result->IsErroneous());
return result;
}
inline void Field::SetDeclaringClass(Class *new_declaring_class) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Field, declaring_class_), new_declaring_class, false);
}
inline Class* Method::GetDeclaringClass() const {
Class* result = GetFieldObject<Class*>(OFFSET_OF_OBJECT_MEMBER(Method, declaring_class_), false);
DCHECK(result != NULL) << this;
DCHECK(result->IsIdxLoaded() || result->IsErroneous()) << this;
return result;
}
inline void Method::SetDeclaringClass(Class *new_declaring_class) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Method, declaring_class_), new_declaring_class, false);
}
inline size_t Array::SizeOf() const {
// This is safe from overflow because the array was already allocated, so we know it's sane.
size_t component_size = GetClass()->GetComponentSize();
int32_t component_count = GetLength();
size_t header_size = sizeof(Object) + (component_size == sizeof(int64_t) ? 8 : 4);
size_t data_size = component_count * component_size;
return header_size + data_size;
}
template<class T>
void ObjectArray<T>::Set(int32_t i, T* object) {
if (LIKELY(IsValidIndex(i))) {
if (object != NULL) {
Class* element_class = GetClass()->GetComponentType();
if (UNLIKELY(!object->InstanceOf(element_class))) {
ThrowArrayStoreException(object);
return;
}
}
MemberOffset data_offset(DataOffset(sizeof(Object*)).Int32Value() + i * sizeof(Object*));
SetFieldObject(data_offset, object, false);
}
}
template<class T>
void ObjectArray<T>::SetWithoutChecks(int32_t i, T* object) {
DCHECK(IsValidIndex(i));
MemberOffset data_offset(DataOffset(sizeof(Object*)).Int32Value() + i * sizeof(Object*));
SetFieldObject(data_offset, object, false);
}
template<class T>
T* ObjectArray<T>::GetWithoutChecks(int32_t i) const {
DCHECK(IsValidIndex(i));
MemberOffset data_offset(DataOffset(sizeof(Object*)).Int32Value() + i * sizeof(Object*));
return GetFieldObject<T*>(data_offset, false);
}
template<class T>
void ObjectArray<T>::Copy(const ObjectArray<T>* src, int src_pos,
ObjectArray<T>* dst, int dst_pos,
size_t length) {
if (src->IsValidIndex(src_pos) &&
src->IsValidIndex(src_pos+length-1) &&
dst->IsValidIndex(dst_pos) &&
dst->IsValidIndex(dst_pos+length-1)) {
MemberOffset src_offset(DataOffset(sizeof(Object*)).Int32Value() + src_pos * sizeof(Object*));
MemberOffset dst_offset(DataOffset(sizeof(Object*)).Int32Value() + dst_pos * sizeof(Object*));
Class* array_class = dst->GetClass();
Heap* heap = Runtime::Current()->GetHeap();
if (array_class == src->GetClass()) {
// No need for array store checks if arrays are of the same type
for (size_t i = 0; i < length; i++) {
Object* object = src->GetFieldObject<Object*>(src_offset, false);
heap->VerifyObject(object);
// directly set field, we do a bulk write barrier at the end
dst->SetField32(dst_offset, reinterpret_cast<uint32_t>(object), false, true);
src_offset = MemberOffset(src_offset.Uint32Value() + sizeof(Object*));
dst_offset = MemberOffset(dst_offset.Uint32Value() + sizeof(Object*));
}
} else {
Class* element_class = array_class->GetComponentType();
CHECK(!element_class->IsPrimitive());
for (size_t i = 0; i < length; i++) {
Object* object = src->GetFieldObject<Object*>(src_offset, false);
if (object != NULL && !object->InstanceOf(element_class)) {
dst->ThrowArrayStoreException(object);
return;
}
heap->VerifyObject(object);
// directly set field, we do a bulk write barrier at the end
dst->SetField32(dst_offset, reinterpret_cast<uint32_t>(object), false, true);
src_offset = MemberOffset(src_offset.Uint32Value() + sizeof(Object*));
dst_offset = MemberOffset(dst_offset.Uint32Value() + sizeof(Object*));
}
}
heap->WriteBarrierArray(dst, dst_pos, length);
}
}
class MANAGED ClassClass : public Class {
private:
int32_t padding_;
int64_t serialVersionUID_;
friend struct ClassClassOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(ClassClass);
};
class MANAGED StringClass : public Class {
private:
CharArray* ASCII_;
Object* CASE_INSENSITIVE_ORDER_;
uint32_t REPLACEMENT_CHAR_;
int64_t serialVersionUID_;
friend struct StringClassOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(StringClass);
};
class MANAGED FieldClass : public Class {
private:
Object* ORDER_BY_NAME_AND_DECLARING_CLASS_;
friend struct FieldClassOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(FieldClass);
};
class MANAGED MethodClass : public Class {
private:
Object* ORDER_BY_SIGNATURE_;
friend struct MethodClassOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(MethodClass);
};
template<class T>
class MANAGED PrimitiveArray : public Array {
public:
typedef T ElementType;
static PrimitiveArray<T>* Alloc(size_t length);
const T* GetData() const {
intptr_t data = reinterpret_cast<intptr_t>(this) + DataOffset(sizeof(T)).Int32Value();
return reinterpret_cast<T*>(data);
}
T* GetData() {
intptr_t data = reinterpret_cast<intptr_t>(this) + DataOffset(sizeof(T)).Int32Value();
return reinterpret_cast<T*>(data);
}
T Get(int32_t i) const {
if (!IsValidIndex(i)) {
return T(0);
}
return GetData()[i];
}
void Set(int32_t i, T value) {
// TODO: ArrayStoreException
if (IsValidIndex(i)) {
GetData()[i] = value;
}
}
static void SetArrayClass(Class* array_class) {
CHECK(array_class_ == NULL);
CHECK(array_class != NULL);
array_class_ = array_class;
}
static void ResetArrayClass() {
CHECK(array_class_ != NULL);
array_class_ = NULL;
}
private:
static Class* array_class_;
DISALLOW_IMPLICIT_CONSTRUCTORS(PrimitiveArray);
};
// C++ mirror of java.lang.String
class MANAGED String : public Object {
public:
static MemberOffset CountOffset() {
return OFFSET_OF_OBJECT_MEMBER(String, count_);
}
static MemberOffset ValueOffset() {
return OFFSET_OF_OBJECT_MEMBER(String, array_);
}
static MemberOffset OffsetOffset() {
return OFFSET_OF_OBJECT_MEMBER(String, offset_);
}
const CharArray* GetCharArray() const {
const CharArray* result = GetFieldObject<const CharArray*>(
ValueOffset(), false);
DCHECK(result != NULL);
return result;
}
int32_t GetOffset() const {
int32_t result = GetField32(OffsetOffset(), false);
DCHECK_LE(0, result);
return result;
}
int32_t GetLength() const;
int32_t GetHashCode();
void ComputeHashCode() {
SetHashCode(ComputeUtf16Hash(GetCharArray(), GetOffset(), GetLength()));
}
int32_t GetUtfLength() const {
return CountUtf8Bytes(GetCharArray()->GetData() + GetOffset(), GetLength());
}
uint16_t CharAt(int32_t index) const;
String* Intern();
static String* AllocFromUtf16(int32_t utf16_length,
const uint16_t* utf16_data_in,
int32_t hash_code = 0);
static String* AllocFromModifiedUtf8(const char* utf);
static String* AllocFromModifiedUtf8(int32_t utf16_length,
const char* utf8_data_in);
static String* Alloc(Class* java_lang_String, int32_t utf16_length);
static String* Alloc(Class* java_lang_String, CharArray* array);
bool Equals(const char* modified_utf8) const;
// TODO: do we need this overload? give it a more intention-revealing name.
bool Equals(const StringPiece& modified_utf8) const;
bool Equals(const String* that) const;
// Compare UTF-16 code point values not in a locale-sensitive manner
int Compare(int32_t utf16_length, const char* utf8_data_in);
// TODO: do we need this overload? give it a more intention-revealing name.
bool Equals(const uint16_t* that_chars, int32_t that_offset,
int32_t that_length) const;
// Create a modified UTF-8 encoded std::string from a java/lang/String object.
std::string ToModifiedUtf8() const;
static Class* GetJavaLangString() {
DCHECK(java_lang_String_ != NULL);
return java_lang_String_;
}
static void SetClass(Class* java_lang_String);
static void ResetClass();
private:
void SetHashCode(int32_t new_hash_code) {
DCHECK_EQ(0u,
GetField32(OFFSET_OF_OBJECT_MEMBER(String, hash_code_), false));
SetField32(OFFSET_OF_OBJECT_MEMBER(String, hash_code_),
new_hash_code, false);
}
void SetCount(int32_t new_count) {
DCHECK_LE(0, new_count);
SetField32(OFFSET_OF_OBJECT_MEMBER(String, count_), new_count, false);
}
void SetOffset(int32_t new_offset) {
DCHECK_LE(0, new_offset);
DCHECK_GE(GetLength(), new_offset);
SetField32(OFFSET_OF_OBJECT_MEMBER(String, offset_), new_offset, false);
}
void SetArray(CharArray* new_array) {
DCHECK(new_array != NULL);
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(String, array_), new_array, false);
}
// Field order required by test "ValidateFieldOrderOfJavaCppUnionClasses".
CharArray* array_;
int32_t count_;
uint32_t hash_code_;
int32_t offset_;
static Class* java_lang_String_;
friend struct StringOffsets; // for verifying offset information
FRIEND_TEST(ObjectTest, StringLength); // for SetOffset and SetCount
DISALLOW_IMPLICIT_CONSTRUCTORS(String);
};
struct StringHashCode {
int32_t operator()(String* string) const {
return string->GetHashCode();
}
};
inline uint32_t Field::GetAccessFlags() const {
DCHECK(GetDeclaringClass()->IsLoaded() || GetDeclaringClass()->IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Field, access_flags_), false);
}
inline MemberOffset Field::GetOffset() const {
DCHECK(GetDeclaringClass()->IsResolved() || GetDeclaringClass()->IsErroneous());
return MemberOffset(GetField32(OFFSET_OF_OBJECT_MEMBER(Field, offset_), false));
}
inline MemberOffset Field::GetOffsetDuringLinking() const {
DCHECK(GetDeclaringClass()->IsLoaded() || GetDeclaringClass()->IsErroneous());
return MemberOffset(GetField32(OFFSET_OF_OBJECT_MEMBER(Field, offset_), false));
}
inline uint32_t Class::GetAccessFlags() const {
// Check class is loaded or this is java.lang.String that has a
// circularity issue during loading the names of its members
DCHECK(IsLoaded() || IsErroneous() ||
this == String::GetJavaLangString() ||
this == Field::GetJavaLangReflectField() ||
this == Method::GetConstructorClass() ||
this == Method::GetMethodClass());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Class, access_flags_), false);
}
inline uint32_t Method::GetAccessFlags() const {
DCHECK(GetDeclaringClass()->IsIdxLoaded() || GetDeclaringClass()->IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, access_flags_), false);
}
inline uint16_t Method::GetMethodIndex() const {
DCHECK(GetDeclaringClass()->IsResolved() || GetDeclaringClass()->IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, method_index_), false);
}
inline uint32_t Method::GetDexMethodIndex() const {
DCHECK(GetDeclaringClass()->IsLoaded() || GetDeclaringClass()->IsErroneous());
return GetField32(OFFSET_OF_OBJECT_MEMBER(Method, method_dex_index_), false);
}
inline void Method::AssertPcIsWithinCode(uintptr_t pc) const {
if (!kIsDebugBuild) {
return;
}
if (IsNative() || IsRuntimeMethod() || IsProxyMethod()) {
return;
}
Runtime* runtime = Runtime::Current();
if (GetCode() == runtime->GetResolutionStubArray(Runtime::kStaticMethod)->GetData()) {
return;
}
DCHECK(IsWithinCode(pc))
<< PrettyMethod(this)
<< " pc=" << std::hex << pc
<< " code=" << GetCode()
<< " size=" << GetCodeSize();
}
inline String* Class::GetName() const {
return GetFieldObject<String*>(OFFSET_OF_OBJECT_MEMBER(Class, name_), false);
}
inline void Class::SetName(String* name) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Class, name_), name, false);
}
// C++ mirror of java.lang.Throwable
class MANAGED Throwable : public Object {
public:
void SetDetailMessage(String* new_detail_message) {
SetFieldObject(OFFSET_OF_OBJECT_MEMBER(Throwable, detail_message_),
new_detail_message, false);
}
String* GetDetailMessage() const {
return GetFieldObject<String*>(OFFSET_OF_OBJECT_MEMBER(Throwable, detail_message_), false);
}
std::string Dump() const;
// This is a runtime version of initCause, you shouldn't use it if initCause may have been
// overridden. Also it asserts rather than throwing exceptions. Currently this is only used
// in cases like the verifier where the checks cannot fail and initCause isn't overridden.
void SetCause(Throwable* cause);
bool IsCheckedException() const;
static Class* GetJavaLangThrowable() {
DCHECK(java_lang_Throwable_ != NULL);
return java_lang_Throwable_;
}
static void SetClass(Class* java_lang_Throwable);
static void ResetClass();
private:
Object* GetStackState() const {
return GetFieldObject<Object*>(OFFSET_OF_OBJECT_MEMBER(Throwable, stack_state_), true);
}
// Field order required by test "ValidateFieldOrderOfJavaCppUnionClasses".
Throwable* cause_;
String* detail_message_;
Object* stack_state_; // Note this is Java volatile:
Object* stack_trace_;
Object* suppressed_exceptions_;
static Class* java_lang_Throwable_;
friend struct ThrowableOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Throwable);
};
// C++ mirror of java.lang.StackTraceElement
class MANAGED StackTraceElement : public Object {
public:
const String* GetDeclaringClass() const {
return GetFieldObject<const String*>(
OFFSET_OF_OBJECT_MEMBER(StackTraceElement, declaring_class_), false);
}
const String* GetMethodName() const {
return GetFieldObject<const String*>(
OFFSET_OF_OBJECT_MEMBER(StackTraceElement, method_name_), false);
}
const String* GetFileName() const {
return GetFieldObject<const String*>(
OFFSET_OF_OBJECT_MEMBER(StackTraceElement, file_name_), false);
}
int32_t GetLineNumber() const {
return GetField32(
OFFSET_OF_OBJECT_MEMBER(StackTraceElement, line_number_), false);
}
static StackTraceElement* Alloc(String* declaring_class,
String* method_name,
String* file_name,
int32_t line_number);
static void SetClass(Class* java_lang_StackTraceElement);
static void ResetClass();
private:
// Field order required by test "ValidateFieldOrderOfJavaCppUnionClasses".
String* declaring_class_;
String* file_name_;
String* method_name_;
int32_t line_number_;
static Class* GetStackTraceElement() {
DCHECK(java_lang_StackTraceElement_ != NULL);
return java_lang_StackTraceElement_;
}
static Class* java_lang_StackTraceElement_;
friend struct StackTraceElementOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(StackTraceElement);
};
class MANAGED InterfaceEntry : public ObjectArray<Object> {
public:
Class* GetInterface() const {
Class* interface = Get(kInterface)->AsClass();
DCHECK(interface != NULL);
return interface;
}
void SetInterface(Class* interface) {
DCHECK(interface != NULL);
DCHECK(interface->IsInterface());
DCHECK(Get(kInterface) == NULL);
Set(kInterface, interface);
}
size_t GetMethodArrayCount() const {
ObjectArray<Method>* method_array = down_cast<ObjectArray<Method>*>(Get(kMethodArray));
if (method_array == NULL) {
return 0;
}
return method_array->GetLength();
}
ObjectArray<Method>* GetMethodArray() const {
ObjectArray<Method>* method_array = down_cast<ObjectArray<Method>*>(Get(kMethodArray));
DCHECK(method_array != NULL);
return method_array;
}
void SetMethodArray(ObjectArray<Method>* new_ma) {
DCHECK(new_ma != NULL);
DCHECK(Get(kMethodArray) == NULL);
Set(kMethodArray, new_ma);
}
static size_t LengthAsArray() {
return kMax;
}
private:
enum {
// Points to the interface class.
kInterface = 0,
// Method pointers into the vtable, allow fast map from interface
// method index to concrete instance method.
kMethodArray = 1,
kMax = 2,
};
DISALLOW_IMPLICIT_CONSTRUCTORS(InterfaceEntry);
};
class MANAGED SynthesizedProxyClass : public Class {
public:
ObjectArray<Class>* GetInterfaces() {
return interfaces_;
}
ObjectArray<ObjectArray<Class> >* GetThrows() {
return throws_;
}
private:
ObjectArray<Class>* interfaces_;
ObjectArray<ObjectArray<Class> >* throws_;
DISALLOW_IMPLICIT_CONSTRUCTORS(SynthesizedProxyClass);
};
class MANAGED Proxy : public Object {
private:
Object* h_;
friend struct ProxyOffsets; // for verifying offset information
DISALLOW_IMPLICIT_CONSTRUCTORS(Proxy);
};
} // namespace art
#endif // ART_SRC_OBJECT_H_