runtime/indirect_reference_table.h - LeafOS-Project/android_art - Gitiles

 /*
  * Copyright (C) 2009 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_INDIRECT_REFERENCE_TABLE_H_
 #define ART_RUNTIME_INDIRECT_REFERENCE_TABLE_H_

 #include <stdint.h>

 #include <iosfwd>
 #include <limits>
 #include <string>

 #include <android-base/logging.h>

 #include "base/bit_utils.h"
 #include "base/locks.h"
 #include "base/macros.h"
 #include "base/mem_map.h"
 #include "base/mutex.h"
 #include "gc_root.h"
 #include "obj_ptr.h"
 #include "offsets.h"
 #include "read_barrier_option.h"

 namespace art {

 class IsMarkedVisitor;
 class RootInfo;

 namespace mirror {
 class Object;
 }  // namespace mirror

 // Maintain a table of indirect references.  Used for local/global JNI references.
 //
 // The table contains object references, where the strong (local/global) references are part of the
 // GC root set (but not the weak global references). When an object is added we return an
 // IndirectRef that is not a valid pointer but can be used to find the original value in O(1) time.
 // Conversions to and from indirect references are performed on upcalls and downcalls, so they need
 // to be very fast.
 //
 // To be efficient for JNI local variable storage, we need to provide operations that allow us to
 // operate on segments of the table, where segments are pushed and popped as if on a stack. For
 // example, deletion of an entry should only succeed if it appears in the current segment, and we
 // want to be able to strip off the current segment quickly when a method returns. Additions to the
 // table must be made in the current segment even if space is available in an earlier area.
 //
 // A new segment is created when we call into native code from interpreted code, or when we handle
 // the JNI PushLocalFrame function.
 //
 // The GC must be able to scan the entire table quickly.
 //
 // In summary, these must be very fast:
 //  - adding or removing a segment
 //  - adding references to a new segment
 //  - converting an indirect reference back to an Object
 // These can be a little slower, but must still be pretty quick:
 //  - adding references to a "mature" segment
 //  - removing individual references
 //  - scanning the entire table straight through
 //
 // If there's more than one segment, we don't guarantee that the table will fill completely before
 // we fail due to lack of space. We do ensure that the current segment will pack tightly, which
 // should satisfy JNI requirements (e.g. EnsureLocalCapacity).

 // Indirect reference definition.  This must be interchangeable with JNI's jobject, and it's
 // convenient to let null be null, so we use void*.
 //
 // We need a (potentially) large table index and a 2-bit reference type (global, local, weak
 // global). We also reserve some bits to be used to detect stale indirect references: we put a
 // serial number in the extra bits, and keep a copy of the serial number in the table. This requires
 // more memory and additional memory accesses on add/get, but is moving-GC safe. It will catch
 // additional problems, e.g.: create iref1 for obj, delete iref1, create iref2 for same obj,
 // lookup iref1. A pattern based on object bits will miss this.
 using IndirectRef = void*;

 // Indirect reference kind, used as the two low bits of IndirectRef.
 //
 // For convenience these match up with enum jobjectRefType from jni.h, except that
 // we use value 0 for JNI transitions instead of marking invalid reference type.
 enum IndirectRefKind {
   kJniTransition = 0,  // <<JNI transition frame reference>>
   kLocal         = 1,  // <<local reference>>
   kGlobal        = 2,  // <<global reference>>
   kWeakGlobal    = 3,  // <<weak global reference>>
   kLastKind      = kWeakGlobal
 };
 std::ostream& operator<<(std::ostream& os, IndirectRefKind rhs);
 const char* GetIndirectRefKindString(IndirectRefKind kind);

 // Table definition.
 //
 // For the global reference table, the expected common operations are adding a new entry and
 // removing a recently-added entry (usually the most-recently-added entry).  For JNI local
 // references, the common operations are adding a new entry and removing an entire table segment.
 //
 // If we delete entries from the middle of the list, we will be left with "holes".  We track the
 // number of holes so that, when adding new elements, we can quickly decide to do a trivial append
 // or go slot-hunting.
 //
 // When the top-most entry is removed, any holes immediately below it are also removed. Thus,
 // deletion of an entry may reduce "top_index" by more than one.
 //
 // To get the desired behavior for JNI locals, we need to know the bottom and top of the current
 // "segment". The top is managed internally, and the bottom is passed in as a function argument.
 // When we call a native method or push a local frame, the current top index gets pushed on, and
 // serves as the new bottom. When we pop a frame off, the value from the stack becomes the new top
 // index, and the value stored in the previous frame becomes the new bottom.
 //
 // Holes are being locally cached for the segment. Otherwise we'd have to pass bottom index and
 // number of holes, which restricts us to 16 bits for the top index. The value is cached within the
 // table. To avoid code in generated JNI transitions, which implicitly form segments, the code for
 // adding and removing references needs to detect the change of a segment. Helper fields are used
 // for this detection.
 //
 // Common alternative implementation: make IndirectRef a pointer to the actual reference slot.
 // Instead of getting a table and doing a lookup, the lookup can be done instantly. Operations like
 // determining the type and deleting the reference are more expensive because the table must be
 // hunted for (i.e. you have to do a pointer comparison to see which table it's in), you can't move
 // the table when expanding it (so realloc() is out), and tricks like serial number checking to
 // detect stale references aren't possible (though we may be able to get similar benefits with other
 // approaches).
 //
 // TODO: consider a "lastDeleteIndex" for quick hole-filling when an add immediately follows a
 // delete; must invalidate after segment pop might be worth only using it for JNI globals.
 //
 // TODO: may want completely different add/remove algorithms for global and local refs to improve
 // performance.  A large circular buffer might reduce the amortized cost of adding global
 // references.

 // The state of the current segment. We only store the index. Splitting it for index and hole
 // count restricts the range too much.
 struct IRTSegmentState {
   uint32_t top_index;
 };

 // Use as initial value for "cookie", and when table has only one segment.
 static constexpr IRTSegmentState kIRTFirstSegment = { 0 };

 // We associate a few bits of serial number with each reference, for error checking.
 static constexpr unsigned int kIRTSerialBits = 3;
 static constexpr uint32_t kIRTMaxSerial = ((1 << kIRTSerialBits) - 1);

 class IrtEntry {
  public:
   void Add(ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

   GcRoot<mirror::Object>* GetReference() {
     DCHECK_LE(serial_, kIRTMaxSerial);
     return &reference_;
   }

   const GcRoot<mirror::Object>* GetReference() const {
     DCHECK_LE(serial_, kIRTMaxSerial);
     return &reference_;
   }

   uint32_t GetSerial() const {
     return serial_;
   }

   void SetReference(ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

  private:
   uint32_t serial_;  // Incremented for each reuse; checked against reference.
   GcRoot<mirror::Object> reference_;
 };
 static_assert(sizeof(IrtEntry) == 2 * sizeof(uint32_t), "Unexpected sizeof(IrtEntry)");
 static_assert(IsPowerOfTwo(sizeof(IrtEntry)), "Unexpected sizeof(IrtEntry)");

 // We initially allocate local reference tables with a very small number of entries, packing
 // multiple tables into a single page. If we need to expand one, we allocate them in units of
 // pages.
 // TODO: We should allocate all IRT tables as nonmovable Java objects, That in turn works better
 // if we break up each table into 2 parallel arrays, one for the Java reference, and one for the
 // serial number. The current scheme page-aligns regions containing IRT tables, and so allows them
 // to be identified and page-protected in the future.
 constexpr size_t kInitialIrtBytes = 512;  // Number of bytes in an initial local table.
 constexpr size_t kSmallIrtEntries = kInitialIrtBytes / sizeof(IrtEntry);
 static_assert(kPageSize % kInitialIrtBytes == 0);
 static_assert(kInitialIrtBytes % sizeof(IrtEntry) == 0);
 static_assert(kInitialIrtBytes % sizeof(void *) == 0);

 // A minimal stopgap allocator for initial small local IRT tables.
 class SmallIrtAllocator {
  public:
   SmallIrtAllocator();

   // Allocate an IRT table for kSmallIrtEntries.
   IrtEntry* Allocate(std::string* error_msg) REQUIRES(!lock_);

   void Deallocate(IrtEntry* unneeded) REQUIRES(!lock_);

  private:
   // A free list of kInitialIrtBytes chunks linked through the first word.
   IrtEntry* small_irt_freelist_;

   // Repository of MemMaps used for small IRT tables.
   std::vector<MemMap> shared_irt_maps_;

   Mutex lock_;  // Level kGenericBottomLock; acquired before mem_map_lock_, which is a C++ mutex.
 };

 class IndirectReferenceTable {
  public:
   enum class ResizableCapacity {
     kNo,
     kYes
   };

   // Constructs an uninitialized indirect reference table. Use `Initialize()` to initialize it.
   IndirectReferenceTable(IndirectRefKind kind, ResizableCapacity resizable);

   // Initialize the indirect reference table.
   //
   // Max_count is the minimum initial capacity (resizable), or minimum total capacity
   // (not resizable). A value of 1 indicates an implementation-convenient small size.
   bool Initialize(size_t max_count, std::string* error_msg);

   ~IndirectReferenceTable();

   /*
    * Checks whether construction of the IndirectReferenceTable succeeded.
    *
    * This object must only be used if IsValid() returns true. It is safe to
    * call IsValid from multiple threads without locking or other explicit
    * synchronization.
    */
   bool IsValid() const;

   // Add a new entry. "obj" must be a valid non-null object reference. This function will
   // return null if an error happened (with an appropriate error message set).
   IndirectRef Add(IRTSegmentState previous_state,
                   ObjPtr<mirror::Object> obj,
                   std::string* error_msg)
       REQUIRES_SHARED(Locks::mutator_lock_);

   // Given an IndirectRef in the table, return the Object it refers to.
   //
   // This function may abort under error conditions.
   template<ReadBarrierOption kReadBarrierOption = kWithReadBarrier>
   ObjPtr<mirror::Object> Get(IndirectRef iref) const REQUIRES_SHARED(Locks::mutator_lock_)
       ALWAYS_INLINE;

   // Updates an existing indirect reference to point to a new object.
   void Update(IndirectRef iref, ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

   // Remove an existing entry.
   //
   // If the entry is not between the current top index and the bottom index
   // specified by the cookie, we don't remove anything.  This is the behavior
   // required by JNI's DeleteLocalRef function.
   //
   // Returns "false" if nothing was removed.
   bool Remove(IRTSegmentState previous_state, IndirectRef iref);

   void AssertEmpty() REQUIRES_SHARED(Locks::mutator_lock_);

   void Dump(std::ostream& os) const
       REQUIRES_SHARED(Locks::mutator_lock_)
       REQUIRES(!Locks::alloc_tracker_lock_);

   IndirectRefKind GetKind() const {
     return kind_;
   }

   // Return the #of entries in the entire table.  This includes holes, and
   // so may be larger than the actual number of "live" entries.
   size_t Capacity() const {
     return segment_state_.top_index;
   }

   // Return the number of non-null entries in the table. Only reliable for a
   // single segment table.
   int32_t NEntriesForGlobal() {
     return segment_state_.top_index - current_num_holes_;
   }

   // Ensure that at least free_capacity elements are available, or return false.
   // Caller ensures free_capacity > 0.
   bool EnsureFreeCapacity(size_t free_capacity, std::string* error_msg)
       REQUIRES_SHARED(Locks::mutator_lock_);
   // See implementation of EnsureFreeCapacity. We'll only state here how much is trivially free,
   // without recovering holes. Thus this is a conservative estimate.
   size_t FreeCapacity() const;

   void VisitRoots(RootVisitor* visitor, const RootInfo& root_info)
       REQUIRES_SHARED(Locks::mutator_lock_);

   IRTSegmentState GetSegmentState() const {
     return segment_state_;
   }

   void SetSegmentState(IRTSegmentState new_state);

   static Offset SegmentStateOffset(size_t pointer_size ATTRIBUTE_UNUSED) {
     // Note: Currently segment_state_ is at offset 0. We're testing the expected value in
     //       jni_internal_test to make sure it stays correct. It is not OFFSETOF_MEMBER, as that
     //       is not pointer-size-safe.
     return Offset(0);
   }

   // Release pages past the end of the table that may have previously held references.
   void Trim() REQUIRES_SHARED(Locks::mutator_lock_);

   // Determine what kind of indirect reference this is. Opposite of EncodeIndirectRefKind.
   ALWAYS_INLINE static inline IndirectRefKind GetIndirectRefKind(IndirectRef iref) {
     return DecodeIndirectRefKind(reinterpret_cast<uintptr_t>(iref));
   }

   /* Reference validation for CheckJNI. */
   bool IsValidReference(IndirectRef, /*out*/std::string* error_msg) const
       REQUIRES_SHARED(Locks::mutator_lock_);

   void SweepJniWeakGlobals(IsMarkedVisitor* visitor)
       REQUIRES_SHARED(Locks::mutator_lock_)
       REQUIRES(!Locks::jni_weak_globals_lock_);

  private:
   static constexpr uint32_t kShiftedSerialMask = (1u << kIRTSerialBits) - 1;

   static constexpr size_t kKindBits = MinimumBitsToStore(
       static_cast<uint32_t>(IndirectRefKind::kLastKind));
   static constexpr uint32_t kKindMask = (1u << kKindBits) - 1;

   static constexpr uintptr_t EncodeIndex(uint32_t table_index) {
     static_assert(sizeof(IndirectRef) == sizeof(uintptr_t), "Unexpected IndirectRef size");
     DCHECK_LE(MinimumBitsToStore(table_index), BitSizeOf<uintptr_t>() - kIRTSerialBits - kKindBits);
     return (static_cast<uintptr_t>(table_index) << kKindBits << kIRTSerialBits);
   }
   static constexpr uint32_t DecodeIndex(uintptr_t uref) {
     return static_cast<uint32_t>((uref >> kKindBits) >> kIRTSerialBits);
   }

   static constexpr uintptr_t EncodeIndirectRefKind(IndirectRefKind kind) {
     return static_cast<uintptr_t>(kind);
   }
   static constexpr IndirectRefKind DecodeIndirectRefKind(uintptr_t uref) {
     return static_cast<IndirectRefKind>(uref & kKindMask);
   }

   static constexpr uintptr_t EncodeSerial(uint32_t serial) {
     DCHECK_LE(MinimumBitsToStore(serial), kIRTSerialBits);
     return serial << kKindBits;
   }
   static constexpr uint32_t DecodeSerial(uintptr_t uref) {
     return static_cast<uint32_t>(uref >> kKindBits) & kShiftedSerialMask;
   }

   constexpr uintptr_t EncodeIndirectRef(uint32_t table_index, uint32_t serial) const {
     DCHECK_LT(table_index, max_entries_);
     return EncodeIndex(table_index) | EncodeSerial(serial) | EncodeIndirectRefKind(kind_);
   }

   static void ConstexprChecks();

   // Extract the table index from an indirect reference.
   ALWAYS_INLINE static uint32_t ExtractIndex(IndirectRef iref) {
     return DecodeIndex(reinterpret_cast<uintptr_t>(iref));
   }

   IndirectRef ToIndirectRef(uint32_t table_index) const {
     DCHECK_LT(table_index, max_entries_);
     uint32_t serial = table_[table_index].GetSerial();
     return reinterpret_cast<IndirectRef>(EncodeIndirectRef(table_index, serial));
   }

   // Resize the backing table to be at least new_size elements long. Currently
   // must be larger than the current size. After return max_entries_ >= new_size.
   bool Resize(size_t new_size, std::string* error_msg);

   void RecoverHoles(IRTSegmentState from);

   // Abort if check_jni is not enabled. Otherwise, just log as an error.
   static void AbortIfNoCheckJNI(const std::string& msg);

   /* extra debugging checks */
   bool CheckEntry(const char*, IndirectRef, uint32_t) const;

   /// semi-public - read/write by jni down calls.
   IRTSegmentState segment_state_;

   // Mem map where we store the indirect refs. If it's invalid, and table_ is non-null, then
   // table_ is valid, but was allocated via allocSmallIRT();
   MemMap table_mem_map_;
   // Bottom of the stack. Do not directly access the object references
   // in this as they are roots. Use Get() that has a read barrier.
   IrtEntry* table_;
   // Bit mask, ORed into all irefs.
   const IndirectRefKind kind_;

   // max #of entries allowed (modulo resizing).
   size_t max_entries_;

   // Some values to retain old behavior with holes. Description of the algorithm is in the .cc
   // file.
   // TODO: Consider other data structures for compact tables, e.g., free lists.
   size_t current_num_holes_;  // Number of holes in the current / top segment.
   IRTSegmentState last_known_previous_state_;

   // Whether the table's capacity may be resized. As there are no locks used, it is the caller's
   // responsibility to ensure thread-safety.
   ResizableCapacity resizable_;
 };

 }  // namespace art

 #endif  // ART_RUNTIME_INDIRECT_REFERENCE_TABLE_H_
	/*
	* Copyright (C) 2009 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_INDIRECT_REFERENCE_TABLE_H_
	#define ART_RUNTIME_INDIRECT_REFERENCE_TABLE_H_

	#include <stdint.h>

	#include <iosfwd>
	#include <limits>
	#include <string>

	#include <android-base/logging.h>

	#include "base/bit_utils.h"
	#include "base/locks.h"
	#include "base/macros.h"
	#include "base/mem_map.h"
	#include "base/mutex.h"
	#include "gc_root.h"
	#include "obj_ptr.h"
	#include "offsets.h"
	#include "read_barrier_option.h"

	namespace art {

	class IsMarkedVisitor;
	class RootInfo;

	namespace mirror {
	class Object;
	} // namespace mirror

	// Maintain a table of indirect references. Used for local/global JNI references.
	//
	// The table contains object references, where the strong (local/global) references are part of the
	// GC root set (but not the weak global references). When an object is added we return an
	// IndirectRef that is not a valid pointer but can be used to find the original value in O(1) time.
	// Conversions to and from indirect references are performed on upcalls and downcalls, so they need
	// to be very fast.
	//
	// To be efficient for JNI local variable storage, we need to provide operations that allow us to
	// operate on segments of the table, where segments are pushed and popped as if on a stack. For
	// example, deletion of an entry should only succeed if it appears in the current segment, and we
	// want to be able to strip off the current segment quickly when a method returns. Additions to the
	// table must be made in the current segment even if space is available in an earlier area.
	//
	// A new segment is created when we call into native code from interpreted code, or when we handle
	// the JNI PushLocalFrame function.
	//
	// The GC must be able to scan the entire table quickly.
	//
	// In summary, these must be very fast:
	// - adding or removing a segment
	// - adding references to a new segment
	// - converting an indirect reference back to an Object
	// These can be a little slower, but must still be pretty quick:
	// - adding references to a "mature" segment
	// - removing individual references
	// - scanning the entire table straight through
	//
	// If there's more than one segment, we don't guarantee that the table will fill completely before
	// we fail due to lack of space. We do ensure that the current segment will pack tightly, which
	// should satisfy JNI requirements (e.g. EnsureLocalCapacity).

	// Indirect reference definition. This must be interchangeable with JNI's jobject, and it's
	// convenient to let null be null, so we use void*.
	//
	// We need a (potentially) large table index and a 2-bit reference type (global, local, weak
	// global). We also reserve some bits to be used to detect stale indirect references: we put a
	// serial number in the extra bits, and keep a copy of the serial number in the table. This requires
	// more memory and additional memory accesses on add/get, but is moving-GC safe. It will catch
	// additional problems, e.g.: create iref1 for obj, delete iref1, create iref2 for same obj,
	// lookup iref1. A pattern based on object bits will miss this.
	using IndirectRef = void*;

	// Indirect reference kind, used as the two low bits of IndirectRef.
	//
	// For convenience these match up with enum jobjectRefType from jni.h, except that
	// we use value 0 for JNI transitions instead of marking invalid reference type.
	enum IndirectRefKind {
	kJniTransition = 0, // <<JNI transition frame reference>>
	kLocal = 1, // <<local reference>>
	kGlobal = 2, // <<global reference>>
	kWeakGlobal = 3, // <<weak global reference>>
	kLastKind = kWeakGlobal
	};
	std::ostream& operator<<(std::ostream& os, IndirectRefKind rhs);
	const char* GetIndirectRefKindString(IndirectRefKind kind);

	// Table definition.
	//
	// For the global reference table, the expected common operations are adding a new entry and
	// removing a recently-added entry (usually the most-recently-added entry). For JNI local
	// references, the common operations are adding a new entry and removing an entire table segment.
	//
	// If we delete entries from the middle of the list, we will be left with "holes". We track the
	// number of holes so that, when adding new elements, we can quickly decide to do a trivial append
	// or go slot-hunting.
	//
	// When the top-most entry is removed, any holes immediately below it are also removed. Thus,
	// deletion of an entry may reduce "top_index" by more than one.
	//
	// To get the desired behavior for JNI locals, we need to know the bottom and top of the current
	// "segment". The top is managed internally, and the bottom is passed in as a function argument.
	// When we call a native method or push a local frame, the current top index gets pushed on, and
	// serves as the new bottom. When we pop a frame off, the value from the stack becomes the new top
	// index, and the value stored in the previous frame becomes the new bottom.
	//
	// Holes are being locally cached for the segment. Otherwise we'd have to pass bottom index and
	// number of holes, which restricts us to 16 bits for the top index. The value is cached within the
	// table. To avoid code in generated JNI transitions, which implicitly form segments, the code for
	// adding and removing references needs to detect the change of a segment. Helper fields are used
	// for this detection.
	//
	// Common alternative implementation: make IndirectRef a pointer to the actual reference slot.
	// Instead of getting a table and doing a lookup, the lookup can be done instantly. Operations like
	// determining the type and deleting the reference are more expensive because the table must be
	// hunted for (i.e. you have to do a pointer comparison to see which table it's in), you can't move
	// the table when expanding it (so realloc() is out), and tricks like serial number checking to
	// detect stale references aren't possible (though we may be able to get similar benefits with other
	// approaches).
	//
	// TODO: consider a "lastDeleteIndex" for quick hole-filling when an add immediately follows a
	// delete; must invalidate after segment pop might be worth only using it for JNI globals.
	//
	// TODO: may want completely different add/remove algorithms for global and local refs to improve
	// performance. A large circular buffer might reduce the amortized cost of adding global
	// references.

	// The state of the current segment. We only store the index. Splitting it for index and hole
	// count restricts the range too much.
	struct IRTSegmentState {
	uint32_t top_index;
	};

	// Use as initial value for "cookie", and when table has only one segment.
	static constexpr IRTSegmentState kIRTFirstSegment = { 0 };

	// We associate a few bits of serial number with each reference, for error checking.
	static constexpr unsigned int kIRTSerialBits = 3;
	static constexpr uint32_t kIRTMaxSerial = ((1 << kIRTSerialBits) - 1);

	class IrtEntry {
	public:
	void Add(ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

	GcRoot<mirror::Object>* GetReference() {
	DCHECK_LE(serial_, kIRTMaxSerial);
	return &reference_;
	}

	const GcRoot<mirror::Object>* GetReference() const {
	DCHECK_LE(serial_, kIRTMaxSerial);
	return &reference_;
	}

	uint32_t GetSerial() const {
	return serial_;
	}

	void SetReference(ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

	private:
	uint32_t serial_; // Incremented for each reuse; checked against reference.
	GcRoot<mirror::Object> reference_;
	};
	static_assert(sizeof(IrtEntry) == 2 * sizeof(uint32_t), "Unexpected sizeof(IrtEntry)");
	static_assert(IsPowerOfTwo(sizeof(IrtEntry)), "Unexpected sizeof(IrtEntry)");

	// We initially allocate local reference tables with a very small number of entries, packing
	// multiple tables into a single page. If we need to expand one, we allocate them in units of
	// pages.
	// TODO: We should allocate all IRT tables as nonmovable Java objects, That in turn works better
	// if we break up each table into 2 parallel arrays, one for the Java reference, and one for the
	// serial number. The current scheme page-aligns regions containing IRT tables, and so allows them
	// to be identified and page-protected in the future.
	constexpr size_t kInitialIrtBytes = 512; // Number of bytes in an initial local table.
	constexpr size_t kSmallIrtEntries = kInitialIrtBytes / sizeof(IrtEntry);
	static_assert(kPageSize % kInitialIrtBytes == 0);
	static_assert(kInitialIrtBytes % sizeof(IrtEntry) == 0);
	static_assert(kInitialIrtBytes % sizeof(void *) == 0);

	// A minimal stopgap allocator for initial small local IRT tables.
	class SmallIrtAllocator {
	public:
	SmallIrtAllocator();

	// Allocate an IRT table for kSmallIrtEntries.
	IrtEntry* Allocate(std::string* error_msg) REQUIRES(!lock_);

	void Deallocate(IrtEntry* unneeded) REQUIRES(!lock_);

	private:
	// A free list of kInitialIrtBytes chunks linked through the first word.
	IrtEntry* small_irt_freelist_;

	// Repository of MemMaps used for small IRT tables.
	std::vector<MemMap> shared_irt_maps_;

	Mutex lock_; // Level kGenericBottomLock; acquired before mem_map_lock_, which is a C++ mutex.
	};

	class IndirectReferenceTable {
	public:
	enum class ResizableCapacity {
	kNo,
	kYes
	};

	// Constructs an uninitialized indirect reference table. Use `Initialize()` to initialize it.
	IndirectReferenceTable(IndirectRefKind kind, ResizableCapacity resizable);

	// Initialize the indirect reference table.
	//
	// Max_count is the minimum initial capacity (resizable), or minimum total capacity
	// (not resizable). A value of 1 indicates an implementation-convenient small size.
	bool Initialize(size_t max_count, std::string* error_msg);

	~IndirectReferenceTable();

	/*
	* Checks whether construction of the IndirectReferenceTable succeeded.
	*
	* This object must only be used if IsValid() returns true. It is safe to
	* call IsValid from multiple threads without locking or other explicit
	* synchronization.
	*/
	bool IsValid() const;

	// Add a new entry. "obj" must be a valid non-null object reference. This function will
	// return null if an error happened (with an appropriate error message set).
	IndirectRef Add(IRTSegmentState previous_state,
	ObjPtr<mirror::Object> obj,
	std::string* error_msg)
	REQUIRES_SHARED(Locks::mutator_lock_);

	// Given an IndirectRef in the table, return the Object it refers to.
	//
	// This function may abort under error conditions.
	template<ReadBarrierOption kReadBarrierOption = kWithReadBarrier>
	ObjPtr<mirror::Object> Get(IndirectRef iref) const REQUIRES_SHARED(Locks::mutator_lock_)
	ALWAYS_INLINE;

	// Updates an existing indirect reference to point to a new object.
	void Update(IndirectRef iref, ObjPtr<mirror::Object> obj) REQUIRES_SHARED(Locks::mutator_lock_);

	// Remove an existing entry.
	//
	// If the entry is not between the current top index and the bottom index
	// specified by the cookie, we don't remove anything. This is the behavior
	// required by JNI's DeleteLocalRef function.
	//
	// Returns "false" if nothing was removed.
	bool Remove(IRTSegmentState previous_state, IndirectRef iref);

	void AssertEmpty() REQUIRES_SHARED(Locks::mutator_lock_);

	void Dump(std::ostream& os) const
	REQUIRES_SHARED(Locks::mutator_lock_)
	REQUIRES(!Locks::alloc_tracker_lock_);

	IndirectRefKind GetKind() const {
	return kind_;
	}

	// Return the #of entries in the entire table. This includes holes, and
	// so may be larger than the actual number of "live" entries.
	size_t Capacity() const {
	return segment_state_.top_index;
	}

	// Return the number of non-null entries in the table. Only reliable for a
	// single segment table.
	int32_t NEntriesForGlobal() {
	return segment_state_.top_index - current_num_holes_;
	}

	// Ensure that at least free_capacity elements are available, or return false.
	// Caller ensures free_capacity > 0.
	bool EnsureFreeCapacity(size_t free_capacity, std::string* error_msg)
	REQUIRES_SHARED(Locks::mutator_lock_);
	// See implementation of EnsureFreeCapacity. We'll only state here how much is trivially free,
	// without recovering holes. Thus this is a conservative estimate.
	size_t FreeCapacity() const;

	void VisitRoots(RootVisitor* visitor, const RootInfo& root_info)
	REQUIRES_SHARED(Locks::mutator_lock_);

	IRTSegmentState GetSegmentState() const {
	return segment_state_;
	}

	void SetSegmentState(IRTSegmentState new_state);

	static Offset SegmentStateOffset(size_t pointer_size ATTRIBUTE_UNUSED) {
	// Note: Currently segment_state_ is at offset 0. We're testing the expected value in
	// jni_internal_test to make sure it stays correct. It is not OFFSETOF_MEMBER, as that
	// is not pointer-size-safe.
	return Offset(0);
	}

	// Release pages past the end of the table that may have previously held references.
	void Trim() REQUIRES_SHARED(Locks::mutator_lock_);

	// Determine what kind of indirect reference this is. Opposite of EncodeIndirectRefKind.
	ALWAYS_INLINE static inline IndirectRefKind GetIndirectRefKind(IndirectRef iref) {
	return DecodeIndirectRefKind(reinterpret_cast<uintptr_t>(iref));
	}

	/* Reference validation for CheckJNI. */
	bool IsValidReference(IndirectRef, /out/std::string* error_msg) const
	REQUIRES_SHARED(Locks::mutator_lock_);

	void SweepJniWeakGlobals(IsMarkedVisitor* visitor)
	REQUIRES_SHARED(Locks::mutator_lock_)
	REQUIRES(!Locks::jni_weak_globals_lock_);

	private:
	static constexpr uint32_t kShiftedSerialMask = (1u << kIRTSerialBits) - 1;

	static constexpr size_t kKindBits = MinimumBitsToStore(
	static_cast<uint32_t>(IndirectRefKind::kLastKind));
	static constexpr uint32_t kKindMask = (1u << kKindBits) - 1;

	static constexpr uintptr_t EncodeIndex(uint32_t table_index) {
	static_assert(sizeof(IndirectRef) == sizeof(uintptr_t), "Unexpected IndirectRef size");
	DCHECK_LE(MinimumBitsToStore(table_index), BitSizeOf<uintptr_t>() - kIRTSerialBits - kKindBits);
	return (static_cast<uintptr_t>(table_index) << kKindBits << kIRTSerialBits);
	}
	static constexpr uint32_t DecodeIndex(uintptr_t uref) {
	return static_cast<uint32_t>((uref >> kKindBits) >> kIRTSerialBits);
	}

	static constexpr uintptr_t EncodeIndirectRefKind(IndirectRefKind kind) {
	return static_cast<uintptr_t>(kind);
	}
	static constexpr IndirectRefKind DecodeIndirectRefKind(uintptr_t uref) {
	return static_cast<IndirectRefKind>(uref & kKindMask);
	}

	static constexpr uintptr_t EncodeSerial(uint32_t serial) {
	DCHECK_LE(MinimumBitsToStore(serial), kIRTSerialBits);
	return serial << kKindBits;
	}
	static constexpr uint32_t DecodeSerial(uintptr_t uref) {
	return static_cast<uint32_t>(uref >> kKindBits) & kShiftedSerialMask;
	}

	constexpr uintptr_t EncodeIndirectRef(uint32_t table_index, uint32_t serial) const {
	DCHECK_LT(table_index, max_entries_);
	return EncodeIndex(table_index) \| EncodeSerial(serial) \| EncodeIndirectRefKind(kind_);
	}

	static void ConstexprChecks();

	// Extract the table index from an indirect reference.
	ALWAYS_INLINE static uint32_t ExtractIndex(IndirectRef iref) {
	return DecodeIndex(reinterpret_cast<uintptr_t>(iref));
	}

	IndirectRef ToIndirectRef(uint32_t table_index) const {
	DCHECK_LT(table_index, max_entries_);
	uint32_t serial = table_[table_index].GetSerial();
	return reinterpret_cast<IndirectRef>(EncodeIndirectRef(table_index, serial));
	}

	// Resize the backing table to be at least new_size elements long. Currently
	// must be larger than the current size. After return max_entries_ >= new_size.
	bool Resize(size_t new_size, std::string* error_msg);

	void RecoverHoles(IRTSegmentState from);

	// Abort if check_jni is not enabled. Otherwise, just log as an error.
	static void AbortIfNoCheckJNI(const std::string& msg);

	/* extra debugging checks */
	bool CheckEntry(const char*, IndirectRef, uint32_t) const;

	/// semi-public - read/write by jni down calls.
	IRTSegmentState segment_state_;

	// Mem map where we store the indirect refs. If it's invalid, and table_ is non-null, then
	// table_ is valid, but was allocated via allocSmallIRT();
	MemMap table_mem_map_;
	// Bottom of the stack. Do not directly access the object references
	// in this as they are roots. Use Get() that has a read barrier.
	IrtEntry* table_;
	// Bit mask, ORed into all irefs.
	const IndirectRefKind kind_;

	// max #of entries allowed (modulo resizing).
	size_t max_entries_;

	// Some values to retain old behavior with holes. Description of the algorithm is in the .cc
	// file.
	// TODO: Consider other data structures for compact tables, e.g., free lists.
	size_t current_num_holes_; // Number of holes in the current / top segment.
	IRTSegmentState last_known_previous_state_;

	// Whether the table's capacity may be resized. As there are no locks used, it is the caller's
	// responsibility to ensure thread-safety.
	ResizableCapacity resizable_;
	};

	} // namespace art

	#endif // ART_RUNTIME_INDIRECT_REFERENCE_TABLE_H_