src/thread.h - platform/art - Git at Google

 /*
  * 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_THREAD_H_
 #define ART_SRC_THREAD_H_

 #include <pthread.h>

 #include <bitset>
 #include <iosfwd>
 #include <list>
 #include <string>
 #include <vector>

 #include "dex_file.h"
 #include "globals.h"
 #include "jni_internal.h"
 #include "logging.h"
 #include "macros.h"
 #include "mutex.h"
 #include "mem_map.h"
 #include "oat/runtime/oat_support_entrypoints.h"
 #include "offsets.h"
 #include "runtime_stats.h"
 #include "stack.h"
 #include "trace.h"
 #include "UniquePtr.h"

 namespace art {

 class Array;
 class Class;
 class ClassLinker;
 class ClassLoader;
 class Context;
 class DebugInvokeReq;
 class Method;
 class Monitor;
 class Object;
 class Runtime;
 class ShadowFrame;
 class StackIndirectReferenceTable;
 class StackTraceElement;
 class StaticStorageBase;
 class Thread;
 class ThreadList;
 class Throwable;

 template<class T> class ObjectArray;
 template<class T> class PrimitiveArray;
 typedef PrimitiveArray<int32_t> IntArray;

 // Thread priorities. These must match the Thread.MIN_PRIORITY,
 // Thread.NORM_PRIORITY, and Thread.MAX_PRIORITY constants.
 enum ThreadPriority {
   kMinThreadPriority = 1,
   kNormThreadPriority = 5,
   kMaxThreadPriority = 10,
 };

 enum ThreadState {
   kTerminated   = 0, // Thread.TERMINATED     JDWP TS_ZOMBIE
   kRunnable     = 1, // Thread.RUNNABLE       JDWP TS_RUNNING
   kTimedWaiting = 2, // Thread.TIMED_WAITING  JDWP TS_WAIT    - in Object.wait() with a timeout
   kBlocked      = 3, // Thread.BLOCKED        JDWP TS_MONITOR - blocked on a monitor
   kWaiting      = 4, // Thread.WAITING        JDWP TS_WAIT    - in Object.wait()
   kStarting     = 5, // Thread.NEW                            - native thread started, not yet ready to run managed code
   kNative       = 6, //                                       - running in a JNI native method
   kVmWait       = 7, //                                       - waiting on an internal runtime resource
   kSuspended    = 8, //                                       - suspended by GC or debugger
 };

 class PACKED Thread {
  public:
   // Space to throw a StackOverflowError in.
 #if !defined(ART_USE_LLVM_COMPILER)
   static const size_t kStackOverflowReservedBytes = 4 * KB;
 #else  // LLVM_x86 requires more memory to throw stack overflow exception.
   static const size_t kStackOverflowReservedBytes = 8 * KB;
 #endif

   static const size_t kDefaultStackSize = 16 * KB;

   class StackVisitor {
    public:
     virtual ~StackVisitor() {}
     // Return 'true' if we should continue to visit more frames, 'false' to stop.
     virtual bool VisitFrame(const Frame& frame, uintptr_t pc) = 0;
   };

   // Creates a new native thread corresponding to the given managed peer.
   // Used to implement Thread.start.
   static void Create(Object* peer, size_t stack_size);

   // Attaches the calling native thread to the runtime, returning the new native peer.
   // Used to implement JNI AttachCurrentThread and AttachCurrentThreadAsDaemon calls.
   static Thread* Attach(const char* thread_name, bool as_daemon, Object* thread_group);

   // Reset internal state of child thread after fork.
   void InitAfterFork();

   static Thread* Current() {
     void* thread = pthread_getspecific(Thread::pthread_key_self_);
     return reinterpret_cast<Thread*>(thread);
   }

   static Thread* FromManagedThread(Object* thread_peer);
   static Thread* FromManagedThread(JNIEnv* env, jobject thread);
   static uint32_t LockOwnerFromThreadLock(Object* thread_lock);

   // Translates 172 to pAllocArrayFromCode and so on.
   static void DumpThreadOffset(std::ostream& os, uint32_t offset, size_t size_of_pointers);

   // When full == true, dumps the detailed thread state and the thread stack (used for SIGQUIT).
   // When full == false, dumps a one-line summary of thread state (used for operator<<).
   void Dump(std::ostream& os, bool full = true) const;

   ThreadState GetState() const {
     return state_;
   }

   ThreadState SetState(ThreadState new_state);
   void SetStateWithoutSuspendCheck(ThreadState new_state);

   bool IsDaemon();
   bool IsSuspended();

   void WaitUntilSuspended();

   bool HoldsLock(Object*);

   /*
    * Changes the priority of this thread to match that of the java.lang.Thread object.
    *
    * We map a priority value from 1-10 to Linux "nice" values, where lower
    * numbers indicate higher priority.
    */
   void SetNativePriority(int newPriority);

   /*
    * Returns the thread priority for the current thread by querying the system.
    * This is useful when attaching a thread through JNI.
    *
    * Returns a value from 1 to 10 (compatible with java.lang.Thread values).
    */
   static int GetNativePriority();

   // Returns the "main" ThreadGroup, used when attaching user threads.
   static Object* GetMainThreadGroup();
   // Returns the "system" ThreadGroup, used when attaching our internal threads.
   static Object* GetSystemThreadGroup();

   bool CanAccessDirectReferences() const {
 #ifdef MOVING_GARBAGE_COLLECTOR
     // TODO: when we have a moving collector, we'll need: return state_ == kRunnable;
 #endif
     return true;
   }

   uint32_t GetThinLockId() const {
     return thin_lock_id_;
   }

   pid_t GetTid() const {
     return tid_;
   }

   // Returns the java.lang.Thread's name, or NULL if this Thread* doesn't have a peer.
   String* GetThreadName() const;

   // Sets 'name' to the java.lang.Thread's name. This requires no transition to managed code,
   // allocation, or locking.
   void GetThreadName(std::string& name) const;

   // Sets the thread's name.
   void SetThreadName(const char* name);

   Object* GetPeer() const {
     return peer_;
   }

   Object* GetThreadGroup() const;

   RuntimeStats* GetStats() {
     return &stats_;
   }

   int GetSuspendCount() const {
     return suspend_count_;
   }

   // Returns the current Method* and native PC (not dex PC) for this thread.
   Method* GetCurrentMethod(uintptr_t* pc = NULL, Method*** sp = NULL) const;

   bool IsExceptionPending() const {
     return exception_ != NULL;
   }

   Throwable* GetException() const {
     DCHECK(CanAccessDirectReferences());
     return exception_;
   }

   void SetException(Throwable* new_exception) {
     DCHECK(CanAccessDirectReferences());
     CHECK(new_exception != NULL);
     // TODO: CHECK(exception_ == NULL);
     exception_ = new_exception;  // TODO
   }

   void ClearException() {
     exception_ = NULL;
   }

   // Find catch block and perform long jump to appropriate exception handle
   void DeliverException();

   Context* GetLongJumpContext();

   Frame GetTopOfStack() const {
     return top_of_managed_stack_;
   }

   // TODO: this is here for testing, remove when we have exception unit tests
   // that use the real stack
   void SetTopOfStack(void* stack, uintptr_t pc) {
     top_of_managed_stack_.SetSP(reinterpret_cast<Method**>(stack));
     top_of_managed_stack_pc_ = pc;
   }

   void SetTopOfStackPC(uintptr_t pc) {
     top_of_managed_stack_pc_ = pc;
   }

   // 'msg' may be NULL.
   void ThrowNewException(const char* exception_class_descriptor, const char* msg);

   void ThrowNewExceptionF(const char* exception_class_descriptor, const char* fmt, ...)
       __attribute__((format(printf, 3, 4)));

   void ThrowNewExceptionV(const char* exception_class_descriptor, const char* fmt, va_list ap);

   // OutOfMemoryError is special, because we need to pre-allocate an instance.
   // Only the GC should call this.
   void ThrowOutOfMemoryError(const char* msg);

   Frame FindExceptionHandler(void* throw_pc, void** handler_pc);

   void* FindExceptionHandlerInMethod(const Method* method,
                                      void* throw_pc,
                                      const DexFile& dex_file,
                                      ClassLinker* class_linker);

   static void Startup();
   static void FinishStartup();
   static void Shutdown();

   // JNI methods
   JNIEnvExt* GetJniEnv() const {
     return jni_env_;
   }

   // Number of references in SIRTs on this thread
   size_t NumSirtReferences();

   // Number of references allocated in ShadowFrames on this thread
   size_t NumShadowFrameReferences();

   // Number of references allocated in SIRTs & shadow frames on this thread
   size_t NumStackReferences() {
     return NumSirtReferences() + NumShadowFrameReferences();
   };

   // Is the given obj in this thread's stack indirect reference table?
   bool SirtContains(jobject obj);

   // Is the given obj in this thread's ShadowFrame?
   bool ShadowFrameContains(jobject obj);

   // Is the given obj in this thread's Sirts & ShadowFrames?
   bool StackReferencesContain(jobject obj);

   void SirtVisitRoots(Heap::RootVisitor* visitor, void* arg);

   void ShadowFrameVisitRoots(Heap::RootVisitor* visitor, void* arg);

   // Convert a jobject into a Object*
   Object* DecodeJObject(jobject obj);

   // Implements java.lang.Thread.interrupted.
   bool Interrupted() {
     MutexLock mu(*wait_mutex_);
     bool interrupted = interrupted_;
     interrupted_ = false;
     return interrupted;
   }

   // Implements java.lang.Thread.isInterrupted.
   bool IsInterrupted() {
     MutexLock mu(*wait_mutex_);
     return interrupted_;
   }

   void Interrupt() {
     MutexLock mu(*wait_mutex_);
     if (interrupted_) {
       return;
     }
     interrupted_ = true;
     NotifyLocked();
   }

   void Notify() {
     MutexLock mu(*wait_mutex_);
     NotifyLocked();
   }

   // Linked list recording transitions from native to managed code
   void PushNativeToManagedRecord(NativeToManagedRecord* record);
   void PopNativeToManagedRecord(const NativeToManagedRecord& record);

   const ClassLoader* GetClassLoaderOverride() {
     // TODO: need to place the class_loader_override_ in a handle
     // DCHECK(CanAccessDirectReferences());
     return class_loader_override_;
   }

   void SetClassLoaderOverride(const ClassLoader* class_loader_override) {
     class_loader_override_ = class_loader_override;
   }

   // Create the internal representation of a stack trace, that is more time
   // and space efficient to compute than the StackTraceElement[]
   jobject CreateInternalStackTrace(JNIEnv* env) const;

   // Convert an internal stack trace representation (returned by CreateInternalStackTrace) to a
   // StackTraceElement[]. If output_array is NULL, a new array is created, otherwise as many
   // frames as will fit are written into the given array. If stack_depth is non-NULL, it's updated
   // with the number of valid frames in the returned array.
   static jobjectArray InternalStackTraceToStackTraceElementArray(JNIEnv* env, jobject internal,
       jobjectArray output_array = NULL, int* stack_depth = NULL);

   void VisitRoots(Heap::RootVisitor* visitor, void* arg);

 #if VERIFY_OBJECT_ENABLED
   void VerifyStack();
 #else
   void VerifyStack() {}
 #endif

   //
   // Offsets of various members of native Thread class, used by compiled code.
   //

   static ThreadOffset SelfOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, self_));
   }

   static ThreadOffset ExceptionOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, exception_));
   }

   static ThreadOffset ThinLockIdOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, thin_lock_id_));
   }

   static ThreadOffset CardTableOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, card_table_));
   }

   static ThreadOffset SuspendCountOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, suspend_count_));
   }

   static ThreadOffset StateOffset() {
     return ThreadOffset(OFFSETOF_VOLATILE_MEMBER(Thread, state_));
   }

   // Size of stack less any space reserved for stack overflow
   size_t GetStackSize() {
     return stack_size_ - (stack_end_ - stack_begin_);
   }

   // Set the stack end to that to be used during a stack overflow
   void SetStackEndForStackOverflow() {
     // During stack overflow we allow use of the full stack
     if (stack_end_ == stack_begin_) {
       DumpStack(std::cerr);
       LOG(FATAL) << "Need to increase kStackOverflowReservedBytes (currently "
                  << kStackOverflowReservedBytes << ")";
     }

     stack_end_ = stack_begin_;
   }

   // Set the stack end to that to be used during regular execution
   void ResetDefaultStackEnd() {
     // Our stacks grow down, so we want stack_end_ to be near there, but reserving enough room
     // to throw a StackOverflowError.
     stack_end_ = stack_begin_ + kStackOverflowReservedBytes;
   }

   static ThreadOffset StackEndOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, stack_end_));
   }

   static ThreadOffset JniEnvOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, jni_env_));
   }

   static ThreadOffset TopOfManagedStackOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, top_of_managed_stack_) +
         OFFSETOF_MEMBER(Frame, sp_));
   }

   static ThreadOffset TopOfManagedStackPcOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, top_of_managed_stack_pc_));
   }

   void PushShadowFrame(ShadowFrame* frame);
   ShadowFrame* PopShadowFrame();

   static ThreadOffset TopShadowFrameOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, top_shadow_frame_));
   }

   void PushSirt(StackIndirectReferenceTable* sirt);
   StackIndirectReferenceTable* PopSirt();

   static ThreadOffset TopSirtOffset() {
     return ThreadOffset(OFFSETOF_MEMBER(Thread, top_sirt_));
   }

   void WalkStack(StackVisitor* visitor, bool include_upcalls = false) const;

   DebugInvokeReq* GetInvokeReq() {
     return debug_invoke_req_;
   }

   void SetDebuggerUpdatesEnabled(bool enabled);

   bool IsTraceStackEmpty() const {
     return trace_stack_->empty();
   }

   TraceStackFrame GetTraceStackFrame(uint32_t depth) const {
     return trace_stack_->at(trace_stack_->size() - depth - 1);
   }

   void PushTraceStackFrame(const TraceStackFrame& frame) {
     trace_stack_->push_back(frame);
   }

   TraceStackFrame PopTraceStackFrame() {
     TraceStackFrame frame = trace_stack_->back();
     trace_stack_->pop_back();
     return frame;
   }

   void CheckSafeToLockOrUnlock(MutexRank rank, bool is_locking);
   void CheckSafeToWait(MutexRank rank);

  private:
   Thread();
   ~Thread();
   void Destroy();
   friend class ThreadList;  // For ~Thread and Destroy.

   void CreatePeer(const char* name, bool as_daemon, Object* thread_group);
   friend class Runtime; // For CreatePeer.

   void DumpState(std::ostream& os) const;
   void DumpStack(std::ostream& os) const;
   void DumpNativeStack(std::ostream& os) const;

   // Out-of-line conveniences for debugging in gdb.
   static Thread* CurrentFromGdb(); // Like Thread::Current.
   void DumpFromGdb() const; // Like Thread::Dump(std::cerr).

   static void* CreateCallback(void* arg);

   void HandleUncaughtExceptions();
   void RemoveFromThreadGroup();

   void Init();
   void InitCardTable();
   void InitCpu();
   void InitFunctionPointers();
   void InitTid();
   void InitPthreadKeySelf();
   void InitStackHwm();

   void NotifyLocked() {
     if (wait_monitor_ != NULL) {
       wait_cond_->Signal();
     }
   }

   static void ThreadExitCallback(void* arg);

   // Thin lock thread id. This is a small integer used by the thin lock implementation.
   // This is not to be confused with the native thread's tid, nor is it the value returned
   // by java.lang.Thread.getId --- this is a distinct value, used only for locking. One
   // important difference between this id and the ids visible to managed code is that these
   // ones get reused (to ensure that they fit in the number of bits available).
   uint32_t thin_lock_id_;

   // System thread id.
   pid_t tid_;

   // Our managed peer (an instance of java.lang.Thread).
   Object* peer_;

   // The top_of_managed_stack_ and top_of_managed_stack_pc_ fields are accessed from
   // compiled code, so we keep them early in the structure to (a) avoid having to keep
   // fixing the assembler offsets and (b) improve the chances that these will still be aligned.

   // Top of the managed stack, written out prior to the state transition from
   // kRunnable to kNative. Uses include giving the starting point for scanning
   // a managed stack when a thread is in native code.
   Frame top_of_managed_stack_;
   // PC corresponding to the call out of the top_of_managed_stack_ frame
   uintptr_t top_of_managed_stack_pc_;

   // Guards the 'interrupted_' and 'wait_monitor_' members.
   mutable Mutex* wait_mutex_;
   ConditionVariable* wait_cond_;
   // Pointer to the monitor lock we're currently waiting on (or NULL), guarded by wait_mutex_.
   Monitor* wait_monitor_;
   // Thread "interrupted" status; stays raised until queried or thrown, guarded by wait_mutex_.
   uint32_t interrupted_;
   // The next thread in the wait set this thread is part of.
   Thread* wait_next_;
   // If we're blocked in MonitorEnter, this is the object we're trying to lock.
   Object* monitor_enter_object_;

   friend class Monitor;

   RuntimeStats stats_;

   // The biased card table, see CardTable for details
   byte* card_table_;

   // The end of this thread's stack. This is the lowest safely-addressable address on the stack.
   // We leave extra space so there's room for the code that throws StackOverflowError.
   byte* stack_end_;

   // Size of the stack
   size_t stack_size_;

   // The "lowest addressable byte" of the stack
   byte* stack_begin_;

   // A linked list (of stack allocated records) recording transitions from
   // native to managed code.
   NativeToManagedRecord* native_to_managed_record_;

   // Top of linked list of stack indirect reference tables or NULL for none
   StackIndirectReferenceTable* top_sirt_;

   // Top of linked list of shadow stack or NULL for none
   // Some backend may require shadow frame to ease the GC work.
   ShadowFrame* top_shadow_frame_;

   // Every thread may have an associated JNI environment
   JNIEnvExt* jni_env_;

   volatile ThreadState state_;

   // Initialized to "this". On certain architectures (such as x86) reading
   // off of Thread::Current is easy but getting the address of Thread::Current
   // is hard. This field can be read off of Thread::Current to give the address.
   Thread* self_;

   Runtime* runtime_;

   // The pending exception or NULL.
   Throwable* exception_;

   // A non-zero value is used to tell the current thread to enter a safe point
   // at the next poll.
   int suspend_count_;
   // How much of 'suspend_count_' is by request of the debugger, used to set things right
   // when the debugger detaches. Must be <= suspend_count_.
   int debug_suspend_count_;

   // Needed to get the right ClassLoader in JNI_OnLoad, but also
   // useful for testing.
   const ClassLoader* class_loader_override_;

   // Thread local, lazily allocated, long jump context. Used to deliver exceptions.
   Context* long_jump_context_;

   // A boolean telling us whether we're recursively throwing OOME.
   uint32_t throwing_OutOfMemoryError_;

   Throwable* pre_allocated_OutOfMemoryError_;

   // JDWP invoke-during-breakpoint support.
   DebugInvokeReq* debug_invoke_req_;

   // TLS key used to retrieve the Thread*.
   static pthread_key_t pthread_key_self_;

   // Additional stack used by method tracer to store method and return pc values.
   // Stored as a pointer since std::vector is not PACKED.
   std::vector<TraceStackFrame>* trace_stack_;

   // A cached copy of the java.lang.Thread's name.
   std::string* name_;

   uint32_t held_mutexes_[kMaxMutexRank + 1];

  public:
   // Runtime support function pointers
   EntryPoints entrypoints_;

  private:
   DISALLOW_COPY_AND_ASSIGN(Thread);
 };

 std::ostream& operator<<(std::ostream& os, const Thread& thread);
 std::ostream& operator<<(std::ostream& os, const ThreadState& state);

 class ScopedThreadStateChange {
  public:
   ScopedThreadStateChange(Thread* thread, ThreadState new_state) : thread_(thread) {
     old_thread_state_ = thread_->SetState(new_state);
   }

   ~ScopedThreadStateChange() {
     thread_->SetState(old_thread_state_);
   }

  private:
   Thread* thread_;
   ThreadState old_thread_state_;
   DISALLOW_COPY_AND_ASSIGN(ScopedThreadStateChange);
 };

 }  // namespace art

 #endif  // ART_SRC_THREAD_H_
	/*
	* 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_THREAD_H_
	#define ART_SRC_THREAD_H_

	#include <pthread.h>

	#include <bitset>
	#include <iosfwd>
	#include <list>
	#include <string>
	#include <vector>

	#include "dex_file.h"
	#include "globals.h"
	#include "jni_internal.h"
	#include "logging.h"
	#include "macros.h"
	#include "mutex.h"
	#include "mem_map.h"
	#include "oat/runtime/oat_support_entrypoints.h"
	#include "offsets.h"
	#include "runtime_stats.h"
	#include "stack.h"
	#include "trace.h"
	#include "UniquePtr.h"

	namespace art {

	class Array;
	class Class;
	class ClassLinker;
	class ClassLoader;
	class Context;
	class DebugInvokeReq;
	class Method;
	class Monitor;
	class Object;
	class Runtime;
	class ShadowFrame;
	class StackIndirectReferenceTable;
	class StackTraceElement;
	class StaticStorageBase;
	class Thread;
	class ThreadList;
	class Throwable;

	template<class T> class ObjectArray;
	template<class T> class PrimitiveArray;
	typedef PrimitiveArray<int32_t> IntArray;

	// Thread priorities. These must match the Thread.MIN_PRIORITY,
	// Thread.NORM_PRIORITY, and Thread.MAX_PRIORITY constants.
	enum ThreadPriority {
	kMinThreadPriority = 1,
	kNormThreadPriority = 5,
	kMaxThreadPriority = 10,
	};

	enum ThreadState {
	kTerminated = 0, // Thread.TERMINATED JDWP TS_ZOMBIE
	kRunnable = 1, // Thread.RUNNABLE JDWP TS_RUNNING
	kTimedWaiting = 2, // Thread.TIMED_WAITING JDWP TS_WAIT - in Object.wait() with a timeout
	kBlocked = 3, // Thread.BLOCKED JDWP TS_MONITOR - blocked on a monitor
	kWaiting = 4, // Thread.WAITING JDWP TS_WAIT - in Object.wait()
	kStarting = 5, // Thread.NEW - native thread started, not yet ready to run managed code
	kNative = 6, // - running in a JNI native method
	kVmWait = 7, // - waiting on an internal runtime resource
	kSuspended = 8, // - suspended by GC or debugger
	};

	class PACKED Thread {
	public:
	// Space to throw a StackOverflowError in.
	#if !defined(ART_USE_LLVM_COMPILER)
	static const size_t kStackOverflowReservedBytes = 4 * KB;
	#else // LLVM_x86 requires more memory to throw stack overflow exception.
	static const size_t kStackOverflowReservedBytes = 8 * KB;
	#endif

	static const size_t kDefaultStackSize = 16 * KB;

	class StackVisitor {
	public:
	virtual ~StackVisitor() {}
	// Return 'true' if we should continue to visit more frames, 'false' to stop.
	virtual bool VisitFrame(const Frame& frame, uintptr_t pc) = 0;
	};

	// Creates a new native thread corresponding to the given managed peer.
	// Used to implement Thread.start.
	static void Create(Object* peer, size_t stack_size);

	// Attaches the calling native thread to the runtime, returning the new native peer.
	// Used to implement JNI AttachCurrentThread and AttachCurrentThreadAsDaemon calls.
	static Thread* Attach(const char* thread_name, bool as_daemon, Object* thread_group);

	// Reset internal state of child thread after fork.
	void InitAfterFork();

	static Thread* Current() {
	void* thread = pthread_getspecific(Thread::pthread_key_self_);
	return reinterpret_cast<Thread*>(thread);
	}

	static Thread* FromManagedThread(Object* thread_peer);
	static Thread* FromManagedThread(JNIEnv* env, jobject thread);
	static uint32_t LockOwnerFromThreadLock(Object* thread_lock);

	// Translates 172 to pAllocArrayFromCode and so on.
	static void DumpThreadOffset(std::ostream& os, uint32_t offset, size_t size_of_pointers);

	// When full == true, dumps the detailed thread state and the thread stack (used for SIGQUIT).
	// When full == false, dumps a one-line summary of thread state (used for operator<<).
	void Dump(std::ostream& os, bool full = true) const;

	ThreadState GetState() const {
	return state_;
	}

	ThreadState SetState(ThreadState new_state);
	void SetStateWithoutSuspendCheck(ThreadState new_state);

	bool IsDaemon();
	bool IsSuspended();

	void WaitUntilSuspended();

	bool HoldsLock(Object*);

	/*
	* Changes the priority of this thread to match that of the java.lang.Thread object.
	*
	* We map a priority value from 1-10 to Linux "nice" values, where lower
	* numbers indicate higher priority.
	*/
	void SetNativePriority(int newPriority);

	/*
	* Returns the thread priority for the current thread by querying the system.
	* This is useful when attaching a thread through JNI.
	*
	* Returns a value from 1 to 10 (compatible with java.lang.Thread values).
	*/
	static int GetNativePriority();

	// Returns the "main" ThreadGroup, used when attaching user threads.
	static Object* GetMainThreadGroup();
	// Returns the "system" ThreadGroup, used when attaching our internal threads.
	static Object* GetSystemThreadGroup();

	bool CanAccessDirectReferences() const {
	#ifdef MOVING_GARBAGE_COLLECTOR
	// TODO: when we have a moving collector, we'll need: return state_ == kRunnable;
	#endif
	return true;
	}

	uint32_t GetThinLockId() const {
	return thin_lock_id_;
	}

	pid_t GetTid() const {
	return tid_;
	}

	// Returns the java.lang.Thread's name, or NULL if this Thread* doesn't have a peer.
	String* GetThreadName() const;

	// Sets 'name' to the java.lang.Thread's name. This requires no transition to managed code,
	// allocation, or locking.
	void GetThreadName(std::string& name) const;

	// Sets the thread's name.
	void SetThreadName(const char* name);

	Object* GetPeer() const {
	return peer_;
	}

	Object* GetThreadGroup() const;

	RuntimeStats* GetStats() {
	return &stats_;
	}

	int GetSuspendCount() const {
	return suspend_count_;
	}

	// Returns the current Method* and native PC (not dex PC) for this thread.
	Method* GetCurrentMethod(uintptr_t* pc = NULL, Method*** sp = NULL) const;

	bool IsExceptionPending() const {
	return exception_ != NULL;
	}

	Throwable* GetException() const {
	DCHECK(CanAccessDirectReferences());
	return exception_;
	}

	void SetException(Throwable* new_exception) {
	DCHECK(CanAccessDirectReferences());
	CHECK(new_exception != NULL);
	// TODO: CHECK(exception_ == NULL);
	exception_ = new_exception; // TODO
	}

	void ClearException() {
	exception_ = NULL;
	}

	// Find catch block and perform long jump to appropriate exception handle
	void DeliverException();

	Context* GetLongJumpContext();

	Frame GetTopOfStack() const {
	return top_of_managed_stack_;
	}

	// TODO: this is here for testing, remove when we have exception unit tests
	// that use the real stack
	void SetTopOfStack(void* stack, uintptr_t pc) {
	top_of_managed_stack_.SetSP(reinterpret_cast<Method**>(stack));
	top_of_managed_stack_pc_ = pc;
	}

	void SetTopOfStackPC(uintptr_t pc) {
	top_of_managed_stack_pc_ = pc;
	}

	// 'msg' may be NULL.
	void ThrowNewException(const char* exception_class_descriptor, const char* msg);

	void ThrowNewExceptionF(const char* exception_class_descriptor, const char* fmt, ...)
	__attribute__((format(printf, 3, 4)));

	void ThrowNewExceptionV(const char* exception_class_descriptor, const char* fmt, va_list ap);

	// OutOfMemoryError is special, because we need to pre-allocate an instance.
	// Only the GC should call this.
	void ThrowOutOfMemoryError(const char* msg);

	Frame FindExceptionHandler(void* throw_pc, void** handler_pc);

	void* FindExceptionHandlerInMethod(const Method* method,
	void* throw_pc,
	const DexFile& dex_file,
	ClassLinker* class_linker);

	static void Startup();
	static void FinishStartup();
	static void Shutdown();

	// JNI methods
	JNIEnvExt* GetJniEnv() const {
	return jni_env_;
	}

	// Number of references in SIRTs on this thread
	size_t NumSirtReferences();

	// Number of references allocated in ShadowFrames on this thread
	size_t NumShadowFrameReferences();

	// Number of references allocated in SIRTs & shadow frames on this thread
	size_t NumStackReferences() {
	return NumSirtReferences() + NumShadowFrameReferences();
	};

	// Is the given obj in this thread's stack indirect reference table?
	bool SirtContains(jobject obj);

	// Is the given obj in this thread's ShadowFrame?
	bool ShadowFrameContains(jobject obj);

	// Is the given obj in this thread's Sirts & ShadowFrames?
	bool StackReferencesContain(jobject obj);

	void SirtVisitRoots(Heap::RootVisitor* visitor, void* arg);

	void ShadowFrameVisitRoots(Heap::RootVisitor* visitor, void* arg);

	// Convert a jobject into a Object*
	Object* DecodeJObject(jobject obj);

	// Implements java.lang.Thread.interrupted.
	bool Interrupted() {
	MutexLock mu(*wait_mutex_);
	bool interrupted = interrupted_;
	interrupted_ = false;
	return interrupted;
	}

	// Implements java.lang.Thread.isInterrupted.
	bool IsInterrupted() {
	MutexLock mu(*wait_mutex_);
	return interrupted_;
	}

	void Interrupt() {
	MutexLock mu(*wait_mutex_);
	if (interrupted_) {
	return;
	}
	interrupted_ = true;
	NotifyLocked();
	}

	void Notify() {
	MutexLock mu(*wait_mutex_);
	NotifyLocked();
	}

	// Linked list recording transitions from native to managed code
	void PushNativeToManagedRecord(NativeToManagedRecord* record);
	void PopNativeToManagedRecord(const NativeToManagedRecord& record);

	const ClassLoader* GetClassLoaderOverride() {
	// TODO: need to place the class_loader_override_ in a handle
	// DCHECK(CanAccessDirectReferences());
	return class_loader_override_;
	}

	void SetClassLoaderOverride(const ClassLoader* class_loader_override) {
	class_loader_override_ = class_loader_override;
	}

	// Create the internal representation of a stack trace, that is more time
	// and space efficient to compute than the StackTraceElement[]
	jobject CreateInternalStackTrace(JNIEnv* env) const;

	// Convert an internal stack trace representation (returned by CreateInternalStackTrace) to a
	// StackTraceElement[]. If output_array is NULL, a new array is created, otherwise as many
	// frames as will fit are written into the given array. If stack_depth is non-NULL, it's updated
	// with the number of valid frames in the returned array.
	static jobjectArray InternalStackTraceToStackTraceElementArray(JNIEnv* env, jobject internal,
	jobjectArray output_array = NULL, int* stack_depth = NULL);

	void VisitRoots(Heap::RootVisitor* visitor, void* arg);

	#if VERIFY_OBJECT_ENABLED
	void VerifyStack();
	#else
	void VerifyStack() {}
	#endif

	//
	// Offsets of various members of native Thread class, used by compiled code.
	//

	static ThreadOffset SelfOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, self_));
	}

	static ThreadOffset ExceptionOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, exception_));
	}

	static ThreadOffset ThinLockIdOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, thin_lock_id_));
	}

	static ThreadOffset CardTableOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, card_table_));
	}

	static ThreadOffset SuspendCountOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, suspend_count_));
	}

	static ThreadOffset StateOffset() {
	return ThreadOffset(OFFSETOF_VOLATILE_MEMBER(Thread, state_));
	}

	// Size of stack less any space reserved for stack overflow
	size_t GetStackSize() {
	return stack_size_ - (stack_end_ - stack_begin_);
	}

	// Set the stack end to that to be used during a stack overflow
	void SetStackEndForStackOverflow() {
	// During stack overflow we allow use of the full stack
	if (stack_end_ == stack_begin_) {
	DumpStack(std::cerr);
	LOG(FATAL) << "Need to increase kStackOverflowReservedBytes (currently "
	<< kStackOverflowReservedBytes << ")";
	}

	stack_end_ = stack_begin_;
	}

	// Set the stack end to that to be used during regular execution
	void ResetDefaultStackEnd() {
	// Our stacks grow down, so we want stack_end_ to be near there, but reserving enough room
	// to throw a StackOverflowError.
	stack_end_ = stack_begin_ + kStackOverflowReservedBytes;
	}

	static ThreadOffset StackEndOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, stack_end_));
	}

	static ThreadOffset JniEnvOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, jni_env_));
	}

	static ThreadOffset TopOfManagedStackOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, top_of_managed_stack_) +
	OFFSETOF_MEMBER(Frame, sp_));
	}

	static ThreadOffset TopOfManagedStackPcOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, top_of_managed_stack_pc_));
	}

	void PushShadowFrame(ShadowFrame* frame);
	ShadowFrame* PopShadowFrame();

	static ThreadOffset TopShadowFrameOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, top_shadow_frame_));
	}

	void PushSirt(StackIndirectReferenceTable* sirt);
	StackIndirectReferenceTable* PopSirt();

	static ThreadOffset TopSirtOffset() {
	return ThreadOffset(OFFSETOF_MEMBER(Thread, top_sirt_));
	}

	void WalkStack(StackVisitor* visitor, bool include_upcalls = false) const;

	DebugInvokeReq* GetInvokeReq() {
	return debug_invoke_req_;
	}

	void SetDebuggerUpdatesEnabled(bool enabled);

	bool IsTraceStackEmpty() const {
	return trace_stack_->empty();
	}

	TraceStackFrame GetTraceStackFrame(uint32_t depth) const {
	return trace_stack_->at(trace_stack_->size() - depth - 1);
	}

	void PushTraceStackFrame(const TraceStackFrame& frame) {
	trace_stack_->push_back(frame);
	}

	TraceStackFrame PopTraceStackFrame() {
	TraceStackFrame frame = trace_stack_->back();
	trace_stack_->pop_back();
	return frame;
	}

	void CheckSafeToLockOrUnlock(MutexRank rank, bool is_locking);
	void CheckSafeToWait(MutexRank rank);

	private:
	Thread();
	~Thread();
	void Destroy();
	friend class ThreadList; // For ~Thread and Destroy.

	void CreatePeer(const char* name, bool as_daemon, Object* thread_group);
	friend class Runtime; // For CreatePeer.

	void DumpState(std::ostream& os) const;
	void DumpStack(std::ostream& os) const;
	void DumpNativeStack(std::ostream& os) const;

	// Out-of-line conveniences for debugging in gdb.
	static Thread* CurrentFromGdb(); // Like Thread::Current.
	void DumpFromGdb() const; // Like Thread::Dump(std::cerr).

	static void* CreateCallback(void* arg);

	void HandleUncaughtExceptions();
	void RemoveFromThreadGroup();

	void Init();
	void InitCardTable();
	void InitCpu();
	void InitFunctionPointers();
	void InitTid();
	void InitPthreadKeySelf();
	void InitStackHwm();

	void NotifyLocked() {
	if (wait_monitor_ != NULL) {
	wait_cond_->Signal();
	}
	}

	static void ThreadExitCallback(void* arg);

	// Thin lock thread id. This is a small integer used by the thin lock implementation.
	// This is not to be confused with the native thread's tid, nor is it the value returned
	// by java.lang.Thread.getId --- this is a distinct value, used only for locking. One
	// important difference between this id and the ids visible to managed code is that these
	// ones get reused (to ensure that they fit in the number of bits available).
	uint32_t thin_lock_id_;

	// System thread id.
	pid_t tid_;

	// Our managed peer (an instance of java.lang.Thread).
	Object* peer_;

	// The top_of_managed_stack_ and top_of_managed_stack_pc_ fields are accessed from
	// compiled code, so we keep them early in the structure to (a) avoid having to keep
	// fixing the assembler offsets and (b) improve the chances that these will still be aligned.

	// Top of the managed stack, written out prior to the state transition from
	// kRunnable to kNative. Uses include giving the starting point for scanning
	// a managed stack when a thread is in native code.
	Frame top_of_managed_stack_;
	// PC corresponding to the call out of the top_of_managed_stack_ frame
	uintptr_t top_of_managed_stack_pc_;

	// Guards the 'interrupted_' and 'wait_monitor_' members.
	mutable Mutex* wait_mutex_;
	ConditionVariable* wait_cond_;
	// Pointer to the monitor lock we're currently waiting on (or NULL), guarded by wait_mutex_.
	Monitor* wait_monitor_;
	// Thread "interrupted" status; stays raised until queried or thrown, guarded by wait_mutex_.
	uint32_t interrupted_;
	// The next thread in the wait set this thread is part of.
	Thread* wait_next_;
	// If we're blocked in MonitorEnter, this is the object we're trying to lock.
	Object* monitor_enter_object_;

	friend class Monitor;

	RuntimeStats stats_;

	// The biased card table, see CardTable for details
	byte* card_table_;

	// The end of this thread's stack. This is the lowest safely-addressable address on the stack.
	// We leave extra space so there's room for the code that throws StackOverflowError.
	byte* stack_end_;

	// Size of the stack
	size_t stack_size_;

	// The "lowest addressable byte" of the stack
	byte* stack_begin_;

	// A linked list (of stack allocated records) recording transitions from
	// native to managed code.
	NativeToManagedRecord* native_to_managed_record_;

	// Top of linked list of stack indirect reference tables or NULL for none
	StackIndirectReferenceTable* top_sirt_;

	// Top of linked list of shadow stack or NULL for none
	// Some backend may require shadow frame to ease the GC work.
	ShadowFrame* top_shadow_frame_;

	// Every thread may have an associated JNI environment
	JNIEnvExt* jni_env_;

	volatile ThreadState state_;

	// Initialized to "this". On certain architectures (such as x86) reading
	// off of Thread::Current is easy but getting the address of Thread::Current
	// is hard. This field can be read off of Thread::Current to give the address.
	Thread* self_;

	Runtime* runtime_;

	// The pending exception or NULL.
	Throwable* exception_;

	// A non-zero value is used to tell the current thread to enter a safe point
	// at the next poll.
	int suspend_count_;
	// How much of 'suspend_count_' is by request of the debugger, used to set things right
	// when the debugger detaches. Must be <= suspend_count_.
	int debug_suspend_count_;

	// Needed to get the right ClassLoader in JNI_OnLoad, but also
	// useful for testing.
	const ClassLoader* class_loader_override_;

	// Thread local, lazily allocated, long jump context. Used to deliver exceptions.
	Context* long_jump_context_;

	// A boolean telling us whether we're recursively throwing OOME.
	uint32_t throwing_OutOfMemoryError_;

	Throwable* pre_allocated_OutOfMemoryError_;

	// JDWP invoke-during-breakpoint support.
	DebugInvokeReq* debug_invoke_req_;

	// TLS key used to retrieve the Thread*.
	static pthread_key_t pthread_key_self_;

	// Additional stack used by method tracer to store method and return pc values.
	// Stored as a pointer since std::vector is not PACKED.
	std::vector<TraceStackFrame>* trace_stack_;

	// A cached copy of the java.lang.Thread's name.
	std::string* name_;

	uint32_t held_mutexes_[kMaxMutexRank + 1];

	public:
	// Runtime support function pointers
	EntryPoints entrypoints_;

	private:
	DISALLOW_COPY_AND_ASSIGN(Thread);
	};

	std::ostream& operator<<(std::ostream& os, const Thread& thread);
	std::ostream& operator<<(std::ostream& os, const ThreadState& state);

	class ScopedThreadStateChange {
	public:
	ScopedThreadStateChange(Thread* thread, ThreadState new_state) : thread_(thread) {
	old_thread_state_ = thread_->SetState(new_state);
	}

	~ScopedThreadStateChange() {
	thread_->SetState(old_thread_state_);
	}

	private:
	Thread* thread_;
	ThreadState old_thread_state_;
	DISALLOW_COPY_AND_ASSIGN(ScopedThreadStateChange);
	};

	} // namespace art

	#endif // ART_SRC_THREAD_H_