src/third_party/llvm-project/lldb/tools/debugserver/source/MacOSX/MachThreadList.cpp - cobalt - Git at Google

 //===-- MachThreadList.cpp --------------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 //  Created by Greg Clayton on 6/19/07.
 //
 //===----------------------------------------------------------------------===//

 #include "MachThreadList.h"

 #include <inttypes.h>
 #include <sys/sysctl.h>

 #include "DNBLog.h"
 #include "DNBThreadResumeActions.h"
 #include "MachProcess.h"

 MachThreadList::MachThreadList()
     : m_threads(), m_threads_mutex(PTHREAD_MUTEX_RECURSIVE),
       m_is_64_bit(false) {}

 MachThreadList::~MachThreadList() {}

 nub_state_t MachThreadList::GetState(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetState();
   return eStateInvalid;
 }

 const char *MachThreadList::GetName(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetName();
   return NULL;
 }

 ThreadInfo::QoS MachThreadList::GetRequestedQoS(nub_thread_t tid,
                                                 nub_addr_t tsd,
                                                 uint64_t dti_qos_class_index) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetRequestedQoS(tsd, dti_qos_class_index);
   return ThreadInfo::QoS();
 }

 nub_addr_t MachThreadList::GetPThreadT(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetPThreadT();
   return INVALID_NUB_ADDRESS;
 }

 nub_addr_t MachThreadList::GetDispatchQueueT(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetDispatchQueueT();
   return INVALID_NUB_ADDRESS;
 }

 nub_addr_t MachThreadList::GetTSDAddressForThread(
     nub_thread_t tid, uint64_t plo_pthread_tsd_base_address_offset,
     uint64_t plo_pthread_tsd_base_offset, uint64_t plo_pthread_tsd_entry_size) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetTSDAddressForThread(
         plo_pthread_tsd_base_address_offset, plo_pthread_tsd_base_offset,
         plo_pthread_tsd_entry_size);
   return INVALID_NUB_ADDRESS;
 }

 nub_thread_t MachThreadList::SetCurrentThread(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp) {
     m_current_thread = thread_sp;
     return tid;
   }
   return INVALID_NUB_THREAD;
 }

 bool MachThreadList::GetThreadStoppedReason(
     nub_thread_t tid, struct DNBThreadStopInfo *stop_info) const {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetStopException().GetStopInfo(stop_info);
   return false;
 }

 bool MachThreadList::GetIdentifierInfo(
     nub_thread_t tid, thread_identifier_info_data_t *ident_info) {
   thread_t mach_port_number = GetMachPortNumberByThreadID(tid);

   mach_msg_type_number_t count = THREAD_IDENTIFIER_INFO_COUNT;
   return ::thread_info(mach_port_number, THREAD_IDENTIFIER_INFO,
                        (thread_info_t)ident_info, &count) == KERN_SUCCESS;
 }

 void MachThreadList::DumpThreadStoppedReason(nub_thread_t tid) const {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     thread_sp->GetStopException().DumpStopReason();
 }

 const char *MachThreadList::GetThreadInfo(nub_thread_t tid) const {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetBasicInfoAsString();
   return NULL;
 }

 MachThreadSP MachThreadList::GetThreadByID(nub_thread_t tid) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   MachThreadSP thread_sp;
   const size_t num_threads = m_threads.size();
   for (size_t idx = 0; idx < num_threads; ++idx) {
     if (m_threads[idx]->ThreadID() == tid) {
       thread_sp = m_threads[idx];
       break;
     }
   }
   return thread_sp;
 }

 MachThreadSP
 MachThreadList::GetThreadByMachPortNumber(thread_t mach_port_number) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   MachThreadSP thread_sp;
   const size_t num_threads = m_threads.size();
   for (size_t idx = 0; idx < num_threads; ++idx) {
     if (m_threads[idx]->MachPortNumber() == mach_port_number) {
       thread_sp = m_threads[idx];
       break;
     }
   }
   return thread_sp;
 }

 nub_thread_t
 MachThreadList::GetThreadIDByMachPortNumber(thread_t mach_port_number) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   MachThreadSP thread_sp;
   const size_t num_threads = m_threads.size();
   for (size_t idx = 0; idx < num_threads; ++idx) {
     if (m_threads[idx]->MachPortNumber() == mach_port_number) {
       return m_threads[idx]->ThreadID();
     }
   }
   return INVALID_NUB_THREAD;
 }

 thread_t MachThreadList::GetMachPortNumberByThreadID(
     nub_thread_t globally_unique_id) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   MachThreadSP thread_sp;
   const size_t num_threads = m_threads.size();
   for (size_t idx = 0; idx < num_threads; ++idx) {
     if (m_threads[idx]->ThreadID() == globally_unique_id) {
       return m_threads[idx]->MachPortNumber();
     }
   }
   return 0;
 }

 bool MachThreadList::GetRegisterValue(nub_thread_t tid, uint32_t set,
                                       uint32_t reg,
                                       DNBRegisterValue *reg_value) const {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetRegisterValue(set, reg, reg_value);

   return false;
 }

 bool MachThreadList::SetRegisterValue(nub_thread_t tid, uint32_t set,
                                       uint32_t reg,
                                       const DNBRegisterValue *reg_value) const {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->SetRegisterValue(set, reg, reg_value);

   return false;
 }

 nub_size_t MachThreadList::GetRegisterContext(nub_thread_t tid, void *buf,
                                               size_t buf_len) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->GetRegisterContext(buf, buf_len);
   return 0;
 }

 nub_size_t MachThreadList::SetRegisterContext(nub_thread_t tid, const void *buf,
                                               size_t buf_len) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->SetRegisterContext(buf, buf_len);
   return 0;
 }

 uint32_t MachThreadList::SaveRegisterState(nub_thread_t tid) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->SaveRegisterState();
   return 0;
 }

 bool MachThreadList::RestoreRegisterState(nub_thread_t tid, uint32_t save_id) {
   MachThreadSP thread_sp(GetThreadByID(tid));
   if (thread_sp)
     return thread_sp->RestoreRegisterState(save_id);
   return 0;
 }

 nub_size_t MachThreadList::NumThreads() const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   return m_threads.size();
 }

 nub_thread_t MachThreadList::ThreadIDAtIndex(nub_size_t idx) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   if (idx < m_threads.size())
     return m_threads[idx]->ThreadID();
   return INVALID_NUB_THREAD;
 }

 nub_thread_t MachThreadList::CurrentThreadID() {
   MachThreadSP thread_sp;
   CurrentThread(thread_sp);
   if (thread_sp.get())
     return thread_sp->ThreadID();
   return INVALID_NUB_THREAD;
 }

 bool MachThreadList::NotifyException(MachException::Data &exc) {
   MachThreadSP thread_sp(GetThreadByMachPortNumber(exc.thread_port));
   if (thread_sp) {
     thread_sp->NotifyException(exc);
     return true;
   }
   return false;
 }

 void MachThreadList::Clear() {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   m_threads.clear();
 }

 uint32_t
 MachThreadList::UpdateThreadList(MachProcess *process, bool update,
                                  MachThreadList::collection *new_threads) {
   // locker will keep a mutex locked until it goes out of scope
   DNBLogThreadedIf(LOG_THREAD, "MachThreadList::UpdateThreadList (pid = %4.4x, "
                                "update = %u) process stop count = %u",
                    process->ProcessID(), update, process->StopCount());
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);

   if (process->StopCount() == 0) {
     int mib[4] = {CTL_KERN, KERN_PROC, KERN_PROC_PID, process->ProcessID()};
     struct kinfo_proc processInfo;
     size_t bufsize = sizeof(processInfo);
     if (sysctl(mib, (unsigned)(sizeof(mib) / sizeof(int)), &processInfo,
                &bufsize, NULL, 0) == 0 &&
         bufsize > 0) {
       if (processInfo.kp_proc.p_flag & P_LP64)
         m_is_64_bit = true;
     }
 #if defined(__i386__) || defined(__x86_64__)
     if (m_is_64_bit)
       DNBArchProtocol::SetArchitecture(CPU_TYPE_X86_64);
     else
       DNBArchProtocol::SetArchitecture(CPU_TYPE_I386);
 #elif defined(__arm__) || defined(__arm64__) || defined(__aarch64__)
     if (m_is_64_bit)
       DNBArchProtocol::SetArchitecture(CPU_TYPE_ARM64);
     else
       DNBArchProtocol::SetArchitecture(CPU_TYPE_ARM);
 #endif
   }

   if (m_threads.empty() || update) {
     thread_array_t thread_list = NULL;
     mach_msg_type_number_t thread_list_count = 0;
     task_t task = process->Task().TaskPort();
     DNBError err(::task_threads(task, &thread_list, &thread_list_count),
                  DNBError::MachKernel);

     if (DNBLogCheckLogBit(LOG_THREAD) || err.Fail())
       err.LogThreaded("::task_threads ( task = 0x%4.4x, thread_list => %p, "
                       "thread_list_count => %u )",
                       task, thread_list, thread_list_count);

     if (err.Status() == KERN_SUCCESS && thread_list_count > 0) {
       MachThreadList::collection currThreads;
       size_t idx;
       // Iterator through the current thread list and see which threads
       // we already have in our list (keep them), which ones we don't
       // (add them), and which ones are not around anymore (remove them).
       for (idx = 0; idx < thread_list_count; ++idx) {
         const thread_t mach_port_num = thread_list[idx];

         uint64_t unique_thread_id =
             MachThread::GetGloballyUniqueThreadIDForMachPortID(mach_port_num);
         MachThreadSP thread_sp(GetThreadByID(unique_thread_id));
         if (thread_sp) {
           // Keep the existing thread class
           currThreads.push_back(thread_sp);
         } else {
           // We don't have this thread, lets add it.
           thread_sp.reset(new MachThread(process, m_is_64_bit, unique_thread_id,
                                          mach_port_num));

           // Add the new thread regardless of its is user ready state...
           // Make sure the thread is ready to be displayed and shown to users
           // before we add this thread to our list...
           if (thread_sp->IsUserReady()) {
             if (new_threads)
               new_threads->push_back(thread_sp);

             currThreads.push_back(thread_sp);
           }
         }
       }

       m_threads.swap(currThreads);
       m_current_thread.reset();

       // Free the vm memory given to us by ::task_threads()
       vm_size_t thread_list_size =
           (vm_size_t)(thread_list_count * sizeof(thread_t));
       ::vm_deallocate(::mach_task_self(), (vm_address_t)thread_list,
                       thread_list_size);
     }
   }
   return static_cast<uint32_t>(m_threads.size());
 }

 void MachThreadList::CurrentThread(MachThreadSP &thread_sp) {
   // locker will keep a mutex locked until it goes out of scope
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   if (m_current_thread.get() == NULL) {
     // Figure out which thread is going to be our current thread.
     // This is currently done by finding the first thread in the list
     // that has a valid exception.
     const size_t num_threads = m_threads.size();
     for (uint32_t idx = 0; idx < num_threads; ++idx) {
       if (m_threads[idx]->GetStopException().IsValid()) {
         m_current_thread = m_threads[idx];
         break;
       }
     }
   }
   thread_sp = m_current_thread;
 }

 void MachThreadList::Dump() const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   const size_t num_threads = m_threads.size();
   for (uint32_t idx = 0; idx < num_threads; ++idx) {
     m_threads[idx]->Dump(idx);
   }
 }

 void MachThreadList::ProcessWillResume(
     MachProcess *process, const DNBThreadResumeActions &thread_actions) {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);

   // Update our thread list, because sometimes libdispatch or the kernel
   // will spawn threads while a task is suspended.
   MachThreadList::collection new_threads;

   // First figure out if we were planning on running only one thread, and if so
   // force that thread to resume.
   bool run_one_thread;
   nub_thread_t solo_thread = INVALID_NUB_THREAD;
   if (thread_actions.GetSize() > 0 &&
       thread_actions.NumActionsWithState(eStateStepping) +
               thread_actions.NumActionsWithState(eStateRunning) ==
           1) {
     run_one_thread = true;
     const DNBThreadResumeAction *action_ptr = thread_actions.GetFirst();
     size_t num_actions = thread_actions.GetSize();
     for (size_t i = 0; i < num_actions; i++, action_ptr++) {
       if (action_ptr->state == eStateStepping ||
           action_ptr->state == eStateRunning) {
         solo_thread = action_ptr->tid;
         break;
       }
     }
   } else
     run_one_thread = false;

   UpdateThreadList(process, true, &new_threads);

   DNBThreadResumeAction resume_new_threads = {-1U, eStateRunning, 0,
                                               INVALID_NUB_ADDRESS};
   // If we are planning to run only one thread, any new threads should be
   // suspended.
   if (run_one_thread)
     resume_new_threads.state = eStateSuspended;

   const size_t num_new_threads = new_threads.size();
   const size_t num_threads = m_threads.size();
   for (uint32_t idx = 0; idx < num_threads; ++idx) {
     MachThread *thread = m_threads[idx].get();
     bool handled = false;
     for (uint32_t new_idx = 0; new_idx < num_new_threads; ++new_idx) {
       if (thread == new_threads[new_idx].get()) {
         thread->ThreadWillResume(&resume_new_threads);
         handled = true;
         break;
       }
     }

     if (!handled) {
       const DNBThreadResumeAction *thread_action =
           thread_actions.GetActionForThread(thread->ThreadID(), true);
       // There must always be a thread action for every thread.
       assert(thread_action);
       bool others_stopped = false;
       if (solo_thread == thread->ThreadID())
         others_stopped = true;
       thread->ThreadWillResume(thread_action, others_stopped);
     }
   }

   if (new_threads.size()) {
     for (uint32_t idx = 0; idx < num_new_threads; ++idx) {
       DNBLogThreadedIf(
           LOG_THREAD, "MachThreadList::ProcessWillResume (pid = %4.4x) "
                       "stop-id=%u, resuming newly discovered thread: "
                       "0x%8.8" PRIx64 ", thread-is-user-ready=%i)",
           process->ProcessID(), process->StopCount(),
           new_threads[idx]->ThreadID(), new_threads[idx]->IsUserReady());
     }
   }
 }

 uint32_t MachThreadList::ProcessDidStop(MachProcess *process) {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   // Update our thread list
   const uint32_t num_threads = UpdateThreadList(process, true);
   for (uint32_t idx = 0; idx < num_threads; ++idx) {
     m_threads[idx]->ThreadDidStop();
   }
   return num_threads;
 }

 //----------------------------------------------------------------------
 // Check each thread in our thread list to see if we should notify our
 // client of the current halt in execution.
 //
 // Breakpoints can have callback functions associated with them than
 // can return true to stop, or false to continue executing the inferior.
 //
 // RETURNS
 //    true if we should stop and notify our clients
 //    false if we should resume our child process and skip notification
 //----------------------------------------------------------------------
 bool MachThreadList::ShouldStop(bool &step_more) {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   uint32_t should_stop = false;
   const size_t num_threads = m_threads.size();
   for (uint32_t idx = 0; !should_stop && idx < num_threads; ++idx) {
     should_stop = m_threads[idx]->ShouldStop(step_more);
   }
   return should_stop;
 }

 void MachThreadList::NotifyBreakpointChanged(const DNBBreakpoint *bp) {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   const size_t num_threads = m_threads.size();
   for (uint32_t idx = 0; idx < num_threads; ++idx) {
     m_threads[idx]->NotifyBreakpointChanged(bp);
   }
 }

 uint32_t
 MachThreadList::EnableHardwareBreakpoint(const DNBBreakpoint *bp) const {
   if (bp != NULL) {
     const size_t num_threads = m_threads.size();
     for (uint32_t idx = 0; idx < num_threads; ++idx)
       m_threads[idx]->EnableHardwareBreakpoint(bp);
   }
   return INVALID_NUB_HW_INDEX;
 }

 bool MachThreadList::DisableHardwareBreakpoint(const DNBBreakpoint *bp) const {
   if (bp != NULL) {
     const size_t num_threads = m_threads.size();
     for (uint32_t idx = 0; idx < num_threads; ++idx)
       m_threads[idx]->DisableHardwareBreakpoint(bp);
   }
   return false;
 }

 // DNBWatchpointSet() -> MachProcess::CreateWatchpoint() ->
 // MachProcess::EnableWatchpoint()
 // -> MachThreadList::EnableHardwareWatchpoint().
 uint32_t
 MachThreadList::EnableHardwareWatchpoint(const DNBBreakpoint *wp) const {
   uint32_t hw_index = INVALID_NUB_HW_INDEX;
   if (wp != NULL) {
     PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
     const size_t num_threads = m_threads.size();
     // On Mac OS X we have to prime the control registers for new threads.  We
     // do this
     // using the control register data for the first thread, for lack of a
     // better way of choosing.
     bool also_set_on_task = true;
     for (uint32_t idx = 0; idx < num_threads; ++idx) {
       if ((hw_index = m_threads[idx]->EnableHardwareWatchpoint(
                wp, also_set_on_task)) == INVALID_NUB_HW_INDEX) {
         // We know that idx failed for some reason.  Let's rollback the
         // transaction for [0, idx).
         for (uint32_t i = 0; i < idx; ++i)
           m_threads[i]->RollbackTransForHWP();
         return INVALID_NUB_HW_INDEX;
       }
       also_set_on_task = false;
     }
     // Notify each thread to commit the pending transaction.
     for (uint32_t idx = 0; idx < num_threads; ++idx)
       m_threads[idx]->FinishTransForHWP();
   }
   return hw_index;
 }

 bool MachThreadList::DisableHardwareWatchpoint(const DNBBreakpoint *wp) const {
   if (wp != NULL) {
     PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
     const size_t num_threads = m_threads.size();

     // On Mac OS X we have to prime the control registers for new threads.  We
     // do this
     // using the control register data for the first thread, for lack of a
     // better way of choosing.
     bool also_set_on_task = true;
     for (uint32_t idx = 0; idx < num_threads; ++idx) {
       if (!m_threads[idx]->DisableHardwareWatchpoint(wp, also_set_on_task)) {
         // We know that idx failed for some reason.  Let's rollback the
         // transaction for [0, idx).
         for (uint32_t i = 0; i < idx; ++i)
           m_threads[i]->RollbackTransForHWP();
         return false;
       }
       also_set_on_task = false;
     }
     // Notify each thread to commit the pending transaction.
     for (uint32_t idx = 0; idx < num_threads; ++idx)
       m_threads[idx]->FinishTransForHWP();

     return true;
   }
   return false;
 }

 uint32_t MachThreadList::NumSupportedHardwareWatchpoints() const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   const size_t num_threads = m_threads.size();
   // Use an arbitrary thread to retrieve the number of supported hardware
   // watchpoints.
   if (num_threads)
     return m_threads[0]->NumSupportedHardwareWatchpoints();
   return 0;
 }

 uint32_t MachThreadList::GetThreadIndexForThreadStoppedWithSignal(
     const int signo) const {
   PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
   uint32_t should_stop = false;
   const size_t num_threads = m_threads.size();
   for (uint32_t idx = 0; !should_stop && idx < num_threads; ++idx) {
     if (m_threads[idx]->GetStopException().SoftSignal() == signo)
       return idx;
   }
   return UINT32_MAX;
 }
	//===-- MachThreadList.cpp --------------------------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// Created by Greg Clayton on 6/19/07.
	//
	//===----------------------------------------------------------------------===//

	#include "MachThreadList.h"

	#include <inttypes.h>
	#include <sys/sysctl.h>

	#include "DNBLog.h"
	#include "DNBThreadResumeActions.h"
	#include "MachProcess.h"

	MachThreadList::MachThreadList()
	: m_threads(), m_threads_mutex(PTHREAD_MUTEX_RECURSIVE),
	m_is_64_bit(false) {}

	MachThreadList::~MachThreadList() {}

	nub_state_t MachThreadList::GetState(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetState();
	return eStateInvalid;
	}

	const char *MachThreadList::GetName(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetName();
	return NULL;
	}

	ThreadInfo::QoS MachThreadList::GetRequestedQoS(nub_thread_t tid,
	nub_addr_t tsd,
	uint64_t dti_qos_class_index) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetRequestedQoS(tsd, dti_qos_class_index);
	return ThreadInfo::QoS();
	}

	nub_addr_t MachThreadList::GetPThreadT(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetPThreadT();
	return INVALID_NUB_ADDRESS;
	}

	nub_addr_t MachThreadList::GetDispatchQueueT(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetDispatchQueueT();
	return INVALID_NUB_ADDRESS;
	}

	nub_addr_t MachThreadList::GetTSDAddressForThread(
	nub_thread_t tid, uint64_t plo_pthread_tsd_base_address_offset,
	uint64_t plo_pthread_tsd_base_offset, uint64_t plo_pthread_tsd_entry_size) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetTSDAddressForThread(
	plo_pthread_tsd_base_address_offset, plo_pthread_tsd_base_offset,
	plo_pthread_tsd_entry_size);
	return INVALID_NUB_ADDRESS;
	}

	nub_thread_t MachThreadList::SetCurrentThread(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp) {
	m_current_thread = thread_sp;
	return tid;
	}
	return INVALID_NUB_THREAD;
	}

	bool MachThreadList::GetThreadStoppedReason(
	nub_thread_t tid, struct DNBThreadStopInfo *stop_info) const {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetStopException().GetStopInfo(stop_info);
	return false;
	}

	bool MachThreadList::GetIdentifierInfo(
	nub_thread_t tid, thread_identifier_info_data_t *ident_info) {
	thread_t mach_port_number = GetMachPortNumberByThreadID(tid);

	mach_msg_type_number_t count = THREAD_IDENTIFIER_INFO_COUNT;
	return ::thread_info(mach_port_number, THREAD_IDENTIFIER_INFO,
	(thread_info_t)ident_info, &count) == KERN_SUCCESS;
	}

	void MachThreadList::DumpThreadStoppedReason(nub_thread_t tid) const {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	thread_sp->GetStopException().DumpStopReason();
	}

	const char *MachThreadList::GetThreadInfo(nub_thread_t tid) const {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetBasicInfoAsString();
	return NULL;
	}

	MachThreadSP MachThreadList::GetThreadByID(nub_thread_t tid) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	MachThreadSP thread_sp;
	const size_t num_threads = m_threads.size();
	for (size_t idx = 0; idx < num_threads; ++idx) {
	if (m_threads[idx]->ThreadID() == tid) {
	thread_sp = m_threads[idx];
	break;
	}
	}
	return thread_sp;
	}

	MachThreadSP
	MachThreadList::GetThreadByMachPortNumber(thread_t mach_port_number) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	MachThreadSP thread_sp;
	const size_t num_threads = m_threads.size();
	for (size_t idx = 0; idx < num_threads; ++idx) {
	if (m_threads[idx]->MachPortNumber() == mach_port_number) {
	thread_sp = m_threads[idx];
	break;
	}
	}
	return thread_sp;
	}

	nub_thread_t
	MachThreadList::GetThreadIDByMachPortNumber(thread_t mach_port_number) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	MachThreadSP thread_sp;
	const size_t num_threads = m_threads.size();
	for (size_t idx = 0; idx < num_threads; ++idx) {
	if (m_threads[idx]->MachPortNumber() == mach_port_number) {
	return m_threads[idx]->ThreadID();
	}
	}
	return INVALID_NUB_THREAD;
	}

	thread_t MachThreadList::GetMachPortNumberByThreadID(
	nub_thread_t globally_unique_id) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	MachThreadSP thread_sp;
	const size_t num_threads = m_threads.size();
	for (size_t idx = 0; idx < num_threads; ++idx) {
	if (m_threads[idx]->ThreadID() == globally_unique_id) {
	return m_threads[idx]->MachPortNumber();
	}
	}
	return 0;
	}

	bool MachThreadList::GetRegisterValue(nub_thread_t tid, uint32_t set,
	uint32_t reg,
	DNBRegisterValue *reg_value) const {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetRegisterValue(set, reg, reg_value);

	return false;
	}

	bool MachThreadList::SetRegisterValue(nub_thread_t tid, uint32_t set,
	uint32_t reg,
	const DNBRegisterValue *reg_value) const {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->SetRegisterValue(set, reg, reg_value);

	return false;
	}

	nub_size_t MachThreadList::GetRegisterContext(nub_thread_t tid, void *buf,
	size_t buf_len) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->GetRegisterContext(buf, buf_len);
	return 0;
	}

	nub_size_t MachThreadList::SetRegisterContext(nub_thread_t tid, const void *buf,
	size_t buf_len) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->SetRegisterContext(buf, buf_len);
	return 0;
	}

	uint32_t MachThreadList::SaveRegisterState(nub_thread_t tid) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->SaveRegisterState();
	return 0;
	}

	bool MachThreadList::RestoreRegisterState(nub_thread_t tid, uint32_t save_id) {
	MachThreadSP thread_sp(GetThreadByID(tid));
	if (thread_sp)
	return thread_sp->RestoreRegisterState(save_id);
	return 0;
	}

	nub_size_t MachThreadList::NumThreads() const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	return m_threads.size();
	}

	nub_thread_t MachThreadList::ThreadIDAtIndex(nub_size_t idx) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	if (idx < m_threads.size())
	return m_threads[idx]->ThreadID();
	return INVALID_NUB_THREAD;
	}

	nub_thread_t MachThreadList::CurrentThreadID() {
	MachThreadSP thread_sp;
	CurrentThread(thread_sp);
	if (thread_sp.get())
	return thread_sp->ThreadID();
	return INVALID_NUB_THREAD;
	}

	bool MachThreadList::NotifyException(MachException::Data &exc) {
	MachThreadSP thread_sp(GetThreadByMachPortNumber(exc.thread_port));
	if (thread_sp) {
	thread_sp->NotifyException(exc);
	return true;
	}
	return false;
	}

	void MachThreadList::Clear() {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	m_threads.clear();
	}

	uint32_t
	MachThreadList::UpdateThreadList(MachProcess *process, bool update,
	MachThreadList::collection *new_threads) {
	// locker will keep a mutex locked until it goes out of scope
	DNBLogThreadedIf(LOG_THREAD, "MachThreadList::UpdateThreadList (pid = %4.4x, "
	"update = %u) process stop count = %u",
	process->ProcessID(), update, process->StopCount());
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);

	if (process->StopCount() == 0) {
	int mib[4] = {CTL_KERN, KERN_PROC, KERN_PROC_PID, process->ProcessID()};
	struct kinfo_proc processInfo;
	size_t bufsize = sizeof(processInfo);
	if (sysctl(mib, (unsigned)(sizeof(mib) / sizeof(int)), &processInfo,
	&bufsize, NULL, 0) == 0 &&
	bufsize > 0) {
	if (processInfo.kp_proc.p_flag & P_LP64)
	m_is_64_bit = true;
	}
	#if defined(__i386__) \|\| defined(__x86_64__)
	if (m_is_64_bit)
	DNBArchProtocol::SetArchitecture(CPU_TYPE_X86_64);
	else
	DNBArchProtocol::SetArchitecture(CPU_TYPE_I386);
	#elif defined(__arm__) \|\| defined(__arm64__) \|\| defined(__aarch64__)
	if (m_is_64_bit)
	DNBArchProtocol::SetArchitecture(CPU_TYPE_ARM64);
	else
	DNBArchProtocol::SetArchitecture(CPU_TYPE_ARM);
	#endif
	}

	if (m_threads.empty() \|\| update) {
	thread_array_t thread_list = NULL;
	mach_msg_type_number_t thread_list_count = 0;
	task_t task = process->Task().TaskPort();
	DNBError err(::task_threads(task, &thread_list, &thread_list_count),
	DNBError::MachKernel);

	if (DNBLogCheckLogBit(LOG_THREAD) \|\| err.Fail())
	err.LogThreaded("::task_threads ( task = 0x%4.4x, thread_list => %p, "
	"thread_list_count => %u )",
	task, thread_list, thread_list_count);

	if (err.Status() == KERN_SUCCESS && thread_list_count > 0) {
	MachThreadList::collection currThreads;
	size_t idx;
	// Iterator through the current thread list and see which threads
	// we already have in our list (keep them), which ones we don't
	// (add them), and which ones are not around anymore (remove them).
	for (idx = 0; idx < thread_list_count; ++idx) {
	const thread_t mach_port_num = thread_list[idx];

	uint64_t unique_thread_id =
	MachThread::GetGloballyUniqueThreadIDForMachPortID(mach_port_num);
	MachThreadSP thread_sp(GetThreadByID(unique_thread_id));
	if (thread_sp) {
	// Keep the existing thread class
	currThreads.push_back(thread_sp);
	} else {
	// We don't have this thread, lets add it.
	thread_sp.reset(new MachThread(process, m_is_64_bit, unique_thread_id,
	mach_port_num));

	// Add the new thread regardless of its is user ready state...
	// Make sure the thread is ready to be displayed and shown to users
	// before we add this thread to our list...
	if (thread_sp->IsUserReady()) {
	if (new_threads)
	new_threads->push_back(thread_sp);

	currThreads.push_back(thread_sp);
	}
	}
	}

	m_threads.swap(currThreads);
	m_current_thread.reset();

	// Free the vm memory given to us by ::task_threads()
	vm_size_t thread_list_size =
	(vm_size_t)(thread_list_count * sizeof(thread_t));
	::vm_deallocate(::mach_task_self(), (vm_address_t)thread_list,
	thread_list_size);
	}
	}
	return static_cast<uint32_t>(m_threads.size());
	}

	void MachThreadList::CurrentThread(MachThreadSP &thread_sp) {
	// locker will keep a mutex locked until it goes out of scope
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	if (m_current_thread.get() == NULL) {
	// Figure out which thread is going to be our current thread.
	// This is currently done by finding the first thread in the list
	// that has a valid exception.
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	if (m_threads[idx]->GetStopException().IsValid()) {
	m_current_thread = m_threads[idx];
	break;
	}
	}
	}
	thread_sp = m_current_thread;
	}

	void MachThreadList::Dump() const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	m_threads[idx]->Dump(idx);
	}
	}

	void MachThreadList::ProcessWillResume(
	MachProcess *process, const DNBThreadResumeActions &thread_actions) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);

	// Update our thread list, because sometimes libdispatch or the kernel
	// will spawn threads while a task is suspended.
	MachThreadList::collection new_threads;

	// First figure out if we were planning on running only one thread, and if so
	// force that thread to resume.
	bool run_one_thread;
	nub_thread_t solo_thread = INVALID_NUB_THREAD;
	if (thread_actions.GetSize() > 0 &&
	thread_actions.NumActionsWithState(eStateStepping) +
	thread_actions.NumActionsWithState(eStateRunning) ==
	1) {
	run_one_thread = true;
	const DNBThreadResumeAction *action_ptr = thread_actions.GetFirst();
	size_t num_actions = thread_actions.GetSize();
	for (size_t i = 0; i < num_actions; i++, action_ptr++) {
	if (action_ptr->state == eStateStepping \|\|
	action_ptr->state == eStateRunning) {
	solo_thread = action_ptr->tid;
	break;
	}
	}
	} else
	run_one_thread = false;

	UpdateThreadList(process, true, &new_threads);

	DNBThreadResumeAction resume_new_threads = {-1U, eStateRunning, 0,
	INVALID_NUB_ADDRESS};
	// If we are planning to run only one thread, any new threads should be
	// suspended.
	if (run_one_thread)
	resume_new_threads.state = eStateSuspended;

	const size_t num_new_threads = new_threads.size();
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	MachThread *thread = m_threads[idx].get();
	bool handled = false;
	for (uint32_t new_idx = 0; new_idx < num_new_threads; ++new_idx) {
	if (thread == new_threads[new_idx].get()) {
	thread->ThreadWillResume(&resume_new_threads);
	handled = true;
	break;
	}
	}

	if (!handled) {
	const DNBThreadResumeAction *thread_action =
	thread_actions.GetActionForThread(thread->ThreadID(), true);
	// There must always be a thread action for every thread.
	assert(thread_action);
	bool others_stopped = false;
	if (solo_thread == thread->ThreadID())
	others_stopped = true;
	thread->ThreadWillResume(thread_action, others_stopped);
	}
	}

	if (new_threads.size()) {
	for (uint32_t idx = 0; idx < num_new_threads; ++idx) {
	DNBLogThreadedIf(
	LOG_THREAD, "MachThreadList::ProcessWillResume (pid = %4.4x) "
	"stop-id=%u, resuming newly discovered thread: "
	"0x%8.8" PRIx64 ", thread-is-user-ready=%i)",
	process->ProcessID(), process->StopCount(),
	new_threads[idx]->ThreadID(), new_threads[idx]->IsUserReady());
	}
	}
	}

	uint32_t MachThreadList::ProcessDidStop(MachProcess *process) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	// Update our thread list
	const uint32_t num_threads = UpdateThreadList(process, true);
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	m_threads[idx]->ThreadDidStop();
	}
	return num_threads;
	}

	//----------------------------------------------------------------------
	// Check each thread in our thread list to see if we should notify our
	// client of the current halt in execution.
	//
	// Breakpoints can have callback functions associated with them than
	// can return true to stop, or false to continue executing the inferior.
	//
	// RETURNS
	// true if we should stop and notify our clients
	// false if we should resume our child process and skip notification
	//----------------------------------------------------------------------
	bool MachThreadList::ShouldStop(bool &step_more) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	uint32_t should_stop = false;
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; !should_stop && idx < num_threads; ++idx) {
	should_stop = m_threads[idx]->ShouldStop(step_more);
	}
	return should_stop;
	}

	void MachThreadList::NotifyBreakpointChanged(const DNBBreakpoint *bp) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	m_threads[idx]->NotifyBreakpointChanged(bp);
	}
	}

	uint32_t
	MachThreadList::EnableHardwareBreakpoint(const DNBBreakpoint *bp) const {
	if (bp != NULL) {
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx)
	m_threads[idx]->EnableHardwareBreakpoint(bp);
	}
	return INVALID_NUB_HW_INDEX;
	}

	bool MachThreadList::DisableHardwareBreakpoint(const DNBBreakpoint *bp) const {
	if (bp != NULL) {
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; idx < num_threads; ++idx)
	m_threads[idx]->DisableHardwareBreakpoint(bp);
	}
	return false;
	}

	// DNBWatchpointSet() -> MachProcess::CreateWatchpoint() ->
	// MachProcess::EnableWatchpoint()
	// -> MachThreadList::EnableHardwareWatchpoint().
	uint32_t
	MachThreadList::EnableHardwareWatchpoint(const DNBBreakpoint *wp) const {
	uint32_t hw_index = INVALID_NUB_HW_INDEX;
	if (wp != NULL) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	const size_t num_threads = m_threads.size();
	// On Mac OS X we have to prime the control registers for new threads. We
	// do this
	// using the control register data for the first thread, for lack of a
	// better way of choosing.
	bool also_set_on_task = true;
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	if ((hw_index = m_threads[idx]->EnableHardwareWatchpoint(
	wp, also_set_on_task)) == INVALID_NUB_HW_INDEX) {
	// We know that idx failed for some reason. Let's rollback the
	// transaction for [0, idx).
	for (uint32_t i = 0; i < idx; ++i)
	m_threads[i]->RollbackTransForHWP();
	return INVALID_NUB_HW_INDEX;
	}
	also_set_on_task = false;
	}
	// Notify each thread to commit the pending transaction.
	for (uint32_t idx = 0; idx < num_threads; ++idx)
	m_threads[idx]->FinishTransForHWP();
	}
	return hw_index;
	}

	bool MachThreadList::DisableHardwareWatchpoint(const DNBBreakpoint *wp) const {
	if (wp != NULL) {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	const size_t num_threads = m_threads.size();

	// On Mac OS X we have to prime the control registers for new threads. We
	// do this
	// using the control register data for the first thread, for lack of a
	// better way of choosing.
	bool also_set_on_task = true;
	for (uint32_t idx = 0; idx < num_threads; ++idx) {
	if (!m_threads[idx]->DisableHardwareWatchpoint(wp, also_set_on_task)) {
	// We know that idx failed for some reason. Let's rollback the
	// transaction for [0, idx).
	for (uint32_t i = 0; i < idx; ++i)
	m_threads[i]->RollbackTransForHWP();
	return false;
	}
	also_set_on_task = false;
	}
	// Notify each thread to commit the pending transaction.
	for (uint32_t idx = 0; idx < num_threads; ++idx)
	m_threads[idx]->FinishTransForHWP();

	return true;
	}
	return false;
	}

	uint32_t MachThreadList::NumSupportedHardwareWatchpoints() const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	const size_t num_threads = m_threads.size();
	// Use an arbitrary thread to retrieve the number of supported hardware
	// watchpoints.
	if (num_threads)
	return m_threads[0]->NumSupportedHardwareWatchpoints();
	return 0;
	}

	uint32_t MachThreadList::GetThreadIndexForThreadStoppedWithSignal(
	const int signo) const {
	PTHREAD_MUTEX_LOCKER(locker, m_threads_mutex);
	uint32_t should_stop = false;
	const size_t num_threads = m_threads.size();
	for (uint32_t idx = 0; !should_stop && idx < num_threads; ++idx) {
	if (m_threads[idx]->GetStopException().SoftSignal() == signo)
	return idx;
	}
	return UINT32_MAX;
	}