src/llvm-project/lldb/source/Plugins/OperatingSystem/Python/OperatingSystemPython.cpp - toolchain/rustc - Git at Google

 //===-- OperatingSystemPython.cpp -----------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include "lldb/Host/Config.h"

 #if LLDB_ENABLE_PYTHON

 #include "OperatingSystemPython.h"

 #include "Plugins/Process/Utility/DynamicRegisterInfo.h"
 #include "Plugins/Process/Utility/RegisterContextDummy.h"
 #include "Plugins/Process/Utility/RegisterContextMemory.h"
 #include "Plugins/Process/Utility/ThreadMemory.h"
 #include "lldb/Core/Debugger.h"
 #include "lldb/Core/Module.h"
 #include "lldb/Core/PluginManager.h"
 #include "lldb/Core/ValueObjectVariable.h"
 #include "lldb/Interpreter/CommandInterpreter.h"
 #include "lldb/Interpreter/ScriptInterpreter.h"
 #include "lldb/Symbol/ObjectFile.h"
 #include "lldb/Symbol/VariableList.h"
 #include "lldb/Target/Process.h"
 #include "lldb/Target/StopInfo.h"
 #include "lldb/Target/Target.h"
 #include "lldb/Target/Thread.h"
 #include "lldb/Target/ThreadList.h"
 #include "lldb/Utility/DataBufferHeap.h"
 #include "lldb/Utility/RegisterValue.h"
 #include "lldb/Utility/StreamString.h"
 #include "lldb/Utility/StructuredData.h"

 #include <memory>

 using namespace lldb;
 using namespace lldb_private;

 LLDB_PLUGIN_DEFINE(OperatingSystemPython)

 void OperatingSystemPython::Initialize() {
   PluginManager::RegisterPlugin(GetPluginNameStatic(),
                                 GetPluginDescriptionStatic(), CreateInstance,
                                 nullptr);
 }

 void OperatingSystemPython::Terminate() {
   PluginManager::UnregisterPlugin(CreateInstance);
 }

 OperatingSystem *OperatingSystemPython::CreateInstance(Process *process,
                                                        bool force) {
   // Python OperatingSystem plug-ins must be requested by name, so force must
   // be true
   FileSpec python_os_plugin_spec(process->GetPythonOSPluginPath());
   if (python_os_plugin_spec &&
       FileSystem::Instance().Exists(python_os_plugin_spec)) {
     std::unique_ptr<OperatingSystemPython> os_up(
         new OperatingSystemPython(process, python_os_plugin_spec));
     if (os_up.get() && os_up->IsValid())
       return os_up.release();
   }
   return nullptr;
 }

 ConstString OperatingSystemPython::GetPluginNameStatic() {
   static ConstString g_name("python");
   return g_name;
 }

 const char *OperatingSystemPython::GetPluginDescriptionStatic() {
   return "Operating system plug-in that gathers OS information from a python "
          "class that implements the necessary OperatingSystem functionality.";
 }

 OperatingSystemPython::OperatingSystemPython(lldb_private::Process *process,
                                              const FileSpec &python_module_path)
     : OperatingSystem(process), m_thread_list_valobj_sp(), m_register_info_up(),
       m_interpreter(nullptr), m_python_object_sp() {
   if (!process)
     return;
   TargetSP target_sp = process->CalculateTarget();
   if (!target_sp)
     return;
   m_interpreter = target_sp->GetDebugger().GetScriptInterpreter();
   if (m_interpreter) {

     std::string os_plugin_class_name(
         python_module_path.GetFilename().AsCString(""));
     if (!os_plugin_class_name.empty()) {
       LoadScriptOptions options;
       char python_module_path_cstr[PATH_MAX];
       python_module_path.GetPath(python_module_path_cstr,
                                  sizeof(python_module_path_cstr));
       Status error;
       if (m_interpreter->LoadScriptingModule(python_module_path_cstr, options,
                                              error)) {
         // Strip the ".py" extension if there is one
         size_t py_extension_pos = os_plugin_class_name.rfind(".py");
         if (py_extension_pos != std::string::npos)
           os_plugin_class_name.erase(py_extension_pos);
         // Add ".OperatingSystemPlugIn" to the module name to get a string like
         // "modulename.OperatingSystemPlugIn"
         os_plugin_class_name += ".OperatingSystemPlugIn";
         StructuredData::ObjectSP object_sp =
             m_interpreter->OSPlugin_CreatePluginObject(
                 os_plugin_class_name.c_str(), process->CalculateProcess());
         if (object_sp && object_sp->IsValid())
           m_python_object_sp = object_sp;
       }
     }
   }
 }

 OperatingSystemPython::~OperatingSystemPython() = default;

 DynamicRegisterInfo *OperatingSystemPython::GetDynamicRegisterInfo() {
   if (m_register_info_up == nullptr) {
     if (!m_interpreter || !m_python_object_sp)
       return nullptr;
     Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_OS));

     LLDB_LOGF(log,
               "OperatingSystemPython::GetDynamicRegisterInfo() fetching "
               "thread register definitions from python for pid %" PRIu64,
               m_process->GetID());

     StructuredData::DictionarySP dictionary =
         m_interpreter->OSPlugin_RegisterInfo(m_python_object_sp);
     if (!dictionary)
       return nullptr;

     m_register_info_up = std::make_unique<DynamicRegisterInfo>(
         *dictionary, m_process->GetTarget().GetArchitecture());
     assert(m_register_info_up->GetNumRegisters() > 0);
     assert(m_register_info_up->GetNumRegisterSets() > 0);
   }
   return m_register_info_up.get();
 }

 // PluginInterface protocol
 ConstString OperatingSystemPython::GetPluginName() {
   return GetPluginNameStatic();
 }

 uint32_t OperatingSystemPython::GetPluginVersion() { return 1; }

 bool OperatingSystemPython::UpdateThreadList(ThreadList &old_thread_list,
                                              ThreadList &core_thread_list,
                                              ThreadList &new_thread_list) {
   if (!m_interpreter || !m_python_object_sp)
     return false;

   Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_OS));

   // First thing we have to do is to try to get the API lock, and the
   // interpreter lock. We're going to change the thread content of the process,
   // and we're going to use python, which requires the API lock to do it. We
   // need the interpreter lock to make sure thread_info_dict stays alive.
   //
   // If someone already has the API lock, that is ok, we just want to avoid
   // external code from making new API calls while this call is happening.
   //
   // This is a recursive lock so we can grant it to any Python code called on
   // the stack below us.
   Target &target = m_process->GetTarget();
   std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
                                                   std::defer_lock);
   (void)api_lock.try_lock(); // See above.
   auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

   LLDB_LOGF(log,
             "OperatingSystemPython::UpdateThreadList() fetching thread "
             "data from python for pid %" PRIu64,
             m_process->GetID());

   // The threads that are in "core_thread_list" upon entry are the threads from
   // the lldb_private::Process subclass, no memory threads will be in this
   // list.
   StructuredData::ArraySP threads_list =
       m_interpreter->OSPlugin_ThreadsInfo(m_python_object_sp);

   const uint32_t num_cores = core_thread_list.GetSize(false);

   // Make a map so we can keep track of which cores were used from the
   // core_thread list. Any real threads/cores that weren't used should later be
   // put back into the "new_thread_list".
   std::vector<bool> core_used_map(num_cores, false);
   if (threads_list) {
     if (log) {
       StreamString strm;
       threads_list->Dump(strm);
       LLDB_LOGF(log, "threads_list = %s", strm.GetData());
     }

     const uint32_t num_threads = threads_list->GetSize();
     for (uint32_t i = 0; i < num_threads; ++i) {
       StructuredData::ObjectSP thread_dict_obj =
           threads_list->GetItemAtIndex(i);
       if (auto thread_dict = thread_dict_obj->GetAsDictionary()) {
         ThreadSP thread_sp(CreateThreadFromThreadInfo(
             *thread_dict, core_thread_list, old_thread_list, core_used_map,
             nullptr));
         if (thread_sp)
           new_thread_list.AddThread(thread_sp);
       }
     }
   }

   // Any real core threads that didn't end up backing a memory thread should
   // still be in the main thread list, and they should be inserted at the
   // beginning of the list
   uint32_t insert_idx = 0;
   for (uint32_t core_idx = 0; core_idx < num_cores; ++core_idx) {
     if (!core_used_map[core_idx]) {
       new_thread_list.InsertThread(
           core_thread_list.GetThreadAtIndex(core_idx, false), insert_idx);
       ++insert_idx;
     }
   }

   return new_thread_list.GetSize(false) > 0;
 }

 ThreadSP OperatingSystemPython::CreateThreadFromThreadInfo(
     StructuredData::Dictionary &thread_dict, ThreadList &core_thread_list,
     ThreadList &old_thread_list, std::vector<bool> &core_used_map,
     bool *did_create_ptr) {
   ThreadSP thread_sp;
   tid_t tid = LLDB_INVALID_THREAD_ID;
   if (!thread_dict.GetValueForKeyAsInteger("tid", tid))
     return ThreadSP();

   uint32_t core_number;
   addr_t reg_data_addr;
   llvm::StringRef name;
   llvm::StringRef queue;

   thread_dict.GetValueForKeyAsInteger("core", core_number, UINT32_MAX);
   thread_dict.GetValueForKeyAsInteger("register_data_addr", reg_data_addr,
                                       LLDB_INVALID_ADDRESS);
   thread_dict.GetValueForKeyAsString("name", name);
   thread_dict.GetValueForKeyAsString("queue", queue);

   // See if a thread already exists for "tid"
   thread_sp = old_thread_list.FindThreadByID(tid, false);
   if (thread_sp) {
     // A thread already does exist for "tid", make sure it was an operating
     // system
     // plug-in generated thread.
     if (!IsOperatingSystemPluginThread(thread_sp)) {
       // We have thread ID overlap between the protocol threads and the
       // operating system threads, clear the thread so we create an operating
       // system thread for this.
       thread_sp.reset();
     }
   }

   if (!thread_sp) {
     if (did_create_ptr)
       *did_create_ptr = true;
     thread_sp = std::make_shared<ThreadMemory>(*m_process, tid, name, queue,
                                                reg_data_addr);
   }

   if (core_number < core_thread_list.GetSize(false)) {
     ThreadSP core_thread_sp(
         core_thread_list.GetThreadAtIndex(core_number, false));
     if (core_thread_sp) {
       // Keep track of which cores were set as the backing thread for memory
       // threads...
       if (core_number < core_used_map.size())
         core_used_map[core_number] = true;

       ThreadSP backing_core_thread_sp(core_thread_sp->GetBackingThread());
       if (backing_core_thread_sp) {
         thread_sp->SetBackingThread(backing_core_thread_sp);
       } else {
         thread_sp->SetBackingThread(core_thread_sp);
       }
     }
   }
   return thread_sp;
 }

 void OperatingSystemPython::ThreadWasSelected(Thread *thread) {}

 RegisterContextSP
 OperatingSystemPython::CreateRegisterContextForThread(Thread *thread,
                                                       addr_t reg_data_addr) {
   RegisterContextSP reg_ctx_sp;
   if (!m_interpreter || !m_python_object_sp || !thread)
     return reg_ctx_sp;

   if (!IsOperatingSystemPluginThread(thread->shared_from_this()))
     return reg_ctx_sp;

   // First thing we have to do is to try to get the API lock, and the
   // interpreter lock. We're going to change the thread content of the process,
   // and we're going to use python, which requires the API lock to do it. We
   // need the interpreter lock to make sure thread_info_dict stays alive.
   //
   // If someone already has the API lock, that is ok, we just want to avoid
   // external code from making new API calls while this call is happening.
   //
   // This is a recursive lock so we can grant it to any Python code called on
   // the stack below us.
   Target &target = m_process->GetTarget();
   std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
                                                   std::defer_lock);
   (void)api_lock.try_lock(); // See above.
   auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

   Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_THREAD));

   if (reg_data_addr != LLDB_INVALID_ADDRESS) {
     // The registers data is in contiguous memory, just create the register
     // context using the address provided
     LLDB_LOGF(log,
               "OperatingSystemPython::CreateRegisterContextForThread (tid "
               "= 0x%" PRIx64 ", 0x%" PRIx64 ", reg_data_addr = 0x%" PRIx64
               ") creating memory register context",
               thread->GetID(), thread->GetProtocolID(), reg_data_addr);
     reg_ctx_sp = std::make_shared<RegisterContextMemory>(
         *thread, 0, *GetDynamicRegisterInfo(), reg_data_addr);
   } else {
     // No register data address is provided, query the python plug-in to let it
     // make up the data as it sees fit
     LLDB_LOGF(log,
               "OperatingSystemPython::CreateRegisterContextForThread (tid "
               "= 0x%" PRIx64 ", 0x%" PRIx64
               ") fetching register data from python",
               thread->GetID(), thread->GetProtocolID());

     StructuredData::StringSP reg_context_data =
         m_interpreter->OSPlugin_RegisterContextData(m_python_object_sp,
                                                     thread->GetID());
     if (reg_context_data) {
       std::string value = std::string(reg_context_data->GetValue());
       DataBufferSP data_sp(new DataBufferHeap(value.c_str(), value.length()));
       if (data_sp->GetByteSize()) {
         RegisterContextMemory *reg_ctx_memory = new RegisterContextMemory(
             *thread, 0, *GetDynamicRegisterInfo(), LLDB_INVALID_ADDRESS);
         if (reg_ctx_memory) {
           reg_ctx_sp.reset(reg_ctx_memory);
           reg_ctx_memory->SetAllRegisterData(data_sp);
         }
       }
     }
   }
   // if we still have no register data, fallback on a dummy context to avoid
   // crashing
   if (!reg_ctx_sp) {
     LLDB_LOGF(log,
               "OperatingSystemPython::CreateRegisterContextForThread (tid "
               "= 0x%" PRIx64 ") forcing a dummy register context",
               thread->GetID());
     reg_ctx_sp = std::make_shared<RegisterContextDummy>(
         *thread, 0, target.GetArchitecture().GetAddressByteSize());
   }
   return reg_ctx_sp;
 }

 StopInfoSP
 OperatingSystemPython::CreateThreadStopReason(lldb_private::Thread *thread) {
   // We should have gotten the thread stop info from the dictionary of data for
   // the thread in the initial call to get_thread_info(), this should have been
   // cached so we can return it here
   StopInfoSP
       stop_info_sp; //(StopInfo::CreateStopReasonWithSignal (*thread, SIGSTOP));
   return stop_info_sp;
 }

 lldb::ThreadSP OperatingSystemPython::CreateThread(lldb::tid_t tid,
                                                    addr_t context) {
   Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_THREAD));

   LLDB_LOGF(log,
             "OperatingSystemPython::CreateThread (tid = 0x%" PRIx64
             ", context = 0x%" PRIx64 ") fetching register data from python",
             tid, context);

   if (m_interpreter && m_python_object_sp) {
     // First thing we have to do is to try to get the API lock, and the
     // interpreter lock. We're going to change the thread content of the
     // process, and we're going to use python, which requires the API lock to
     // do it. We need the interpreter lock to make sure thread_info_dict stays
     // alive.
     //
     // If someone already has the API lock, that is ok, we just want to avoid
     // external code from making new API calls while this call is happening.
     //
     // This is a recursive lock so we can grant it to any Python code called on
     // the stack below us.
     Target &target = m_process->GetTarget();
     std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
                                                     std::defer_lock);
     (void)api_lock.try_lock(); // See above.
     auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

     StructuredData::DictionarySP thread_info_dict =
         m_interpreter->OSPlugin_CreateThread(m_python_object_sp, tid, context);
     std::vector<bool> core_used_map;
     if (thread_info_dict) {
       ThreadList core_threads(m_process);
       ThreadList &thread_list = m_process->GetThreadList();
       bool did_create = false;
       ThreadSP thread_sp(
           CreateThreadFromThreadInfo(*thread_info_dict, core_threads,
                                      thread_list, core_used_map, &did_create));
       if (did_create)
         thread_list.AddThread(thread_sp);
       return thread_sp;
     }
   }
   return ThreadSP();
 }

 #endif // #if LLDB_ENABLE_PYTHON
	//===-- OperatingSystemPython.cpp -----------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include "lldb/Host/Config.h"

	#if LLDB_ENABLE_PYTHON

	#include "OperatingSystemPython.h"

	#include "Plugins/Process/Utility/DynamicRegisterInfo.h"
	#include "Plugins/Process/Utility/RegisterContextDummy.h"
	#include "Plugins/Process/Utility/RegisterContextMemory.h"
	#include "Plugins/Process/Utility/ThreadMemory.h"
	#include "lldb/Core/Debugger.h"
	#include "lldb/Core/Module.h"
	#include "lldb/Core/PluginManager.h"
	#include "lldb/Core/ValueObjectVariable.h"
	#include "lldb/Interpreter/CommandInterpreter.h"
	#include "lldb/Interpreter/ScriptInterpreter.h"
	#include "lldb/Symbol/ObjectFile.h"
	#include "lldb/Symbol/VariableList.h"
	#include "lldb/Target/Process.h"
	#include "lldb/Target/StopInfo.h"
	#include "lldb/Target/Target.h"
	#include "lldb/Target/Thread.h"
	#include "lldb/Target/ThreadList.h"
	#include "lldb/Utility/DataBufferHeap.h"
	#include "lldb/Utility/RegisterValue.h"
	#include "lldb/Utility/StreamString.h"
	#include "lldb/Utility/StructuredData.h"

	#include <memory>

	using namespace lldb;
	using namespace lldb_private;

	LLDB_PLUGIN_DEFINE(OperatingSystemPython)

	void OperatingSystemPython::Initialize() {
	PluginManager::RegisterPlugin(GetPluginNameStatic(),
	GetPluginDescriptionStatic(), CreateInstance,
	nullptr);
	}

	void OperatingSystemPython::Terminate() {
	PluginManager::UnregisterPlugin(CreateInstance);
	}

	OperatingSystem OperatingSystemPython::CreateInstance(Process process,
	bool force) {
	// Python OperatingSystem plug-ins must be requested by name, so force must
	// be true
	FileSpec python_os_plugin_spec(process->GetPythonOSPluginPath());
	if (python_os_plugin_spec &&
	FileSystem::Instance().Exists(python_os_plugin_spec)) {
	std::unique_ptr<OperatingSystemPython> os_up(
	new OperatingSystemPython(process, python_os_plugin_spec));
	if (os_up.get() && os_up->IsValid())
	return os_up.release();
	}
	return nullptr;
	}

	ConstString OperatingSystemPython::GetPluginNameStatic() {
	static ConstString g_name("python");
	return g_name;
	}

	const char *OperatingSystemPython::GetPluginDescriptionStatic() {
	return "Operating system plug-in that gathers OS information from a python "
	"class that implements the necessary OperatingSystem functionality.";
	}

	OperatingSystemPython::OperatingSystemPython(lldb_private::Process *process,
	const FileSpec &python_module_path)
	: OperatingSystem(process), m_thread_list_valobj_sp(), m_register_info_up(),
	m_interpreter(nullptr), m_python_object_sp() {
	if (!process)
	return;
	TargetSP target_sp = process->CalculateTarget();
	if (!target_sp)
	return;
	m_interpreter = target_sp->GetDebugger().GetScriptInterpreter();
	if (m_interpreter) {

	std::string os_plugin_class_name(
	python_module_path.GetFilename().AsCString(""));
	if (!os_plugin_class_name.empty()) {
	LoadScriptOptions options;
	char python_module_path_cstr[PATH_MAX];
	python_module_path.GetPath(python_module_path_cstr,
	sizeof(python_module_path_cstr));
	Status error;
	if (m_interpreter->LoadScriptingModule(python_module_path_cstr, options,
	error)) {
	// Strip the ".py" extension if there is one
	size_t py_extension_pos = os_plugin_class_name.rfind(".py");
	if (py_extension_pos != std::string::npos)
	os_plugin_class_name.erase(py_extension_pos);
	// Add ".OperatingSystemPlugIn" to the module name to get a string like
	// "modulename.OperatingSystemPlugIn"
	os_plugin_class_name += ".OperatingSystemPlugIn";
	StructuredData::ObjectSP object_sp =
	m_interpreter->OSPlugin_CreatePluginObject(
	os_plugin_class_name.c_str(), process->CalculateProcess());
	if (object_sp && object_sp->IsValid())
	m_python_object_sp = object_sp;
	}
	}
	}
	}

	OperatingSystemPython::~OperatingSystemPython() = default;

	DynamicRegisterInfo *OperatingSystemPython::GetDynamicRegisterInfo() {
	if (m_register_info_up == nullptr) {
	if (!m_interpreter \|\| !m_python_object_sp)
	return nullptr;
	Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_OS));

	LLDB_LOGF(log,
	"OperatingSystemPython::GetDynamicRegisterInfo() fetching "
	"thread register definitions from python for pid %" PRIu64,
	m_process->GetID());

	StructuredData::DictionarySP dictionary =
	m_interpreter->OSPlugin_RegisterInfo(m_python_object_sp);
	if (!dictionary)
	return nullptr;

	m_register_info_up = std::make_unique<DynamicRegisterInfo>(
	*dictionary, m_process->GetTarget().GetArchitecture());
	assert(m_register_info_up->GetNumRegisters() > 0);
	assert(m_register_info_up->GetNumRegisterSets() > 0);
	}
	return m_register_info_up.get();
	}

	// PluginInterface protocol
	ConstString OperatingSystemPython::GetPluginName() {
	return GetPluginNameStatic();
	}

	uint32_t OperatingSystemPython::GetPluginVersion() { return 1; }

	bool OperatingSystemPython::UpdateThreadList(ThreadList &old_thread_list,
	ThreadList &core_thread_list,
	ThreadList &new_thread_list) {
	if (!m_interpreter \|\| !m_python_object_sp)
	return false;

	Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_OS));

	// First thing we have to do is to try to get the API lock, and the
	// interpreter lock. We're going to change the thread content of the process,
	// and we're going to use python, which requires the API lock to do it. We
	// need the interpreter lock to make sure thread_info_dict stays alive.
	//
	// If someone already has the API lock, that is ok, we just want to avoid
	// external code from making new API calls while this call is happening.
	//
	// This is a recursive lock so we can grant it to any Python code called on
	// the stack below us.
	Target &target = m_process->GetTarget();
	std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
	std::defer_lock);
	(void)api_lock.try_lock(); // See above.
	auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

	LLDB_LOGF(log,
	"OperatingSystemPython::UpdateThreadList() fetching thread "
	"data from python for pid %" PRIu64,
	m_process->GetID());

	// The threads that are in "core_thread_list" upon entry are the threads from
	// the lldb_private::Process subclass, no memory threads will be in this
	// list.
	StructuredData::ArraySP threads_list =
	m_interpreter->OSPlugin_ThreadsInfo(m_python_object_sp);

	const uint32_t num_cores = core_thread_list.GetSize(false);

	// Make a map so we can keep track of which cores were used from the
	// core_thread list. Any real threads/cores that weren't used should later be
	// put back into the "new_thread_list".
	std::vector<bool> core_used_map(num_cores, false);
	if (threads_list) {
	if (log) {
	StreamString strm;
	threads_list->Dump(strm);
	LLDB_LOGF(log, "threads_list = %s", strm.GetData());
	}

	const uint32_t num_threads = threads_list->GetSize();
	for (uint32_t i = 0; i < num_threads; ++i) {
	StructuredData::ObjectSP thread_dict_obj =
	threads_list->GetItemAtIndex(i);
	if (auto thread_dict = thread_dict_obj->GetAsDictionary()) {
	ThreadSP thread_sp(CreateThreadFromThreadInfo(
	*thread_dict, core_thread_list, old_thread_list, core_used_map,
	nullptr));
	if (thread_sp)
	new_thread_list.AddThread(thread_sp);
	}
	}
	}

	// Any real core threads that didn't end up backing a memory thread should
	// still be in the main thread list, and they should be inserted at the
	// beginning of the list
	uint32_t insert_idx = 0;
	for (uint32_t core_idx = 0; core_idx < num_cores; ++core_idx) {
	if (!core_used_map[core_idx]) {
	new_thread_list.InsertThread(
	core_thread_list.GetThreadAtIndex(core_idx, false), insert_idx);
	++insert_idx;
	}
	}

	return new_thread_list.GetSize(false) > 0;
	}

	ThreadSP OperatingSystemPython::CreateThreadFromThreadInfo(
	StructuredData::Dictionary &thread_dict, ThreadList &core_thread_list,
	ThreadList &old_thread_list, std::vector<bool> &core_used_map,
	bool *did_create_ptr) {
	ThreadSP thread_sp;
	tid_t tid = LLDB_INVALID_THREAD_ID;
	if (!thread_dict.GetValueForKeyAsInteger("tid", tid))
	return ThreadSP();

	uint32_t core_number;
	addr_t reg_data_addr;
	llvm::StringRef name;
	llvm::StringRef queue;

	thread_dict.GetValueForKeyAsInteger("core", core_number, UINT32_MAX);
	thread_dict.GetValueForKeyAsInteger("register_data_addr", reg_data_addr,
	LLDB_INVALID_ADDRESS);
	thread_dict.GetValueForKeyAsString("name", name);
	thread_dict.GetValueForKeyAsString("queue", queue);

	// See if a thread already exists for "tid"
	thread_sp = old_thread_list.FindThreadByID(tid, false);
	if (thread_sp) {
	// A thread already does exist for "tid", make sure it was an operating
	// system
	// plug-in generated thread.
	if (!IsOperatingSystemPluginThread(thread_sp)) {
	// We have thread ID overlap between the protocol threads and the
	// operating system threads, clear the thread so we create an operating
	// system thread for this.
	thread_sp.reset();
	}
	}

	if (!thread_sp) {
	if (did_create_ptr)
	*did_create_ptr = true;
	thread_sp = std::make_shared<ThreadMemory>(*m_process, tid, name, queue,
	reg_data_addr);
	}

	if (core_number < core_thread_list.GetSize(false)) {
	ThreadSP core_thread_sp(
	core_thread_list.GetThreadAtIndex(core_number, false));
	if (core_thread_sp) {
	// Keep track of which cores were set as the backing thread for memory
	// threads...
	if (core_number < core_used_map.size())
	core_used_map[core_number] = true;

	ThreadSP backing_core_thread_sp(core_thread_sp->GetBackingThread());
	if (backing_core_thread_sp) {
	thread_sp->SetBackingThread(backing_core_thread_sp);
	} else {
	thread_sp->SetBackingThread(core_thread_sp);
	}
	}
	}
	return thread_sp;
	}

	void OperatingSystemPython::ThreadWasSelected(Thread *thread) {}

	RegisterContextSP
	OperatingSystemPython::CreateRegisterContextForThread(Thread *thread,
	addr_t reg_data_addr) {
	RegisterContextSP reg_ctx_sp;
	if (!m_interpreter \|\| !m_python_object_sp \|\| !thread)
	return reg_ctx_sp;

	if (!IsOperatingSystemPluginThread(thread->shared_from_this()))
	return reg_ctx_sp;

	// First thing we have to do is to try to get the API lock, and the
	// interpreter lock. We're going to change the thread content of the process,
	// and we're going to use python, which requires the API lock to do it. We
	// need the interpreter lock to make sure thread_info_dict stays alive.
	//
	// If someone already has the API lock, that is ok, we just want to avoid
	// external code from making new API calls while this call is happening.
	//
	// This is a recursive lock so we can grant it to any Python code called on
	// the stack below us.
	Target &target = m_process->GetTarget();
	std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
	std::defer_lock);
	(void)api_lock.try_lock(); // See above.
	auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

	Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_THREAD));

	if (reg_data_addr != LLDB_INVALID_ADDRESS) {
	// The registers data is in contiguous memory, just create the register
	// context using the address provided
	LLDB_LOGF(log,
	"OperatingSystemPython::CreateRegisterContextForThread (tid "
	"= 0x%" PRIx64 ", 0x%" PRIx64 ", reg_data_addr = 0x%" PRIx64
	") creating memory register context",
	thread->GetID(), thread->GetProtocolID(), reg_data_addr);
	reg_ctx_sp = std::make_shared<RegisterContextMemory>(
	thread, 0, GetDynamicRegisterInfo(), reg_data_addr);
	} else {
	// No register data address is provided, query the python plug-in to let it
	// make up the data as it sees fit
	LLDB_LOGF(log,
	"OperatingSystemPython::CreateRegisterContextForThread (tid "
	"= 0x%" PRIx64 ", 0x%" PRIx64
	") fetching register data from python",
	thread->GetID(), thread->GetProtocolID());

	StructuredData::StringSP reg_context_data =
	m_interpreter->OSPlugin_RegisterContextData(m_python_object_sp,
	thread->GetID());
	if (reg_context_data) {
	std::string value = std::string(reg_context_data->GetValue());
	DataBufferSP data_sp(new DataBufferHeap(value.c_str(), value.length()));
	if (data_sp->GetByteSize()) {
	RegisterContextMemory *reg_ctx_memory = new RegisterContextMemory(
	thread, 0, GetDynamicRegisterInfo(), LLDB_INVALID_ADDRESS);
	if (reg_ctx_memory) {
	reg_ctx_sp.reset(reg_ctx_memory);
	reg_ctx_memory->SetAllRegisterData(data_sp);
	}
	}
	}
	}
	// if we still have no register data, fallback on a dummy context to avoid
	// crashing
	if (!reg_ctx_sp) {
	LLDB_LOGF(log,
	"OperatingSystemPython::CreateRegisterContextForThread (tid "
	"= 0x%" PRIx64 ") forcing a dummy register context",
	thread->GetID());
	reg_ctx_sp = std::make_shared<RegisterContextDummy>(
	*thread, 0, target.GetArchitecture().GetAddressByteSize());
	}
	return reg_ctx_sp;
	}

	StopInfoSP
	OperatingSystemPython::CreateThreadStopReason(lldb_private::Thread *thread) {
	// We should have gotten the thread stop info from the dictionary of data for
	// the thread in the initial call to get_thread_info(), this should have been
	// cached so we can return it here
	StopInfoSP
	stop_info_sp; //(StopInfo::CreateStopReasonWithSignal (*thread, SIGSTOP));
	return stop_info_sp;
	}

	lldb::ThreadSP OperatingSystemPython::CreateThread(lldb::tid_t tid,
	addr_t context) {
	Log *log(lldb_private::GetLogIfAllCategoriesSet(LIBLLDB_LOG_THREAD));

	LLDB_LOGF(log,
	"OperatingSystemPython::CreateThread (tid = 0x%" PRIx64
	", context = 0x%" PRIx64 ") fetching register data from python",
	tid, context);

	if (m_interpreter && m_python_object_sp) {
	// First thing we have to do is to try to get the API lock, and the
	// interpreter lock. We're going to change the thread content of the
	// process, and we're going to use python, which requires the API lock to
	// do it. We need the interpreter lock to make sure thread_info_dict stays
	// alive.
	//
	// If someone already has the API lock, that is ok, we just want to avoid
	// external code from making new API calls while this call is happening.
	//
	// This is a recursive lock so we can grant it to any Python code called on
	// the stack below us.
	Target &target = m_process->GetTarget();
	std::unique_lock<std::recursive_mutex> api_lock(target.GetAPIMutex(),
	std::defer_lock);
	(void)api_lock.try_lock(); // See above.
	auto interpreter_lock = m_interpreter->AcquireInterpreterLock();

	StructuredData::DictionarySP thread_info_dict =
	m_interpreter->OSPlugin_CreateThread(m_python_object_sp, tid, context);
	std::vector<bool> core_used_map;
	if (thread_info_dict) {
	ThreadList core_threads(m_process);
	ThreadList &thread_list = m_process->GetThreadList();
	bool did_create = false;
	ThreadSP thread_sp(
	CreateThreadFromThreadInfo(*thread_info_dict, core_threads,
	thread_list, core_used_map, &did_create));
	if (did_create)
	thread_list.AddThread(thread_sp);
	return thread_sp;
	}
	}
	return ThreadSP();
	}

	#endif // #if LLDB_ENABLE_PYTHON