// Distributed under the Boost Software License, Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // (C) Copyright 2007 Anthony Williams // (C) Copyright 2007 David Deakins #define _WIN32_WINNT 0x400 #define WINVER 0x400 #include #include #include #ifndef UNDER_CE #include #endif #include #include #include #include #include #include namespace boost { namespace { boost::once_flag current_thread_tls_init_flag=BOOST_ONCE_INIT; DWORD current_thread_tls_key=0; void create_current_thread_tls_key() { tss_cleanup_implemented(); // if anyone uses TSS, we need the cleanup linked in current_thread_tls_key=TlsAlloc(); BOOST_ASSERT(current_thread_tls_key!=TLS_OUT_OF_INDEXES); } void cleanup_tls_key() { if(current_thread_tls_key) { TlsFree(current_thread_tls_key); current_thread_tls_key=0; } } detail::thread_data_base* get_current_thread_data() { if(!current_thread_tls_key) { return 0; } return (detail::thread_data_base*)TlsGetValue(current_thread_tls_key); } void set_current_thread_data(detail::thread_data_base* new_data) { boost::call_once(current_thread_tls_init_flag,create_current_thread_tls_key); BOOST_VERIFY(TlsSetValue(current_thread_tls_key,new_data)); } #ifdef BOOST_NO_THREADEX // Windows CE doesn't define _beginthreadex struct ThreadProxyData { typedef unsigned (__stdcall* func)(void*); func start_address_; void* arglist_; ThreadProxyData(func start_address,void* arglist) : start_address_(start_address), arglist_(arglist) {} }; DWORD WINAPI ThreadProxy(LPVOID args) { ThreadProxyData* data=reinterpret_cast(args); DWORD ret=data->start_address_(data->arglist_); delete data; return ret; } typedef void* uintptr_t; inline uintptr_t const _beginthreadex(void* security, unsigned stack_size, unsigned (__stdcall* start_address)(void*), void* arglist, unsigned initflag, unsigned* thrdaddr) { DWORD threadID; HANDLE hthread=CreateThread(static_cast(security),stack_size,ThreadProxy, new ThreadProxyData(start_address,arglist),initflag,&threadID); if (hthread!=0) *thrdaddr=threadID; return reinterpret_cast(hthread); } #endif } namespace detail { struct thread_exit_callback_node { boost::detail::thread_exit_function_base* func; thread_exit_callback_node* next; thread_exit_callback_node(boost::detail::thread_exit_function_base* func_, thread_exit_callback_node* next_): func(func_),next(next_) {} }; struct tss_data_node { void const* key; boost::shared_ptr func; void* value; tss_data_node* next; tss_data_node(void const* key_,boost::shared_ptr func_,void* value_, tss_data_node* next_): key(key_),func(func_),value(value_),next(next_) {} }; } namespace { void run_thread_exit_callbacks() { detail::thread_data_ptr current_thread_data(get_current_thread_data(),false); if(current_thread_data) { while(current_thread_data->tss_data || current_thread_data->thread_exit_callbacks) { while(current_thread_data->thread_exit_callbacks) { detail::thread_exit_callback_node* const current_node=current_thread_data->thread_exit_callbacks; current_thread_data->thread_exit_callbacks=current_node->next; if(current_node->func) { (*current_node->func)(); boost::detail::heap_delete(current_node->func); } boost::detail::heap_delete(current_node); } while(current_thread_data->tss_data) { detail::tss_data_node* const current_node=current_thread_data->tss_data; current_thread_data->tss_data=current_node->next; if(current_node->func) { (*current_node->func)(current_node->value); } boost::detail::heap_delete(current_node); } } set_current_thread_data(0); } } unsigned __stdcall thread_start_function(void* param) { detail::thread_data_base* const thread_info(reinterpret_cast(param)); set_current_thread_data(thread_info); try { thread_info->run(); } catch(thread_interrupted const&) { } // Removed as it stops the debugger identifying the cause of the exception // Unhandled exceptions still cause the application to terminate // catch(...) // { // std::terminate(); // } run_thread_exit_callbacks(); return 0; } } thread::thread() {} void thread::start_thread() { uintptr_t const new_thread=_beginthreadex(0,0,&thread_start_function,thread_info.get(),CREATE_SUSPENDED,&thread_info->id); if(!new_thread) { throw thread_resource_error(); } intrusive_ptr_add_ref(thread_info.get()); thread_info->thread_handle=(detail::win32::handle)(new_thread); ResumeThread(thread_info->thread_handle); } thread::thread(detail::thread_data_ptr data): thread_info(data) {} namespace { struct externally_launched_thread: detail::thread_data_base { externally_launched_thread() { ++count; interruption_enabled=false; } void run() {} private: externally_launched_thread(externally_launched_thread&); void operator=(externally_launched_thread&); }; void make_external_thread_data() { externally_launched_thread* me=detail::heap_new(); set_current_thread_data(me); } detail::thread_data_base* get_or_make_current_thread_data() { detail::thread_data_base* current_thread_data(get_current_thread_data()); if(!current_thread_data) { make_external_thread_data(); current_thread_data=get_current_thread_data(); } return current_thread_data; } } thread::~thread() { detach(); } thread::id thread::get_id() const { return thread::id(get_thread_info()); } bool thread::joinable() const { return get_thread_info(); } void thread::join() { detail::thread_data_ptr local_thread_info=get_thread_info(); if(local_thread_info) { this_thread::interruptible_wait(local_thread_info->thread_handle,detail::timeout::sentinel()); release_handle(); } } bool thread::timed_join(boost::system_time const& wait_until) { detail::thread_data_ptr local_thread_info=get_thread_info(); if(local_thread_info) { if(!this_thread::interruptible_wait(local_thread_info->thread_handle,get_milliseconds_until(wait_until))) { return false; } release_handle(); } return true; } void thread::detach() { release_handle(); } void thread::release_handle() { lock_guard l1(thread_info_mutex); thread_info=0; } void thread::interrupt() { detail::thread_data_ptr local_thread_info=get_thread_info(); if(local_thread_info) { local_thread_info->interrupt(); } } bool thread::interruption_requested() const { detail::thread_data_ptr local_thread_info=get_thread_info(); return local_thread_info.get() && (detail::win32::WaitForSingleObject(local_thread_info->interruption_handle,0)==0); } unsigned thread::hardware_concurrency() { SYSTEM_INFO info={0}; GetSystemInfo(&info); return info.dwNumberOfProcessors; } thread::native_handle_type thread::native_handle() { detail::thread_data_ptr local_thread_info=get_thread_info(); return local_thread_info?(detail::win32::handle)local_thread_info->thread_handle:detail::win32::invalid_handle_value; } detail::thread_data_ptr thread::get_thread_info() const { boost::mutex::scoped_lock l(thread_info_mutex); return thread_info; } namespace this_thread { namespace { LARGE_INTEGER get_due_time(detail::timeout const& target_time) { LARGE_INTEGER due_time={0}; if(target_time.relative) { unsigned long const elapsed_milliseconds=GetTickCount()-target_time.start; LONGLONG const remaining_milliseconds=(target_time.milliseconds-elapsed_milliseconds); LONGLONG const hundred_nanoseconds_in_one_millisecond=10000; if(remaining_milliseconds>0) { due_time.QuadPart=-(remaining_milliseconds*hundred_nanoseconds_in_one_millisecond); } } else { SYSTEMTIME target_system_time={0}; target_system_time.wYear=target_time.abs_time.date().year(); target_system_time.wMonth=target_time.abs_time.date().month(); target_system_time.wDay=target_time.abs_time.date().day(); target_system_time.wHour=(WORD)target_time.abs_time.time_of_day().hours(); target_system_time.wMinute=(WORD)target_time.abs_time.time_of_day().minutes(); target_system_time.wSecond=(WORD)target_time.abs_time.time_of_day().seconds(); if(!SystemTimeToFileTime(&target_system_time,((FILETIME*)&due_time))) { due_time.QuadPart=0; } else { long const hundred_nanoseconds_in_one_second=10000000; due_time.QuadPart+=target_time.abs_time.time_of_day().fractional_seconds()*(hundred_nanoseconds_in_one_second/target_time.abs_time.time_of_day().ticks_per_second()); } } return due_time; } } bool interruptible_wait(detail::win32::handle handle_to_wait_for,detail::timeout target_time) { detail::win32::handle handles[3]={0}; unsigned handle_count=0; unsigned wait_handle_index=~0U; unsigned interruption_index=~0U; unsigned timeout_index=~0U; if(handle_to_wait_for!=detail::win32::invalid_handle_value) { wait_handle_index=handle_count; handles[handle_count++]=handle_to_wait_for; } if(get_current_thread_data() && get_current_thread_data()->interruption_enabled) { interruption_index=handle_count; handles[handle_count++]=get_current_thread_data()->interruption_handle; } detail::win32::handle_manager timer_handle; #ifndef UNDER_CE unsigned const min_timer_wait_period=20; if(!target_time.is_sentinel()) { detail::timeout::remaining_time const time_left=target_time.remaining_milliseconds(); if(time_left.milliseconds > min_timer_wait_period) { // for a long-enough timeout, use a waitable timer (which tracks clock changes) timer_handle=CreateWaitableTimer(NULL,false,NULL); if(timer_handle!=0) { LARGE_INTEGER due_time=get_due_time(target_time); bool const set_time_succeeded=SetWaitableTimer(timer_handle,&due_time,0,0,0,false)!=0; if(set_time_succeeded) { timeout_index=handle_count; handles[handle_count++]=timer_handle; } } } else if(!target_time.relative) { // convert short absolute-time timeouts into relative ones, so we don't race against clock changes target_time=detail::timeout(time_left.milliseconds); } } #endif bool const using_timer=timeout_index!=~0u; detail::timeout::remaining_time time_left(0); do { if(!using_timer) { time_left=target_time.remaining_milliseconds(); } if(handle_count) { unsigned long const notified_index=detail::win32::WaitForMultipleObjects(handle_count,handles,false,using_timer?INFINITE:time_left.milliseconds); if(notified_indexinterruption_handle); throw thread_interrupted(); } else if(notified_index==timeout_index) { return false; } } } else { detail::win32::Sleep(time_left.milliseconds); } if(target_time.relative) { target_time.milliseconds-=detail::timeout::max_non_infinite_wait; } } while(time_left.more); return false; } thread::id get_id() { return thread::id(get_or_make_current_thread_data()); } void interruption_point() { if(interruption_enabled() && interruption_requested()) { detail::win32::ResetEvent(get_current_thread_data()->interruption_handle); throw thread_interrupted(); } } bool interruption_enabled() { return get_current_thread_data() && get_current_thread_data()->interruption_enabled; } bool interruption_requested() { return get_current_thread_data() && (detail::win32::WaitForSingleObject(get_current_thread_data()->interruption_handle,0)==0); } void yield() { detail::win32::Sleep(0); } disable_interruption::disable_interruption(): interruption_was_enabled(interruption_enabled()) { if(interruption_was_enabled) { get_current_thread_data()->interruption_enabled=false; } } disable_interruption::~disable_interruption() { if(get_current_thread_data()) { get_current_thread_data()->interruption_enabled=interruption_was_enabled; } } restore_interruption::restore_interruption(disable_interruption& d) { if(d.interruption_was_enabled) { get_current_thread_data()->interruption_enabled=true; } } restore_interruption::~restore_interruption() { if(get_current_thread_data()) { get_current_thread_data()->interruption_enabled=false; } } } namespace detail { void add_thread_exit_function(thread_exit_function_base* func) { detail::thread_data_base* const current_thread_data(get_or_make_current_thread_data()); thread_exit_callback_node* const new_node= heap_new(func, current_thread_data->thread_exit_callbacks); current_thread_data->thread_exit_callbacks=new_node; } tss_data_node* find_tss_data(void const* key) { detail::thread_data_base* const current_thread_data(get_current_thread_data()); if(current_thread_data) { detail::tss_data_node* current_node=current_thread_data->tss_data; while(current_node) { if(current_node->key==key) { return current_node; } current_node=current_node->next; } } return NULL; } void* get_tss_data(void const* key) { if(tss_data_node* const current_node=find_tss_data(key)) { return current_node->value; } return NULL; } void set_tss_data(void const* key,boost::shared_ptr func,void* tss_data,bool cleanup_existing) { if(tss_data_node* const current_node=find_tss_data(key)) { if(cleanup_existing && current_node->func.get()) { (*current_node->func)(current_node->value); } current_node->func=func; current_node->value=tss_data; } else { detail::thread_data_base* const current_thread_data(get_or_make_current_thread_data()); tss_data_node* const new_node=heap_new(key,func,tss_data,current_thread_data->tss_data); current_thread_data->tss_data=new_node; } } } } extern "C" BOOST_THREAD_DECL void on_process_enter() {} extern "C" BOOST_THREAD_DECL void on_thread_enter() {} extern "C" BOOST_THREAD_DECL void on_process_exit() { boost::cleanup_tls_key(); } extern "C" BOOST_THREAD_DECL void on_thread_exit() { boost::run_thread_exit_callbacks(); }