// wait.cpp - written and placed in the public domain by Wei Dai #include "pch.h" #include "wait.h" #include "misc.h" #ifdef SOCKETS_AVAILABLE #ifdef USE_BERKELEY_STYLE_SOCKETS #include #include #include #include #endif NAMESPACE_BEGIN(CryptoPP) unsigned int WaitObjectContainer::MaxWaitObjects() { #ifdef USE_WINDOWS_STYLE_SOCKETS return MAXIMUM_WAIT_OBJECTS * (MAXIMUM_WAIT_OBJECTS-1); #else return FD_SETSIZE; #endif } WaitObjectContainer::WaitObjectContainer(WaitObjectsTracer* tracer) : m_tracer(tracer), m_eventTimer(Timer::MILLISECONDS) , m_sameResultCount(0), m_noWaitTimer(Timer::MILLISECONDS) { Clear(); m_eventTimer.StartTimer(); } void WaitObjectContainer::Clear() { #ifdef USE_WINDOWS_STYLE_SOCKETS m_handles.clear(); #else m_maxFd = 0; FD_ZERO(&m_readfds); FD_ZERO(&m_writefds); #endif m_noWait = false; m_firstEventTime = 0; } inline void WaitObjectContainer::SetLastResult(LastResultType result) { if (result == m_lastResult) m_sameResultCount++; else { m_lastResult = result; m_sameResultCount = 0; } } void WaitObjectContainer::DetectNoWait(LastResultType result, CallStack const& callStack) { if (result == m_lastResult && m_noWaitTimer.ElapsedTime() > 1000) { if (m_sameResultCount > m_noWaitTimer.ElapsedTime()) { if (m_tracer) { std::string desc = "No wait loop detected - m_lastResult: "; desc.append(IntToString(m_lastResult)).append(", call stack:"); for (CallStack const* cs = &callStack; cs; cs = cs->Prev()) desc.append("\n- ").append(cs->Format()); m_tracer->TraceNoWaitLoop(desc); } try { throw 0; } catch (...) {} // help debugger break } m_noWaitTimer.StartTimer(); m_sameResultCount = 0; } } void WaitObjectContainer::SetNoWait(CallStack const& callStack) { DetectNoWait(LASTRESULT_NOWAIT, CallStack("WaitObjectContainer::SetNoWait()", &callStack)); m_noWait = true; } void WaitObjectContainer::ScheduleEvent(double milliseconds, CallStack const& callStack) { if (milliseconds <= 3) DetectNoWait(LASTRESULT_SCHEDULED, CallStack("WaitObjectContainer::ScheduleEvent()", &callStack)); double thisEventTime = m_eventTimer.ElapsedTimeAsDouble() + milliseconds; if (!m_firstEventTime || thisEventTime < m_firstEventTime) m_firstEventTime = thisEventTime; } #ifdef USE_WINDOWS_STYLE_SOCKETS struct WaitingThreadData { bool waitingToWait, terminate; HANDLE startWaiting, stopWaiting; const HANDLE *waitHandles; unsigned int count; HANDLE threadHandle; DWORD threadId; DWORD* error; }; WaitObjectContainer::~WaitObjectContainer() { try // don't let exceptions escape destructor { if (!m_threads.empty()) { HANDLE threadHandles[MAXIMUM_WAIT_OBJECTS]; unsigned int i; for (i=0; i pThread((WaitingThreadData *)lParam); WaitingThreadData &thread = *pThread; std::vector handles; while (true) { thread.waitingToWait = true; ::WaitForSingleObject(thread.startWaiting, INFINITE); thread.waitingToWait = false; if (thread.terminate) break; if (!thread.count) continue; handles.resize(thread.count + 1); handles[0] = thread.stopWaiting; std::copy(thread.waitHandles, thread.waitHandles+thread.count, handles.begin()+1); DWORD result = ::WaitForMultipleObjects((DWORD)handles.size(), &handles[0], FALSE, INFINITE); if (result == WAIT_OBJECT_0) continue; // another thread finished waiting first, so do nothing SetEvent(thread.stopWaiting); if (!(result > WAIT_OBJECT_0 && result < WAIT_OBJECT_0 + handles.size())) { assert(!"error in WaitingThread"); // break here so we can see which thread has an error *thread.error = ::GetLastError(); } } return S_OK; // return a value here to avoid compiler warning } void WaitObjectContainer::CreateThreads(unsigned int count) { size_t currentCount = m_threads.size(); if (currentCount == 0) { m_startWaiting = ::CreateEvent(NULL, TRUE, FALSE, NULL); m_stopWaiting = ::CreateEvent(NULL, TRUE, FALSE, NULL); } if (currentCount < count) { m_threads.resize(count); for (size_t i=currentCount; i MAXIMUM_WAIT_OBJECTS) { // too many wait objects for a single WaitForMultipleObjects call, so use multiple threads static const unsigned int WAIT_OBJECTS_PER_THREAD = MAXIMUM_WAIT_OBJECTS-1; unsigned int nThreads = (unsigned int)((m_handles.size() + WAIT_OBJECTS_PER_THREAD - 1) / WAIT_OBJECTS_PER_THREAD); if (nThreads > MAXIMUM_WAIT_OBJECTS) // still too many wait objects, maybe implement recursive threading later? throw Err("WaitObjectContainer: number of wait objects exceeds limit"); CreateThreads(nThreads); DWORD error = S_OK; for (unsigned int i=0; i 0) { unsigned long timeAfterWait = t.ElapsedTime(); OutputDebugString(("Handles " + IntToString(m_handles.size()) + ", Woke up by " + IntToString(result-WAIT_OBJECT_0) + ", Busied for " + IntToString(timeBeforeWait-lastTime) + " us, Waited for " + IntToString(timeAfterWait-timeBeforeWait) + " us, max " + IntToString(milliseconds) + "ms\n").c_str()); lastTime = timeAfterWait; } #endif if (result >= WAIT_OBJECT_0 && result < WAIT_OBJECT_0 + m_handles.size()) { if (result == m_lastResult) m_sameResultCount++; else { m_lastResult = result; m_sameResultCount = 0; } return true; } else if (result == WAIT_TIMEOUT) { SetLastResult(timeoutIsScheduledEvent ? LASTRESULT_SCHEDULED : LASTRESULT_TIMEOUT); return timeoutIsScheduledEvent; } else throw Err("WaitObjectContainer: WaitForMultipleObjects failed with error " + IntToString(::GetLastError())); } } #else // #ifdef USE_WINDOWS_STYLE_SOCKETS void WaitObjectContainer::AddReadFd(int fd, CallStack const& callStack) // TODO: do something with callStack { FD_SET(fd, &m_readfds); m_maxFd = STDMAX(m_maxFd, fd); } void WaitObjectContainer::AddWriteFd(int fd, CallStack const& callStack) // TODO: do something with callStack { FD_SET(fd, &m_writefds); m_maxFd = STDMAX(m_maxFd, fd); } bool WaitObjectContainer::Wait(unsigned long milliseconds) { if (m_noWait || (!m_maxFd && !m_firstEventTime)) return true; bool timeoutIsScheduledEvent = false; if (m_firstEventTime) { double timeToFirstEvent = SaturatingSubtract(m_firstEventTime, m_eventTimer.ElapsedTimeAsDouble()); if (timeToFirstEvent <= milliseconds) { milliseconds = (unsigned long)timeToFirstEvent; timeoutIsScheduledEvent = true; } } timeval tv, *timeout; if (milliseconds == INFINITE_TIME) timeout = NULL; else { tv.tv_sec = milliseconds / 1000; tv.tv_usec = (milliseconds % 1000) * 1000; timeout = &tv; } int result = select(m_maxFd+1, &m_readfds, &m_writefds, NULL, timeout); if (result > 0) return true; else if (result == 0) return timeoutIsScheduledEvent; else throw Err("WaitObjectContainer: select failed with error " + IntToString(errno)); } #endif // ******************************************************** std::string CallStack::Format() const { return m_info; } std::string CallStackWithNr::Format() const { return std::string(m_info) + " / nr: " + IntToString(m_nr); } std::string CallStackWithStr::Format() const { return std::string(m_info) + " / " + std::string(m_z); } bool Waitable::Wait(unsigned long milliseconds, CallStack const& callStack) { WaitObjectContainer container; GetWaitObjects(container, callStack); // reduce clutter by not adding this func to stack return container.Wait(milliseconds); } NAMESPACE_END #endif