Timer::Caller Timer::call( const Function& func , double interval , bool repeat ) { // push function without paused time TimeFunc*tf = new TimeFunc( get_s()-mms_to_s(paused_time_mms)+interval, repeat?interval:0, func); to_call.push(tf); return Caller(&(tf->state)); }
int main() { string fileName; cout<<"Please enter the caller file name: "<<endl; cin>>fileName; ifstream in; in.open(fileName); while(in.fail()) { cout<<"Please enter the caller file name again: "<<endl; cin>>fileName; in.open(fileName); } string line; string::size_type lasPos, pos; vector<string> vec; string delimiter=" "; getline(in, line); // the label line while(getline(in, line)) { lasPos=line.find_first_not_of(delimiter, 0); pos=line.find_first_of(delimiter, lasPos); while(lasPos!=string::npos || pos!=string::npos) { vec.push_back(line.substr(lasPos, pos-lasPos)); lasPos=line.find_first_not_of(delimiter, pos); pos=line.find_first_of(delimiter, lasPos); } int timestamp=atoi(vec[0].c_str()); if(timestamp!=Callhandler::getInstance()->getTimestamp()) { Callhandler::getInstance()->setTimestamp(timestamp); Callhandler::getInstance()->freeEmployee(); Callhandler::getInstance()->serveQueue(); } int rank=atoi(vec[2].c_str()); string name=vec[1]; Callhandler::getInstance()->dispatch(Caller(rank, name)); vec.clear(); } return 0; }
void CLR_RT_StackFrame::Pop() { NATIVE_PROFILE_CLR_CORE(); #if defined(TINYCLR_PROFILE_NEW_CALLS) { // // This passivates any outstanding handler. // CLR_PROF_HANDLER_CALLCHAIN(pm2,m_callchain); m_callchain.Leave(); } #endif #if defined(TINYCLR_PROFILE_NEW_CALLS) g_CLR_PRF_Profiler.RecordFunctionReturn( m_owningThread, m_callchain ); #endif #if defined(TINYCLR_ENABLE_SOURCELEVELDEBUGGING) if(m_owningThread->m_fHasJMCStepper || (m_flags & c_HasBreakpoint)) { g_CLR_RT_ExecutionEngine.Breakpoint_StackFrame_Pop( this, false ); } #endif const CLR_UINT32 c_flagsToCheck = CLR_RT_StackFrame::c_CallOnPop | CLR_RT_StackFrame::c_Synchronized | CLR_RT_StackFrame::c_SynchronizedGlobally | CLR_RT_StackFrame::c_NativeProfiled; if(m_flags & c_flagsToCheck) { if(m_flags & CLR_RT_StackFrame::c_CallOnPop) { m_flags |= CLR_RT_StackFrame::c_CalledOnPop; if(m_nativeMethod) { (void)m_nativeMethod( *this ); } } if(m_flags & CLR_RT_StackFrame::c_Synchronized) { m_flags &= ~CLR_RT_StackFrame::c_Synchronized; (void)HandleSynchronized( false, false ); } if(m_flags & CLR_RT_StackFrame::c_SynchronizedGlobally) { m_flags &= ~CLR_RT_StackFrame::c_SynchronizedGlobally; (void)HandleSynchronized( false, true ); } #if defined(ENABLE_NATIVE_PROFILER) if(m_flags & CLR_RT_StackFrame::c_NativeProfiled) { m_owningThread->m_fNativeProfiled = false; m_flags &= ~CLR_RT_StackFrame::c_NativeProfiled; Native_Profiler_Stop(); } #endif } CLR_RT_StackFrame* caller = Caller(); if(caller->Prev() != NULL) { #if defined(TINYCLR_ENABLE_SOURCELEVELDEBUGGING) if(caller->m_flags & CLR_RT_StackFrame::c_HasBreakpoint) { g_CLR_RT_ExecutionEngine.Breakpoint_StackFrame_Step( caller, caller->m_IP ); } #endif // // Constructors are slightly different, they push the 'this' pointer back into the caller stack. // // This is to enable the special case for strings, where the object can be recreated by the constructor... // if(caller->m_flags & CLR_RT_StackFrame::c_ExecutingConstructor) { CLR_RT_HeapBlock& src = this ->Arg0 ( ); CLR_RT_HeapBlock& dst = caller->PushValueAndAssign( src ); dst.Promote(); // // Undo the special "object -> reference" hack done by CEE_NEWOBJ. // if(dst.DataType() == DATATYPE_BYREF) { dst.ChangeDataType( DATATYPE_OBJECT ); } caller->m_flags &= ~CLR_RT_StackFrame::c_ExecutingConstructor; _ASSERTE((m_flags & CLR_RT_StackFrame::c_AppDomainTransition) == 0); } else { //Note that ExecutingConstructor is checked on 'caller', whereas the other two flags are checked on 'this' const CLR_UINT32 c_moreFlagsToCheck = CLR_RT_StackFrame::c_PseudoStackFrameForFilter | CLR_RT_StackFrame::c_AppDomainTransition; if(m_flags & c_moreFlagsToCheck) { if(m_flags & CLR_RT_StackFrame::c_PseudoStackFrameForFilter) { //Do nothing here. Pushing return values onto stack frames that don't expect them are a bad idea. } #if defined(TINYCLR_APPDOMAINS) else if((m_flags & CLR_RT_StackFrame::c_AppDomainTransition) != 0) { (void)PopAppDomainTransition(); } #endif } else //!c_moreFlagsToCheck { // // Push the return, if any. // if(m_call.m_target->retVal != DATATYPE_VOID) { if(m_owningThread->m_currentException.Dereference() == NULL) { CLR_RT_HeapBlock& src = this ->TopValue ( ); CLR_RT_HeapBlock& dst = caller->PushValueAndAssign( src ); dst.Promote(); } } } } } #if defined(TINYCLR_ENABLE_SOURCELEVELDEBUGGING) else { int idx = m_owningThread->m_scratchPad; if(idx >= 0) { CLR_RT_HeapBlock_Array* array = g_CLR_RT_ExecutionEngine.m_scratchPadArray; if(array && array->m_numOfElements > (CLR_UINT32)idx) { CLR_RT_HeapBlock* dst = (CLR_RT_HeapBlock*)array->GetElement( (CLR_UINT32)idx ); CLR_RT_HeapBlock* exception = m_owningThread->m_currentException.Dereference(); dst->SetObjectReference( NULL ); if(exception != NULL) { dst->SetObjectReference( exception ); } else if(m_call.m_target->retVal != DATATYPE_VOID) { CLR_RT_SignatureParser sig; sig.Initialize_MethodSignature( this->m_call.m_assm, this->m_call.m_target ); CLR_RT_SignatureParser::Element res; CLR_RT_TypeDescriptor desc; dst->Assign( this->TopValue() ); //Perform boxing, if needed. //Box to the return value type _SIDE_ASSERTE(SUCCEEDED(sig.Advance( res ))); _SIDE_ASSERTE(SUCCEEDED(desc.InitializeFromType( res.m_cls ))); if(c_CLR_RT_DataTypeLookup[ this->DataType() ].m_flags & CLR_RT_DataTypeLookup::c_OptimizedValueType || desc.m_handlerCls.m_target->IsEnum() ) { if(FAILED(dst->PerformBoxing( desc.m_handlerCls ))) { dst->SetObjectReference( NULL ); } } } } } } #endif // // We could be jumping outside of a nested exception handler. // m_owningThread->PopEH( this, NULL ); // // If this StackFrame owns a SubThread, kill it. // { CLR_RT_SubThread* sth = (CLR_RT_SubThread*)m_owningSubThread->Next(); if(sth->Next() && sth->m_owningStackFrame == this) { CLR_RT_SubThread::DestroyInstance( sth->m_owningThread, sth, CLR_RT_SubThread::MODE_IncludeSelf ); } } g_CLR_RT_EventCache.Append_Node( this ); }
Caller MetaObject::operator[](const std::string &mname) const { if (_methods.find(mname)==_methods.end()) throw Exceptions::NoSuchMethod(); return Caller(mname, _methods.find(mname)->second, MetaContext(mname, *this), *_state); }
Timer::Caller Timer::call_at( const Function& func , double time ) { TimeFunc*tf = new TimeFunc(time-mms_to_s(paused_time_mms),0,func); to_call.push(tf); return Caller(&tf->state); }