void System::executeScript(const std::string& filename, WindowBase* wnd) {
if (!m_scriptSys.ExecuteFile(filename, wnd))
{
logEvent(log::error, std::string("Unable to execute Lua file: ") + m_scriptSys.GetLastError());
}
}
void sptrace_log_alloc(PsmPartition trace, unsigned long addr, int size,
char *fileName, int lineNbr)
{
if (!trace) return;
logEvent(trace, OP_ALLOCATE, addr, size, NULL, fileName, lineNbr, NULL);
}
uint64_t EventLogger::logStateEvent(ExecutionState *state, ExecutionState *other,
unsigned event, uint64_t count) {
return logEvent(state, event, count);
}
static void
eventCallback(CFSocketRef s, CFSocketCallBackType type, CFDataRef address, const void *data, void *info)
{
int so = CFSocketGetNative(s);
int status;
union {
char bytes[1024];
struct kern_event_msg ev_msg1; // first kernel event
} buf;
struct kern_event_msg *ev_msg = &buf.ev_msg1;
int offset = 0;
status = recv(so, &buf, sizeof(buf), 0);
if (status == -1) {
SCLog(TRUE, LOG_ERR, CFSTR("recv() failed: %s"), strerror(errno));
goto error;
}
cache_open();
while (offset < status) {
if ((offset + ev_msg->total_size) > status) {
SCLog(TRUE, LOG_NOTICE, CFSTR("missed SYSPROTO_EVENT event, buffer not big enough"));
break;
}
switch (ev_msg->vendor_code) {
case KEV_VENDOR_APPLE :
switch (ev_msg->kev_class) {
case KEV_NETWORK_CLASS :
processEvent_Apple_Network(ev_msg);
break;
case KEV_IOKIT_CLASS :
case KEV_SYSTEM_CLASS :
case KEV_APPLESHARE_CLASS :
case KEV_FIREWALL_CLASS :
case KEV_IEEE80211_CLASS :
break;
default :
/* unrecognized (Apple) event class */
logEvent(CFSTR("New (Apple) class"), ev_msg);
break;
}
break;
default :
/* unrecognized vendor code */
logEvent(CFSTR("New vendor"), ev_msg);
break;
}
offset += ev_msg->total_size;
ev_msg = (struct kern_event_msg *)(void *)&buf.bytes[offset];
}
cache_write(store);
cache_close();
post_network_changed();
return;
error :
SCLog(TRUE, LOG_ERR, CFSTR("kernel event monitor disabled."));
CFSocketInvalidate(s);
return;
}
// Performs a union operation on two interval lists to produce a
// result list. The list's intervals may have different
// MdamRefList*s associated with them. Any reference lists
// associated with otherList are ignored and disjunctNum is used
// instead. The this list and the otherList are inputs to the
// intersect operation. The result replaces the this list. The
// original interval list entries for the this list are deleted.
MdamIntervalList & MdamIntervalList::unionSeparateDisjuncts
(const MdamIntervalList & otherList,
const Int32 disjunctNum,
const ULng32 keyLen,
FixedSizeHeapManager & mdamIntervalHeap,
FixedSizeHeapManager & mdamRefListEntryHeap)
{
// Move entries from this into tempIntervalList.
#if defined ( NA_MDAM_EXECUTOR_DEBUG_ILTF )
MdamIntervalList tempIntervalList(2);
#else
MdamIntervalList tempIntervalList;
#endif /* NA_MDAM_EXECUTOR_DEBUG_ILTF */
giveAllIntervals(tempIntervalList);
MdamIntervalListMerger getNextPoint(&tempIntervalList,
&otherList,
keyLen);
MdamEndPoint currentEndPoint;
MdamEndPoint previousEndPoint;
// Track the active interval for each interval list. Zero means
// there is no active interval. This mechanism permits access
// to the corresponding reference list.
MdamInterval * intervalPtr0 = 0;
MdamInterval * intervalPtr1 = 0;
while(getNextPoint(currentEndPoint))
{
if (getNextPoint.getPreviousActiveIntervals() != 0
&& currentEndPoint.givesNonEmptyInterval(&previousEndPoint,keyLen))
{
// Create a new interval. The constructor will reverse the
// inclusion of end endpoint, if appropriate, and build
// the reference list.
MdamInterval * tempIntervalPtr = new(mdamIntervalHeap)
MdamInterval(previousEndPoint,
currentEndPoint,
intervalPtr0,
intervalPtr1,
disjunctNum,
mdamRefListEntryHeap);
// Append the new interval onto this list.
append(tempIntervalPtr);
}; // end if
// Adjust active reference lists.
currentEndPoint.adjustIntervalPtr(intervalPtr0, 0);
currentEndPoint.adjustIntervalPtr(intervalPtr1, 1);
// Save the current endpoint.
previousEndPoint = currentEndPoint;
if (currentEndPoint.end()){previousEndPoint.reverseInclusion();};
}; // end while
#if defined ( NA_MDAM_EXECUTOR_DEBUG_ILTF )
// Log entry for intervals resulting from the union operation.
logEvent(8,countIntervals(),otherList.intervalListId_);
#endif /* NA_MDAM_EXECUTOR_DEBUG_ILTF */
// Delete the original this list entries because the destructor
// can't.
tempIntervalList.deleteAllIntervals(mdamIntervalHeap,
mdamRefListEntryHeap);
return *this;
}
void EventsWidget::onPlayerDisconnectEvent(const QString &player)
{
logEvent("PlayerDisconnect", tr("Player %1 disconnected.").arg(player));
}
void RedisClient::SshTransporter::OnSshSocketDestroyed()
{
m_socket = nullptr;
emit logEvent("SSH socket detroyed");
}
void EventsWidget::onPlayerJoinEvent(const QString &player, const QString &guid)
{
logEvent("PlayerJoin", tr("Player %1 joined the game (GUID: %2).").arg(player, guid));
}
void EventsWidget::onPlayerLeaveEvent(const QString &player, const QString &info)
{
Q_UNUSED(info);
logEvent("PlayerLeave", tr("Player %1 left the game.").arg(player)); // TODO: Impelment score stuffs here?
}
//====================================
int servuinoFunc(int event, int pin, int value, const char *p, unsigned char uc)
//====================================
{
int res=999,fail=0;
char eventText[120];
char custText[120];
strcpy(custText,"no-text");
g_curStep++;
updateFromRegister();
clearRW();
if(g_ongoingInterrupt == S_NO)interruptPinValues();
if(g_serialMode == S_ON)
{
x_pinMode[0] = RX;
x_pinMode[1] = TX;
}
sprintf(eventText,"%d Unknown event: %d pin=%d value=%d",g_curStep,event,pin,value);
if(event == S_UNIMPLEMENTED)
{
sprintf(eventText,"Unimplemented: %s",p);
}
if(event == S_SETUP)
{
sprintf(eventText,"setup");
}
if(event == S_LOOP)
{
sprintf(eventText,"servuinoLoop %d",g_curLoop);
}
if(event == S_PIN_MODE_INPUT)
{
fail = checkRange(FAIL,"digpin",pin);
if(fail == 0)
{
x_pinMode[pin] = value;
if(value==INPUT)
{
// Set pin status according to scenario when mode is INPUT
res = x_pinScenario[pin][g_curStep];
x_pinDigValue[pin] = res;
writeRegister(1,R_PIN,pin,value);
writeRegister(1,R_DDR,pin,0);
sprintf(eventText,"pinMode pin=%d INPUT",pin);
sprintf(custText,"%s %d",g_custText[event][pin],pin);
}
}
res = 0;
}
if(event == S_PIN_MODE_OUTPUT)
{
fail = checkRange(FAIL,"digpin",pin);
if(fail == 0)
{
x_pinMode[pin] = value;
if(value==OUTPUT)
{
// Set pin status according to PORT register when mode is OUTPUT
x_pinDigValue[pin] = readRegister(R_PORT,pin);
writeRegister(1,R_DDR,pin,1);
sprintf(eventText,"pinMode pin=%d OUTPUT",pin);
sprintf(custText,"%s %d",g_custText[event][pin],pin);
}
}
res = 0;
}
if(event == S_DIGITAL_WRITE_LOW || event == S_DIGITAL_WRITE_HIGH)
{
x_pinRW[pin] = T_WRITE;
fail = checkRange(FAIL,"digpin",pin);
fail = fail + checkRange(FAIL,"digval",value);
if(fail == 0)
{
x_pinDigValue[pin] = value;
writeRegister(1,R_PORT,pin,value);
sprintf(eventText,"digitalWrite pin=%d value=%d",pin,value);
sprintf(custText,"%s %d",g_custText[event][pin],value);
}
res = 0;
if(x_pinMode[pin] != OUTPUT)
errorLog("DigitalWrite when pin Mode is INPUT",pin);
}
if(event == S_DIGITAL_READ)
{
x_pinRW[pin] = T_READ;
res = x_pinScenario[pin][g_curStep];
x_pinDigValue[pin] = res;
writeRegister(1,R_PIN,pin,value);
sprintf(eventText,"digitalRead pin=%d value=%d",pin,res);
sprintf(custText,"%s %d",g_custText[event][pin],res);
//value = getDigitalPinValue(pin,currentStep);
if(x_pinMode[pin] != INPUT)
errorLog("DigitalRead when pin Mode is OUPUT",pin);
}
if(event == S_ANALOG_WRITE)//PWM pinMode OUTPUT not necessary (see arduino.com)
{
x_pinRW[pin] = T_WRITE;
fail = checkRange(FAIL,"pwmpin",pin);
fail = fail + checkRange(FAIL,"pwmval",value);
if(fail == 0)
{
x_pinAnaValue[pin] = value;
//writeRegister(pin,value);
sprintf(eventText,"analogWrite pin=%d value=%d",pin,value);
sprintf(custText,"%s %d",g_custText[event][pin],value);
}
res = 0;
}
if(event == S_ANALOG_READ)
{
x_pinRW[pin] = T_READ;
res = x_pinScenario[pin][g_curStep];
x_pinAnaValue[pin] = res;
sprintf(eventText,"analogRead pin=%d value=%d",pin-g_nDigPins,res);
sprintf(custText,"%s %d",g_custText[event][pin],res);
}
if(event == S_ANALOG_REFERENCE)
{
sprintf(eventText,"analogReference type=%s",p);
}
if(event == S_DELAY)
{
sprintf(eventText,"delay %d ms",pin);
fprintf(f_time,"+ %d %d\n",g_curStep,pin*1000);
}
if(event == S_DELAY_MS)
{
sprintf(eventText,"delay %d us",pin);
fprintf(f_time,"+ %d %d\n",g_curStep,pin);
}
if(event == S_ATTACH_INTERRUPT_LOW)
{
sprintf(eventText,"attached LOW interrupt %d",pin);
}
if(event == S_ATTACH_INTERRUPT_RISING)
{
sprintf(eventText,"attached RISING interrupt %d",pin);
}
if(event == S_ATTACH_INTERRUPT_FALLING)
{
sprintf(eventText,"attached FALLING interrupt %d",pin);
}
if(event == S_ATTACH_INTERRUPT_CHANGE)
{
sprintf(eventText,"attached CHANGE interrupt %d",pin);
}
if(event == S_DETACH_INTERRUPT)
{
g_interruptType[pin] = 0;
sprintf(eventText,"detached interrupt %d",pin);
}
if(event == S_SERIAL_BEGIN)
{
sprintf(eventText,"Serial.begin baud=%d",pin);
if(g_serialMode == S_ON)
errorLog("Serial begin already exists",g_curStep);
g_serialMode = S_ON;
}
if(event == S_SERIAL_END)
{
sprintf(eventText,"Serial.end");
if(g_serialMode != S_ON)
errorLog("Serial end without serial.begin",g_curStep);
g_serialMode = S_OFF;
}
if(event == S_SERIAL_PRINT_INT)
{
sprintf(eventText,"Serial.print(int) %d",pin);
fprintf(f_serial,"%d SL [%d]\n",g_curStep,pin);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINT_INT_BASE)
{
sprintf(eventText,"Serial.print(int,base) %d base=%d",pin,value);
fprintf(f_serial,"%d SL [%d]\n",g_curStep,pin);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINT_CHAR)
{
sprintf(eventText,"Serial.print(char) %s",p);
fprintf(f_serial,"%d SL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINT_UCHAR)
{
sprintf(eventText,"Serial.print(uchar) %c",uc);
fprintf(f_serial,"%d SL [%c]\n",g_curStep,uc);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINT_STRING)
{
sprintf(eventText,"Serial.print(string) %s",p);
fprintf(f_serial,"%d SL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINT_SSTRING)
{
sprintf(eventText,"Serial.print(String) %s",p);
fprintf(f_serial,"%d SL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_INT)
{
sprintf(eventText,"Serial.println(int) %d",pin);
fprintf(f_serial,"%d NL [%d]\n",g_curStep,pin);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_INT_BASE)
{
sprintf(eventText,"Serial.println(int,base) %d base=%d",pin,value);
fprintf(f_serial,"%d NL [%d]\n",g_curStep,pin);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_CHAR)
{
sprintf(eventText,"Serial.println(char) %s",p);
fprintf(f_serial,"%d NL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_UCHAR)
{
sprintf(eventText,"Serial.println(uchar) %c",uc);
fprintf(f_serial,"%d NL [%c]\n",g_curStep,*p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_STRING)
{
sprintf(eventText,"Serial.println(string) %s",p);
fprintf(f_serial,"%d NL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_SSTRING)
{
sprintf(eventText,"Serial.println(String) %s",p);
fprintf(f_serial,"%d NL [%s]\n",g_curStep,p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_PRINTLN_VOID)
{
sprintf(eventText,"Serial.println(void)");
fprintf(f_serial,"%d NL []\n",g_curStep);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_SERIAL_WRITE)
{
sprintf(eventText,"Serial.write %s",p);
if(g_serialMode != S_ON)
errorLog("Serial print without serial.begin",g_curStep);
}
if(event == S_EEPROM_WRITE)
{
sprintf(eventText,"EEPROM.write address=%d value=%d",pin,value);
if(pin > 512)
errorLog("EEPROM write: address > 512: ",pin);
if(pin < 0)
errorLog("EEPROM write: address < 0: ",pin);
if(value > 255)
errorLog("EEPROM write: value > 255: ",value);
if(value < 0)
errorLog("EEPROM write: value < 0: ",value);
res = 0;
}
if(event == S_EEPROM_READ)
{
sprintf(eventText,"EEPROM.read address=%d value=%d",pin,value);
if(pin > 512)
errorLog("EEPROM read: address > 512: ",pin);
if(pin < 0)
errorLog("EEPROM read: address < 0: ",pin);
if(value > 255)
errorLog("EEPROM read: value > 255: ",value);
if(value < 0)
errorLog("EEPROM read: value < 0: ",value);
res = 0;
}
logEvent(eventText);
logCust(custText);
writeStatus();
if(g_curStep == g_simulationLength) stopEncoding();
if(g_doInterrupt == S_YES && g_ongoingInterrupt == S_NO)interruptNow();
return(res);
}
int manageIoDevice( Device* device, Heap* ready_queue,
ActivityLog* activity_log )
{
// variables
char action_message[STD_STR_LEN];
PCB temp;
// case: an I/O completion interrupt has been raised
if( device->data.interrupt_flag )
{
// time this action
stopwatch( 's', IO_TIMER );
// kill the I/O simulating thread
pthread_join( device->data.thread_id, NULL );
// release the device from the process, load it into the main
// scheduler
device->data.interrupt_flag = false;
device->data.in_use = false;
insert_heap( ready_queue, *(device->working_process), FIFO_HEAP );
device->working_process = NULL;
// log this action
sprintf( action_message, "%s action completed for process %d - "
"process placed back in main scheduler",
device->name, device->working_process->pid );
logEvent( activity_log, SYSTEM, action_message,
stopwatch( 'x', IO_TIMER ) );
}
// case: an I/O processed is running and needs to be managed
else if( device->data.in_use )
{
// log the maintenance of the process (simulate with a short wait)
stopwatch( 's', IO_TIMER );
usleep( IO_MANAGEMENT_TIME );
sprintf( action_message,
"I/O maintnenance: %s still in use by process %d",
device->name, device->working_process->pid );
logEvent( activity_log, SYSTEM, action_message,
stopwatch( 'x', IO_TIMER ) );
}
// case: an I/O process is wating to run and the I/O device is free
// (it is possible that the device was previously freed previously)
if( !(device->data.in_use) && !is_Heap_empty( &(device->waiting_queue ) ) )
{
// start the I/O process on this device
stopwatch( 's', IO_TIMER );
temp = remove_PCB_from_Heap( &(device->waiting_queue) );
device->working_process = &temp;
// startup the independent I/O action (simulated of course)
pthread_attr_init( &(device->data.attribute) );
pthread_create( &(device->data.thread_id), &(device->data.attribute),
conductIoProcess, (void*) &(device->data) );
// log the action
sprintf( action_message, "Starting process %d on %s",
device->working_process->pid, device->name );
logEvent( activity_log, SYSTEM, action_message,
stopwatch( 'x', IO_TIMER ) );
}
}
//returns bytesize of sent filename (or -1 on error);
static uint32_t sendNextRequestedFile(connectionObject *connection)
{
uint32_t filenameBytesize = 0;
diskFileObject *outgoingFile = NULL;
uint32_t bytesAlreadyRead = 0;
uint32_t bytesToRead = 0;
uint32_t fileBytesize = 0; //TODO eventually make uint64_t + support this in networking + client + server +disklfile etc, switch to 64 bit eventually (used many spots make sure to change all when I do it)...
if(connection == NULL){
logEvent("Error", "Something was NULL that shouldn't have been");
goto error;
}
//get the requested file name bytesize
filenameBytesize = connection->router->getIncomingBytesize(connection->router);
//WARNING the assumption that MAX_FILE_ID_BYTESIZE is exact size of buffer connection->requestedFilename must hold true for security to be present
if(filenameBytesize > MAX_FILE_ID_BYTESIZE || filenameBytesize == 0){
return 0;
}
//initialize filename
if( !connection->router->receive(connection->router, connection->requestedFilename, filenameBytesize) ){
logEvent("Error", "Failed to determine requested file name");
return 0;
}
//random NOTE (Stop relying on strlen for anything anywhere)
outgoingFile = getFileById(connection->requestedFilename, filenameBytesize);
if(!outgoingFile && !sendFileNotFound(connection)){
logEvent("Error", "Failed to send file not found to client");
goto error;
}
fileBytesize = outgoingFile->getBytesize(outgoingFile);
if(fileBytesize == -1){
logEvent("Error", "Failed to get file bytesize");
goto error;
}
if( !connection->router->transmitBytesize(connection->router, fileBytesize) ){
logEvent("Error", "Failed to transmit file bytesize to client");
goto error;
}
for(bytesAlreadyRead = 0, bytesToRead = 0; bytesAlreadyRead < fileBytesize; bytesAlreadyRead += bytesToRead){
bytesToRead = ( (fileBytesize - bytesAlreadyRead) < FILE_CHUNK_BYTESIZE ) ? (fileBytesize - bytesAlreadyRead) : FILE_CHUNK_BYTESIZE;
if( !outgoingFile->dfRead(outgoingFile, connection->dataCache, bytesToRead, bytesAlreadyRead) ){
logEvent("Error", "Failed to read file bytes");
goto error;
}
if( !connection->router->transmit(connection->router, connection->dataCache, bytesToRead) ){ //TODO should we make a packet format that is padded and fixed size? I think so.
logEvent("Error", "Failed to transmit file to client");
goto error;
}
}
return filenameBytesize;
error:
return -1;
}
static int initializeSharedFiles(const char *sharedFolderPath, uint32_t maxCacheMegabytes)
{
uint32_t availableCacheBytes;
uint32_t fileBytesCached;
DIR *directory;
struct dirent *fileEntry;
diskFileObject *diskFile;
if(sharedFolderPath == NULL){
logEvent("Error", "Something was NULL that shouldn't have been");
return 0;
}
initializeFileBank();
//simple unsigned integer wrap protection, limits cache to slightly over four gigabytes
if(maxCacheMegabytes > UINT32_MAX / BYTES_IN_A_MEGABYTE){
logEvent("Error", "maximum cache megabyte size supported is (UINT32_MAX / BYTES_IN_A_MEGABYTE), as cache is internally stored in bytes in a uint32_t");
return 0;
}
else{
globalMaxCacheBytes = maxCacheMegabytes * BYTES_IN_A_MEGABYTE;
}
availableCacheBytes = globalMaxCacheBytes;
directory = opendir( sharedFolderPath );
if(directory == NULL){
logEvent("Error", "Failed to open shared folder");
return 0;
}
while((fileEntry = readdir(directory))){
if( !strcmp(fileEntry->d_name, ".") || !strcmp(fileEntry->d_name, "..") ){
continue;
}
diskFile = newDiskFile();
if(diskFile == NULL){
logEvent("Error", "Failed to create diskFile object");
return 0;
}
if( !diskFile->dfOpen(diskFile, sharedFolderPath, fileEntry->d_name, "r") ){ //TODO make consts in accordance with cert (everywhere)
logEvent("Error", "Failed to open file on disk");
return 0;
}
fileBytesCached = diskFile->cacheBytes(diskFile, FILE_CHUNK_BYTESIZE); //TODO we need to switch from a byte paradigm to a file chunk paradigm to ensure compatibility with mmap page sizes, don't keep track of max cached bytes but rather max cached file chunks, this cache is too small
availableCacheBytes -= fileBytesCached; //BROKEN WARNING SEE ABOVE TODO //and should be available cache bytes TODO TODO TODO TODO TODO TODO BROKEN WARNING
if( depositFile(diskFile) != 1){
logEvent("Error", "Failed to deposit a file into shared file bank, does the shared folder have too many files in it?");
return 0;
}
}
return 1;
}
void System::reset(bool complete)
{
m_render.cleanup(complete);
m_windowMgr->reset(complete);
logEvent(log::system, "Resetting window tree...");
m_tickedWnd.clear();
m_subscribeTickWnd.clear();
m_dragContainer = 0;
m_tooltipWindow = 0;
m_dragWindow = 0;
m_rootWindow = 0;
m_containsMouse = 0;
m_focusWindow = 0;
m_exclusiveInputWindow = 0;
m_captureWindow = 0;
m_dragging = false;
m_dragfired = false;
m_dragfreeze = false;
m_rootWindow.reset();
m_dragContainer.reset();
m_tooltipWindow.reset();
m_menuWindow.reset();
if (complete) {
m_scriptSys.reset();
makeLuaBinding();
}
m_rootWindow = std::make_shared<WindowBase>(*this, "systemroot");
if(!m_rootWindow)
throw std::exception("Couldn't create root window!");
auto drag = std::make_shared<DragContainer>(*this, "systemdrag");
m_dragContainer = drag;
if (!m_dragContainer)
throw std::exception("Couldn't create drag window!");
drag->reset();
auto tooltip = std::make_shared<Tooltip>(*this, "systemtooltip");
m_tooltipWindow = tooltip;
if(!tooltip)
throw std::exception("Couldn't create tooltip window!");
tooltip->reset();
auto menu = std::make_shared<Menu>(*this, "systemmenu");
m_menuWindow = menu;
if (!m_menuWindow)
throw std::exception("Couldn't create menu window!");
m_windowMgr->loadLeafWindow(m_menuWindow, "base/menu.xml");
menu->reset();
m_rootWindow->setArea(Rect(point(.0f, .0f), m_render.getSize())); // full window area
m_rootWindow->setVisible(true);
m_rootWindow->add(m_dragContainer);
m_rootWindow->add(m_tooltipWindow);
m_rootWindow->add(m_menuWindow);
m_rootWindow->setAcceptDrop(true);
logEvent(log::system, "Gui subsystem is ready");
}
void EventsWidget::onDisconnected()
{
logEvent("Disconnected", tr("Disconnected."));
}
void EventsWidget::onPlayerSpawnEvent(const QString &player, int teamId)
{
logEvent("PlayerSpawn", tr("Player %1 spawned, and is on team %2.").arg(player).arg(BF4LevelDictionary::getTeam(teamId - 1).name));
}
/* Events */
void EventsWidget::onPlayerAuthenticatedEvent(const QString &player)
{
logEvent("PlayerAuthenticated", tr("Player %1 authenticated.").arg(player));
}
void EventsWidget::onPlayerChatEvent(const QString &sender, const QString &message, const QString &target)
{
Q_UNUSED(target);
logEvent("PlayerChat", QString("%1: %2").arg(sender).arg(message));
}
int main(int argc, char ** argv)
{
if (security_init() != 0) {
log(CRITICAL, "Security initialisation Error. Exiting.");
return EXIT_SECURITY_ERROR;
}
if (security_check() != SECURITY_OKAY) {
log(CRITICAL, "Security check error. Exiting.");
return EXIT_SECURITY_ERROR;
}
interactive_signals();
int config_status = loadConfig(argc, argv, USAGE_SERVER);
if (config_status < 0) {
if (config_status == CONFIG_VERSION) {
std::cout << argv[0] << " (cyphesis) " << consts::version
<< " (Cyphesis build " << consts::buildId << ")"
<< std::endl << std::flush;
return 0;
} else if (config_status == CONFIG_HELP) {
showUsage(argv[0], USAGE_SERVER);
return 0;
} else if (config_status != CONFIG_ERROR) {
log(ERROR, "Unknown error reading configuration.");
}
// Fatal error loading config file.
return EXIT_CONFIG_ERROR;
}
if (daemon_flag) {
int pid = daemonise();
if (pid == -1) {
return EXIT_FORK_ERROR;
} else if (pid > 0) {
return EXIT_SUCCESS;
}
}
readConfigItem(instance, "usedatabase", database_flag);
// If we are a daemon logging to syslog, we need to set it up.
initLogger();
// Initialise the persistance subsystem. If we have been built with
// database support, this will open the various databases used to
// store server data.
if (database_flag) {
Persistence * p = Persistence::instance();
int dbstatus = p->init();
if (dbstatus < 0) {
database_flag = false;
log(ERROR, "Error opening database. Database disabled.");
if (dbstatus == DATABASE_TABERR) {
log(INFO, "Database connection established, "
"but unable to create required tables.");
log(INFO, "Please ensure that any obsolete database "
"tables have been removed.");
} else {
log(INFO, "Unable to connect to the RDBMS.");
log(INFO, "Please ensure that the RDBMS is running, "
"the cyphesis database exists and is accessible "
"to the user running cyphesis.");
}
log(INFO, String::compose("To disable this message please run:\n\n"
" cyconfig --%1:usedatabase=false\n\n"
"to permanently disable database usage.",
instance));
}
}
// If the restricted flag is set in the config file, then we
// don't allow connecting users to create accounts. Accounts must
// be created manually by the server administrator.
if (restricted_flag) {
log(INFO, "Setting restricted mode.");
}
readConfigItem(instance, "inittime", timeoffset);
std::string server_name;
if (readConfigItem(instance, "servername", server_name) != 0) {
if (instance == CYPHESIS) {
server_name = get_hostname();
} else {
server_name = instance;
}
}
int nice = 1;
readConfigItem(instance, "nice", nice);
// Start up the python subsystem.
init_python_api();
{ // scope for CommServer
// Create commserver instance that will handle connections from clients.
// The commserver will create the other server related objects, and the
// world object pair (World + WorldRouter), and initialise the admin
// account. The primary ruleset name is passed in so it
// can be stored and queried by clients.
Inheritance::instance();
WorldRouter world;
Ruleset::init();
TeleportAuthenticator::init();
StorageManager store(world);
// This ID is currently generated every time, but should perhaps be
// persistent in future.
std::string server_id, lobby_id;
long int_id, lobby_int_id;
if (((int_id = newId(server_id)) < 0) ||
((lobby_int_id = newId(lobby_id)) < 0)) {
log(CRITICAL, "Unable to get server IDs from Database");
return EXIT_DATABASE_ERROR;
}
ServerRouting server(world, ruleset, server_name,
server_id, int_id,
lobby_id, lobby_int_id);
CommServer commServer(server);
if (commServer.setup() != 0) {
log(CRITICAL, "Internal error setting up server infrastructure");
return EXIT_SOCKET_ERROR;
}
// This is where we should restore the database, before
// the listen sockets are open. Unlike earlier code, we are
// attempting to construct the internal state from the database,
// not creating a new world using the contents of the database as a
// template
if (database_flag) {
// log(INFO, _("Restoring world from database..."));
store.restoreWorld();
// FIXME Do the following steps.
// Read the world entity if any from the database, or set it up.
// If it was there, make sure it did not get any of the wrong
// position or orientation data.
store.initWorld();
// log(INFO, _("Restored world."));
CommPSQLSocket * dbsocket = new CommPSQLSocket(commServer,
Persistence::instance()->m_connection);
commServer.addSocket(dbsocket);
commServer.addIdle(dbsocket);
IdleConnector * storage_idle = new IdleConnector(commServer);
storage_idle->idling.connect(sigc::mem_fun(&store, &StorageManager::tick));
commServer.addIdle(storage_idle);
} else {
std::string adminId;
long intId = newId(adminId);
assert(intId >= 0);
Admin * admin = new Admin(0, "admin", "BAD_HASH", adminId, intId);
server.addAccount(admin);
}
// Add the test object, and call it regularly so it can do what it does.
// UpdateTester * update_tester = new UpdateTester(commServer);
// commServer.addIdle(update_tester);
CommTCPListener * listener = new CommTCPListener(commServer,
*new CommClientFactory<Connection>());
if (client_port_num < 0) {
client_port_num = dynamic_port_start;
for (; client_port_num <= dynamic_port_end; client_port_num++) {
if (listener->setup(client_port_num) == 0) {
break;
}
}
if (client_port_num > dynamic_port_end) {
log(ERROR, String::compose("Could not find free client listen "
"socket in range %1-%2. Init failed.",
dynamic_port_start, dynamic_port_end));
log(INFO, String::compose("To allocate 8 more ports please run:"
"\n\n cyconfig "
"--cyphesis:dynamic_port_end=%1\n\n",
dynamic_port_end + 8));
return EXIT_PORT_ERROR;
}
log(INFO, String::compose("Auto configuring new instance \"%1\" "
"to use port %2.",
instance, client_port_num));
global_conf->setItem(instance, "tcpport", client_port_num,
varconf::USER);
global_conf->setItem(CYPHESIS, "dynamic_port_start",
client_port_num + 1, varconf::USER);
} else {
if (listener->setup(client_port_num) != 0) {
log(ERROR, String::compose("Could not create client listen socket "
"on port %1. Init failed.",
client_port_num));
return EXIT_SOCKET_ERROR;
}
}
commServer.addSocket(listener);
#ifdef HAVE_SYS_UN_H
CommUnixListener * localListener = new CommUnixListener(commServer,
*new CommClientFactory<TrustedConnection>());
if (localListener->setup(client_socket_name) != 0) {
log(ERROR, String::compose("Could not create local listen socket "
"with address \"%1\"",
localListener->getPath()));
delete localListener;
} else {
commServer.addSocket(localListener);
}
CommUnixListener * pythonListener = new CommUnixListener(commServer,
*new CommPythonClientFactory());
if (pythonListener->setup(python_socket_name) != 0) {
log(ERROR, String::compose("Could not create python listen socket "
"with address %1.",
pythonListener->getPath()));
delete pythonListener;
} else {
commServer.addSocket(pythonListener);
}
#endif
CommTCPListener * httpListener = new CommTCPListener(commServer,
*new CommHttpClientFactory());
if (httpListener->setup(http_port_num) != 0) {
log(ERROR, String::compose("Could not create http listen socket on "
"port %1.", http_port_num));
delete httpListener;
} else {
commServer.addSocket(httpListener);
}
if (useMetaserver) {
CommMetaClient * cmc = new CommMetaClient(commServer);
if (cmc->setup(mserver) == 0) {
commServer.addIdle(cmc);
} else {
log(ERROR, "Error creating metaserver comm channel.");
delete cmc;
}
}
#if defined(HAVE_LIBHOWL) || defined(HAVE_AVAHI)
CommMDNSPublisher * cmdns = new CommMDNSPublisher(commServer);
if (cmdns->setup() == 0) {
commServer.addSocket(cmdns);
commServer.addIdle(cmdns);
} else {
log(ERROR, "Unable to register service with MDNS daemon.");
delete cmdns;
}
#endif // defined(HAVE_LIBHOWL) || defined(HAVE_AVAHI)
// Configuration is now complete, and verified as somewhat sane, so
// we save the updated user config.
updateUserConfiguration();
log(INFO, "Running");
logEvent(START, "- - - Standalone server startup");
// Inform things that want to know that we are running.
running();
// Reduce our system priority to make it easier to debug a runaway
// server.
if (nice != 0) {
reduce_priority(nice);
}
// Loop until the exit flag is set. The exit flag can be set anywhere in
// the code easily.
while (!exit_flag) {
try {
commServer.poll();
}
catch (...) {
// It is hoped that commonly thrown exception, particularly
// exceptions that can be caused by external influences
// should be caught close to where they are thrown. If
// an exception makes it here then it should be debugged.
log(ERROR, "Exception caught in main()");
}
}
// exit flag has been set so we close down the databases, and indicate
// to the metaserver (if we are using one) that this server is going down.
// It is assumed that any preparation for the shutdown that is required
// by the game has been done before exit flag was set.
log(NOTICE, "Performing clean shutdown...");
} // close scope of CommServer, WorldRouter, and ServerRouting, which
// cause the destruction of the server and world objects, and the entire
// world contents
Persistence::instance()->shutdown();
EntityBuilder::instance()->flushFactories();
EntityBuilder::del();
ArithmeticBuilder::del();
MindFactory::del();
TeleportAuthenticator::del();
Inheritance::clear();
// Shutdown the python interpretter. This frees lots of memory, and if
// the malloc heap is in any way corrupt, a segfault is likely to
// occur at this point. Previous occassions where pointers have been
// deleted twice elsewhere in the code, have resulted in a segfault
// at this point. AlRiddoch 10th November 2001
shutdown_python_api();
delete global_conf;
log(INFO, "Clean shutdown complete.");
logEvent(STOP, "- - - Standalone server shutdown");
return 0;
}
void EventsWidget::onPlayerTeamChangeEvent(const QString &player, int teamId, int squadId)
{
Q_UNUSED(squadId);
logEvent("PlayerTeamChange", tr("Player %1 changed team to %2.").arg(player).arg(teamId));
}
static void
processEvent_Apple_Network(struct kern_event_msg *ev_msg)
{
const char * eventName = NULL;
int dataLen = (ev_msg->total_size - KEV_MSG_HEADER_SIZE);
void * event_data = &ev_msg->event_data[0];
Boolean handled = TRUE;
char ifr_name[IFNAMSIZ];
switch (ev_msg->kev_subclass) {
case KEV_INET_SUBCLASS : {
eventName = inetEventNameString(ev_msg->event_code);
switch (ev_msg->event_code) {
case KEV_INET_NEW_ADDR :
case KEV_INET_CHANGED_ADDR :
case KEV_INET_ADDR_DELETED :
case KEV_INET_SIFDSTADDR :
case KEV_INET_SIFBRDADDR :
case KEV_INET_SIFNETMASK : {
struct kev_in_data * ev;
ev = (struct kev_in_data *)event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_update_ipv4(NULL, ifr_name);
break;
}
case KEV_INET_ARPCOLLISION : {
struct kev_in_collision * ev;
ev = (struct kev_in_collision *)event_data;
if ((dataLen < sizeof(*ev))
|| (dataLen < (sizeof(*ev) + ev->hw_len))) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_collision_ipv4(ifr_name,
ev->ia_ipaddr,
ev->hw_len,
ev->hw_addr);
break;
}
#if !TARGET_OS_IPHONE
case KEV_INET_PORTINUSE : {
struct kev_in_portinuse * ev;
ev = (struct kev_in_portinuse *)event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
port_in_use_ipv4(ev->port, ev->req_pid);
break;
}
#endif /* !TARGET_OS_IPHONE */
default :
handled = FALSE;
break;
}
break;
}
case KEV_INET6_SUBCLASS : {
struct kev_in6_data * ev;
eventName = inet6EventNameString(ev_msg->event_code);
ev = (struct kev_in6_data *)event_data;
switch (ev_msg->event_code) {
case KEV_INET6_NEW_USER_ADDR :
case KEV_INET6_CHANGED_ADDR :
case KEV_INET6_ADDR_DELETED :
case KEV_INET6_NEW_LL_ADDR :
case KEV_INET6_NEW_RTADV_ADDR :
case KEV_INET6_DEFROUTER :
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_update_ipv6(NULL, ifr_name);
break;
default :
handled = FALSE;
break;
}
break;
}
case KEV_DL_SUBCLASS : {
struct net_event_data * ev;
eventName = dlEventNameString(ev_msg->event_code);
ev = (struct net_event_data *)event_data;
switch (ev_msg->event_code) {
case KEV_DL_IF_ATTACHED :
/*
* new interface added
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_add(ifr_name);
break;
case KEV_DL_IF_DETACHED :
/*
* interface removed
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_remove(ifr_name);
break;
case KEV_DL_IF_DETACHING :
/*
* interface detaching
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
interface_detaching(ifr_name);
break;
case KEV_DL_PROTO_ATTACHED :
case KEV_DL_PROTO_DETACHED : {
struct kev_dl_proto_data * protoEvent;
protoEvent = (struct kev_dl_proto_data *)event_data;
if (dataLen < sizeof(*protoEvent)) {
handled = FALSE;
break;
}
copy_if_name(&protoEvent->link_data,
ifr_name, sizeof(ifr_name));
if (protoEvent->proto_remaining_count == 0) {
mark_if_down(ifr_name);
} else {
mark_if_up(ifr_name);
}
break;
}
#ifdef KEV_DL_IF_IDLE_ROUTE_REFCNT
case KEV_DL_IF_IDLE_ROUTE_REFCNT: {
/*
* interface route refcnt idle
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
interface_update_idle_state(ifr_name);
break;
}
#endif // KEV_DL_IF_IDLE_ROUTE_REFCNT
case KEV_DL_LINK_OFF :
case KEV_DL_LINK_ON :
/*
* update the link status in the store
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_update_status(ifr_name, FALSE);
break;
#ifdef KEV_DL_LINK_QUALITY_METRIC_CHANGED
case KEV_DL_LINK_QUALITY_METRIC_CHANGED: {
struct kev_dl_link_quality_metric_data * lqm_data;
lqm_data = (struct kev_dl_link_quality_metric_data *) event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
interface_update_quality_metric(ifr_name,
lqm_data->link_quality_metric);
break;
}
#endif // KEV_DL_LINK_QUALITY_METRIC_CHANGED
#ifdef KEV_DL_ISSUES
case KEV_DL_ISSUES: {
struct kev_dl_issues *issues;
issues = (struct kev_dl_issues *)event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
interface_update_link_issues(ifr_name,
issues->timestamp,
issues->modid,
DLIL_MODIDLEN,
issues->info,
(bcmp(issues->info, info_zero, DLIL_MODIDLEN) != 0)
?DLIL_MODARGLEN
:0);
break;
}
#endif // KEV_DL_ISSUES
case KEV_DL_SIFFLAGS :
case KEV_DL_SIFMETRICS :
case KEV_DL_SIFMTU :
case KEV_DL_SIFPHYS :
case KEV_DL_SIFMEDIA :
case KEV_DL_SIFGENERIC :
case KEV_DL_ADDMULTI :
case KEV_DL_DELMULTI :
case KEV_DL_LINK_ADDRESS_CHANGED :
case KEV_DL_WAKEFLAGS_CHANGED :
#ifdef KEV_DL_IFCAP_CHANGED
case KEV_DL_IFCAP_CHANGED :
#endif // KEV_DL_IFCAP_CHANGED
break;
default :
handled = FALSE;
break;
}
break;
}
#ifdef KEV_ND6_SUBCLASS
case KEV_ND6_SUBCLASS : {
eventName = nd6EventNameString(ev_msg->event_code);
switch (ev_msg->event_code) {
case KEV_KEV_ND6_RA :
break;
default :
handled = FALSE;
break;
}
break;
}
#endif // KEV_ND6_SUBCLASS
case KEV_LOG_SUBCLASS : {
break;
}
default :
handled = FALSE;
break;
}
if (handled == FALSE) {
CFStringRef evStr;
evStr = CFStringCreateWithCString(NULL,
(eventName != NULL) ? eventName : "New Apple network subclass",
kCFStringEncodingASCII);
logEvent(evStr, ev_msg);
CFRelease(evStr);
}
return;
}
void EventsWidget::onServerRoundOverEvent(int winningTeamId)
{
logEvent("ServerRoundOver", tr("The round has just ended, and %1 won.").arg(winningTeamId));
}
static void
processEvent_Apple_Network(struct kern_event_msg *ev_msg)
{
const char * eventName = NULL;
int dataLen = (ev_msg->total_size - KEV_MSG_HEADER_SIZE);
void * event_data = &ev_msg->event_data[0];
Boolean handled = TRUE;
char ifr_name[IFNAMSIZ+1];
switch (ev_msg->kev_subclass) {
case KEV_INET_SUBCLASS : {
eventName = inetEventNameString(ev_msg->event_code);
switch (ev_msg->event_code) {
case KEV_INET_NEW_ADDR :
case KEV_INET_CHANGED_ADDR :
case KEV_INET_ADDR_DELETED :
case KEV_INET_SIFDSTADDR :
case KEV_INET_SIFBRDADDR :
case KEV_INET_SIFNETMASK : {
struct kev_in_data * ev;
ev = (struct kev_in_data *)event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_update_ipv4(NULL, ifr_name);
break;
}
case KEV_INET_ARPCOLLISION : {
struct kev_in_collision * ev;
ev = (struct kev_in_collision *)event_data;
if ((dataLen < sizeof(*ev))
|| (dataLen < (sizeof(*ev) + ev->hw_len))) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_collision_ipv4(ifr_name,
ev->ia_ipaddr,
ev->hw_len,
ev->hw_addr);
break;
}
default :
handled = FALSE;
break;
}
break;
}
case KEV_INET6_SUBCLASS : {
struct kev_in6_data * ev;
eventName = inet6EventNameString(ev_msg->event_code);
ev = (struct kev_in6_data *)event_data;
switch (ev_msg->event_code) {
case KEV_INET6_NEW_USER_ADDR :
case KEV_INET6_CHANGED_ADDR :
case KEV_INET6_ADDR_DELETED :
case KEV_INET6_NEW_LL_ADDR :
case KEV_INET6_NEW_RTADV_ADDR :
case KEV_INET6_DEFROUTER :
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
interface_update_ipv6(NULL, ifr_name);
break;
default :
handled = FALSE;
break;
}
break;
}
case KEV_DL_SUBCLASS : {
struct net_event_data * ev;
eventName = dlEventNameString(ev_msg->event_code);
ev = (struct net_event_data *)event_data;
switch (ev_msg->event_code) {
case KEV_DL_IF_ATTACHED :
/*
* new interface added
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_add(ifr_name);
break;
case KEV_DL_IF_DETACHED :
/*
* interface removed
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_remove(ifr_name);
break;
case KEV_DL_IF_DETACHING :
/*
* interface detaching
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
interface_detaching(ifr_name);
break;
case KEV_DL_SIFFLAGS :
case KEV_DL_SIFMETRICS :
case KEV_DL_SIFMTU :
case KEV_DL_SIFPHYS :
case KEV_DL_SIFMEDIA :
case KEV_DL_SIFGENERIC :
case KEV_DL_ADDMULTI :
case KEV_DL_DELMULTI :
handled = FALSE;
break;
case KEV_DL_PROTO_ATTACHED :
case KEV_DL_PROTO_DETACHED : {
struct kev_dl_proto_data * protoEvent;
protoEvent = (struct kev_dl_proto_data *)event_data;
if (dataLen < sizeof(*protoEvent)) {
handled = FALSE;
break;
}
copy_if_name(&protoEvent->link_data,
ifr_name, sizeof(ifr_name));
if (protoEvent->proto_remaining_count == 0) {
mark_if_down(ifr_name);
} else {
mark_if_up(ifr_name);
}
break;
}
case KEV_DL_LINK_OFF :
case KEV_DL_LINK_ON :
/*
* update the link status in the store
*/
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(ev, ifr_name, sizeof(ifr_name));
link_update_status(ifr_name, FALSE);
break;
default :
handled = FALSE;
break;
}
break;
}
case KEV_ATALK_SUBCLASS: {
struct kev_atalk_data * ev;
eventName = atalkEventNameString(ev_msg->event_code);
ev = (struct kev_atalk_data *)event_data;
if (dataLen < sizeof(*ev)) {
handled = FALSE;
break;
}
copy_if_name(&ev->link_data, ifr_name, sizeof(ifr_name));
switch (ev_msg->event_code) {
case KEV_ATALK_ENABLED:
interface_update_atalk_address(ev, ifr_name);
break;
case KEV_ATALK_DISABLED:
interface_update_shutdown_atalk();
break;
case KEV_ATALK_ZONEUPDATED:
interface_update_atalk_zone(ev, ifr_name);
break;
case KEV_ATALK_ROUTERUP:
case KEV_ATALK_ROUTERUP_INVALID:
case KEV_ATALK_ROUTERDOWN:
interface_update_appletalk(NULL, ifr_name);
break;
case KEV_ATALK_ZONELISTCHANGED:
break;
default :
handled = FALSE;
break;
}
break;
}
default :
handled = FALSE;
break;
}
if (handled == FALSE) {
CFStringRef evStr;
evStr = CFStringCreateWithCString(NULL,
(eventName != NULL) ? eventName : "New Apple network subclass",
kCFStringEncodingASCII);
logEvent(evStr, ev_msg);
CFRelease(evStr);
}
return;
}
void EventsWidget::onServerRoundOverPlayersEvent(const QString &playerInfo)
{
logEvent("ServerRoundOverPlayers", tr("The round has just ended, and %1 is the final detailed player stats.").arg(playerInfo)); // TODO: Check what this actually outputs.
}
MdamIntervalList::MdamIntervalList(const Lng32 callerTag)
: firstIntervalPtr_(0), lastIntervalPtr_(0),
intervalListId_(NA_JulianTimestamp())
{
logEvent(5,0,-1,callerTag);
}
void EventsWidget::onServerRoundOverTeamScoresEvent(const QString &teamScores)
{
logEvent("ServerRoundOverTeamScores", tr("The round has just ended, and %1 is the final ticket/kill/life count for each team.").arg(teamScores));
}
void sptrace_log_memo(PsmPartition trace, unsigned long addr, char *text,
char *fileName, int lineNbr)
{
if (!trace) return;
logEvent(trace, OP_MEMO, addr, -1, text, fileName, lineNbr, NULL);
}
/* Connection */
void EventsWidget::onConnected()
{
logEvent("Connected", tr("Connected to %1:%2.").arg(m_connection->socket->peerAddress().toString()).arg(m_connection->socket->peerPort()));
}
void threadUsbMain(void*)
{
int t;
logEvent(LOG_THREAD_USB, "USB thread launched");
usbInit();
logEvent(LOG_THREAD_USB, "USB module initialized");
while(1==1)
{
threadCopyContentDefaultUsbOut();
threadCopyContentCoreUsbOut();
usbHandler();
usbService();
if ((usbStreamVideo)&(usbConnected))
{
Sleep(0);
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_HIGHEST);
}
else
{
Sleep(100);
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_NORMAL);
}
}
/*
int a;
unsigned char buf2[64];
int lastPreviewUsbStreamVideo;
lastPreviewUsbStreamVideo=2;
SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_HIGHEST);
int i;
for(i=0;i<64;i++)
buf2[i]=0;
while (1==1)
{
threadCopyContentPreviewSetupOut2();
if (previewUsbConnect)
{
usbConnect();
previewUsbConnect=0;
usbStatusService();
}
if (previewUsbDisconnect)
{
usbDisconnect();
previewUsbDisconnect=0;
}
if (lastPreviewUsbStreamVideo!=previewUsbStreamVideo)
{
lastPreviewUsbStreamVideo=previewUsbStreamVideo;
usbStatusService();
}
if (usbPipeStrmIn!=INVALID_HANDLE_VALUE)
Sleep(0);
else
Sleep(500);
WaitForSingleObject(threadMutexUsbBufferAccess, INFINITE);
usbCopyToUsbBuffer();
// j=threadOpenglFrameRate;
ReleaseMutex(threadMutexUsbBufferAccess);
usbService(&usbUsbBuffer[0], &buf2[0]);
} */
}
InternalIOWork::InternalIOWork(IOService& serv, const String& name)
: InternalIOService::work(serv.asioService()),
mName(name)
{
logEvent("created");
}
