void EnergyMonitor::calcLevelRect(Common::Rect &r) {
if (getStop() == 0) {
r = Common::Rect();
} else {
getBounds(r);
r.left = r.right - r.width() * (kMaxJMPEnergy - getTime()) / getStop();
}
}
void EnergyMonitor::setEnergyValue(const uint32 value) {
if (isRunning()) {
stop();
setTime(getStop() - value);
start();
} else {
setTime(getStop() - value);
}
}
Error Context::removeUnreachableCode() {
PodList<Node*>::Link* link = _unreachableList.getFirst();
Node* stop = getStop();
while (link != NULL) {
Node* node = link->getValue();
if (node != NULL && node->getPrev() != NULL) {
// Locate all unreachable nodes.
Node* first = node;
do {
if (node->isFetched())
break;
node = node->getNext();
} while (node != stop);
// Remove.
if (node != first) {
Node* last = (node != NULL) ? node->getPrev() : getCompiler()->getLastNode();
getCompiler()->removeNodes(first, last);
}
}
link = link->getNext();
}
return kErrorOk;
}
virtual void * run()
{
while ( ! getStop() )
{
uint64_t const s = libmaus2::util::GetFileSize::getDirSize(fn);
// (*sizestream) << "[S]\t" << fn << "\t" << s << std::endl;
if ( s > maxsize )
{
maxsize = s;
if ( sizestream )
printSize(*sizestream);
}
struct timespec req, rem;
req.tv_sec = sleeptime;
req.tv_nsec = 0;
rem.tv_sec = 0;
rem.tv_nsec = 0;
nanosleep(&req,&rem);
}
return 0;
}
void Camera::setStop(const Parameter & p, const Stop & s)
{
if (getStop(p) != s)
{
LOCK_MUTEX;
requestedStopChanges[p] = s;
UNLOCK_MUTEX;
}
}
int CServerLinker::addInLoop(void)
{
int iRtn = Q_RTN_OK;
OrderMsg stOrderMsg;
stOrderMsg.emType = OrderType_AddServerLinker;
stOrderMsg.pHandle = this;
if (!getStop())
{
iRtn = m_pEvent->sendOrderMsg((const char*)(&stOrderMsg), sizeof(stOrderMsg));
}
return iRtn;
}
bool TimeBase::isRunning() {
if (_paused && _pausedRate != 0)
return true;
Common::Rational rate = getRate();
if (rate == 0)
return false;
if (getFlags() & kLoopTimeBase)
return true;
if (rate > 0)
return getTime() != getStop();
return getTime() != getStart();
}
void TransferFunctionControlPointConnection::updateShape() {
if (left_ == nullptr && right_ == nullptr) {
path_ = QPainterPath();
}
path_ = QPainterPath(getStart());
path_.lineTo(getStop());
rect_ = path_.boundingRect();
QPainterPathStroker pathStrocker;
pathStrocker.setWidth(10.0);
shape_ = pathStrocker.createStroke(path_);
prepareGeometryChange();
update();
}
void ChannelAccessThr::run()
{
//printchannel(); //for Debug
CHNODE mynode[register_chacc.size()];
unsigned int i = 0;
//const char SHM_KEY[] = "0x50000000";
//const key_t SHM_KEY = 0x50000000;
//char *shmPtr = m_pattach->mCachedData.open (SHM_KEY, register_chacc.size()*sizeof(CachedData), CachedChannelAccess::RT_SHM_CREAT | CachedChannelAccess::RT_SHM_RDWR);
mutex.lock();
for ( reg_chacciter = register_chacc.begin(); reg_chacciter != register_chacc.end(); ++reg_chacciter, i++)
{
mynode[i].objname = QString(reg_chacciter->objname.c_str());
mynode[i].acacc = m_pattach;
mynode[i].pvname = QString(reg_chacciter->pvname.c_str());
mynode[i].dbrequest = reg_chacciter->dbrequest;
mynode[i].chindex = reg_chacciter->chindex;
ca_create_channel(reg_chacciter->pvname.c_str(), connectionCallback, &mynode[i], 10, (oldChannelNotify**)&mynode[i].ch_id);
};
ca_pend_event(1.0);
for ( reg_chacciter = register_chacc.begin(), i=0; reg_chacciter != register_chacc.end(); ++reg_chacciter, i++)
{
if (mynode[i].onceConnected)
{
//qDebug("Conn PV:%s", mynode[i].pvname.toStdString().c_str() );
}
else if (mynode[i].onceConnected == 0)
{
//qDebug("NotConn PV:%s", mynode[i].pvname.toStdString().c_str() );
m_pattach->ConnectionStatusObj(mynode[i].objname, -1);
};
}
mutex.unlock();
#if 1
//in vm image, ca_pend_event(0.0001) stop processing on running;
while(true)
{
if(getStop() == true) break;
ca_pend_event(0.0001);
};
ca_context_destroy();
exit();
#else
//in vm image, this code no problem why?? U know?
ca_pend_event(0.0);
#endif
}
Error Context::removeUnreachableCode() {
Compiler* compiler = getCompiler();
PodList<HLNode*>::Link* link = _unreachableList.getFirst();
HLNode* stop = getStop();
while (link != nullptr) {
HLNode* node = link->getValue();
if (node != nullptr && node->getPrev() != nullptr && node != stop) {
// Locate all unreachable nodes.
HLNode* first = node;
do {
if (node->isFetched())
break;
node = node->getNext();
} while (node != stop);
// Remove unreachable nodes that are neither informative nor directives.
if (node != first) {
HLNode* end = node;
node = first;
// NOTE: The strategy is as follows:
// 1. The algorithm removes everything until it finds a first label.
// 2. After the first label is found it removes only removable nodes.
bool removeEverything = true;
do {
HLNode* next = node->getNext();
bool remove = node->isRemovable();
if (!remove) {
if (node->isLabel())
removeEverything = false;
remove = removeEverything;
}
if (remove) {
ASMJIT_TSEC({
this->_traceNode(this, node, "[REMOVED UNREACHABLE] ");
});
compiler->removeNode(node);
}
node = next;
} while (node != end);
}
void ChannelAccessThr::run()
{
unsigned int i = 0;
vecnode.reserve(register_chacc.size());
mutex.lock();
for ( reg_chacciter = register_chacc.begin(); reg_chacciter != register_chacc.end(); ++reg_chacciter, i++)
{
CHNODE node;
node.objname = QString(reg_chacciter->objname.c_str());
node.acacc = m_pattach;
node.pvname = QString(reg_chacciter->pvname.c_str());
node.dbrequest = reg_chacciter->dbrequest;
node.chindex = reg_chacciter->chindex;
node.pItem = reg_chacciter->pItem;
vecnode.push_back(node);
ca_create_channel(reg_chacciter->pvname.c_str(), connectionCallback, (void*)&(vecnode.at(i)), 10, (oldChannelNotify**)&((vecnode.at(i)).ch_id));
};
ca_pend_event(1.0);
for ( reg_chacciter = register_chacc.begin(), i=0; reg_chacciter != register_chacc.end(); ++reg_chacciter, i++)
{
CHNODE *pNode = &vecnode.at(i);
if (pNode->onceConnected)
{
}
else if (pNode->onceConnected == 0)
{
m_pattach->ConnectionStatusObj(pNode->objname, -1);
};
}
mutex.unlock();
while(true)
{
if(getStop() == true) break;
ca_pend_event(0.0001);
};
ca_context_destroy();
exit();
}
Error Context::removeUnreachableCode() {
Compiler* compiler = getCompiler();
PodList<HLNode*>::Link* link = _unreachableList.getFirst();
HLNode* stop = getStop();
while (link != NULL) {
HLNode* node = link->getValue();
if (node != NULL && node->getPrev() != NULL && node != stop) {
// Locate all unreachable nodes.
HLNode* first = node;
do {
if (node->isFetched())
break;
node = node->getNext();
} while (node != stop);
// Remove unreachable nodes that are neither informative nor directives.
if (node != first) {
HLNode* end = node;
node = first;
do {
HLNode* next = node->getNext();
if (!node->isInformative() && node->getType() != kHLNodeTypeAlign) {
ASMJIT_TLOG("[%05d] Unreachable\n", node->getFlowId());
compiler->removeNode(node);
}
node = next;
} while (node != end);
}
}
link = link->getNext();
}
return kErrorOk;
}
bool Interval::operator<(const Interval & b) const {
if(getStart() == b.getStart()){
return (getStop() < b.getStop());
}
return (getStart() < b.getStart());
}
bool Interval::overlaps(const Interval & b, bool strand_specific){
if(getStrand() == b.getStrand() || getStrand() == BOTH || b.getStrand() == BOTH || !strand_specific){
return (getStart() < b.getStop() && b.getStart() < getStop());
}
return false;
}
void SinglePlotThread::run()
{
#if 0
// event gathering
//printchannel(); //for Debug
mutex.lock();
mynode.plot = m_plot;
chid unit_chid;
dbr_string_t units;
QString unitch = m_pvname + ".EGU";
ca_create_channel(unitch.toStdString().c_str(), 0, 0, 0, &unit_chid);
ca_pend_io(0.1);
ca_get(DBR_STRING, unit_chid, (void *)&units);
ca_pend_io(0.1);
m_plot->SetUnit(units);
ca_create_channel(m_pvname.toStdString().c_str(), connectionCallback, &mynode, 0, (oldChannelNotify**)&mynode.mychid);
ca_replace_access_rights_event(mynode.mychid, accessRightsCallback);
ca_create_subscription (DBR_TIME_DOUBLE, 0, mynode.mychid, DBE_VALUE|DBE_ALARM, eventCallback, &mynode, &mynode.myevid);
//ca_add_event(DBR_GR_DOUBLE, mynode.mychid, eventCallback, &mynode, &mynode.myevid);
mutex.unlock();
ca_pend_event(0.0);
#else
//periodic gathering
mutex.lock();
chid unit_chid, val_chid;
dbr_string_t units;
QString unitch = m_pvname + ".EGU";
ca_create_channel(unitch.toStdString().c_str(), 0, 0, 0, &unit_chid); ca_pend_io(0.2);
ca_get(DBR_STRING, unit_chid, (void *)&units); ca_pend_io(0.2);
m_plot->SetUnit(units);
struct dbr_time_double data;
ca_create_channel(m_pvname.toStdString().c_str(), 0, 0, 0, &val_chid);
ca_pend_io(0.2);
epicsTime stamp;
struct local_tm_nano_sec tm;
int totsec = 0;
//for periodic single plot local time
int year, month, day, hour, min, sec;
int factor = 1;
switch(mperiodic)
{
case PointOne:
factor *= 0.1;
break;
case PointFive:
factor *= 0.5;
break;
case FiveSec:
factor *= 5;
break;
case TenSec:
factor *= 10;
break;
case OneSec:
default:
break;
};
while(getStop()==false)
{
ca_get(DBR_TIME_DOUBLE, val_chid, (void *)&data);
ca_pend_io(0.2);
//qDebug("%s : %f\n",ca_name(val_chid), data.value);
Epoch2Datetime(year, month, day, hour, min, sec);
#if 0
stamp = data.stamp;
tm = (local_tm_nano_sec) stamp;
totsec = tm.ansi_tm.tm_hour*3600+tm.ansi_tm.tm_min*60+tm.ansi_tm.tm_sec;
m_plot->GetValue(data.value, totsec,tm.ansi_tm.tm_year,tm.ansi_tm.tm_mon, tm.ansi_tm.tm_mday );
#else
totsec = hour*3600+min*60+sec;
m_plot->GetValue(data.value, totsec, year, month, day);
#endif
usleep(1000000*factor);
};
//ca_clear_channel(unit_chid);
//ca_clear_channel(val_chid);
ca_context_destroy();
mutex.unlock();
exit();
qDebug("SinglePlot Exit");
#endif
}
void TimeBase::getSegment(TimeValue &startTime, TimeValue &stopTime, const TimeScale scale) const {
startTime = getStart(scale);
stopTime = getStop(scale);
}
void EnergyMonitor::timeChanged(const TimeValue currentTime) {
if (currentTime == getStop()) {
PegasusEngine *vm = (PegasusEngine *)g_engine;
if (vm->getEnergyDeathReason() != -1)
vm->die(vm->getEnergyDeathReason());
} else {
uint32 currentEnergy = kMaxJMPEnergy - currentTime;
EnergyStage newStage;
if (currentEnergy > kWorriedEnergy)
newStage = kStageCasual;
else if (currentEnergy > kNervousEnergy)
newStage = kStageWorried;
else if (currentEnergy > kPanicStrickenEnergy)
newStage = kStageNervous;
else
newStage = kStagePanicStricken;
if (_stage != newStage) {
uint32 newFrame;
switch (newStage) {
case kStageCasual:
_barColor = g_system->getScreenFormat().RGBToColor(0x48, 0xB0, 0xD8);
newFrame = kFrameLightOff;
break;
case kStageWorried:
_barColor = g_system->getScreenFormat().RGBToColor(0xD8, 0xC0, 0x30);
newFrame = kFrameLightYellow;
break;
case kStageNervous:
_barColor = g_system->getScreenFormat().RGBToColor(0xD8, 0x78, 0x38);
newFrame = kFrameLightOrange;
break;
case kStagePanicStricken:
_barColor = g_system->getScreenFormat().RGBToColor(0xD8, 0x40, 0x38);
newFrame = kFrameLightRed;
break;
default:
error("no stage in energy monitor?");
break;
}
_stage = newStage;
uint32 oldFrame = _energyLight.getCurrentFrameIndex();
if (!_calibrating) {
if (oldFrame > newFrame || oldFrame == 0xffffffff || _dontFlash) {
_energyLight.setCurrentFrameIndex(newFrame);
_dontFlash = false;
} else {
_lightBlinker.startBlinking(&_energyLight, oldFrame, newFrame, 4, 1, 3);
triggerRedraw();
}
}
}
Common::Rect r;
calcLevelRect(r);
if (r != _levelRect) {
_levelRect = r;
triggerRedraw();
}
}
}
