diff --git a/redhat/tdebase/tdebase-14.0.0-fix_starttde_trap.patch b/redhat/tdebase/tdebase-14.0.0-fix_starttde_trap.patch new file mode 100644 index 000000000..fb50a6d6f --- /dev/null +++ b/redhat/tdebase/tdebase-14.0.0-fix_starttde_trap.patch @@ -0,0 +1,11 @@ +--- tdebase/starttde.ORI 2014-04-20 18:05:28.820084805 +0200 ++++ tdebase/starttde 2014-04-20 18:06:08.059237113 +0200 +@@ -81,7 +81,7 @@ + + # When the X server dies we get a HUP signal from xinit. We must ignore it + # because we still need to do some cleanup. +-trap '[starttde] echo GOT SIGHUP' HUP ++trap 'echo "[starttde] GOT SIGHUP"' HUP + + # Check if a TDE session is already running. + if kcheckrunning >/dev/null 2>&1; then diff --git a/redhat/tdelibs/tdelibs-14.0.0-reduce_tdehwlib_cpueagerness.patch b/redhat/tdelibs/tdelibs-14.0.0-reduce_tdehwlib_cpueagerness.patch new file mode 100644 index 000000000..dc0e67b49 --- /dev/null +++ b/redhat/tdelibs/tdelibs-14.0.0-reduce_tdehwlib_cpueagerness.patch @@ -0,0 +1,934 @@ +--- tdelibs/tdecore/tdehw/tdehardwaredevices.h.ORI 2014-03-09 14:50:49.667308933 +0100 ++++ tdelibs/tdecore/tdehw/tdehardwaredevices.h 2014-03-09 19:35:43.366162065 +0100 +@@ -23,6 +23,7 @@ + #include + #include + #include ++#include + #include + #include + +@@ -75,6 +76,7 @@ + + typedef TQPtrList TDEGenericHardwareList; + typedef TQMap TDEDeviceIDMap; ++typedef TQDict TDECPUDeviceCache; + + class TDECORE_EXPORT TDEHardwareDevices : public TQObject + { +@@ -141,6 +143,12 @@ + TDEStorageDevice* findDiskByUID(TQString uid); + + /** ++ * Return the CPU device with system path @arg syspath, or 0 if no device exists for that path ++ * @return TDEGenericDevice ++ */ ++ TDECPUDevice* findCPUBySystemPath(TQString syspath, bool inCache); ++ ++ /** + * Look up the device in the system PCI database + * @param vendorid a TQString containing the vendor ID in hexadecimal + * @param modelid a TQString containing the model ID in hexadecimal +@@ -222,6 +230,15 @@ + void setTriggerlessHardwareUpdatesEnabled(bool enable); + + /** ++ * Enable or disable automatic state updates of battery hardware devices. ++ * When enabled, your application will use ++ * additional CPU resources to continually poll triggerless hardware devices. ++ * Automatic updates are disabled by default. ++ * @param enable a bool specifiying whether or not automatic updates should be enabled ++ */ ++ void setBatteryUpdatesEnabled(bool enable); ++ ++ /** + * Convert a byte count to human readable form + * @param bytes a double containing the number of bytes + * @return a TQString containing the human readable byte count +@@ -246,6 +263,7 @@ + void processHotPluggedHardware(); + void processModifiedMounts(); + void processModifiedCPUs(); ++ void processBatteryDevices(); + void processStatelessDevices(); + void processEventDeviceKeyPressed(unsigned int keycode, TDEEventDevice* edevice); + +@@ -280,6 +298,7 @@ + int m_procMountsFd; + KSimpleDirWatch* m_cpuWatch; + TQTimer* m_cpuWatchTimer; ++ TQTimer* m_batteryWatchTimer; + TQTimer* m_deviceWatchTimer; + + TQSocketNotifier* m_devScanNotifier; +@@ -292,6 +311,8 @@ + TDEDeviceIDMap* usb_id_map; + TDEDeviceIDMap* pnp_id_map; + TDEDeviceIDMap* dpy_id_map; ++ ++ TDECPUDeviceCache m_cpuByPathCache; + + friend class TDEGenericDevice; + friend class TDEStorageDevice; +--- tdelibs/tdecore/tdehw/tdehardwaredevices.cpp.ORI 2014-03-09 10:18:31.643019852 +0100 ++++ tdelibs/tdecore/tdehw/tdehardwaredevices.cpp 2014-03-09 19:37:30.389672774 +0100 +@@ -70,6 +70,24 @@ + // Compile-time configuration + #include "config.h" + ++// Profiling stuff ++//#define CPUPROFILING ++//#define STATELESSPROFILING ++ ++#include ++timespec diff(timespec start, timespec end) ++{ ++ timespec temp; ++ if ((end.tv_nsec-start.tv_nsec)<0) { ++ temp.tv_sec = end.tv_sec-start.tv_sec-1; ++ temp.tv_nsec = 1000000000+end.tv_nsec-start.tv_nsec; ++ } else { ++ temp.tv_sec = end.tv_sec-start.tv_sec; ++ temp.tv_nsec = end.tv_nsec-start.tv_nsec; ++ } ++ return temp; ++} ++ + // BEGIN BLOCK + // Copied from include/linux/genhd.h + #define GENHD_FL_REMOVABLE 1 +@@ -199,6 +217,10 @@ + m_deviceWatchTimer = new TQTimer(this); + connect( m_deviceWatchTimer, SIGNAL(timeout()), this, SLOT(processStatelessDevices()) ); + ++ // Special case for battery polling (longer delay, 5 seconds) ++ m_batteryWatchTimer = new TQTimer(this); ++ connect( m_batteryWatchTimer, SIGNAL(timeout()), this, SLOT(processBatteryDevices()) ); ++ + // Update internal device information + queryHardwareInformation(); + } +@@ -207,6 +229,7 @@ + TDEHardwareDevices::~TDEHardwareDevices() { + // Stop device scanning + m_deviceWatchTimer->stop(); ++ m_batteryWatchTimer->stop(); + + // [FIXME 0.01] + #if 0 +@@ -243,6 +266,7 @@ + if (nodezerocpufreq.exists()) { + m_cpuWatchTimer->start( 500, FALSE ); // 0.5 second repeating timer + } ++ m_batteryWatchTimer->stop(); // Battery devices are included in stateless devices + m_deviceWatchTimer->start( 1000, FALSE ); // 1 second repeating timer + } + else { +@@ -251,6 +275,20 @@ + } + } + ++void TDEHardwareDevices::setBatteryUpdatesEnabled(bool enable) { ++ if (enable) { ++ TQDir nodezerocpufreq("/sys/devices/system/cpu/cpu0/cpufreq"); ++ if (nodezerocpufreq.exists()) { ++ m_cpuWatchTimer->start( 500, FALSE ); // 0.5 second repeating timer ++ } ++ m_batteryWatchTimer->start( 5000, FALSE ); // 5 second repeating timer ++ } ++ else { ++ m_cpuWatchTimer->stop(); ++ m_batteryWatchTimer->stop(); ++ } ++} ++ + void TDEHardwareDevices::rescanDeviceInformation(TDEGenericDevice* hwdevice) { + rescanDeviceInformation(hwdevice, true); + } +@@ -270,6 +308,7 @@ + syspath += "/"; + } + TDEGenericDevice *hwdevice; ++ + // We can't use m_deviceList directly as m_deviceList can only have one iterator active against it at any given time + TDEGenericHardwareList devList = listAllPhysicalDevices(); + for ( hwdevice = devList.first(); hwdevice; hwdevice = devList.next() ) { +@@ -281,6 +320,30 @@ + return 0; + } + ++TDECPUDevice* TDEHardwareDevices::findCPUBySystemPath(TQString syspath, bool inCache=true) { ++ TDECPUDevice* cdevice; ++ ++ // Look for the device in the cache first ++ if(inCache && !m_cpuByPathCache.isEmpty()) { ++ cdevice = m_cpuByPathCache.find(syspath); ++ if(cdevice) { ++ return cdevice; ++ } ++ } ++ ++ // If the CPU was not found in cache, we need to parse the entire device list to get it. ++ cdevice = dynamic_cast(findBySystemPath(syspath)); ++ if(cdevice) { ++ if(inCache) { ++ m_cpuByPathCache.insert(syspath, cdevice); // Add the device to the cache ++ } ++ return cdevice; ++ } ++ ++ return 0; ++} ++ ++ + TDEGenericDevice* TDEHardwareDevices::findByUniqueID(TQString uid) { + TDEGenericDevice *hwdevice; + // We can't use m_deviceList directly as m_deviceList can only have one iterator active against it at any given time +@@ -410,17 +473,29 @@ + // Detect what changed between the old cpu information and the new information, + // and emit appropriate events + ++#ifdef CPUPROFILING ++ timespec time1, time2, time3; ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time1); ++ time3 = time1; ++ printf("TDEHardwareDevices::processModifiedCPUs() : begin at '%u'\n", time1.tv_nsec); ++#endif ++ + // Read new CPU information table + m_cpuInfo.clear(); + TQFile cpufile( "/proc/cpuinfo" ); + if ( cpufile.open( IO_ReadOnly ) ) { + TQTextStream stream( &cpufile ); +- while ( !stream.atEnd() ) { +- m_cpuInfo.append(stream.readLine()); +- } ++ // Using read() instead of readLine() inside a loop is 4 times faster ! ++ m_cpuInfo = TQStringList::split('\n', stream.read(), true); + cpufile.close(); + } + ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : checkpoint1 at %u [%u]\n", time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif ++ + // Ensure "processor" is the first entry in each block and determine which cpuinfo type is in use + bool cpuinfo_format_x86 = true; + bool cpuinfo_format_arm = false; +@@ -431,39 +506,43 @@ + TQStringList::Iterator blockBegin = m_cpuInfo.begin(); + for (TQStringList::Iterator cpuit1 = m_cpuInfo.begin(); cpuit1 != m_cpuInfo.end(); ++cpuit1) { + curline1 = *cpuit1; +- curline1 = curline1.stripWhiteSpace(); + if (!(*blockBegin).startsWith("processor")) { + bool found = false; + TQStringList::Iterator cpuit2; + for (cpuit2 = blockBegin; cpuit2 != m_cpuInfo.end(); ++cpuit2) { + curline2 = *cpuit2; +- curline2 = curline2.stripWhiteSpace(); + if (curline2.startsWith("processor")) { + found = true; + break; + } +- else if (curline2 == "") { ++ else if (curline2 == NULL || curline2 == "") { + break; + } + } + if (found) { + m_cpuInfo.insert(blockBegin, (*cpuit2)); + } +- else { ++ else if(blockNumber == 0) { + m_cpuInfo.insert(blockBegin, "processor : 0"); + } + } +- if (curline1 == "") { ++ if (curline1 == NULL || curline1 == "") { + blockNumber++; + blockBegin = cpuit1; + blockBegin++; + } +- if (curline1.startsWith("Processor")) { ++ else if (curline1.startsWith("Processor")) { + cpuinfo_format_x86 = false; + cpuinfo_format_arm = true; + } + } + ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : checkpoint2 at %u [%u]\n", time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif ++ + // Parse CPU information table + TDECPUDevice *cdevice; + cdevice = 0; +@@ -482,44 +561,45 @@ + for (cpuit = m_cpuInfo.begin(); cpuit != m_cpuInfo.end(); ++cpuit) { + curline = *cpuit; + if (curline.startsWith("processor")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); ++ curline.remove(0, curline.find(":")+2); + processorNumber = curline.toInt(); +- if (!cdevice) cdevice = dynamic_cast(findBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); ++ if (!cdevice) { ++ cdevice = dynamic_cast(findCPUBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); ++ } + if (cdevice) { +- if (cdevice->coreNumber() != processorNumber) modified = true; +- cdevice->internalSetCoreNumber(processorNumber); ++ if (cdevice->coreNumber() != processorNumber) { ++ modified = true; ++ cdevice->internalSetCoreNumber(processorNumber); ++ } + } + } +- if (curline.startsWith("model name")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); +- if (cdevice) { +- if (cdevice->name() != curline) modified = true; ++ else if (cdevice && curline.startsWith("model name")) { ++ curline.remove(0, curline.find(":")+2); ++ if (cdevice->name() != curline) { ++ modified = true; + cdevice->internalSetName(curline); + } + } +- if (curline.startsWith("cpu MHz")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); +- if (cdevice) { +- if (cdevice->frequency() != curline.toDouble()) modified = true; ++ else if (cdevice && curline.startsWith("cpu MHz")) { ++ curline.remove(0, curline.find(":")+2); ++ if (cdevice->frequency() != curline.toDouble()) { ++ modified = true; + cdevice->internalSetFrequency(curline.toDouble()); +- have_frequency = true; + } ++ have_frequency = true; + } +- if (curline.startsWith("vendor_id")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); +- if (cdevice) { +- if (cdevice->vendorName() != curline) modified = true; ++ else if (cdevice && curline.startsWith("vendor_id")) { ++ curline.remove(0, curline.find(":")+2); ++ if (cdevice->vendorName() != curline) { ++ modified = true; + cdevice->internalSetVendorName(curline); +- if (cdevice->vendorEncoded() != curline) modified = true; ++ } ++ if (cdevice->vendorEncoded() != curline) { ++ modified = true; + cdevice->internalSetVendorEncoded(curline); + } + } +- curline = curline.stripWhiteSpace(); +- if (curline == "") { ++ else if (curline == NULL || curline == "") { + cdevice = 0; + } + } +@@ -535,29 +615,25 @@ + for (cpuit = m_cpuInfo.begin(); cpuit != m_cpuInfo.end(); ++cpuit) { + curline = *cpuit; + if (curline.startsWith("Processor")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); ++ curline.remove(0, curline.find(":")+2); + modelName = curline; + } +- if (curline.startsWith("Hardware")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); ++ else if (curline.startsWith("Hardware")) { ++ curline.remove(0, curline.find(":")+2); + vendorName = curline; + } +- if (curline.startsWith("Serial")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); ++ else if (curline.startsWith("Serial")) { ++ curline.remove(0, curline.find(":")+2); + serialNumber = curline; + } + } + for (TQStringList::Iterator cpuit = m_cpuInfo.begin(); cpuit != m_cpuInfo.end(); ++cpuit) { + curline = *cpuit; + if (curline.startsWith("processor")) { +- curline.remove(0, curline.find(":")+1); +- curline = curline.stripWhiteSpace(); ++ curline.remove(0, curline.find(":")+2); + processorNumber = curline.toInt(); + if (!cdevice) { +- cdevice = dynamic_cast(findBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); ++ cdevice = dynamic_cast(findCPUBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); + if (cdevice) { + // Set up CPU information structures + if (cdevice->coreNumber() != processorNumber) modified = true; +@@ -573,8 +649,7 @@ + } + } + } +- curline = curline.stripWhiteSpace(); +- if (curline == "") { ++ if (curline == NULL || curline == "") { + cdevice = 0; + } + } +@@ -582,9 +657,17 @@ + + processorCount = processorNumber+1; + ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : checkpoint3 at %u [%u]\n", time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif ++ ++ TDECPUDevice* firstCPU; ++ + // Read in other information from cpufreq, if available + for (processorNumber=0; processorNumber(findBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); ++ cdevice = dynamic_cast(findCPUBySystemPath(TQString("/sys/devices/system/cpu/cpu%1").arg(processorNumber))); + TQDir cpufreq_dir(TQString("/sys/devices/system/cpu/cpu%1/cpufreq").arg(processorNumber)); + TQString scalinggovernor; + TQString scalingdriver; +@@ -595,107 +678,131 @@ + TQStringList frequencylist; + TQStringList governorlist; + if (cpufreq_dir.exists()) { +- TQString nodename = cpufreq_dir.path(); +- nodename.append("/scaling_governor"); +- TQFile scalinggovernorfile(nodename); +- if (scalinggovernorfile.open(IO_ReadOnly)) { +- TQTextStream stream( &scalinggovernorfile ); +- scalinggovernor = stream.readLine(); +- scalinggovernorfile.close(); +- } +- nodename = cpufreq_dir.path(); +- nodename.append("/scaling_driver"); +- TQFile scalingdriverfile(nodename); +- if (scalingdriverfile.open(IO_ReadOnly)) { +- TQTextStream stream( &scalingdriverfile ); +- scalingdriver = stream.readLine(); +- scalingdriverfile.close(); +- } +- nodename = cpufreq_dir.path(); +- nodename.append("/cpuinfo_min_freq"); +- TQFile minfrequencyfile(nodename); +- if (minfrequencyfile.open(IO_ReadOnly)) { +- TQTextStream stream( &minfrequencyfile ); +- minfrequency = stream.readLine().toDouble()/1000.0; +- minfrequencyfile.close(); +- } +- nodename = cpufreq_dir.path(); +- nodename.append("/cpuinfo_max_freq"); +- TQFile maxfrequencyfile(nodename); +- if (maxfrequencyfile.open(IO_ReadOnly)) { +- TQTextStream stream( &maxfrequencyfile ); +- maxfrequency = stream.readLine().toDouble()/1000.0; +- maxfrequencyfile.close(); ++ TQString nodename; ++ if(processorNumber == 0) { ++ // Remember the first CPU options so that we can reuse it later. ++ firstCPU = cdevice; ++ ++ nodename = cpufreq_dir.path(); ++ nodename.append("/scaling_governor"); ++ TQFile scalinggovernorfile(nodename); ++ if (scalinggovernorfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &scalinggovernorfile ); ++ scalinggovernor = stream.readLine(); ++ scalinggovernorfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/scaling_driver"); ++ TQFile scalingdriverfile(nodename); ++ if (scalingdriverfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &scalingdriverfile ); ++ scalingdriver = stream.readLine(); ++ scalingdriverfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/cpuinfo_min_freq"); ++ TQFile minfrequencyfile(nodename); ++ if (minfrequencyfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &minfrequencyfile ); ++ minfrequency = stream.readLine().toDouble()/1000.0; ++ minfrequencyfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/cpuinfo_max_freq"); ++ TQFile maxfrequencyfile(nodename); ++ if (maxfrequencyfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &maxfrequencyfile ); ++ maxfrequency = stream.readLine().toDouble()/1000.0; ++ maxfrequencyfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/cpuinfo_transition_latency"); ++ TQFile trlatencyfile(nodename); ++ if (trlatencyfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &trlatencyfile ); ++ trlatency = stream.readLine().toDouble()/1000.0; ++ trlatencyfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/scaling_available_frequencies"); ++ TQFile availfreqsfile(nodename); ++ if (availfreqsfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &availfreqsfile ); ++ frequencylist = TQStringList::split(" ", stream.readLine()); ++ availfreqsfile.close(); ++ } ++ nodename = cpufreq_dir.path(); ++ nodename.append("/scaling_available_governors"); ++ TQFile availgvrnsfile(nodename); ++ if (availgvrnsfile.open(IO_ReadOnly)) { ++ TQTextStream stream( &availgvrnsfile ); ++ governorlist = TQStringList::split(" ", stream.readLine()); ++ availgvrnsfile.close(); ++ } + } +- nodename = cpufreq_dir.path(); +- nodename.append("/cpuinfo_transition_latency"); +- TQFile trlatencyfile(nodename); +- if (trlatencyfile.open(IO_ReadOnly)) { +- TQTextStream stream( &trlatencyfile ); +- trlatency = stream.readLine().toDouble()/1000.0; +- trlatencyfile.close(); ++ // Other CPU should have the same values as the first one. Simply copy them. ++ else { ++ scalinggovernor = firstCPU->governor(); ++ scalingdriver = firstCPU->scalingDriver(); ++ minfrequency = firstCPU->minFrequency(); ++ maxfrequency = firstCPU->maxFrequency(); ++ trlatency = firstCPU->transitionLatency(); ++ frequencylist = firstCPU->availableFrequencies(); ++ governorlist = firstCPU->availableGovernors(); + } ++ ++ // The following data are different on each CPU + nodename = cpufreq_dir.path(); + nodename.append("/affected_cpus"); + TQFile tiedcpusfile(nodename); + if (tiedcpusfile.open(IO_ReadOnly)) { + TQTextStream stream( &tiedcpusfile ); + affectedcpulist = TQStringList::split(" ", stream.readLine()); + tiedcpusfile.close(); + } +- nodename = cpufreq_dir.path(); +- nodename.append("/scaling_available_frequencies"); +- TQFile availfreqsfile(nodename); +- if (availfreqsfile.open(IO_ReadOnly)) { +- TQTextStream stream( &availfreqsfile ); +- frequencylist = TQStringList::split(" ", stream.readLine()); +- availfreqsfile.close(); +- } +- nodename = cpufreq_dir.path(); +- nodename.append("/scaling_available_governors"); +- TQFile availgvrnsfile(nodename); +- if (availgvrnsfile.open(IO_ReadOnly)) { +- TQTextStream stream( &availgvrnsfile ); +- governorlist = TQStringList::split(" ", stream.readLine()); +- availgvrnsfile.close(); +- } + ++ // We may already have the CPU Mhz information in '/proc/cpuinfo' + if (!have_frequency) { + nodename = cpufreq_dir.path(); + nodename.append("/cpuinfo_cur_freq"); + TQFile cpufreqfile(nodename); + if (cpufreqfile.open(IO_ReadOnly)) { + TQTextStream stream( &cpufreqfile ); +- if (cdevice) cdevice->internalSetFrequency(stream.readLine().toDouble()/1000.0); ++ if (cdevice) { ++ cdevice->internalSetFrequency(stream.readLine().toDouble()/1000.0); ++ } + cpufreqfile.close(); + have_frequency = true; + } + } + +- bool frequencyFound; ++ bool minfrequencyFound = false; ++ bool maxfrequencyFound = false; + TQStringList::Iterator freqit; +- frequencyFound = false; + for ( freqit = frequencylist.begin(); freqit != frequencylist.end(); ++freqit ) { + double thisfrequency = (*freqit).toDouble()/1000.0; + if (thisfrequency == minfrequency) { +- frequencyFound = true; ++ minfrequencyFound = true; ++ } ++ if (thisfrequency == maxfrequency) { ++ maxfrequencyFound = true; + } ++ + } +- if (!frequencyFound) { ++ if (!minfrequencyFound) { + int minFrequencyInt = (minfrequency*1000.0); + frequencylist.prepend(TQString("%1").arg(minFrequencyInt)); + } +- frequencyFound = false; +- for ( freqit = frequencylist.begin(); freqit != frequencylist.end(); ++freqit ) { +- double thisfrequency = (*freqit).toDouble()/1000.0; +- if (thisfrequency == maxfrequency) { +- frequencyFound = true; +- } +- } +- if (!frequencyFound) { ++ if (!maxfrequencyFound) { + int maxfrequencyInt = (maxfrequency*1000.0); + frequencylist.append(TQString("%1").arg(maxfrequencyInt)); + } ++ ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : checkpoint3.%u at %u [%u]\n", processorNumber, time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif + } + else { + if (have_frequency) { +@@ -708,33 +815,61 @@ + + // Update CPU information structure + if (cdevice) { +- if (cdevice->governor() != scalinggovernor) modified = true; +- cdevice->internalSetGovernor(scalinggovernor); +- if (cdevice->scalingDriver() != scalingdriver) modified = true; +- cdevice->internalSetScalingDriver(scalingdriver); +- if (cdevice->minFrequency() != minfrequency) modified = true; +- cdevice->internalSetMinFrequency(minfrequency); +- if (cdevice->maxFrequency() != maxfrequency) modified = true; +- cdevice->internalSetMaxFrequency(maxfrequency); +- if (cdevice->transitionLatency() != trlatency) modified = true; +- cdevice->internalSetTransitionLatency(trlatency); +- if (cdevice->dependentProcessors().join(" ") != affectedcpulist.join(" ")) modified = true; +- cdevice->internalSetDependentProcessors(affectedcpulist); +- if (cdevice->availableFrequencies().join(" ") != frequencylist.join(" ")) modified = true; +- cdevice->internalSetAvailableFrequencies(frequencylist); +- if (cdevice->availableGovernors().join(" ") != governorlist.join(" ")) modified = true; +- cdevice->internalSetAvailableGovernors(governorlist); ++ if (cdevice->governor() != scalinggovernor) { ++ modified = true; ++ cdevice->internalSetGovernor(scalinggovernor); ++ } ++ if (cdevice->scalingDriver() != scalingdriver) { ++ modified = true; ++ cdevice->internalSetScalingDriver(scalingdriver); ++ } ++ if (cdevice->minFrequency() != minfrequency) { ++ modified = true; ++ cdevice->internalSetMinFrequency(minfrequency); ++ } ++ if (cdevice->maxFrequency() != maxfrequency) { ++ modified = true; ++ cdevice->internalSetMaxFrequency(maxfrequency); ++ } ++ if (cdevice->transitionLatency() != trlatency) { ++ modified = true; ++ cdevice->internalSetTransitionLatency(trlatency); ++ } ++ if (cdevice->dependentProcessors().join(" ") != affectedcpulist.join(" ")) { ++ modified = true; ++ cdevice->internalSetDependentProcessors(affectedcpulist); ++ } ++ if (cdevice->availableFrequencies().join(" ") != frequencylist.join(" ")) { ++ modified = true; ++ cdevice->internalSetAvailableFrequencies(frequencylist); ++ } ++ if (cdevice->availableGovernors().join(" ") != governorlist.join(" ")) { ++ modified = true; ++ cdevice->internalSetAvailableGovernors(governorlist); ++ } + } + } + ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : checkpoint4 at %u [%u]\n", time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif ++ + if (modified) { + for (processorNumber=0; processorNumberuniqueID()); + } + } ++ ++#ifdef CPUPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processModifiedCPUs() : end at %u [%u]\n", time2.tv_nsec, diff(time1,time2).tv_nsec); ++ printf("TDEHardwareDevices::processModifiedCPUs() : total time: %u\n", diff(time3,time2).tv_nsec); ++#endif + } + + void TDEHardwareDevices::processStatelessDevices() { +@@ -742,6 +877,13 @@ + // So far, network cards and sensors need to be polled + TDEGenericDevice *hwdevice; + ++#ifdef STATELESSPROFILING ++ timespec time1, time2, time3; ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time1); ++ printf("TDEHardwareDevices::processStatelessDevices() : begin at '%u'\n", time1.tv_nsec); ++ time3 = time1; ++#endif ++ + // We can't use m_deviceList directly as m_deviceList can only have one iterator active against it at any given time + TDEGenericHardwareList devList = listAllPhysicalDevices(); + for ( hwdevice = devList.first(); hwdevice; hwdevice = devList.next() ) { +@@ -749,10 +891,36 @@ + rescanDeviceInformation(hwdevice, false); + emit hardwareUpdated(hwdevice); + emit hardwareEvent(TDEHardwareEvent::HardwareUpdated, hwdevice->uniqueID()); ++#ifdef STATELESSPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processStatelessDevices() : '%s' finished at %u [%u]\n", (hwdevice->name()).ascii(), time2.tv_nsec, diff(time1,time2).tv_nsec); ++ time1 = time2; ++#endif ++ } ++ } ++ ++#ifdef STATELESSPROFILING ++ clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &time2); ++ printf("TDEHardwareDevices::processStatelessDevices() : end at '%u'\n", time2.tv_nsec); ++ printf("TDEHardwareDevices::processStatelessDevices() : took '%u'\n", diff(time3,time2).tv_nsec); ++#endif ++} ++ ++void TDEHardwareDevices::processBatteryDevices() { ++ TDEGenericDevice *hwdevice; ++ ++ // We can't use m_deviceList directly as m_deviceList can only have one iterator active against it at any given time ++ TDEGenericHardwareList devList = listAllPhysicalDevices(); ++ for ( hwdevice = devList.first(); hwdevice; hwdevice = devList.next() ) { ++ if (hwdevice->type() == TDEGenericDeviceType::Battery) { ++ rescanDeviceInformation(hwdevice, false); ++ emit hardwareUpdated(hwdevice); ++ emit hardwareEvent(TDEHardwareEvent::HardwareUpdated, hwdevice->uniqueID()); + } + } + } + ++ + void TDEHardwareDevices::processEventDeviceKeyPressed(unsigned int keycode, TDEEventDevice* edevice) { + emit eventDeviceKeyPressed(keycode, edevice); + } +@@ -2556,13 +2724,13 @@ + if (nodename == "address") { + ndevice->internalSetMacAddress(line); + } +- if (nodename == "carrier") { ++ else if (nodename == "carrier") { + ndevice->internalSetCarrierPresent(line.toInt()); + } +- if (nodename == "dormant") { ++ else if (nodename == "dormant") { + ndevice->internalSetDormant(line.toInt()); + } +- if (nodename == "operstate") { ++ else if (nodename == "operstate") { + TQString friendlyState = line.lower(); + friendlyState[0] = friendlyState[0].upper(); + ndevice->internalSetState(friendlyState); +@@ -2594,7 +2762,7 @@ + if (family == AF_INET) { + ndevice->internalSetIpV4Address(address); + } +- if (family == AF_INET6) { ++ else if (family == AF_INET6) { + address.truncate(address.findRev("%")); + ndevice->internalSetIpV6Address(address); + } +@@ -2605,7 +2773,7 @@ + if (family == AF_INET) { + ndevice->internalSetIpV4Netmask(address); + } +- if (family == AF_INET6) { ++ else if (family == AF_INET6) { + address.truncate(address.findRev("%")); + ndevice->internalSetIpV6Netmask(address); + } +@@ -2616,7 +2784,7 @@ + if (family == AF_INET) { + ndevice->internalSetIpV4Broadcast(address); + } +- if (family == AF_INET6) { ++ else if (family == AF_INET6) { + address.truncate(address.findRev("%")); + ndevice->internalSetIpV6Broadcast(address); + } +@@ -2627,7 +2795,7 @@ + if (family == AF_INET) { + ndevice->internalSetIpV4Destination(address); + } +- if (family == AF_INET6) { ++ else if (family == AF_INET6) { + address.truncate(address.findRev("%")); + ndevice->internalSetIpV6Destination(address); + } +@@ -2658,13 +2826,13 @@ + if (nodename == "rx_bytes") { + ndevice->internalSetRxBytes(line.toDouble()); + } +- if (nodename == "tx_bytes") { ++ else if (nodename == "tx_bytes") { + ndevice->internalSetTxBytes(line.toDouble()); + } +- if (nodename == "rx_packets") { ++ else if (nodename == "rx_packets") { + ndevice->internalSetRxPackets(line.toDouble()); + } +- if (nodename == "tx_packets") { ++ else if (nodename == "tx_packets") { + ndevice->internalSetTxPackets(line.toDouble()); + } + file.close(); +@@ -2705,19 +2873,19 @@ + if (sensornodetype == "label") { + sensors[sensornodename].label = line; + } +- if (sensornodetype == "input") { ++ else if (sensornodetype == "input") { + sensors[sensornodename].current = lineValue; + } +- if (sensornodetype == "min") { ++ else if (sensornodetype == "min") { + sensors[sensornodename].minimum = lineValue; + } +- if (sensornodetype == "max") { ++ else if (sensornodetype == "max") { + sensors[sensornodename].maximum = lineValue; + } +- if (sensornodetype == "warn") { ++ else if (sensornodetype == "warn") { + sensors[sensornodename].warning = lineValue; + } +- if (sensornodetype == "crit") { ++ else if (sensornodetype == "crit") { + sensors[sensornodename].critical = lineValue; + } + file.close(); +@@ -2752,40 +2920,40 @@ + if (nodename == "alarm") { + bdevice->internalSetAlarmEnergy(line.toDouble()/1000000.0); + } +- if (nodename == "charge_full" || nodename == "energy_full") { ++ else if (nodename == "charge_full" || nodename == "energy_full") { + bdevice->internalSetMaximumEnergy(line.toDouble()/1000000.0); + } +- if (nodename == "charge_full_design" || nodename == "energy_full_design") { ++ else if (nodename == "charge_full_design" || nodename == "energy_full_design") { + bdevice->internalSetMaximumDesignEnergy(line.toDouble()/1000000.0); + } +- if (nodename == "charge_now" || nodename == "energy_now") { ++ else if (nodename == "charge_now" || nodename == "energy_now") { + bdevice->internalSetEnergy(line.toDouble()/1000000.0); + } +- if (nodename == "manufacturer") { ++ else if (nodename == "manufacturer") { + bdevice->internalSetVendorName(line.stripWhiteSpace()); + } +- if (nodename == "model_name") { ++ else if (nodename == "model_name") { + bdevice->internalSetVendorModel(line.stripWhiteSpace()); + } +- if (nodename == "power_now" || nodename == "current_now") { ++ else if (nodename == "power_now" || nodename == "current_now") { + bdevice->internalSetDischargeRate(line.toDouble()/1000000.0); + } +- if (nodename == "present") { ++ else if (nodename == "present") { + bdevice->internalSetInstalled(line.toInt()); + } +- if (nodename == "serial_number") { ++ else if (nodename == "serial_number") { + bdevice->internalSetSerialNumber(line.stripWhiteSpace()); + } +- if (nodename == "status") { ++ else if (nodename == "status") { + bdevice->internalSetStatus(line); + } +- if (nodename == "technology") { ++ else if (nodename == "technology") { + bdevice->internalSetTechnology(line); + } +- if (nodename == "voltage_min_design") { ++ else if (nodename == "voltage_min_design") { + bdevice->internalSetMinimumVoltage(line.toDouble()/1000000.0); + } +- if (nodename == "voltage_now") { ++ else if (nodename == "voltage_now") { + bdevice->internalSetVoltage(line.toDouble()/1000000.0); + } + file.close(); +@@ -2823,13 +2991,13 @@ + if (nodename == "manufacturer") { + pdevice->internalSetVendorName(line.stripWhiteSpace()); + } +- if (nodename == "model_name") { ++ else if (nodename == "model_name") { + pdevice->internalSetVendorModel(line.stripWhiteSpace()); + } +- if (nodename == "online") { ++ else if (nodename == "online") { + pdevice->internalSetOnline(line.toInt()); + } +- if (nodename == "serial_number") { ++ else if (nodename == "serial_number") { + pdevice->internalSetSerialNumber(line.stripWhiteSpace()); + } + file.close(); +@@ -2868,10 +3036,10 @@ + } + bdevice->internalSetPowerLevel(pl); + } +- if (nodename == "max_brightness") { ++ else if (nodename == "max_brightness") { + bdevice->internalSetMaximumRawBrightness(line.toInt()); + } +- if (nodename == "actual_brightness") { ++ else if (nodename == "actual_brightness") { + bdevice->internalSetCurrentRawBrightness(line.toInt()); + } + file.close(); +@@ -2901,10 +3069,10 @@ + if (nodename == "status") { + mdevice->internalSetConnected(line.lower() == "connected"); + } +- if (nodename == "enabled") { ++ else if (nodename == "enabled") { + mdevice->internalSetEnabled(line.lower() == "enabled"); + } +- if (nodename == "modes") { ++ else if (nodename == "modes") { + TQStringList resinfo; + TQStringList resolutionsStringList = line.upper(); + while ((!stream.atEnd()) && (!line.isNull())) { +@@ -2921,7 +3089,7 @@ + } + mdevice->internalSetResolutions(resolutions); + } +- if (nodename == "dpms") { ++ else if (nodename == "dpms") { + TDEDisplayPowerLevel::TDEDisplayPowerLevel pl = TDEDisplayPowerLevel::On; + if (line == "On") { + pl = TDEDisplayPowerLevel::On;