perfmon/src/perfmon_model.cpp
author Dremov Kirill (Nokia-D-MSW/Tampere) <kirill.dremov@nokia.com>
Tue, 02 Feb 2010 00:17:27 +0200
changeset 0 d6fe6244b863
permissions -rw-r--r--
Revision: 201003 Kit: 201005

/*
* Copyright (c) 2009 Nokia Corporation and/or its subsidiary(-ies). 
* All rights reserved.
* This component and the accompanying materials are made available
* under the terms of "Eclipse Public License v1.0"
* which accompanies this distribution, and is available
* at the URL "http://www.eclipse.org/legal/epl-v10.html".
*
* Initial Contributors:
* Nokia Corporation - initial contribution.
*
* Contributors:
*
* Description:  
*
*/


// INCLUDE FILES

#include "perfmon_model.h"
#include "perfmon_app.h"
#include "perfmon_settingsviewdlg.h"
#include "perfmon.hrh"
#include "perfmon_valuescontainer.h"
#include "perfmon_graphscontainer.h"
#include "perfmon_datapopupcontainer.h"
#include <perfmon.rsg>

#include <coeutils.h>
#include <bautils.h>
#include <eikenv.h>
#include <e32hal.h>
#include <u32std.h>
#include <s32file.h>
#include <akntitle.h> 
#include <eikspane.h>
#include <aknnotewrappers.h>  

_LIT(KAppName, "PerfMon");
_LIT(KDefaultLogFilePath, "c:\\data\\PerfMon.log");

const TInt KCalibrationLength = 2;
const TInt KMinimumSamplesLength = 16;
const TInt KCPUTimeMultiplier = 1000000; // used to avoid TReal conversions

const TInt KSettingsDrive = EDriveC;
_LIT(KSettingsFileName, "perfmon_settings.ini");


// --------------------------------------------------------------------------------------------

TInt CPULoadCount(TAny* aInt)
	{
	// increase the counter
	(*(TUint*)aInt)++;
	return 1;
	}

TInt CPULoadNOPThread(TAny* aParam)
	{
	CTrapCleanup* pC = CTrapCleanup::New();
	CActiveScheduler* pS = new CActiveScheduler;
	CActiveScheduler::Install(pS);

	CIdle* idle = CIdle::NewL(CActive::EPriorityStandard);
	TCallBack cb(CPULoadCount, aParam);
	idle->Start(cb);

	pS->Start();

	delete idle;
	delete pS;
	delete pC;

	return 0;
	}

// ===================================== MEMBER FUNCTIONS =====================================

CPerfMonModel* CPerfMonModel::NewL()
	{
	CPerfMonModel* self = new(ELeave) CPerfMonModel;
	CleanupStack::PushL(self);
	self->ConstructL();
	CleanupStack::Pop();
	return self;
	}

// --------------------------------------------------------------------------------------------

CPerfMonModel::CPerfMonModel() : CActive(EPriorityUserInput)
	{
	}

// --------------------------------------------------------------------------------------------

void CPerfMonModel::ConstructL()
	{
	iDrawState = EDrawStateInvalid;
	iCurrentCPUMode = ECPUModeNotSet;
	iLogFileInitialized = EFalse;
	
    iEnv = CEikonEnv::Static();
    User::LeaveIfError(iLs.Connect());

    User::LeaveIfError(iTimer.CreateLocal());
	CActiveScheduler::Add(this);
	}

// --------------------------------------------------------------------------------------------

void CPerfMonModel::ActivateModelL()
	{
    // load settings
    TRAP_IGNORE(LoadSettingsL());

	// create data storages for the samples
	CreateSamplesDataArrayL();
	
	// initialize the data popup container in top-right corner
	iDataPopupContainer = new(ELeave) CPerfMonDataPopupContainer;
	iDataPopupContainer->ConstructL(TRect(0,0,1,1));
	
	// set default modes
	HandleSettingsChangeL();

    // start sampling data immediately (jump to RunL)    
    iTimer.After(iStatus, 100);
    SetActive();
	}

// --------------------------------------------------------------------------------------------

void CPerfMonModel::DeActivateModelL()
	{
	Cancel();
	
	DeActivateCPUMonitoring();

	if (iDataPopupContainer)
	    {
	    delete iDataPopupContainer;
	    iDataPopupContainer = NULL;
	    }

    // close log file
	OpenLogFile(EFalse);
	}
	
// --------------------------------------------------------------------------------------------

CPerfMonModel::~CPerfMonModel()
	{
	iTimer.Close();

    // clear data storages
	if (iSampleEntryArray)
	    {
        for (TInt i=0; i<iSampleEntryArray->Count(); i++)
            {
            delete iSampleEntryArray->At(i).iSampleDataArray;
            }
	    
	    delete iSampleEntryArray;
	    }

	    
	iLs.Close();
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::DoCancel()
	{
    iTimer.Cancel();
	}

// --------------------------------------------------------------------------------------------

void CPerfMonModel::RunL()
	{
	// calculate new values 
	UpdateSamplesDataL();
	
	// log changes
	AppendLatestSamplesToLogsL();
	
	// redraw views
	SendDrawEventToContainersL();  

    // continue
    iTimer.After(iStatus, iSettings.iHeartBeat * 1000); // convert from milliseconds to microseconds
    SetActive();
	}

// --------------------------------------------------------------------------------------------

void CPerfMonModel::HandleSettingsChangeL()
    {
    // set priority of the thread
    RThread().SetPriority(SettingItemToThreadPriority(iSettings.iPriority));
    
    // set visibility and location of the data popup
    iDataPopupContainer->UpdateVisibility();
    iDataPopupContainer->SetPositionAndSize();
    
    // init cpu monitor if setting has been changed
    if (iCurrentCPUMode != iSettings.iCPUMode)
        {
        DeActivateCPUMonitoring();
        ActivateCPUMonitoringL();
        }
    
    // close log file
    OpenLogFile(EFalse);
    
    // enable log file
    if (iSettings.iLoggingEnabled && (iSettings.iLoggingMode == ELoggingModeLogFile || iSettings.iLoggingMode == ELoggingModeRDebugLogFile))
        OpenLogFile(ETrue);
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::EnableLogging(TBool aEnable)
    {
    if (aEnable)
        {
        if (iSettings.iLoggingMode == ELoggingModeLogFile || iSettings.iLoggingMode == ELoggingModeRDebugLogFile)
            OpenLogFile(ETrue);
        
        iSettings.iLoggingEnabled = ETrue;
        }
    else // disable
        {
        iSettings.iLoggingEnabled = EFalse;
        OpenLogFile(EFalse);
        }
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::OpenLogFile(TBool aOpen)
    {
    // open log file for writing
    if (aOpen)
        {
        if (!iLogFileInitialized)
            {
            TInt err(KErrNone);
            
            // open the log file for writing
            if (iLogFile.Open(iEnv->FsSession(), iSettings.iLoggingFilePath, EFileWrite) != KErrNone)
                {
                iEnv->FsSession().MkDirAll(iSettings.iLoggingFilePath);
                err = iLogFile.Replace(iEnv->FsSession(), iSettings.iLoggingFilePath, EFileWrite);
                }
            else
                {
                // file opens correctly, seek to the end
                TInt fileSize=0;
                iLogFile.Size(fileSize);
                err = iLogFile.Seek(ESeekCurrent, fileSize);
                }
            
            if (err == KErrNone)
                {
                iLogFileInitialized = ETrue;
                }
            else
                {
                // show error
                CAknErrorNote* note = new(ELeave) CAknErrorNote();
                note->ExecuteLD(_L("Unable to create log file, check settings"));                
                }
            }        
        }

    // close handle to log file
    else 
        {
        if (iLogFileInitialized)
            {
            iLogFile.Flush();
            iLogFile.Close();
            
            iLogFileInitialized = EFalse;
            }
        }
    }
    
// --------------------------------------------------------------------------------------------

void CPerfMonModel::ActivateCPUMonitoringL()
    {
    // reset counter variables
	iCPULoadCalibrating = ETrue;
	iCPULoadCalibrationCounter = 0;
	iCPULoadMaxValue = 999999999;
	iCPULoadPreviousValue = 1;
	iCPULoadCounter = 0;

    // use null thread is cpu time is supported and the setting is on
    if (CPUTimeSupported() && iSettings.iCPUMode == ECPUModeCPUTime) 
        {
        // try to open handle to null thread
        if (OpenHandleToNullThread())
            {
            // handle is open, get initial value
            TTimeIntervalMicroSeconds time;
            iNullThread.GetCpuTime(time);
            iCPULoadPreviousValue = time.Int64();
            iPreviousTime.HomeTime();
            
            iCurrentCPUMode = ECPUModeCPUTime;
            return; // cpu time is succesfully in use           
            }
        }

    // otherwise use normal sampling with nops    
    iCurrentCPUMode = ECPUModeNotSet;

    // show a warning if cpu time cannot be taken in use
    if (iSettings.iCPUMode == ECPUModeCPUTime)
        {
        CAknInformationNote* note = new(ELeave) CAknInformationNote();
        note->ExecuteLD(_L("CPU Time not supported in this system, using NOPs sampling"));
        }
        
    // create a thread for CPU load monitoring
    User::LeaveIfError(iCPULoadThread.Create(_L("PerfMonCPULoad"), CPULoadNOPThread, 0x1000, 0x1000, 0x100000, &iCPULoadCounter));
    iCPULoadThread.SetPriority(EPriorityLess);
    iCPULoadThread.Resume();    
    
    iCurrentCPUMode = ECPUModeNOPs; // NOPs taken succesfully in use
    }

// --------------------------------------------------------------------------------------------

TBool CPerfMonModel::OpenHandleToNullThread()
    {
    // find the kernel process and then the null thread
    TFindProcess fp(_L("ekern.exe*"));
    
    TFullName kernelName;
    if (fp.Next(kernelName) == KErrNone)
        {
        // process found, append null thread identifier
        kernelName.Append(_L("::Null"));
        
        // find the thread
        TFindThread ft(kernelName);

        TFullName threadName;
        if (ft.Next(threadName) == KErrNone)
            {
            // open instance to the thread
            if (iNullThread.Open(threadName) != KErrNone)
                return EFalse;                
            }
        }
    
    // process not found
    else
        return EFalse;
    
    // success!
    return ETrue;        
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::DeActivateCPUMonitoring()
    {
    if (iCurrentCPUMode == ECPUModeCPUTime)
        {
        iNullThread.Close();
        }
    
    else if (iCurrentCPUMode == ECPUModeNOPs)    
        {
        // kill the cpu load thread
        iCPULoadThread.Kill(0);
        iCPULoadThread.Close();        
        } 
    }

// --------------------------------------------------------------------------------------------

TBool CPerfMonModel::CPUTimeSupported()
    {
    TTimeIntervalMicroSeconds time;
    TInt err = RThread().GetCpuTime(time);
    
    if (err == KErrNone && time.Int64() > 0)
        return ETrue;
    else
        return EFalse;
    }

// --------------------------------------------------------------------------------------------

TThreadPriority CPerfMonModel::SettingItemToThreadPriority(TInt aIndex)
    {
    TThreadPriority threadPriority = EPriorityNull;
    
    switch ( aIndex )
        {
        case EThreadPriorityTypeMuchLess:
            {
            threadPriority = EPriorityMuchLess; break;
            }
        case EThreadPriorityTypeLess:
            {
            threadPriority = EPriorityLess; break;
            }
        case EThreadPriorityTypeNormal:
            {
            threadPriority = EPriorityNormal; break;
            }
        case EThreadPriorityTypeMore:
            {
            threadPriority = EPriorityMore; break;
            }
        case EThreadPriorityTypeMuchMore:
            {
            threadPriority = EPriorityMuchMore; break;
            }
        case EThreadPriorityTypeRealTime:
            {
            threadPriority = EPriorityRealTime; break;
            }
        case EThreadPriorityTypeAbsoluteVeryLow:
            {
            threadPriority = EPriorityAbsoluteVeryLow; break;
            }
        case EThreadPriorityTypeAbsoluteLow:
            {
            threadPriority = EPriorityAbsoluteLow; break;
            }
        case EThreadPriorityTypeAbsoluteBackground:
            {
            threadPriority = EPriorityAbsoluteBackground; break;
            }
        case EThreadPriorityTypeAbsoluteForeground:
            {
            threadPriority = EPriorityAbsoluteForeground; break;
            }
        case EThreadPriorityTypeAbsoluteHigh:
            {
            threadPriority = EPriorityAbsoluteHigh; break;
            }

        default:
            {
            User::Panic(_L("Wrong tp index"), 276);
            break;
            }
        }

    return threadPriority;
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::CreateSamplesDataArrayL()
    {
    TInt maxSamples = iSettings.iMaxSamples >= KMinimumSamplesLength ? iSettings.iMaxSamples : KMinimumSamplesLength;

    // create the data structure to store all samples
    iSampleEntryArray = new(ELeave) CSampleEntryArray(16);

    // add all source entries
    for (TInt i=0; i<ESourcesLength; i++)
        {
        TSampleEntry newSampleEntry;
        
        if (i == ESourceCPU)
            {
            newSampleEntry.iDescription.Copy(_L("CPU"));
            newSampleEntry.iUnitTypeShort.Copy(KNullDesC);
            newSampleEntry.iUnitTypeLong.Copy(KNullDesC);
            newSampleEntry.iDriveNumber = -1;
            newSampleEntry.iGraphColor = KRgbYellow;            
            }
        
        else if (i == ESourceRAM)
            {
            newSampleEntry.iDescription.Copy(_L("RAM"));
            newSampleEntry.iUnitTypeShort.Copy(_L("b"));
            newSampleEntry.iUnitTypeLong.Copy(_L("bytes"));
            newSampleEntry.iDriveNumber = -1;
            newSampleEntry.iGraphColor = KRgbGreen;            
            }        
        
        else //drives
            {
            TChar driveLetter = 'C' + i-ESourceC; // C is the first drive

            newSampleEntry.iDescription.Append(driveLetter);
            newSampleEntry.iDescription.Append(_L(":"));
            newSampleEntry.iUnitTypeShort.Copy(_L("b"));
            newSampleEntry.iUnitTypeLong.Copy(_L("bytes"));
            
            iEnv->FsSession().CharToDrive(driveLetter, newSampleEntry.iDriveNumber);
            
            newSampleEntry.iGraphColor = KRgbCyan;
            newSampleEntry.iGraphColor.SetGreen(255-(i-ESourceC)*30);
            newSampleEntry.iGraphColor.SetRed(i*30);
            }
        
        newSampleEntry.iSampleDataArray = new(ELeave) CSampleDataArray(maxSamples); 
        
        iSampleEntryArray->AppendL(newSampleEntry);        
        }

    // save current time as start time
    iStartTime.HomeTime();
    }
	
// --------------------------------------------------------------------------------------------

void CPerfMonModel::UpdateSamplesDataL()
    {
    // reset inactivity timers
    if (iSettings.iKeepBacklightOn)
        User::ResetInactivityTime();
   
    // get current time
    TTime currentTime;
    currentTime.HomeTime();
    
    // calculate time difference
    TTimeIntervalMicroSeconds timeDeltaFromPreviousSample = currentTime.MicroSecondsFrom(iPreviousTime);
    
    // remember current time as previous
    iPreviousTime = currentTime;
    
    
    // get CPU
    TInt64 cpuLoadDelta(0);
    TInt64 cpuLoadFree(0);
    TInt64 cpuLoadSize(0);
    TInt64 currentCPUValue(0);
    
    if (iCurrentCPUMode == ECPUModeCPUTime || iCurrentCPUMode == ECPUModeNOPs)
        {
        if (iCurrentCPUMode == ECPUModeCPUTime)
            {
            TTimeIntervalMicroSeconds time;
            iNullThread.GetCpuTime(time);
            currentCPUValue = time.Int64();
            }
        else if (iCurrentCPUMode == ECPUModeNOPs)
            {
            currentCPUValue = iCPULoadCounter;
            }    
            
        // get delta and store the previous value
        cpuLoadDelta = currentCPUValue - iCPULoadPreviousValue;
        iCPULoadPreviousValue = currentCPUValue;
        
        // velocity = distance / time
        cpuLoadFree = cpuLoadDelta * KCPUTimeMultiplier / timeDeltaFromPreviousSample.Int64();
        

        // detect maximum value
        if (cpuLoadFree > iCPULoadMaxValue)
            iCPULoadMaxValue = cpuLoadFree;
     
        
        // check calibration status      
    	if (iCPULoadCalibrating)
    	    {
    	    iCPULoadCalibrationCounter++;        
            cpuLoadSize = cpuLoadFree;
            
            // check if need to calibrate anymore
     	    if (iCPULoadCalibrationCounter > KCalibrationLength)
    	        {
    	        iCPULoadCalibrating = EFalse;
    	        
                // from the samples, get the minimum value, and let it be the max value 
        		for (TInt i=0; i<iSampleEntryArray->At(0).iSampleDataArray->Count(); i++)
        		    {
        		    TInt64 newCPULoadMaxValue = iCPULoadMaxValue;
        		    
        		    if (iSampleEntryArray->At(0).iSampleDataArray->At(i).iFree < newCPULoadMaxValue)
        		        {
        		        newCPULoadMaxValue = iSampleEntryArray->At(0).iSampleDataArray->At(i).iFree;
        		        }
        		    
        		    iCPULoadMaxValue = newCPULoadMaxValue;     		    
        		    }	        
    	        
    	        // adjust priority of the poller thread
                if (iCurrentCPUMode == ECPUModeNOPs)
                    {
                    iCPULoadThread.SetPriority(EPriorityAbsoluteVeryLow);
                    }    	        
    	        }

    	    }
    	else
    	    {
            cpuLoadSize = iCPULoadMaxValue;
    	    }            
        }

	
	// save cpu sample data    
    TSampleData cpuSample;
    cpuSample.iFree = cpuLoadFree;
    cpuSample.iSize = cpuLoadSize;
    cpuSample.iTimeFromStart = currentTime.MicroSecondsFrom(iStartTime);

    iSampleEntryArray->At(0).iSampleDataArray->InsertL(0, cpuSample);
    
 
    
    // get ram memory
    TMemoryInfoV1Buf ramMemory;
    UserHal::MemoryInfo(ramMemory);
    
    TSampleData memorySample;
    memorySample.iFree = ramMemory().iFreeRamInBytes;
    memorySample.iSize = ramMemory().iMaxFreeRamInBytes;
    memorySample.iTimeFromStart = currentTime.MicroSecondsFrom(iStartTime);

    iSampleEntryArray->At(1).iSampleDataArray->InsertL(0, memorySample); 
    
    
    // all drives
    for (TInt i=2; i<iSampleEntryArray->Count(); i++)
        {
        TSampleData driveSample;
        
        // get volume info from RFs
        TVolumeInfo volumeInfo;
        if (iEnv->FsSession().Volume(volumeInfo, iSampleEntryArray->At(i).iDriveNumber) == KErrNone)
            {
            driveSample.iFree = volumeInfo.iFree;
            driveSample.iSize = volumeInfo.iSize;
            }
        else
            {
            driveSample.iFree = 0;
            driveSample.iSize = 0;
            }    

        driveSample.iTimeFromStart = currentTime.MicroSecondsFrom(iStartTime);
    
        iSampleEntryArray->At(i).iSampleDataArray->InsertL(0, driveSample); 
        }
    
    
    // compress sample data arrays to save memory
    TInt curLength(iSampleEntryArray->At(0).iSampleDataArray->Count());
    
    TInt maxSamples = iSettings.iMaxSamples >= KMinimumSamplesLength ? iSettings.iMaxSamples : KMinimumSamplesLength;
    
    if (curLength > maxSamples && curLength % 5 == 0)
        {
        for (TInt i=0; i<iSampleEntryArray->Count(); i++)
            {
            iSampleEntryArray->At(i).iSampleDataArray->ResizeL(maxSamples); // looses old samples
            iSampleEntryArray->At(i).iSampleDataArray->Compress();
            }         
        }
    }

// --------------------------------------------------------------------------------------------
    
void CPerfMonModel::AppendLatestSamplesToLogsL()
    {
    if (iSettings.iLoggingEnabled && SampleEntryArray())
        {
        // loop all sources
        for (TInt i=0; i<SampleEntryArray()->Count(); i++)
            {
            // check if this setting has been enabled and it has some data
            if (iSettings.iLoggingSources.iSrcEnabled[i] && SampleEntryArray()->At(i).iSampleDataArray->Count() > 0)
                {
                // get current sample
                TSampleData& currentSample = SampleEntryArray()->At(i).iSampleDataArray->At(0);
                
                TBuf<128> buf;
                buf.Append(_L("PERFMON;"));
                buf.Append(SampleEntryArray()->At(i).iDescription);
                buf.Append(_L(";"));
                buf.AppendNum(currentSample.iTimeFromStart.Int64());
                buf.Append(_L(";"));
                buf.AppendNum(currentSample.iFree);
                buf.Append(_L(";"));
                buf.AppendNum(currentSample.iSize);

                // print to RDebug
                if (iSettings.iLoggingMode == ELoggingModeRDebug || iSettings.iLoggingMode == ELoggingModeRDebugLogFile)
                    {
                    RDebug::Print(buf);
                    }
                
                // print to log file
                if (iSettings.iLoggingMode == ELoggingModeLogFile || iSettings.iLoggingMode == ELoggingModeRDebugLogFile)
                    {
                    buf.Append(_L("\r\n"));
                    
                    TBuf8<128> buf8;
                    buf8.Copy(buf);
                    
                    iLogFile.Write(buf8);
                    }        
                }
            }
        }
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::SetValuesContainer(CPerfMonValuesContainer* aContainer)
    {
    iValuesContainer = aContainer;
    iDrawState = EDrawStateValues;
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::SetGraphsContainer(CPerfMonGraphsContainer* aContainer)
    {
    iGraphsContainer = aContainer;
    iDrawState = EDrawStateGraphs;
    }
    
// --------------------------------------------------------------------------------------------

void CPerfMonModel::SendDrawEventToContainersL()
    {
    if (iDrawState == EDrawStateValues && iValuesContainer)
        iValuesContainer->DrawUpdate();
    else if (iDrawState == EDrawStateGraphs && iGraphsContainer)
        iGraphsContainer->DrawUpdate();
           
    if (iDataPopupContainer)
        iDataPopupContainer->DrawUpdate();
    }
            
// --------------------------------------------------------------------------------------------

void CPerfMonModel::LoadSettingsL()
    {
    // set defaults
    iSettings.iHeartBeat = 600;
    iSettings.iMaxSamples = 64;
    iSettings.iPriority = EThreadPriorityTypeNormal;
    iSettings.iCPUMode = ECPUModeCPUTime;
    iSettings.iKeepBacklightOn = ETrue;

    iSettings.iDataPopupVisibility = EDataPopupVisbilityAlwaysOn;
    iSettings.iDataPopupLocation = EDataPopupLocationTopRight;
    iSettings.iDataPopupSources.SetDefaults1();

    iSettings.iGraphsVerticalBarPeriod = 5;
    iSettings.iGraphsSources.SetDefaults2();

    iSettings.iLoggingMode = ELoggingModeRDebug;
    iSettings.iLoggingFilePath.Copy(KDefaultLogFilePath);
    iSettings.iLoggingSources.SetDefaults2();
    
    iSettings.iLoggingEnabled = EFalse;


    // make sure that the private path of this app in c-drive exists
    iEnv->FsSession().CreatePrivatePath( KSettingsDrive ); // c:\\private\\20011385\\
    
    // handle settings always in the private directory 
    if (iEnv->FsSession().SetSessionToPrivate( KSettingsDrive ) == KErrNone)
        {
        // open or create a dictionary file store
        CDictionaryFileStore* settingsStore = CDictionaryFileStore::OpenLC(iEnv->FsSession(), KSettingsFileName, KUidPerfMon);

        LoadDFSValueL(settingsStore, KPMSettingHeartBeat,                   iSettings.iHeartBeat);
        LoadDFSValueL(settingsStore, KPMSettingMaxSamples,                  iSettings.iMaxSamples);
        LoadDFSValueL(settingsStore, KPMSettingPriority,                    iSettings.iPriority);
        LoadDFSValueL(settingsStore, KPMSettingCPUMode,                     iSettings.iCPUMode);
        LoadDFSValueL(settingsStore, KPMSettingKeepBackLightOn,             iSettings.iKeepBacklightOn);

        LoadDFSValueL(settingsStore, KPMSettingDataPopupVisbility,          iSettings.iDataPopupVisibility);
        LoadDFSValueL(settingsStore, KPMSettingDataPopupLocation,           iSettings.iDataPopupLocation);
        LoadDFSValueL(settingsStore, KPMSettingDataPopupSources,            iSettings.iDataPopupSources);

        LoadDFSValueL(settingsStore, KPMSettingGraphsVerticalBarPeriod,     iSettings.iGraphsVerticalBarPeriod);
        LoadDFSValueL(settingsStore, KPMSettingGraphsSources,               iSettings.iGraphsSources);

        LoadDFSValueL(settingsStore, KPMSettingLoggingMode,                 iSettings.iLoggingMode);
        LoadDFSValueL(settingsStore, KPMSettingLoggingFilePath,             iSettings.iLoggingFilePath);
        LoadDFSValueL(settingsStore, KPMSettingLoggingSources,              iSettings.iLoggingSources);

        CleanupStack::PopAndDestroy(); // settingsStore         
        }
    }

// --------------------------------------------------------------------------------------------

void CPerfMonModel::SaveSettingsL()
    {
    // handle settings always in c:\\private\\20011385\\
    if (iEnv->FsSession().SetSessionToPrivate( KSettingsDrive ) == KErrNone)
        {
        // delete existing store to make sure that it is clean and not eg corrupted
        if (BaflUtils::FileExists(iEnv->FsSession(), KSettingsFileName))
            {
            iEnv->FsSession().Delete(KSettingsFileName);
            }
        
        // create a dictionary file store
        CDictionaryFileStore* settingsStore = CDictionaryFileStore::OpenLC(iEnv->FsSession(), KSettingsFileName, KUidPerfMon);

        SaveDFSValueL(settingsStore, KPMSettingHeartBeat,                   iSettings.iHeartBeat);
        SaveDFSValueL(settingsStore, KPMSettingMaxSamples,                  iSettings.iMaxSamples);
        SaveDFSValueL(settingsStore, KPMSettingPriority,                    iSettings.iPriority);
        SaveDFSValueL(settingsStore, KPMSettingCPUMode,                     iSettings.iCPUMode);
        SaveDFSValueL(settingsStore, KPMSettingKeepBackLightOn,             iSettings.iKeepBacklightOn);

        SaveDFSValueL(settingsStore, KPMSettingDataPopupVisbility,          iSettings.iDataPopupVisibility);
        SaveDFSValueL(settingsStore, KPMSettingDataPopupLocation,           iSettings.iDataPopupLocation);
        SaveDFSValueL(settingsStore, KPMSettingDataPopupSources,            iSettings.iDataPopupSources);

        SaveDFSValueL(settingsStore, KPMSettingGraphsVerticalBarPeriod,     iSettings.iGraphsVerticalBarPeriod);
        SaveDFSValueL(settingsStore, KPMSettingGraphsSources,               iSettings.iGraphsSources);

        SaveDFSValueL(settingsStore, KPMSettingLoggingMode,                 iSettings.iLoggingMode);
        SaveDFSValueL(settingsStore, KPMSettingLoggingFilePath,             iSettings.iLoggingFilePath);
        SaveDFSValueL(settingsStore, KPMSettingLoggingSources,              iSettings.iLoggingSources);
       
        settingsStore->CommitL();
        CleanupStack::PopAndDestroy(); // settingsStore             
        }
    }
    	
// --------------------------------------------------------------------------------------------

TInt CPerfMonModel::LaunchSettingsDialogL()
    {
    // launch the settings dialog
    TPerfMonSettings newSettings = iSettings;
    
    CPerfMonSettingsViewDlg* dlg = CPerfMonSettingsViewDlg::NewL(newSettings);
    TInt returnValue = dlg->ExecuteLD(R_PERFMON_SETTINGS_DIALOG);
    
    // always save settings since the settings dialog does not provide a possibility to cancel
    iSettings = newSettings;
    SaveSettingsL();
    HandleSettingsChangeL();

    // make sure that the title of the application is correct
    CEikStatusPane* sp = iEnv->AppUiFactory()->StatusPane();
    CAknTitlePane* tp = static_cast<CAknTitlePane*>( sp->ControlL( TUid::Uid( EEikStatusPaneUidTitle ) ) );
    tp->SetTextL(KAppName);
    
    return returnValue;
    }
	
// ---------------------------------------------------------------------------

void CPerfMonModel::LoadDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, TInt& aValue)
    {
    if (aDicFS->IsPresentL(aUid))
        {
        RDictionaryReadStream in;
        in.OpenLC(*aDicFS, aUid);
        aValue = in.ReadInt16L();
        CleanupStack::PopAndDestroy(); // in        
        }
    }

// ---------------------------------------------------------------------------

void CPerfMonModel::LoadDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, TDes& aValue)
    {
    if (aDicFS->IsPresentL(aUid))
        {
        RDictionaryReadStream in;
        in.OpenLC(*aDicFS, aUid);
        TInt bufLength = in.ReadInt16L();   // get length of descriptor
        in.ReadL(aValue, bufLength);        // get the descriptor itself
        CleanupStack::PopAndDestroy(); // in
        }
    }

// ---------------------------------------------------------------------------

void CPerfMonModel::LoadDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, TPerfMonSources& aValue)
    {
    if (aDicFS->IsPresentL(aUid))
        {
        RDictionaryReadStream in;
        in.OpenLC(*aDicFS, aUid);
        TInt bufLength = in.ReadInt16L();   // get length of the array
        
        if (bufLength < 0 || bufLength > ESourcesLength)     // check for validaty
            User::Leave(KErrNotSupported);
        
        for (TInt i=0; i<bufLength; i++)    // get all items
            aValue.iSrcEnabled[i] = in.ReadInt16L();
        
        CleanupStack::PopAndDestroy(); // in
        }
    }
    
// ---------------------------------------------------------------------------

void CPerfMonModel::SaveDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, const TInt& aValue)
    {
    RDictionaryWriteStream out;
    out.AssignLC(*aDicFS, aUid);
    out.WriteInt16L(aValue);
    out.CommitL(); 	
    CleanupStack::PopAndDestroy(); // out
    }

// ---------------------------------------------------------------------------

void CPerfMonModel::SaveDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, const TDes& aValue)
    {
    RDictionaryWriteStream out;
    out.AssignLC(*aDicFS, aUid);
    out.WriteInt16L(aValue.Length());       // write length of the descriptor
    out.WriteL(aValue, aValue.Length());    // write the descriptor itself
    out.CommitL(); 	
    CleanupStack::PopAndDestroy(); // out
    }

// ---------------------------------------------------------------------------

void CPerfMonModel::SaveDFSValueL(CDictionaryFileStore* aDicFS, const TUid& aUid, const TPerfMonSources& aValue)
    {
    RDictionaryWriteStream out;
    out.AssignLC(*aDicFS, aUid);
    
    out.WriteInt16L(ESourcesLength);        // write length of the array
    
    for (TInt i=0; i<ESourcesLength; i++)   // write all items
        out.WriteInt16L(aValue.iSrcEnabled[i]);
    
    out.CommitL(); 	
    CleanupStack::PopAndDestroy(); // out
    }
    
// ---------------------------------------------------------------------------
    
// End of File