// Copyright (c) 1996-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of the License "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:
// e32test\pccd\t_atadr3.cpp
// Test the Compact Flash card (ATA) media driver
//
//
#include <e32test.h>
#include <e32svr.h>
#include <e32hal.h>
#include "u32std.h"
#include "../misc/prbs.h"
//#define __USE_MUTEX__
//#define __DISABLE_KILLER__
#define SYSTEM ETrue
const TInt KErrVerify=-100;
const TInt KSectorSize=512;
const TInt KSectorShift=9;
const TInt KVerifyBlockSize=8; // in sectors
LOCAL_D TBusLocalDrive WriterDrive;
LOCAL_D RTest test(_L("T_ATADR3"));
LOCAL_D TInt DriveNumber;
LOCAL_D TInt DriveSizeInSectors;
LOCAL_D RThread TheWriterThread;
LOCAL_D RThread TheKillerThread;
LOCAL_D RSemaphore Sem;
LOCAL_D TInt CurrentSector=0;
LOCAL_D TInt MediaChanges=0;
LOCAL_D TInt PowerDowns=0;
LOCAL_D TInt Kills=0;
LOCAL_D TInt SectorsWritten=0;
LOCAL_D TInt Aborts=0;
LOCAL_D TUint WritePattern=0;
#ifdef __USE_MUTEX__
LOCAL_D RMutex Mutex;
#define WAIT Mutex.Wait()
#define SIGNAL Mutex.Signal()
#else
#define WAIT
#define SIGNAL
#endif
inline TUint RoundDownToSector(TUint aPos)
{ return aPos&~0x1ff; }
inline TUint RoundUpToSector(TUint aPos)
{ return (aPos+0x1ff)&~0x1ff; }
LOCAL_C TInt WriteSectors(TBusLocalDrive& aDrive, TInt aSector, TInt aCount, TUint8* aBuf)
{
WAIT;
TInt r=KErrNotReady;
TInt pos=aSector<<KSectorShift;
TPtrC8 p(aBuf,aCount*KSectorSize);
while (r==KErrNotReady || (r==KErrAbort && (++Aborts,1)))
r=aDrive.Write(pos,p);
SIGNAL;
return r;
}
LOCAL_C TInt ReadSectors(TBusLocalDrive& aDrive, TInt aSector, TInt aCount, TUint8* aBuf)
{
WAIT;
TInt r=KErrNotReady;
TInt pos=aSector<<KSectorShift;
TInt len=aCount*KSectorSize;
TPtr8 p(aBuf,0,len);
while (r==KErrNotReady || r==KErrAbort)
r=aDrive.Read(pos,len,p);
if (r==KErrNone && p.Length()!=len)
r=KErrUnderflow;
SIGNAL;
return r;
}
LOCAL_C void GenerateTestPattern(TInt aSector, TUint aState, TUint8* aBuf)
{
TUint seed[2];
seed[1]=0;
seed[0]=TUint(aSector)^(aState<<16);
*aBuf++=TUint8(aState&0xff);
*aBuf++=TUint8((aState>>8)&0xff);
TInt i;
for (i=0; i<KSectorSize-2; i++)
*aBuf++=TUint8(Random(seed));
}
LOCAL_C void Write(TBusLocalDrive& aDrive, TInt aSector, TInt aCount, TUint8* aBuf)
{
TInt n;
for (n=0; n<aCount; n++)
GenerateTestPattern(aSector+n,WritePattern,aBuf+n*KSectorSize);
TInt r=WriteSectors(aDrive,aSector,aCount,aBuf);
if (r!=KErrNone)
User::Panic(_L("WRITE"),r);
}
LOCAL_C void Write(TBusLocalDrive& aDrive, TInt aSector, TInt aCount)
{
const TInt KMaxLen = KSectorSize * 8;
TInt len=aCount*KSectorSize;
test (len <= KMaxLen);
TUint8 buf[KMaxLen];
Write(aDrive,aSector,aCount,buf);
}
LOCAL_C TInt Verify(TInt aSector, TInt aCount, TUint8* aBuf)
{
TUint32 buf[KSectorSize/4];
TUint8* pB=(TUint8*)buf;
while(aCount--)
{
TUint state=aBuf[0]|(aBuf[1]<<8);
GenerateTestPattern(aSector,state,pB);
if (Mem::Compare(aBuf,KSectorSize,pB,KSectorSize)!=0)
return KErrVerify;
++aSector;
aBuf+=KSectorSize;
}
return KErrNone;
}
LOCAL_C TInt Verify(TBusLocalDrive& aDrive, TInt aSector, TInt aCount)
{
const TInt KMaxLen = KSectorSize * 8;
TInt len=aCount*KSectorSize;
test (len <= KMaxLen);
TUint8 buf[KMaxLen];
TInt r=ReadSectors(aDrive,aSector,aCount,buf);
if (r!=KErrNone)
return r;
return Verify(aSector,aCount,buf);
}
LOCAL_C TInt WriterThread(TAny*)
{
/*
* SetSystem() API was removed by __SECURE_API__
* "Systemize" will be implemented later calling a LDD which will set thread's "system" flag
RThread().SetSystem(SYSTEM);
*/
TUint seed[2];
seed[0]=User::NTickCount();
seed[1]=0;
TUint32 buf[8*KSectorSize/4];
TUint8* pB=(TUint8*)buf;
TBool medChg=EFalse;
WriterDrive.Close(); // close handle from previous incarnation of this thread
TInt r=WriterDrive.Connect(DriveNumber,medChg);
if (r!=KErrNone)
User::Panic(_L("WRITER-CONNECT"),r);
FOREVER
{
TInt remain=DriveSizeInSectors-CurrentSector;
TInt n=Random(seed)&15;
if (n>8 || n==0)
n=1;
if (n>remain)
n=remain;
if (n==1)
{
Write(WriterDrive,CurrentSector,1,pB);
++WritePattern;
Write(WriterDrive,CurrentSector,1,pB+KSectorSize);
SectorsWritten+=2;
}
else
{
Write(WriterDrive,CurrentSector,n,pB);
SectorsWritten+=n;
}
CurrentSector+=n;
if (CurrentSector==DriveSizeInSectors)
{
CurrentSector=0;
++WritePattern;
}
}
}
LOCAL_C TInt KillerThread(TAny*)
{
/*
* SetSystem() API was removed by __SECURE_API__
* "Systemize" will be implemented later calling a LDD which will set thread's "system" flag
RThread().SetSystem(SYSTEM);
*/
TUint seed[2];
seed[0]=0xadf85458;
seed[1]=0;
TBusLocalDrive drive;
TBool medChg=EFalse;
TInt r=drive.Connect(DriveNumber,medChg);
if (r!=KErrNone)
User::Panic(_L("KILLER-CONNECT"),r);
RTimer timer;
r=timer.CreateLocal();
if (r!=KErrNone)
User::Panic(_L("KILLER-TIMER"),r);
TInt action=0;
FOREVER
{
TUint x=Random(seed);
TUint ms=1000+(x&4095);
User::AfterHighRes(ms*1000);
switch (action)
{
case 0:
#ifndef __DISABLE_KILLER__
drive.ForceMediaChange();
#endif
++MediaChanges;
break;
case 1:
{
#ifndef __DISABLE_KILLER__
TTime now;
now.HomeTime();
now+=TTimeIntervalSeconds(2);
TRequestStatus s;
timer.At(s,now);
UserHal::SwitchOff();
User::WaitForRequest(s);
++PowerDowns;
#endif
break;
}
case 2:
#ifndef __DISABLE_KILLER__
TheWriterThread.Kill(0);
#endif
++Kills;
#ifndef __DISABLE_KILLER__
++WritePattern;
Sem.Wait();
TheWriterThread.SetPriority(EPriorityNormal);
#endif
break;
case 3:
#ifndef __DISABLE_KILLER__
drive.ForceMediaChange();
#endif
++MediaChanges;
#ifndef __DISABLE_KILLER__
x=Random(seed);
ms=50+(x&511);
User::AfterHighRes(ms*1000);
TheWriterThread.Kill(0);
#endif
++Kills;
#ifndef __DISABLE_KILLER__
++WritePattern;
Sem.Wait();
TheWriterThread.SetPriority(EPriorityNormal);
#endif
break;
case 4:
break;
}
if (++action==5)
action=0;
#ifndef __DISABLE_KILLER__
TInt curr=CurrentSector;
TInt remain=DriveSizeInSectors-curr;
TInt n=(remain<8)?remain:8;
r=Verify(drive,curr,n);
if (r!=KErrNone)
User::Panic(_L("VERIFY"),r);
#endif
}
}
LOCAL_C TInt CreateKillerThread()
{
TInt r=TheKillerThread.Create(_L("Killer"),KillerThread,0x2000,NULL,NULL);
if (r!=KErrNone)
return r;
TheKillerThread.SetPriority(EPriorityMore);
TheKillerThread.Resume();
return KErrNone;
}
LOCAL_C TInt CreateWriterThread()
{
FOREVER
{
TInt r=TheWriterThread.Create(_L("Writer"),WriterThread,0x2000,NULL,NULL);
if (r==KErrNone)
break;
if (r!=KErrAlreadyExists)
return r;
test.Printf(_L("Writer thread still exists\n"));
User::After(200000);
}
TheWriterThread.SetPriority(EPriorityLess);
TheWriterThread.Resume();
return KErrNone;
}
GLDEF_C TInt E32Main()
{
/*
* SetSystem() API was removed by __SECURE_API__
* "Systemize" will be implemented later calling a LDD which will set thread's "system" flag
RThread().SetSystem(SYSTEM);
*/
WriterDrive.SetHandle(0);
test.Title();
TInt drv=-1;
while (drv<0 || drv>=KMaxLocalDrives)
{
test.Printf(_L("\nSelect drive C-K: "));
TChar c=(TUint)test.Getch();
c.UpperCase();
if (c.IsAlpha())
drv=TUint(c)-'C';
else
drv=-1;
}
TBuf<1> b;
b.SetLength(1);
b[0]=(TText)(drv+'C');
test.Printf(_L("%S\n"),&b);
TBuf<80> buf=_L("Connect to drive ");
buf+=b;
test.Start(buf);
TBusLocalDrive drive;
TBool medChg=EFalse;
TInt r=drive.Connect(drv,medChg);
test(r==KErrNone);
DriveNumber=drv;
test.Next(_L("Get capabilities"));
TLocalDriveCapsV2 driveCaps;
TPckg<TLocalDriveCapsV2> capsPckg(driveCaps);
r=drive.Caps(capsPckg);
test(r==KErrNone);
TUint driveSize=I64LOW(driveCaps.iSize);
DriveSizeInSectors=(driveSize&~0xfff)>>KSectorShift; // round down to multiple of 8 sectors
test.Printf(_L("Drive size = %08x (%dK)\n"),driveSize,driveSize>>10);
test.Printf(_L("Media type = %d\n"),driveCaps.iType);
test.Printf(_L("Connection Bus = %d\n"),driveCaps.iConnectionBusType);
test.Printf(_L("Drive attributes = %08x\n"),driveCaps.iDriveAtt);
test.Printf(_L("Media attributes = %08x\n"),driveCaps.iMediaAtt);
test.Printf(_L("Base address = %08x\n"),driveCaps.iBaseAddress);
test.Printf(_L("File system ID = %08x\n"),driveCaps.iFileSystemId);
test.Printf(_L("Hidden sectors = %08x\n"),driveCaps.iHiddenSectors);
test.Printf(_L("Press any key...\n"));
test.Getch();
#ifdef __USE_MUTEX__
test.Next(_L("Create mutex"));
r=Mutex.CreateLocal();
test(r==KErrNone);
#endif
test.Next(_L("Initialise drive"));
TInt sector;
for (sector=0; sector<DriveSizeInSectors; sector+=8)
{
Write(drive,sector,8);
if ((sector&127)==0)
test.Printf(_L("."));
}
test.Printf(_L("\n"));
test.Next(_L("Verify drive"));
for (sector=0; sector<DriveSizeInSectors; sector+=8)
{
test(Verify(drive,sector,8)==KErrNone);
if ((sector&127)==0)
test.Printf(_L("."));
}
test.Printf(_L("\n\nPress ENTER to continue..."));
TKeyCode k=EKeyNull;
while (k!=EKeyEnter)
k=test.Getch();
test.Printf(_L("\n"));
test.Next(_L("Create semaphore"));
r=Sem.CreateLocal(0);
test(r==KErrNone);
test.Next(_L("Create writer thread"));
r=CreateWriterThread();
test(r==KErrNone);
TheWriterThread.SetPriority(EPriorityNormal);
test.Next(_L("Create killer thread"));
r=CreateKillerThread();
test(r==KErrNone);
TBool exit=EFalse;
sector=0;
TInt verifies=0;
TInt fails=0;
while (!exit)
{
r=Verify(drive,sector,KVerifyBlockSize);
if (r!=KErrNone)
{
++fails;
test.Printf(_L("Sector %d Fail %d\n"),sector,r);
}
else
++verifies;
sector+=KVerifyBlockSize;
if (sector==DriveSizeInSectors)
{
sector=0;
test.Printf(_L("W %d VER %d FAIL %d MC %d PD %d K %d A %d\n"),SectorsWritten,verifies,fails,MediaChanges,PowerDowns,Kills,Aborts);
}
if ((sector&63)==0)
{
if (TheKillerThread.ExitType()!=EExitPending)
{
const TDesC& cat=TheKillerThread.ExitCategory();
test.Printf(_L("KillerThread exited %d,%d,%S\n"),TheKillerThread.ExitType(),
TheKillerThread.ExitReason(),&cat);
break;
}
TExitType xt=TheWriterThread.ExitType();
if (xt==EExitPanic)
{
const TDesC& cat=TheWriterThread.ExitCategory();
test.Printf(_L("WriterThread Panic %S %d\n"),&cat,TheWriterThread.ExitReason());
break;
}
if (xt!=EExitPending)
{
// restart writer thread
TheWriterThread.Close();
r=CreateWriterThread();
if (r!=KErrNone)
{
test.Printf(_L("Restart writer thread failed %d\n"),r);
break;
}
Sem.Signal();
}
}
}
buf=_L("Disconnect from drive ");
buf+=b;
test.Next(buf);
drive.Disconnect();
test.End();
return 0;
}