// 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_idrv.cpp
// Overview:
// Tests for the internal RAM drive
// API Information:
// TBusLocalDrive
// Details:
// - Load a Physical Device Driver for the RAM Media Driver.
// - Find the internal drive: type == EMediaRam
// - Display and adjust various drive capabilities, verify results
// are as expected.
// - Read and write the drive using various drive sizes, verify results
// are as expected.
// - Format the drive, verify results.
// - Set original size and reformat.
// Platforms/Drives/Compatibility:
// All.
// Assumptions/Requirement/Pre-requisites:
// Failures and causes:
// Base Port information:
//
//
#include <e32test.h>
#include <e32svr.h>
#include <e32hal.h>
#include <e32uid.h>
#include "../mmu/mmudetect.h"
#include <f32file.h>
#define PDD_NAME _L("MEDINT")
const TInt KTestDriveLen=0x00040000; //256K
const TInt KSmallDriveInc=0x00000400; //1K
const TInt KBigDriveLen=0x00100000; //1M - WINS
const TInt KTestBufLen=256;
RTest test(_L("T_IDRV"));
void Format(TInt aDrive, RFs& aFs)
//
// Format current drive
//
{
test.Next(_L("Format"));
TBuf<4> driveBuf=_L("?:\\");
driveBuf[0]=(TText)(aDrive+'A');
RFormat format;
TInt count;
TInt r=format.Open(aFs,driveBuf,EHighDensity,count);
test(r==KErrNone);
while(count)
{
TInt r=format.Next(count);
test(r==KErrNone);
}
format.Close();
}
GLDEF_C TInt E32Main()
{
test.Title();
if (!HaveVirtMem())
{
test.Printf(_L("Needs MMU\n"));
return 0;
}
#if defined(__EPOC32__) && defined(__CPU_X86)
test.Printf(_L("Doesn't run on X86\n"));
#else
TBusLocalDrive theInternalDrive;
TInt msgHandle = KLocalMessageHandle;
UserSvr::UnlockRamDrive();
test.Printf(_L("Warning - this will destroy internal drive.\r\n"));
TChar c= 'C';
c.UpperCase();
if (c!='C')
return(0);
test.Start(_L("Check loader running"));
test.Next(_L("Load Internal Ram Media Driver"));
TInt r=User::LoadPhysicalDevice(PDD_NAME);
test(r==KErrNone || r==KErrAlreadyExists);
test.Next(_L("Find internal drive"));
TDriveInfoV1Buf driveInfoBuf;
UserHal::DriveInfo(driveInfoBuf);
TDriveInfoV1& driveInfo = driveInfoBuf();
TInt drive = 0;
for ( ; drive < driveInfo.iTotalSupportedDrives; ++drive)
{
TBool changedFlag;
theInternalDrive.Connect(drive, changedFlag);
TLocalDriveCapsV2 info;
TPckg<TLocalDriveCapsV2> infoPckg(info);
theInternalDrive.Caps(infoPckg);
if (info.iType == EMediaRam)
{
break;
}
theInternalDrive.Disconnect();
}
test(drive < driveInfo.iTotalSupportedDrives);
test.Next(_L("Capabilities"));
TLocalDriveCapsV2 info;
TPckg<TLocalDriveCapsV2> infoPckg(info);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
TUint saveSize=I64LOW(info.iSize);
test(info.iType==EMediaRam);
test(info.iConnectionBusType==EConnectionBusInternal);
test(info.iDriveAtt==(KDriveAttLocal|KDriveAttInternal));
test(info.iMediaAtt==(KMediaAttVariableSize|KMediaAttFormattable));
test(info.iFileSystemId==KDriveFileSysFAT);
test.Printf(_L("Current drive size: %lx\n"),info.iSize);
test.Next(_L("Set size to zero"));
test(theInternalDrive.ReduceSize(0,saveSize)==KErrNone);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
test(info.iSize==0);
test(theInternalDrive.ReduceSize(0,-1)==KErrArgument);
test(theInternalDrive.Enlarge(-1)==KErrArgument);
test.Next(_L("Increase to large size"));
#if defined (__WINS__)
TUint cSize=KBigDriveLen;
#else
TMemoryInfoV1Buf memBuf;
TMemoryInfoV1 &mi=memBuf();
UserHal::MemoryInfo(memBuf);
// TUint cSize=(mi.iTotalRamInBytes-KTestDriveLen); // Leave last 256K - used by Kernel etc.
// TUint cSize=mi.iTotalRamInBytes>>1; // Half ram
// TUint cSize=mi.iTotalRamInBytes>>2; // Quarter ram
TUint cSize=mi.iTotalRamInBytes>>3; // Eighth ram
#endif
test.Printf(_L("(Increasing to %dbytes)\r\n"),cSize);
test(theInternalDrive.Enlarge(cSize)==KErrNone);
// test(theInternalDrive.Enlarge(cSize-saveSize)==KErrNone); // ???
test(theInternalDrive.Caps(infoPckg)==KErrNone);
test(I64LOW(info.iSize)==cSize);
test.Next(_L("Increase by 1K"));
cSize+=KSmallDriveInc;
test(theInternalDrive.Enlarge(KSmallDriveInc)==KErrNone);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
test(I64LOW(info.iSize)==cSize);
test.Next(_L("Reduce to 256K"));
test(theInternalDrive.ReduceSize(0,(cSize-KTestDriveLen))==KErrNone);
cSize=KTestDriveLen;
test(theInternalDrive.Caps(infoPckg)==KErrNone);
test(I64LOW(info.iSize)==(TUint)KTestDriveLen);
test.Next(_L("Write/Read"));
TBuf8<KTestBufLen> wrBuf(KTestBufLen),rdBuf;
TUint i,j,len;
for (i=0 ; i<(TUint)KTestBufLen ; i++)
wrBuf[i]=(TUint8)i;
for (i=0,j=0;i<(TUint)KTestDriveLen;i+=len,j++)
{
len=Min(KTestBufLen,(KTestDriveLen-i));
rdBuf.Fill(0,len);
wrBuf[0]=(TUint8)j;
test(theInternalDrive.Write(i,len,&wrBuf,msgHandle,0)==KErrNone);
test(theInternalDrive.Read(i,len,&rdBuf,msgHandle,0)==KErrNone);
wrBuf.SetLength(len);
test(rdBuf.Compare(wrBuf)==0);
}
test.Next(_L("Reduce size - 256 bytes from start"));
test(theInternalDrive.ReduceSize(0,KTestBufLen)==KErrNone);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
cSize-=KTestBufLen;
test(I64LOW(info.iSize)==(TUint)cSize);
for (i=0,j=1;i<cSize;i+=len,j++)
{
len=Min(KTestBufLen,(cSize-i));
rdBuf.Fill(0,len);
wrBuf[0]=(TUint8)j;
test(theInternalDrive.Read(i,len,&rdBuf,msgHandle,0)==KErrNone);
wrBuf.SetLength(len);
test(rdBuf.Compare(wrBuf)==0);
}
test.Next(_L("Reduce size - (4K+127) bytes from middle"));
TInt reduction=((KTestBufLen<<4)+((KTestBufLen>>1)-1));
test(theInternalDrive.ReduceSize(KTestBufLen,reduction)==KErrNone);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
cSize-=reduction;
test(I64LOW(info.iSize)==(TUint)cSize);
TBuf8<KTestBufLen> odBuf(KTestBufLen); // To verify new pattern
for (i=0 ; i<(TUint)KTestBufLen ; i++)
{
if (i<=(KTestBufLen>>1))
odBuf[i]=(TUint8)(i+((KTestBufLen>>1)-1));
else
odBuf[i]=(TUint8)(i-((KTestBufLen>>1)+1));
}
for (i=0,j=1;i<cSize;i+=len,j++)
{
len=Min(KTestBufLen,(cSize-i));
rdBuf.Fill(0,len);
test(theInternalDrive.Read(i,len,&rdBuf,msgHandle,0)==KErrNone);
if (j==2)
j+=17;
if (j==1)
{
wrBuf[0]=(TUint8)j;
wrBuf.SetLength(len);
test(rdBuf.Compare(wrBuf)==0);
}
else
{
odBuf.SetLength(KTestBufLen);
odBuf[((KTestBufLen>>1)+1)]=(TUint8)j;
odBuf.SetLength(len);
test(rdBuf.Compare(odBuf)==0);
}
}
test.Next(_L("Reduce size - (8K-1) bytes from end"));
reduction=((KTestBufLen<<5)-1);
test(theInternalDrive.ReduceSize((cSize-reduction),reduction)==KErrNone);
test(theInternalDrive.Caps(infoPckg)==KErrNone);
cSize-=reduction;
test(info.iSize==cSize);
for (i=0,j=1;i<cSize;i+=len,j++)
{
len=Min(KTestBufLen,(cSize-i));
rdBuf.Fill(0,len);
test(theInternalDrive.Read(i,len,&rdBuf,msgHandle,0)==KErrNone);
if (j==2)
j+=17;
if (j==1)
{
wrBuf[0]=(TUint8)j;
wrBuf.SetLength(len);
test(rdBuf.Compare(wrBuf)==0);
}
else
{
odBuf.SetLength(KTestBufLen);
odBuf[((KTestBufLen>>1)+1)]=(TUint8)j;
odBuf.SetLength(len);
test(rdBuf.Compare(odBuf)==0);
}
}
test.Next(_L("Format"));
wrBuf.Fill(0,KTestBufLen);
TFormatInfo fi;
TInt ret;
while((ret=theInternalDrive.Format(fi))!=KErrEof)
test(ret==KErrNone);
for (i=0;i<cSize;i+=len)
{
len=Min(KTestBufLen,(cSize-i));
rdBuf.Fill(0xAA,len);
test(theInternalDrive.Read(i,len,&rdBuf,msgHandle,0)==KErrNone);
wrBuf.SetLength(len);
test(rdBuf.Compare(wrBuf)==0);
}
test.Next(_L("Restore original size"));
TInt sizeDif=cSize-saveSize;
if (sizeDif>0)
test(theInternalDrive.ReduceSize(0,sizeDif)==KErrNone);
else
test(theInternalDrive.Enlarge(sizeDif*-1)==KErrNone);
test.Next(_L("Disconnect from internal drive"));
theInternalDrive.Disconnect();
RFs fs;
test(fs.Connect()==KErrNone);
for(drive=25 ; drive>=0; --drive)
{
TDriveInfo info;
if(fs.Drive(info,drive)==KErrNone)
if(info.iType==EMediaRam)
{
TBuf<256> text;
text.Append(_L("Formatting drive "));
text.Append(TText(drive+'A'));
text.Append(_L(": ..."));
test.Next(text);
Format(drive,fs);
break;
}
}
test.End();
#endif // x86
return(0);
}