Convert Kernelhwsrv package from SFL to EPL
kernel\eka\compsupp is subject to the ARM EABI LICENSE
userlibandfileserver\fatfilenameconversionplugins\unicodeTables is subject to the Unicode license
kernel\eka\kernel\zlib is subject to the zlib license
// Copyright (c) 2000-2009 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:
//
#include <e32std.h>
#include <e32std_private.h>
#include <e32svr.h>
#include <e32test.h>
#include "randgen.h"
#include "user_config.h"
RTest test( _L("TF_READ") );
const TInt KTestUserDataSize = 1024;
const TInt KBufferGuardSize = 16384;
const TInt KMaxWriteLength = 512;
const TInt64 KSampleDataRandomSeed = MAKE_TINT64(0x3e000111,0xAFCBDF0F);
const TInt64 KRandomTestSeed = MAKE_TINT64(0x90009901,0xABEF1011);
enum TPanicNo
{
EPanicGetDesOverflow,
EPanicGetDesInitialOverflow,
EPanicCheckOverflow
};
LOCAL_D void Panic( TPanicNo aPanic )
{
_LIT( KPanicCat, "TF_READ" );
User::Panic( KPanicCat, aPanic );
}
class CCheckedBuffer : public CBase
{
public:
CCheckedBuffer( TInt auserDataSize, TInt aGuardSize );
~CCheckedBuffer();
void CreateL();
void InitialiseGuard();
TBool CheckGuard( TInt aUserDataLength ) const;
TBool CheckGuardAtStartOfUserData( TInt aGuardLength ) const;
void GetDes( TPtrC8& aDes ) const;
void GetDes( TPtr8& aDes, TInt aInitialLength, TInt aMaxLength ) const;
private:
CCheckedBuffer();
private:
TPtr8 iUserData; // pointer to user data area
const TInt iUserDataSize;
const TInt iGuardSize;
TUint8* iAllocCell;
};
CCheckedBuffer::CCheckedBuffer( TInt aUserDataSize, TInt aGuardSize )
: iUserData(0,0), iUserDataSize( aUserDataSize ), iGuardSize( aGuardSize )
{
}
CCheckedBuffer::~CCheckedBuffer()
{
delete iAllocCell;
}
void CCheckedBuffer::CreateL()
{
TInt totalCellSizeRequired = iUserDataSize + (2 * iGuardSize);
iAllocCell = (TUint8*)User::AllocL( totalCellSizeRequired );
test.Printf( _L("Allocated heap cell for checked buffer\n") );
iUserData.Set( iAllocCell + iGuardSize, iUserDataSize, iUserDataSize );
}
void CCheckedBuffer::GetDes( TPtrC8& aDes ) const
//
// Create descriptor to the whole user data area in aDes
//
{
aDes.Set( iAllocCell + iGuardSize, iUserDataSize );
}
void CCheckedBuffer::GetDes( TPtr8& aDes, TInt aInitialLength, TInt aMaxLength ) const
//
// Create modifiable descriptor to the user data area in aDes,
// with a maximum length aMaxLength, and initial length aInitialLength
//
{
__ASSERT_ALWAYS( aMaxLength <= iUserDataSize, Panic(EPanicGetDesOverflow) );
__ASSERT_ALWAYS( aInitialLength <= iUserDataSize, Panic(EPanicGetDesInitialOverflow) );
aDes.Set( iAllocCell + iGuardSize, aInitialLength, aMaxLength );
}
void CCheckedBuffer::InitialiseGuard()
//
// Create the guard regions
//
{
TInt totalCellSize = User::AllocLen( iAllocCell );
Mem::Fill( iAllocCell, totalCellSize, 0x5A );
}
TBool CCheckedBuffer::CheckGuard( TInt aUserDataLength ) const
//
// Checks that the guard value is still present before the user data
// area, and after aUserDataLength bytes of user data
//
{
const TUint8* p = iAllocCell;
const TUint8* pUserDataStart = iUserData.Ptr();
for( ; p < pUserDataStart; p++ )
{
if( 0x5a != *p )
{
return EFalse;
}
}
p = pUserDataStart + aUserDataLength;
const TUint8* pEnd = iAllocCell + User::AllocLen( iAllocCell );
for( ; p < pEnd; p++ )
{
if( 0x5a != *p )
{
return EFalse;
}
}
return ETrue;
}
TBool CCheckedBuffer::CheckGuardAtStartOfUserData( TInt aGuardLength ) const
//
// Checks that the first aGuardLength bytes of the user data area
// contain the guard value
//
{
const TUint8* p = iUserData.Ptr();
const TUint8* pEnd = p + aGuardLength;
for( ; p < pEnd; p++ )
{
if( 0x5a != *p )
{
return EFalse;
}
}
return ETrue;
}
class CReadTest : public CBase
{
public:
~CReadTest();
void CreateL();
void DoTest();
private:
static TInt DummyThread( TAny* aParam );
void CreateSampleData();
static TBool CheckZero( const TPtrC8& aDes );
void CreateTestData( TInt aBlockNumber, TBool aEndOfBlock );
TBool CompareAgainstFlash( TInt aFlashOffset, const TPtrC8& aDes, TInt aDescOffset );
void TestSimpleReads();
void TestSimpleThreadReads();
void TestUnalignedReads();
void TestUnalignedThreadReads();
void TestOffsetBufferThreadReads();
void TestOffsetBufferUnalignedThreadReads();
void TestReadsFromAllBlocks();
void TestSimpleScatterReads1();
void TestSimpleScatterReads2();
void TestScatterGather();
void TestReadAcrossBlock();
void PerformCheckedRead( TInt aReadPos, TInt aReadLen );
void PerformCheckedThreadRead( TInt aReadPos, TInt aReadLen, TInt aDescOffset );
private:
TInt iFlashSize;
TInt iBlockSize;
TInt iBlockCount;
TBusLocalDrive iDrive;
TBool iDriveOpened;
TBuf8<512> iReadBuffer;
TRandomGenerator iRandom;
TBuf8<KTestUserDataSize> iSampleData;
CCheckedBuffer* iBuffer;
RThread iDummyThread;
};
CReadTest::~CReadTest()
{
if( iDriveOpened )
{
iDrive.Disconnect();
}
}
void CReadTest::CreateL()
{
//
// Load the device drivers
//
TInt r;
#ifndef SKIP_PDD_LOAD
test.Printf( _L("Loading %S\n"), &KLfsDriverName );
r = User::LoadPhysicalDevice( KLfsDriverName );
test( KErrNone == r || KErrAlreadyExists == r );
#endif
#ifdef UNMOUNT_DRIVE
RFs fs;
test( KErrNone == fs.Connect() );
#if 0 // XXX - API violation on EKA2
test( KErrNone == fs.SetDefaultPath( _L("Z:\\") ) );
#endif
TFullName name;
fs.FileSystemName( name, KLffsLogicalDriveNumber );
if( name.Length() > 0 )
{
test.Printf( _L("Unmounting drive") );
test( KErrNone == fs.DismountFileSystem( _L("Lffs"), KLffsLogicalDriveNumber) );
User::After( 2000000 );
test.Printf( _L("Drive unmounted") );
}
fs.Close();
#endif
//
// Open a TBusLogicalDevice to it
//
test.Printf( _L("Opening media channel\n") );
TBool changedFlag = EFalse;
r = iDrive.Connect( KDriveNumber, changedFlag );
User::LeaveIfError( r );
iDriveOpened = ETrue;
//
// Get size of Flash drive
//
TLocalDriveCapsV2Buf info;
iDrive.Caps(info);
iFlashSize = I64LOW(info().iSize);
iBlockSize = info().iEraseBlockSize;
iBlockCount = iFlashSize / iBlockSize;
test.Printf( _L("Flash size is 0x%x bytes\n"), iFlashSize );
//
// Create a dummy thread that we can use to force
// other-thread write operations
//
#if 0
test( KErrNone == iDummyThread.Create( _L("DUMMY"), DummyThread, 256, KMinHeapSize, KMinHeapSize, NULL ) );
#else
// XXX TONYL
test( KErrNone == iDummyThread.Create( _L("DUMMY"), DummyThread, KDefaultStackSize, KMinHeapSize, KMinHeapSize, NULL ) );
// test.Printf( _L("== do it"));
// TInt pas = iDummyThread.Create( _L("DUMMY"), DummyThread, KDefaultStackSize, KMinHeapSize, KMinHeapSize, NULL );
// test.Printf( _L("CREATE = %d"), pas);
// test (pas == KErrNone);
#endif
#if 1
iDummyThread.Resume();
#endif
//
// Create a checked buffer
//
iBuffer = new(ELeave) CCheckedBuffer( KTestUserDataSize, KBufferGuardSize );
iBuffer->CreateL();
//
// Seed the pseudo-random number generator
//
iRandom.SetSeed( KSampleDataRandomSeed );
test.Printf( _L("CreateL complete\n") );
}
TInt CReadTest::DummyThread( TAny* /* aParam */ )
//
// Thread does nothing at all
//
{
#if 1
test.Printf( _L("== do it"));
#endif
for(;;)
{
User::WaitForAnyRequest(); // just block
}
}
void CReadTest::TestSimpleReads()
//
// Makes reads of 1 byte to 512 bytes into the start of the
// checked buffer and tests that only the expected bytes have changed
// This uses the simple read function from TBusLocalDrive, and
// reads from an aligned Flash address
//
{
test.Next( _L("Testing simple reads\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
test.Printf( _L("Reading %d bytes\n"), readLen );
//
// Prepare the guard data
//
iBuffer->InitialiseGuard();
//
// Set up the descriptor, length=0, maxlen=readLen
//
iBuffer->GetDes( des, 0, readLen );
//
// Now read some data into it
//
test( KErrNone == iDrive.Read( 0, readLen, des ) );
//
// Check what we got
//
test( des.Length() == readLen );
TPtrC8 newDes;
iBuffer->GetDes( newDes );
test( newDes.Ptr() == des.Ptr() );
test( iBuffer->CheckGuard( readLen ) );
test( CompareAgainstFlash( 0, des, 0 ) );
}
}
void CReadTest::TestSimpleThreadReads()
//
// Makes reads of 1 byte to 512 bytes into the start of the
// checked buffer and tests that only the expected bytes have changed
// This uses the more complex read function from TBusLocalDrive, and
// reads from an aligned Flash address
//
{
test.Next( _L("Testing simple reads using other-thread read function\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
test.Printf( _L("Reading %d bytes\n"), readLen );
//
// Prepare the guard data
//
iBuffer->InitialiseGuard();
test.Printf( _L("AA\n"));
//
// Set up the descriptor, length=0, maxlen=readLen
//
iBuffer->GetDes( des, 0, readLen );
test.Printf( _L("BB\n"));
//
// Now read some data into it
//
test( KErrNone == iDrive.Read( 0, readLen, &des, KLocalMessageHandle, 0 ) );
test.Printf( _L("CC\n"));
#if 0
test( KErrNone == iDrive.Read( 0, readLen, &des, iDummyThread.Handle(), 0 ) );
#else
// XXX - this works
test( KErrNone == iDrive.Read( 0, readLen, &des, KLocalMessageHandle, 0 ) );
#endif
//
// Check what we got
//
test.Printf( _L("DD\n"));
test.Printf( _L("DD\n"));
test.Printf( _L("DD\n"));
test.Printf( _L("DD\n"));
test( des.Length() == readLen );
TPtrC8 newDes;
test.Printf( _L("EE\n"));
iBuffer->GetDes( newDes );
test.Printf( _L("FF\n"));
test( newDes.Ptr() == des.Ptr() );
test( iBuffer->CheckGuard( readLen ) );
test.Printf( _L("GG\n"));
test( CompareAgainstFlash( 0, des, 0 ) );
test.Printf( _L("HH\n"));
}
}
void CReadTest::TestUnalignedReads()
//
// Makes reads of 1 byte to 512 bytes into the start of the
// checked buffer and tests that only the expected bytes have changed
// This uses the simple read function from TBusLocalDrive.
// The data is read from an unaligned address (0ffset 1, 2, 3)
//
{
test.Next( _L("Testing unaligned reads\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
//
// Set up the descriptor, length=0, maxlen=readLen
//
iBuffer->GetDes( des, 0, readLen );
//
// Repeat for each offset
//
for( TInt offs = 1; offs < 4; offs++ )
{
test.Printf( _L("Reading %d unaligned bytes from offset %d\n"), readLen, offs );
iBuffer->InitialiseGuard();
test( KErrNone == iDrive.Read( offs, readLen, des ) );
test( des.Length() == readLen );
TPtrC8 newDes;
iBuffer->GetDes( newDes );
test( newDes.Ptr() == des.Ptr() );
test( iBuffer->CheckGuard( readLen ) );
test( CompareAgainstFlash( offs, des, 0 ) );
}
}
}
void CReadTest::TestUnalignedThreadReads()
//
// Makes reads of 1 byte to 512 bytes into the start of the
// checked buffer and tests that only the expected bytes have changed
// This uses the thread read function from TBusLocalDrive.
// The data is read from an unaligned address (0ffset 1, 2, 3)
//
{
test.Next( _L("Testing unaligned other-thread reads\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
//
// Set up the descriptor, length=0, maxlen=readLen
//
iBuffer->GetDes( des, 0, readLen );
//
// Repeat for each offset
//
for( TInt offs = 1; offs < 4; offs++ )
{
test.Printf( _L("Reading %d unaligned bytes from offset %d\n"), readLen, offs );
iBuffer->InitialiseGuard();
#if 0
test( KErrNone == iDrive.Read( offs, readLen, &des, iDummyThread.Handle(), 0 ) );
#else
test( KErrNone == iDrive.Read( offs, readLen, &des, KLocalMessageHandle, 0 ) );
#endif
test( des.Length() == readLen );
TPtrC8 newDes;
iBuffer->GetDes( newDes );
test( newDes.Ptr() == des.Ptr() );
test( iBuffer->CheckGuard( readLen ) );
test( CompareAgainstFlash( offs, des, 0 ) );
}
}
}
void CReadTest::TestOffsetBufferThreadReads()
//
// Makes reads of 1 byte to 512 bytes to an offset position in the
// checked buffer and tests that only the expected bytes have changed
// This uses the more complex read function from TBusLocalDrive, and
// reads from an aligned Flash address
//
{
test.Next( _L("Testing other-thread reads into offset position in descriptor\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
test.Printf( _L("Reading %d bytes\n"), readLen );
//
// Repeat test for offsets 0..64 in buffer
//
for( TInt destOffset = 1; destOffset < 64; destOffset++ )
{
// test.Printf( _L("... dest offset = %d"), destOffset );
//
// Prepare the guard data
//
iBuffer->InitialiseGuard();
//
// Set up the descriptor, length=0, maxlen=readLen+destOffset
//
iBuffer->GetDes( des, 0, readLen + destOffset );
#if 0
test( KErrNone == iDrive.Read( 0, readLen, &des, iDummyThread.Handle(), destOffset ) );
#else
test( KErrNone == iDrive.Read( 0, readLen, &des, KLocalMessageHandle, destOffset ) );
#endif
//
// Check what we got
//
test( des.Length() == readLen + destOffset );
TPtrC8 newDes;
iBuffer->GetDes( newDes );
test( newDes.Ptr() == des.Ptr() );
//
// end of written data is at readLen + destOffset
//
test( iBuffer->CheckGuard( readLen+destOffset ) );
//
// check the section between that start of the user data and
// the offset position still contains guard data
//
test( iBuffer->CheckGuardAtStartOfUserData( destOffset ) );
test( CompareAgainstFlash( 0, des, destOffset ) );
}
}
}
void CReadTest::TestOffsetBufferUnalignedThreadReads()
//
// Makes reads of 1 byte to 512 bytes to an offset position in the
// checked buffer and tests that only the expected bytes have changed
// This uses the more complex read function from TBusLocalDrive, and
// reads from an aligned Flash address
//
{
test.Next( _L("Testing other-thread unaligned reads into offset position in descriptor\n") );
//
// Descriptor to user data area, passed to media driver
//
TPtr8 des(0,0);
for( TInt readLen = 1; readLen <= 500; readLen++ )
{
test.Printf( _L("Reading %d bytes\n"), readLen );
//
// Repeat test for offsets 0..64 in buffer
//
for( TInt destOffset = 1; destOffset < 64; destOffset++ )
{
// test.Printf( _L("... dest offset = %d"), destOffset );
//
// repeat for each source offset
//
for( TInt offs = 1; offs < 4; offs++ )
{
//
// Prepare the guard data
//
iBuffer->InitialiseGuard();
//
// Set up the descriptor, length=0, maxlen=readLen+destOffset
//
iBuffer->GetDes( des, 0, readLen + destOffset );
#if 0
test( KErrNone == iDrive.Read( offs, readLen, &des, iDummyThread.Handle(), destOffset ) );
#else
test( KErrNone == iDrive.Read( offs, readLen, &des, KLocalMessageHandle, destOffset ) );
#endif
//
// Check what we got
//
test( des.Length() == readLen + destOffset );
TPtrC8 newDes;
iBuffer->GetDes( newDes );
test( newDes.Ptr() == des.Ptr() );
//
// end of written data is at readLen + destOffset
//
test( iBuffer->CheckGuard( readLen+destOffset ) );
//
// check the section between that start of the user data and
// the offset position still contains guard data
//
test( iBuffer->CheckGuardAtStartOfUserData( destOffset ) );
test( CompareAgainstFlash( offs, des, destOffset ) );
} // end for
}
}
}
void CReadTest::PerformCheckedRead( TInt aReadPos, TInt aReadLen )
{
TPtr8 des(0,0);
iBuffer->InitialiseGuard();
iBuffer->GetDes( des, 0, aReadLen );
test.Printf( _L("Reading %d byte(s) from offset 0x%x\n"), aReadLen, aReadPos );
test( KErrNone == iDrive.Read( aReadPos, aReadLen, des ) );
test( des.Length() == aReadLen );
test( iBuffer->CheckGuard( aReadLen ) );
test( CompareAgainstFlash( aReadPos, des, 0 ) );
}
void CReadTest::PerformCheckedThreadRead( TInt aReadPos, TInt aReadLen, TInt aDescOffset )
{
TPtr8 des(0,0);
iBuffer->InitialiseGuard();
iBuffer->GetDes( des, 0, aReadLen + aDescOffset );
test.Printf( _L("Reading %d byte(s) from offset 0x%x to thread descriptor offset %d\n"), aReadLen, aReadPos, aDescOffset );
#if 0
test( KErrNone == iDrive.Read( aReadPos, aReadLen, &des, iDummyThread.Handle(), aDescOffset ) );
#else
test( KErrNone == iDrive.Read( aReadPos, aReadLen, &des, KLocalMessageHandle, aDescOffset ) );
#endif
// test.Printf( _L("Check descriptor length") );
test( des.Length() == aReadLen + aDescOffset );
// test.Printf( _L("Check guard") );
test( iBuffer->CheckGuard( aReadLen + aDescOffset ) );
// test.Printf( _L("Check guard at start of descriptor") );
test( iBuffer->CheckGuardAtStartOfUserData( aDescOffset ) );
test( CompareAgainstFlash( aReadPos, des, aDescOffset ) );
}
void CReadTest::TestReadsFromAllBlocks()
//
// Does some spot-test reads from all blocks to make sure
// that reading across the whole Flash works
//
{
test.Next( _L("Testing reads from all blocks\n") );
for( TInt block = 0; block < iBlockCount; block++ )
{
test.Printf( _L("Reading from block %d"), block );
TInt readBase = (block * iBlockSize);
PerformCheckedRead( readBase, 1 );
PerformCheckedRead( readBase, 24 );
PerformCheckedRead( readBase, 99 );
PerformCheckedRead( readBase, 511 );
PerformCheckedRead( readBase+1, 1 );
PerformCheckedRead( readBase+1, 24 );
PerformCheckedRead( readBase+1, 99 );
PerformCheckedRead( readBase+1, 511 );
PerformCheckedRead( readBase+3, 1 );
PerformCheckedRead( readBase+3, 24 );
PerformCheckedRead( readBase+3, 99 );
PerformCheckedRead( readBase+3, 511 );
PerformCheckedThreadRead( readBase, 1, 0 );
PerformCheckedThreadRead( readBase, 24, 0 );
PerformCheckedThreadRead( readBase, 99, 2 );
PerformCheckedThreadRead( readBase, 511, 0 );
PerformCheckedThreadRead( readBase+1, 1, 11 );
PerformCheckedThreadRead( readBase+1, 24, 4 );
PerformCheckedThreadRead( readBase+1, 99, 24 );
PerformCheckedThreadRead( readBase+1, 511, 0 );
PerformCheckedThreadRead( readBase+3, 1, 32 );
PerformCheckedThreadRead( readBase+3, 24, 333 );
PerformCheckedThreadRead( readBase+3, 99, 0 );
PerformCheckedThreadRead( readBase+3, 511, 1 );
}
}
void CReadTest::TestSimpleScatterReads1()
//
// Does some simple reads of varying length from the
// blocks in pseudo-random order.
//
{
test.Next( _L("Testing simple scatter reads\n") );
TRandomGenerator random;
random.SetSeed( KRandomTestSeed );
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
TInt block = random.Next() % iBlockCount;
test.Printf( _L("Reading block %d"), block );
TInt readBase = (block * iBlockSize);
PerformCheckedRead( readBase, readLen );
}
}
void CReadTest::TestSimpleScatterReads2()
//
// Does some simple reads of varying length from the
// blocks in pseudo-random order.
//
// This is similar to TestSimpleScatterReads1 except that
// as the length reduces the read position is moved along
// and the test uses the thread-read variant
//
{
test.Next( _L("Testing simple scatter reads\n") );
TRandomGenerator random;
random.SetSeed( KRandomTestSeed );
for( TInt readLen = 1; readLen <= 512; readLen++ )
{
TInt block = random.Next() % iBlockCount;
test.Printf( _L("Reading block %d"), block );
TInt readBase = (block * iBlockSize) + (512 - readLen);
PerformCheckedRead( readBase, readLen );
}
}
void CReadTest::TestScatterGather()
//
// This reads bytes from all over the Flash and concatenates
// them into a single descriptor. This isn't representative of
// anything a real filesystem would do (at present!) but
// is an interesting test of the media driver
//
{
test.Next( _L("Testing scatter-gather reads\n") );
TRandomGenerator random;
random.SetSeed( KRandomTestSeed );
const TInt KMaxReads = 500;
struct SReadInfo
{
TInt iOffset;
TInt iLength;
};
SReadInfo* readInfoArray = new SReadInfo[KMaxReads];
test( NULL != readInfoArray );
TPtr8 des(0,0);
iBuffer->InitialiseGuard();
iBuffer->GetDes( des, 0, KTestUserDataSize );
TInt descOffset = 0;
TInt readCount;
for( readCount = 0; readCount < KMaxReads; readCount++ )
{
//
// Create random read position and length
//
TInt block = random.Next() % iBlockCount;
TInt blockOffset = random.Next() % 1000;
if( blockOffset > 500 )
{
blockOffset = iBlockSize - 1 - blockOffset;
}
TInt readOffset = (block * iBlockSize) + blockOffset;
TInt readLength = (random.Next() % 8) + 1;
if( des.Length() + readLength > des.MaxLength() )
{
break; // finished
}
//
// Save the position & length
//
readInfoArray[readCount].iOffset = readOffset;
readInfoArray[readCount].iLength = readLength;
//
// do the read
//
_LIT( KScatterReadMsg, "Reading Flash @%x %d bytes to desc offset %d" );
test.Printf( KScatterReadMsg, readOffset, readLength, descOffset );
#if 0
test( KErrNone == iDrive.Read( readOffset, readLength, &des, iDummyThread.Handle(), descOffset ) );
#else
test( KErrNone == iDrive.Read( readOffset, readLength, &des, KLocalMessageHandle, descOffset ) );
#endif
test( des.Length() == descOffset + readLength );
descOffset += readLength;
}
//
// Now check all the data against the Flash contents
//
descOffset = 0;
for( TInt i = 0; i < readCount; i++ )
{
TInt readOffset = readInfoArray[i].iOffset ;
TInt readLength = readInfoArray[i].iLength;
TPtrC8 ptr( des.Ptr() + descOffset, readLength );
test( CompareAgainstFlash( readOffset, ptr, 0 ) );
descOffset += readLength;
}
delete[] readInfoArray;
}
void CReadTest::TestReadAcrossBlock()
//
// Test reads that cross a block boundary
//
{
test.Next( _L("Testing reads across block boundary\n") );
for( TInt block = 1; block < iBlockCount - 1; block++ )
{
for( TInt readLen = 2; readLen <= 1024; readLen++ )
{
TInt blockBase = (block * iBlockSize);
TInt readOffs = blockBase + (iBlockSize - (readLen/2));
PerformCheckedRead( readOffs, readLen );
}
}
}
void CReadTest::CreateSampleData()
//
// Fills iSampleData with pseudo-random test data
//
{
TUint32* p = (TUint32*)iSampleData.Ptr();
for( TInt j = 0; j < KTestUserDataSize/4; j++ )
{
*p++ = iRandom.Next();
}
iSampleData.SetLength( KTestUserDataSize );
}
TBool CReadTest::CheckZero( const TPtrC8& aDes )
//
// Checks that all bytes in aDes are zero
//
{
for( TInt i = aDes.Length(); i > 0; )
{
--i;
if( 0 != aDes[i] )
{
return EFalse;
}
}
return ETrue;
}
void CReadTest::CreateTestData( TInt aBlockNumber, TBool aEndOfBlock )
//
// Writes some test data to the Flash. If aEndOfBlock is EFalse the
// data is created at the start of the block. If it is ETrue then
// the data is created right at the end of the block
//
{
test.Printf( _L("Writing test data to Flash block %d\n"), aBlockNumber );
//
// Generate some test data
//
CreateSampleData();
test.Printf( _L("Erasing block") );
TInt writeBaseOffset = (aBlockNumber * iBlockSize);
test( KErrNone == iDrive.Format( writeBaseOffset, iBlockSize ) );
TInt writeCount = iSampleData.Length() / KMaxWriteLength;
TInt r = KErrNone;
if( aEndOfBlock )
{
writeBaseOffset += iBlockSize - iSampleData.Length();
}
TInt writeOffset = writeBaseOffset;
const TUint8* src = iSampleData.Ptr();
test.Printf( _L("Writing data") );
for( ; (writeCount > 0) && (KErrNone == r); writeCount-- )
{
TPtrC8 buf( src, KMaxWriteLength );
test( KErrNone == iDrive.Write( writeOffset, buf ) );
writeOffset += KMaxWriteLength;
src += KMaxWriteLength;
}
test( r == KErrNone );
//
// check that the data was written ok
//
test.Printf( _L("Verifying data") );
test( CompareAgainstFlash( writeBaseOffset, iSampleData, 0 ) );
test.Printf( _L("... test data written\n") );
}
TBool CReadTest::CompareAgainstFlash( TInt aFlashOffset, const TPtrC8& aDes, TInt aDescOffset )
//
// Checks that the data in aDes matches that in the Flash at position
// aFlashOffset.
// The test starts at offset aDescOffset in aSampleData. The data length
// tested is aDes->Length() - aDescOffset
//
{
TInt dataLength = aDes.Length() - aDescOffset;
const TUint8* srcPtr = aDes.Ptr() + aDescOffset;
TUint offset = aFlashOffset;
TBool failed = EFalse;
const TInt readBufLen = iReadBuffer.MaxLength();
while( (dataLength > 0) && !failed )
{
TInt len = Min( dataLength, readBufLen );
TInt r = iDrive.Read( offset, len, iReadBuffer );
if( r != KErrNone )
{
test.Printf( _L("... FAIL: read failed (%d) at offset 0x%x\n"), r, offset );
test( KErrNone == r );
}
test( iReadBuffer.Length() == len );
if( 0 != Mem::Compare( srcPtr, len, iReadBuffer.Ptr(), len ) )
{
test.Printf( _L("... FAIL: mismatch around offset 0x%x\n"), offset );
failed = ETrue;
}
offset += len;
dataLength -= len;
srcPtr += len;
}
return !failed;
}
void CReadTest::DoTest()
//
// Main test dispatcher
//
{
//
// Create some test data at start of block 0
//
CreateTestData( 0, EFalse );
//
// Now do the simple tests, all reads will return zeros
//
#if 0
TestSimpleReads();
#endif
TestSimpleThreadReads();
TestUnalignedReads();
TestUnalignedThreadReads();
TestOffsetBufferThreadReads();
TestOffsetBufferUnalignedThreadReads();
//
// Create some more data at start of all other blocks
//
test.Next( _L("Creating more test data in other blocks") );
for( TInt i = 1; i < iBlockCount; i++ )
{
CreateTestData( i, EFalse );
}
//
// Make sure we can read valid data out of the other blocks
//
TestReadsFromAllBlocks();
//
// Now do some scatter-read tests
//
TestSimpleScatterReads1();
TestSimpleScatterReads2();
//
// Create some more testdata at end of all blocks
//
test.Next( _L("Creating test data at end of blocks") );
for( TInt i = 0; i < iBlockCount; i++ )
{
CreateTestData( i, ETrue );
}
//
// Do a full scatter-gather test
//
TestScatterGather();
TestReadAcrossBlock();
}
TInt E32Main()
{
test.Title();
test.Start(_L("Testing media read operations"));
CReadTest reader;
TRAPD( ret, reader.CreateL() );
test( KErrNone == ret );
reader.DoTest();
test.End();
return 0;
}