/**
@SYMTestCaseID
GRAPHICS-UI-BENCH-0151
@SYMPREQ PREQ39
@SYMREQ REQ9236
@SYMREQ REQ9237
@SYMTestCaseDesc
Measures the performance of DrawBitmap() for the current screen mode, for various bitmap pixel formats.
The bitmap is drawn without scaling.
@SYMTestActions
Create a copy of the bitmap, and scale to the required size, prior to running the test.
For each required source pixel format, use DrawBitmap() to tile a bitmap across the target, avoiding any
clipping or overlap.
@SYMTestExpectedResults
The performance to be logged as a pixel rate, per bitmap.
*/
void CTBitBltPerfDirectGdi::SimpleDrawBitmapL()
{
INFO_PRINTF1(_L("CTBitBltPerfDirectGdi::SimpleDrawBitmap"));
_LIT(KTestName, "DirectGdiDrawBitmap");
for (TInt source = 0; source < iBitmapImage.Count(); ++source)
{
// Use a bitmap that needs no scaling.
CFbsBitmap* bitmapBitBltImage = CopyIntoNewBitmapL(iBitmapImage[source], iBitmapImage[source]->DisplayMode());
CleanupStack::PushL(bitmapBitBltImage);
bitmapBitBltImage->Resize(KCropTo.Size());
BitBltBitmapTestL(EDrawBitmap, bitmapBitBltImage, NULL, bitmapBitBltImage->SizeInPixels(), KTestName, iContext);
CleanupStack::PopAndDestroy(1, bitmapBitBltImage);
}
}
/**
@SYMTestCaseID
GRAPHICS-FBSERV-0512
@SYMTestCaseDesc
Creates bitmaps in different ways and checks if memory allocation succeeded
@SYMTestActions
Creates normal size bitmaps, large bitmaps, loads bitmaps, loads shared bitmaps,
duplicated bitmaps, resizes bitmaps, compresses bitmaps, externalized bitmaps to write store,
internalizes bitmaps back again from write store. All ways of creating bitmaps are tested
against Out Of Memory error conditions
@SYMTestExpectedResults
Test should pass
*/
void CTAlloc::BitmapsL()
{
TInt heapMarkCheckFlag;
if( !iStep->GetIntFromConfig(KDefaultSectionName, KFbsHeapMarkCheckFlag, heapMarkCheckFlag) )
{
INFO_PRINTF1(_L("Error reading ini file"));
User::Leave(KErrNotFound);
}
CFbsBitmap iBitmap;
CFbsBitmap iBitmap2;
iTestBitmapName = KTestBitmapOnZ;
TInt ret = iBitmap.Load(iTestBitmapName,ETfbs,NULL);
TEST2(ret, KErrNone);
ret = iBitmap.Create(KLargeSize,EColor256); // Expand server caches
TEST2(ret, KErrNone);
iBitmap.Reset();
TInt count;
// Create bitmap
INFO_PRINTF1(_L("CFbsBitmap::Create()\r\n"));
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Create(KSmallSize,EColor256);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret=iBitmap.Create(KSmallSize,EGray2);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// Create (large)
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Create(KLargeSize,EColor256);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Create(KLargeSize,EColor256);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// Load
INFO_PRINTF1(_L("CFbsBitmap::Load()\r\n"));
ret = iBitmap.Load(iTestBitmapName,ETfbs,NULL);
TEST2(ret, KErrNone);
iBitmap.Reset();
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Load(iTestBitmapName,ETfbs,NULL);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Load(iTestBitmapName,ETfbs,NULL);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// Load (shared)
INFO_PRINTF1(_L("CFbsBitmap::Load() - shared \r\n"));
// Do an initial load to ensure the StreamId cache does not get updated whilst OOM testing
ret = iBitmap.Load(iTestBitmapName,ETfbs,ETrue);
TEST2(ret, KErrNone);
iBitmap.Reset();
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Load(iTestBitmapName,ETfbs,ETrue);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
continue;
}
else if (ret != KErrNone)
TEST2(ret, KErrNone);
ret = iBitmap2.Load(iTestBitmapName,ETfbs,ETrue);
if (ret == KErrNoMemory)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
continue;
}
else if (ret == KErrNone)
{
iBitmap.Reset();
iBitmap2.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Load(iTestBitmapName,ETfbs,ETrue);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
continue;
}
else if (ret != KErrNone)
TEST2(ret, KErrNone);
ret = iBitmap2.Load(iTestBitmapName,ETfbs,ETrue);
if (ret == KErrNoMemory)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
continue;
}
else if (ret == KErrNone)
{
iBitmap.Reset();
iBitmap2.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// Duplicate
CFbsBitmap bmpalt;
ret = bmpalt.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::Duplicate()\r\n"));
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Duplicate(bmpalt.Handle());
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==1);
ret = bmpalt.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Duplicate(bmpalt.Handle());
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
bmpalt.Reset();
TEST(iFbs->ResourceCount()==0);
// Resize
// force fbserv to do a resize. This makes the pile to insert an index in it's array
// If the array is empty when the tests below are run then the insert will look like a mem leak
ret=iBitmap.Create(KLargeSize,EColor256);
iBitmap.Resize(KLargeSizeAlt);
iBitmap.Reset();
ret=iBitmap.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::Resize()\r\n"));
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Resize(KSmallSizeAlt);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// force fbserv to do a resize. This makes the pile to insert an index in it's array
// If the array is empty when the tests below are run then the insert will look like a mem leak
ret=iBitmap.Create(KLargeSize,EColor256);
iBitmap.Resize(KLargeSizeAlt);
iBitmap.Reset();
ret=iBitmap.Create(KLargeSize,EColor256);
TEST2(ret, KErrNone);
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Resize(KLargeSizeAlt);
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// Compress
ret=iBitmap.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::Compress()\r\n"));
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Compress();
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
ret=iBitmap.Create(KLargeSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::Compress()\r\n"));
for (count = 1; ; count++)
{
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
ret = iBitmap.Compress();
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
// WriteStore creation
RFs fs;
ret=fs.Connect();
TEST2(ret, KErrNone);
CDirectFileStore* writestore=NULL;
//Construct filename using the thread id to enable concurrent test runs.
_LIT(KSbmFileName,"c:\\tall_");
TBuf<36> buf(KSbmFileName);
TThreadId threadId = RThread().Id();
TUint64 id = threadId.Id();
TBuf<20> threadIdBuf;
threadIdBuf.Num(id);
buf.Append(threadIdBuf);
buf.Append(_L(".sbm"));
TRAP(ret,writestore=CDirectFileStore::ReplaceL(fs,buf,EFileStream|EFileWrite));
TEST2(ret, KErrNone);
TUidType uidtype(KDirectFileStoreLayoutUid,KMultiBitmapFileImageUid);
TRAP(ret,writestore->SetTypeL(uidtype));
TEST2(ret, KErrNone);
RStoreWriteStream writestrm;
TStreamId headerid(0);
TRAP(ret,headerid=writestrm.CreateL(*writestore));
TEST2(ret, KErrNone);
TRAP(ret,writestore->SetRootL(headerid));
TEST2(ret, KErrNone);
// Externalize
ret=iBitmap.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::ExternalizeL()\r\n"));
for (count = 1; ; count++)
{
__UHEAP_SETFAIL(RHeap::EDeterministic,count);
__UHEAP_MARK;
TRAP(ret,iBitmap.ExternalizeL(writestrm));
if (ret == KErrNoMemory)
{
__UHEAP_MARKEND;
}
else if (ret == KErrNone)
{
iBitmap.Reset();
__UHEAP_MARKEND;
break;
}
else
{
__UHEAP_MARKEND;
TEST2(ret, KErrNone);
}
}
__UHEAP_RESET;
TEST(iFbs->ResourceCount()==0);
// ExternalizeRectangle
ret=iBitmap.Create(KSmallSize,EColor256);
TEST2(ret, KErrNone);
INFO_PRINTF1(_L("CFbsBitmap::ExternalizeRectangleL()\r\n"));
for (count = 1; ; count++)
{
__UHEAP_SETFAIL(RHeap::EDeterministic,count);
__UHEAP_MARK;
TRAP(ret,iBitmap.ExternalizeRectangleL(writestrm,TRect(3,3,7,7)));
if (ret == KErrNoMemory)
{
__UHEAP_MARKEND;
}
else if (ret == KErrNone)
{
__UHEAP_MARKEND;
break;
}
else
{
__UHEAP_MARKEND;
TEST2(ret, KErrNone);
}
}
__UHEAP_RESET;
writestrm.Close();
delete writestore;
iBitmap.Reset();
TEST(iFbs->ResourceCount()==0);
// Internalize
INFO_PRINTF1(_L("CFbsBitmap::InternalizeL()\r\n"));
for (count = 1; ; count++)
{
// ReadStore creation
CDirectFileStore* readstore=NULL;
TRAP(ret,readstore=CDirectFileStore::OpenL(fs,buf,EFileStream|EFileRead|EFileShareAny));
TEST2(ret, KErrNone);
RStoreReadStream readstrm;
headerid=readstore->Root();
TRAP(ret,readstrm.OpenL(*readstore,headerid));
TEST2(ret, KErrNone);
iFbs->SendCommand(EFbsMessDefaultAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
TRAP(ret,iBitmap.InternalizeL(readstrm));
readstrm.Close();
delete readstore;
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
for (count = 1; ; count++)
{
// ReadStore re-creation
CDirectFileStore* readstore=NULL;
// TRAP(ret,readstore=CDirectFileStore::OpenL(fs,_L("c:\\tall.sbm"),EFileStream|EFileRead|EFileShareAny));
TRAP(ret,readstore=CDirectFileStore::OpenL(fs,buf,EFileStream|EFileRead|EFileShareAny));
TEST2(ret, KErrNone);
headerid=readstore->Root();
RStoreReadStream readstrm;
TRAP(ret,readstrm.OpenL(*readstore,headerid));
TEST2(ret, KErrNone);
iFbs->SendCommand(EFbsMessUserAllocFail,count);
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMark);
iFbs->SendCommand(EFbsMessUserMark);
}
TRAP(ret,iBitmap.InternalizeL(readstrm));
readstrm.Close();
delete readstore;
if (ret == KErrNoMemory)
{
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
}
else if (ret == KErrNone)
{
iBitmap.Reset();
if(heapMarkCheckFlag)
{
iFbs->SendCommand(EFbsMessDefaultMarkEnd);
iFbs->SendCommand(EFbsMessUserMarkEnd);
}
break;
}
else
TEST2(ret, KErrNone);
}
iFbs->SendCommand(EFbsMessDefaultAllocFail,0);
iFbs->SendCommand(EFbsMessUserAllocFail,0);
TEST(iFbs->ResourceCount()==0);
fs.Delete(buf);
fs.Close();
}
