// Copyright (c) 2006-2009 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\mmu\t_mmcpaging.cpp
// Suite of tests specifically to test the demand paging subsystem when
// booted from MMC rather than NAND.
// 002 Read/Write and Page test
//
//
//! @SYMTestCaseID KBASE-T_MMCPAGING-0331
//! @SYMTestType UT
//! @SYMPREQ PREQ1110
//! @SYMTestCaseDesc Demand Paging MMC Paging tests.
//! @SYMTestActions 001 Check that the rom is paged
//! @SYMTestExpectedResults All tests should pass.
//! @SYMTestPriority High
//! @SYMTestStatus Implemented
#include <e32test.h>
RTest test(_L("T_MMCPAGING"));
#include <e32rom.h>
#include <e32svr.h>
#include <u32hal.h>
#include <f32file.h>
#include <f32dbg.h>
#include <d32locd.h>
#include <hal.h>
#define __TEST_PAGING_MEDIA_DRIVER__
#include "mmcdp.h"
TInt DriveNumber=-1; // Parameter - Which drive? -1 = autodetect.
TInt locDriveNumber;
TInt MaxDeferLoops=40; // Parameter - Defer test, for how long?
TInt Maxloops=400; // Parameter - RW Soak, for how long?
TBool Forever=EFalse; // Parameter - RW Soak forever?
TBool Testing=ETrue; // Used to communicate when testing has finished between threads.
RFs TheFs;
TBusLocalDrive Drive;
TLocalDriveCapsV4 DriveCaps;
TInt PagedTrashCount=0; // Incremented by threads, is used to detect preemption.
TInt GlobError=KErrNone; // To communicate an error between threads.
TBool CtrlIOSupported=ETrue;
//const TInt KDiskSectorShift = 9;
const TInt KBufSizeInBytes = (32 * 1024);
LOCAL_D TBuf8<KBufSizeInBytes> Buffer;
// Three functions for the garbage test.
// CreateFile creates a file, and sets up the buffer for WriteNumber.
// After the code has finished writing numbers to the start,
// CloseAndDestroy cleans up.
void CreateFile(RFile &aFile,const TDesC& aFileName)
{
TBuf<256> fileName;
fileName.Append((TChar)('A'+DriveNumber));
fileName+=_L(":\\f32-tst\\");
TInt r=TheFs.MkDirAll(fileName);
test(r==KErrNone || r== KErrAlreadyExists);
fileName += aFileName;
r=aFile.Replace(TheFs,fileName,EFileWrite);
if (r!=KErrNone)
test.Printf(_L("Error %d: file '%S' could not be created\n"),r,&fileName);
test(r==KErrNone);
Buffer.SetLength(4);
}
void CloseAndDestroy(RFile &aFile)
{
TBuf<256> fileName;
aFile.FullName(fileName);
aFile.Close();
TheFs.Delete(fileName);
}
TInt WriteNumber(RFile &aFile)
{
TInt r;
Buffer[0]++;
r = aFile.Write(0,Buffer);
if (r==KErrNone)
return aFile.Flush();
else
return r;
}
// Finds the 1st MMC drive, or checks the specified one fits requirements
static TInt FindFsMMCDrive()
{
TDriveList driveList;
TDriveInfo driveInfo;
TInt r=TheFs.DriveList(driveList);
test(r == KErrNone);
TInt drvNum = DriveNumber;
if (drvNum<0)
drvNum = 0;
do
{
if(!driveList[drvNum])
continue; //-- skip unexisting drive
test(TheFs.Drive(driveInfo, drvNum) == KErrNone);
if(driveInfo.iMediaAtt&KMediaAttPageable)
{
// Internal MMC ?
if (driveInfo.iType == EMediaHardDisk &&
(driveInfo.iDriveAtt & KDriveAttInternal) &&
(!(driveInfo.iDriveAtt & KDriveAttRemovable)))
return (drvNum);
}
}
while(DriveNumber<0 && ++drvNum<KMaxDrives);
return (-1);
}
//
// Writes to main area for the entire disk and reads back to verify.
// The function is called from TestMmcAccuratcy, which will have also
// started the background RepeatedPagingThread
//
void testWriteMain()
{
TInt i;
TInt r;
TInt changeCount=0;
TInt totChangeCount=0;
TInt cCount=0;
TInt fullcCount=0;
TInt oldPagedTrashCount=0;
TInt delta=0;
TInt high=0;
TInt tot=0;
TInt fullTot=0;
TInt blockNo;
SMmcStats stats;
TInt reqPageCount=0;
TInt reqNormalCount=0;
TInt readSize = KBufSizeInBytes/2;
TInt writeSize = KBufSizeInBytes/2;
Buffer.SetLength(2*readSize);
TPtr8 subBuf1(&Buffer[0],readSize);
TPtrC8 subBuf2(&Buffer[readSize], readSize);
test.Printf(_L("writeSize = %d\n"), writeSize);
// TInt64 size = DriveCaps.iSize - (DriveCaps.iSize % readSize);
for(i = 0; i<readSize; i++)
Buffer[readSize+i] = (char)(i%100);
// Zero Stats
if(CtrlIOSupported)
{
TPtr8 statsBuf((TUint8*) &stats, sizeof(stats));
test(Drive.ControlIO(KMmcGetStats,statsBuf,0) == KErrNone);
}
TFileName fileName = _L("?:\\f32-tst\\mmcpage.txt");
fileName[0] = (TText) ('A'+DriveNumber);
r = TheFs.MkDirAll(fileName);
test(r==KErrNone || r== KErrAlreadyExists);
// fileName += KTempFileName;
RFile tempFile;
r=tempFile.Replace(TheFs,fileName,EFileWrite);
if (r!=KErrNone)
test.Printf(_L("Error %d: file '%S' could not be created\n"),r,&fileName);
test(r==KErrNone);
TVolumeInfo volInfo;
r = TheFs.Volume(volInfo, DriveNumber);
test (r == KErrNone);
TInt64 size = volInfo.iFree - (volInfo.iFree % readSize);
TInt maxFileSize = (size > KMaxTInt) ? KMaxTInt : (TInt) size;
test.Printf(_L("Volume size %ld, free %ld maxFileSize %d file '%S'\n"), volInfo.iSize, volInfo.iFree, maxFileSize, &fileName);
while (((totChangeCount<Maxloops) || Forever) && (GlobError==KErrNone))
{
for(TInt pos=0;
((pos+writeSize) < maxFileSize) && ((totChangeCount<Maxloops) || Forever) && (GlobError==KErrNone);
pos+=(TUint)(readSize))
{
blockNo=I64LOW(pos / writeSize);
if (pos % (writeSize) == 0)
test.Printf(_L("Block %d at %u \r"), blockNo, I64LOW(pos));
//write the pattern
r = tempFile.Write(pos,subBuf2);
if (r != KErrNone)
test.Printf(_L("Write failed %d"), r);
test(r==KErrNone);
//read back and verify
r = tempFile.Read(pos,subBuf1,readSize);
test(r==KErrNone);
for(i=0;i<readSize;i++)
if(Buffer[i]!=Buffer[readSize+i])
{
r = KErrCorrupt;
break;
}
delta = PagedTrashCount-oldPagedTrashCount;
cCount++;
if (delta)
{
if (delta>high)
high=delta;
tot+=delta;
oldPagedTrashCount=PagedTrashCount;
changeCount++;
}
if (pos % (writeSize) == 0)
{
if ((blockNo%80==0) && (blockNo!=0))
{
totChangeCount+=changeCount;
if(CtrlIOSupported)
{
test.Printf(_L("High%4d Avg%2d %d%% CC=%4d \n"), high, (TInt) (tot/cCount), (TInt)(changeCount*100)/cCount, totChangeCount);
TPtr8 statsBuf((TUint8*) &stats, sizeof(stats));
Drive.ControlIO(KMmcGetStats,statsBuf,0);
test.Printf(_L("PR %d(%d%%) NR %d\n"), stats.iReqPage, (TInt) ((stats.iReqPage*100)/cCount), stats.iReqNormal);
test(stats.iReqPage>0);
reqPageCount+=stats.iReqPage;
reqNormalCount+=stats.iReqNormal;
}
high=0;
fullTot+=tot;
tot=0;
fullcCount+=cCount;
cCount=0;
changeCount=0;
}
}
test(r==KErrNone);
}
if(CtrlIOSupported)
{
test.Printf(_L("Totals: Avg %2d %d%% CC=%4d \n"), fullTot/fullcCount, (TInt)(totChangeCount*100)/fullcCount, totChangeCount);
test.Printf(_L("PR %d(%d%%) NR %d\n"), reqPageCount,(TInt) (reqPageCount*100/fullcCount), reqNormalCount );
}
// If totChangeCount does not change, mmc maybe busy waiting.
test(totChangeCount>0);
}
tempFile.Close();
r = TheFs.Delete(fileName);
test (r == KErrNone);
if (GlobError!=KErrNone)
{
test.Printf(_L("\nPageing failed with %x\n"), GlobError);
test(0);
}
else
test.Printf(_L("\ndone\n"));
}
TUint8 ReadByte(volatile TUint8* aPtr)
{
return *aPtr;
}
#define READ(a) ReadByte((volatile TUint8*)(a))
TUint32 RandomNo =0;
TUint32 Random()
{
RandomNo = RandomNo*69069+1;
return RandomNo;
}
// Many instances of this run while testWriteMain runs,
// to cause random background paging.
LOCAL_C TInt RepeatedPagingThread(TAny* aUseTb)
{
// RTest test(_L("RepeatedPagingThread"));
TBool trashBurst = EFalse;
// This makes the paging system continually page stuff.
// get info about a paged ROM...
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
TUint8* start = (TUint8*)romHeader+romHeader->iPageableRomStart;
TUint size = romHeader->iPageableRomSize;
TInt pageSize = 0;
PagedTrashCount=1;
UserSvr::HalFunction(EHalGroupKernel,EKernelHalPageSizeInBytes,&pageSize,0);
RandomNo=123;
PagedTrashCount++;
while (Testing)
{
TInt r=UserSvr::HalFunction(EHalGroupVM,EVMHalFlushCache,0,0);
if (Random() & 1)
User::AfterHighRes(500+Random() & 2047);
if (r<0)
{
GlobError=r;
PagedTrashCount=99;
return (KErrNone);
}
if (trashBurst)
{
if ((Random() & 0xf) == 0xf)
trashBurst=EFalse;
PagedTrashCount++;
}
else
{
for(TInt i=size/(pageSize); (i>0) && !trashBurst; --i)
{
READ(start+((TInt64(Random())*TInt64(size))>>32));
if ((RandomNo & 0x3f) == 0x3f)
{
trashBurst= (TBool) aUseTb;
}
PagedTrashCount++;
if (RandomNo & 1)
User::AfterHighRes(500+Random() & 2047);
}
}
}
return(KErrNone);
}
// This starts up multiple instances of repeatedPagingThread, and runs testWriteMain.
// After its done, it calls format, to clean up the drive.
void TestMmcAccuratcy()
{
RThread thisThread;
const TInt KNoThreads=10;
TInt i;
test.Printf(_L("Reset stats\n"));
i=UserSvr::HalFunction(EHalGroupMedia,EMediaHalResetConcurrencyInfo,(TAny*)locDriveNumber,(TAny*)EMediaPagingStatsRom);
test(i==KErrNone || i==KErrNotSupported);
if(i==KErrNotSupported)
test.Printf(_L("Concurrency stats not supported on this build\n"));
i=UserSvr::HalFunction(EHalGroupMedia,EMediaHalResetPagingBenchmark,(TAny*)locDriveNumber,(TAny*)EMediaPagingStatsRom);
test(i==KErrNone || i==KErrNotSupported);
if(i==KErrNotSupported)
test.Printf(_L("Benchmark stats not supported on this build\n"));
if (Maxloops>0)
{
TRequestStatus stat[KNoThreads];
// Start Read Test
RThread repeatedPagingThread[KNoThreads];
test.Next(_L("Read/Write and Page test"));
for (i=0; i<KNoThreads; i++)
{
test(repeatedPagingThread[i].Create(_L(""),RepeatedPagingThread,KDefaultStackSize,NULL,(TAny*) ETrue)==KErrNone);
repeatedPagingThread[i].Logon(stat[i]);
test(stat[i]==KRequestPending);
repeatedPagingThread[i].Resume();
}
// Start repeated paging.
thisThread.SetPriority(EPriorityMore);
Testing=ETrue;
testWriteMain();
Testing = 0;
thisThread.SetPriority(EPriorityNormal);
for (i=0; i<KNoThreads; i++)
User::WaitForRequest(stat[i]);
test.Printf(_L("Collect concurrency stats\n"));
SMediaROMPagingConcurrencyInfo info;
SPagingBenchmarkInfo infoBench;
i=UserSvr::HalFunction(EHalGroupMedia,EMediaHalGetROMConcurrencyInfo,(TAny*)locDriveNumber,&info);
test(i==KErrNone || i==KErrNotSupported);
TInt r=UserSvr::HalFunction(EHalGroupMedia,EMediaHalGetROMPagingBenchmark,(TAny*)locDriveNumber,&infoBench);
test(r==KErrNone || r==KErrNotSupported);
if(i==KErrNone)
{
test.Printf(_L("Media concurrency stats:\n\n"));
test.Printf(_L("The total number of page in requests issued whilst processing other page in requests: %d\n"),info.iTotalConcurrentReqs);
test.Printf(_L("The total number of page in requests issued with at least one queue not empty: %d\n"),info.iTotalReqIssuedNonEmptyQ);
test.Printf(_L("The maximum number of pending page in requests in the main queue any time during this session: %d\n"),info.iMaxReqsInPending);
test.Printf(_L("The maximum number of pending page in requests in the deferred queue any time during this session: %d\n"),info.iMaxReqsInDeferred);
test.Printf(_L("The total number of page in requests first-time deferred during this session: %d\n"),info.iTotalFirstTimeDeferrals);
test.Printf(_L("The total number of page in requests re-deferred during this session: %d\n"),info.iTotalReDeferrals);
test.Printf(_L("The maximum number of deferrals of any single page in request during this session: %d\n"),info.iMaxDeferrals);
test.Printf(_L("The total number of times the main queue was emptied when completing an asynchronous request during this session: %d\n"),info.iTotalSynchEmptiedMainQ);
test.Printf(_L("The total number of page in requests serviced from main queue when completing an asynchronous request: %d\n"),info.iTotalSynchServicedFromMainQ);
test.Printf(_L("The total number of page in requests deferred after being picked out of main queue when completing an asynchronous request: %d\n"),info.iTotalSynchDeferredFromMainQ);
test.Printf(_L("The total number of times the page in DFC run with an empty main queue during this session: %d\n"),info.iTotalRunDry);
test.Printf(_L("The total number of dry runs of paging DFC avoided during this session: %d\n"),info.iTotalDryRunsAvoided);
}
if(r==KErrNone)
{
TInt freq = 0;
r = HAL::Get(HAL::EFastCounterFrequency, freq);
if (r==KErrNone)
{
TReal mult = 1000000.0 / freq;
TReal min = 0.0;
TReal max = 0.0;
TReal avg = 0.0;
if (infoBench.iCount != 0)
{
min = infoBench.iMinTime * mult;
max = infoBench.iMaxTime * mult;
avg = (infoBench.iTotalTime * mult) / infoBench.iCount;
}
test.Printf(_L("Media benchmarks:\n\n"));
test.Printf(_L("The total number of page in requests issued: %d\n"),infoBench.iCount);
test.Printf(_L("The average latency of any page in request in the Media subsystem: %9.1f(us)\n"),avg);
test.Printf(_L("The maximum latency of any page in request in the Media subsystem: %9.1f(us)\n"),max);
test.Printf(_L("The minimum latency of any page in request in the Media subsystem: %9.1f(us)\n"),min);
}
}
}
else
test.Next(_L("Read/Write test - Skipped!"));
}
// ************************************************************************************
/*
// This code causes a flush
// It is done in a second thread to see if you really do get just
// one deferral, with the other page requests just waiting in line.
// (Paging is not re-entrant)
TInt PagesBeingPaged=0;
RMutex PageMutex;
RSemaphore PageSemaphore;
RSemaphore PageDoneSemaphore;
LOCAL_C TInt CausePage(TAny*)
{
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
TUint8* start = (TUint8*)romHeader+romHeader->iPageableRomStart;
TUint size = romHeader->iPageableRomSize;
TUint8* addr=NULL;
TBool flush;
while (Testing)
{
// Wait on semaphore
PageSemaphore.Wait();
flush = (PagesBeingPaged==0);
PagesBeingPaged++;
addr=start+((TInt64(Random())*TInt64(size))>>32);
PageDoneSemaphore.Signal();
if (flush)
UserSvr::HalFunction(EHalGroupVM,EVMHalFlushCache,0,0);
READ(addr);
PageMutex.Wait();
PagesBeingPaged--;
PageMutex.Signal();
}
return 0;
}
*/
// ************************************************************************************
//
// The gubbins that starts all the tests
//
// ParseCommandLine reads the arguments and sets globals accordingly.
//
void ParseCommandLine()
{
TBuf<32> args;
User::CommandLine(args);
TLex lex(args);
FOREVER
{
TPtrC token=lex.NextToken();
if(token.Length()!=0)
{
if ((token.Length()==2) && (token[1]==':'))
DriveNumber=User::UpperCase(token[0])-'A';
else if (token.Length()==1)
{
TChar driveLetter = User::UpperCase(token[0]);
if ((driveLetter>='A') && (driveLetter<='Z'))
DriveNumber=driveLetter - (TChar) 'A';
else
test.Printf(_L("Unknown argument '%S' was ignored.\n"), &token);
}
else if ((token==_L("help")) || (token==_L("-h")) || (token==_L("-?")))
{
test.Printf(_L("\nUsage: t_mmcpaging <driveletter> [rwsoak <cc>] [defer <c>]\n'-' indicated infinity.\n\n"));
test.Getch();
Maxloops=0;
}
else if (token==_L("rwsoak"))
{
TPtrC val=lex.NextToken();
TLex lexv(val);
TInt v;
if (val==_L("-"))
Forever=ETrue;
else
if (lexv.Val(v)==KErrNone)
Maxloops=v;
else
test.Printf(_L("Bad value for rwsoak '%S' was ignored.\n"), &val);
}
else if (token==_L("defer"))
{
TPtrC val=lex.NextToken();
TLex lexv(val);
TInt v;
if (val==_L("-"))
MaxDeferLoops=KMaxTInt;
else
if (lexv.Val(v)==KErrNone)
MaxDeferLoops=v;
else
test.Printf(_L("Bad value for defer '%S' was ignored.\n"), &val);
}
else
test.Printf(_L("Unknown argument '%S' was ignored.\n"), &token);
}
else
break;
}
}
//
// E32Main
//
TInt E32Main()
{
TInt r;
test.Title();
test.Printf(_L("key\n---\n"));
test.Printf(_L("PR: Paging requests\n"));
test.Printf(_L("NR: Normal requests\n\n"));
test.Start(_L("Check that the rom is paged"));
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
if (romHeader->iPageableRomStart==NULL)
test.Printf(_L("Test ROM is not paged - test skipped!\r\n"));
else
{
ParseCommandLine();
test(TheFs.Connect()==KErrNone);
r=UserSvr::HalFunction(EHalGroupVM,EVMHalFlushCache,0,0);
if(r<0)
{
test.Printf(_L("DemandPagingFlushPages Error = %d\n"),r);
test(0);
}
DriveNumber = FindFsMMCDrive();
if(DriveNumber<0)
test.Printf(_L("MMC Flash not found - test skipped!\r\n"));
else
{
RFile file;
TBuf<256> fileName;
fileName.Append((TChar)('A'+DriveNumber));
fileName+=_L(":\\f32-tst\\");
TInt r=TheFs.MkDirAll(fileName);
test(r==KErrNone || r== KErrAlreadyExists);
fileName += _L("redglare.txt");
r=file.Replace(TheFs,fileName,EFileWrite);
if (r!=KErrNone)
test.Printf(_L("Error %d: file '%S' could not be created\n"),r,&fileName);
test(r==KErrNone);
r=file.Write(_L8("The red glare of an ancient sun reflecting on the leaden surface of a primeval soup of decomposing matter"));
if (r!=KErrNone)
test.Printf(_L("Error %d: could not write to file\n"),r);
test(r==KErrNone);
test(file.Flush() == KErrNone);
SBlockMapInfo info;
TInt64 start=0;
r=file.BlockMap(info,start, -1,ETestDebug);
if (r!=KErrNone && r!=KErrCompletion)
test.Printf(_L("Error %d: could not obtain block map\n"),r);
test(r==KErrNone || r==KErrCompletion);
locDriveNumber=info.iLocalDriveNumber;
test.Printf(_L("Found drive: %c (MMC drive %d)\r\n"), DriveNumber+'A',locDriveNumber);
file.Close();
TDriveInfo driveInfo;
test(TheFs.Drive(driveInfo, DriveNumber) == KErrNone);
// Connect to device driver
TBool changeFlag = EFalse;
r = Drive.Connect(locDriveNumber,changeFlag);
TPckg<TLocalDriveCapsV4> capsPack(DriveCaps);
Drive.Caps(capsPack);
test(r == KErrNone);
SMmcStats stats;
TPtr8 statsBuf((TUint8*) &stats, sizeof(stats));
r = Drive.ControlIO(KMmcGetStats,statsBuf,0);
if (r!=KErrNone)
{
test.Printf(_L("LocalDrive does not support testing IO Requests\n"));
CtrlIOSupported=EFalse;
}
test.Printf(_L("LocalDrive Connected\n"));
//
// Run tests
//
TestMmcAccuratcy();
//
// Free device and end test program
//
Drive.Disconnect();
}
}
test.End();
return 0;
}