// 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:
// f32test\demandpaging\t_pagestress.cpp
// Demand Paging Stress Tests
// t_pagestress.exe basically attempts to cause large ammounts of paging by calling
// functions (256) which are alligned on a page boundary from multiple threads.
// There are mulitple versions of t_pagestress installed on a test system to test rom
// and code paging from various media types.
// Usage:
// t_pagestress and t_pagestress_rom
// Common command lines:
// t_pagestress lowmem
// debug - switch on debugging information
// silent - no output to the screen or serial port
// check - check the allignments
// single - run the tests in a single thread
// multiple <numThreads> - run the tests in multiple threads where <numThreads>
// interleave - force thread interleaving
// prio - each thread reschedules in between each function call, causes lots of context changes
// media - perform media access during the tests, very stressful
// lowmem - low memory tests
// forward - patern in which to execute function calls
// backward - patern in which to execute function calls
// random - patern in which to execute function calls
// all - patern in which to execute function calls (forward, backward and random)
// inst - for debugging a parameter passed to a spawned exe to give it an id.
// iters <count> - the number of times to loop (a '-' means run forever)
// t_pagestress causes a large ammount of paging by repeatedly calling
// 256 functions which have been aligned on page boundaries from
// multiple threads.
// 1 - a single thread calling all functions
// 2 - Multiple threads calling all functions
// 3 - Multiple threads calling all functions with a priority change
// after each function call
// 4 - Multiple threads calling all functions with background
// media activity
// 5 - Multiple threads calling all functions with media activity and
// a priority change after each function call
// 6 - Multiple threads calling all functions with process interleave
// 7 - Multiple threads calling all functions with process interleave
// and a priority change after each function call
// 8 - Multiple threads calling all functions with process interleave
// media acess and a priority change after each function call
// 9 - Multiple threads calling all functions with low available memory
// 10 - Multiple threads calling all functions with low available memory,
// starting with initial free ram.
//
//
//! @SYMTestCaseID KBASE-T_PAGESTRESS-0327
//! @SYMTestType UT
//! @SYMPREQ PREQ1110
//! @SYMTestCaseDesc Demand Paging Stress Tests
//! @SYMTestActions 0 - Check the alignment of all functions
//! @SYMTestExpectedResults All tests should pass.
//! @SYMTestPriority High
//! @SYMTestStatus Implemented
#include <e32test.h>
RTest test(_L("T_PAGESTRESS"));
#include <e32rom.h>
#include <e32svr.h>
#include <u32hal.h>
#include <f32file.h>
#include <f32dbg.h>
#include <e32msgqueue.h>
#include <e32math.h>
#include "testdefs.h"
#ifdef __X86__
#define TEST_ON_UNPAGED
#endif
/* The following line will cause t_pagestress.h to declare an array of function
* pointers to page boundary aligned functions that we can use in this test...
*/
#define TPS_DECLARE_ARRAY
#include "t_pagestress.h"
TBool TestDebug = EFalse;
TBool TestSilent = EFalse;
TBool TestExit = EFalse;
TBool TestCheck = EFalse;
TBool TestSingle = EFalse;
TBool TestMultiple = EFalse;
TBool TestForever = EFalse;
TInt TestMaxLoops = 20;
TInt TestMultipleThreadCount = 50;
TInt TestInstanceId = 0;
#define TEST_INTERLEAVE_PRIO EPriorityMore//EPriorityRealTime //23 // KNandThreadPriority - 1
TBool TestInterleave = EFalse;
TBool TestWeAreTheTestBase = EFalse;
TBool TestBootedFromMmc = EFalse;
TInt DriveNumber=-1; // Parameter - Which drive? -1 = autodetect.
#define TEST_NONE 0x0
#define TEST_FORWARD 0x2
#define TEST_BACKWARD 0x4
#define TEST_RANDOM 0x8
#define TEST_ALL (TEST_RANDOM | TEST_BACKWARD | TEST_FORWARD)
TUint32 TestWhichTests = TEST_ALL;
TBuf<32> TestNameBuffer;
TBool TestPrioChange = ETrue;
TBool TestStopMedia = EFalse;
TBool TestMediaAccess = EFalse;
#define TEST_LM_NUM_FREE 0
#define TEST_LM_BLOCKSIZE 1
#define TEST_LM_BLOCKS_FREE 4
TBool TestLowMem = EFalse;
RPageStressTestLdd Ldd;
TInt TestPageSize = 4096;
RSemaphore TestMultiSem;
RMsgQueue<TBuf <64> > TestMsgQueue;
TBool TestIsDemandPaged = ETrue;
#define TEST_NEXT(__args) \
if (!TestSilent)\
test.Next __args;
#define DBGS_PRINT(__args)\
if (!TestSilent)\
test.Printf __args ;
#define DBGD_PRINT(__args)\
if (TestDebug)\
test.Printf __args ;\
#define DEBUG_PRINT(__args)\
if (!TestSilent)\
{\
if (aMsgQueue && aBuffer && aTheSem)\
{\
aBuffer->Zero();\
aBuffer->Format __args ;\
aTheSem->Wait();\
aMsgQueue->SendBlocking(*aBuffer);\
aTheSem->Signal();\
}\
else\
{\
test.Printf __args ;\
}\
}
#define RUNTEST(__test, __error)\
if (!TestSilent)\
test(__test == __error);\
else\
__test;
#define RUNTEST1(__test)\
if (!TestSilent)\
test(__test);
#define DEBUG_PRINT1(__args)\
if (TestDebug)\
{\
DEBUG_PRINT(__args)\
}
//
// CheckAlignments
//
// The following functions wanders through the function pointer array
// declared in t_pagestress.h and ensures that the alignment has worked,
// (a good start!) and then calls each of the functions in turn to
// ensure that they work, simple first sanity check test.
//
TInt CheckAlignments()
{
// now it's time to play with the array of function pointers...
TInt seed = 1;
TUint32 index = 0;
TInt ret = KErrNone;
while (index < (PAGESTRESS_FUNC_COUNT - 1))
{
DBGD_PRINT((_L("\nAddress (%u) 0x%x difference to next %u\n"), index, (TUint32)PagestressFuncPtrs[index], (TUint32)PagestressFuncPtrs[index + 1] - (TUint32)PagestressFuncPtrs[index]));
if ((((TUint32)PagestressFuncPtrs[index + 1] - (TUint32)PagestressFuncPtrs[0]) % 4096) != 0)
{
DBGS_PRINT((_L("\nError! Allignment for %u is not offset of 4096 from index 0 0x%x 0x%x\n"), index, (TUint32)PagestressFuncPtrs[index + 1], (TUint32)PagestressFuncPtrs[0]));
ret = KErrGeneral;
}
//seed = PagestressFuncPtrs[index](seed, index);
seed = CallTestFunc(seed, index, index);
index ++;
}
return ret;
}
//
// RunThreadForward
//
// Walk through the function pointer array (forwards) calling each function
//
void RunThreadForward()
{
TInt seed = 1;
TUint32 index = 0;
RThread thisThread;
while (index < PAGESTRESS_FUNC_COUNT)
{
if (TestPrioChange)
{
TThreadPriority originalThreadPriority = thisThread.Priority();
thisThread.SetPriority(EPriorityLess);
User::AfterHighRes(0);
thisThread.SetPriority(originalThreadPriority);
}
//seed = PagestressFuncPtrs[index](seed, index);
seed = CallTestFunc(seed, index, index);
index ++;
}
}
//
// RunThreadBackward
//
// Walk through the function pointer array (backwards) calling each function
//
void RunThreadBackward()
{
TInt seed = 1;
TInt index = PAGESTRESS_FUNC_COUNT;
RThread thisThread;
while (index > 0)
{
if (TestPrioChange)
{
TThreadPriority originalThreadPriority = thisThread.Priority();
thisThread.SetPriority(EPriorityLess);
User::AfterHighRes(0);
thisThread.SetPriority(originalThreadPriority);
}
index --;
//seed = PagestressFuncPtrs[index](seed, index);
seed = CallTestFunc(seed, index, index);
}
}
//
// RunThreadRandom
//
// Walk through the function pointer array in a random order a number of times calling each function
//
void RunThreadRandom()
{
TInt seed = 1;
TInt index = 0;
TInt randNum;
RThread thisThread;
while (index < (TInt)PAGESTRESS_FUNC_COUNT)
{
if (TestPrioChange)
{
TThreadPriority originalThreadPriority = thisThread.Priority();
thisThread.SetPriority(EPriorityLess);
User::AfterHighRes(0);
thisThread.SetPriority(originalThreadPriority);
}
randNum = Math::Random();
randNum %= PAGESTRESS_FUNC_COUNT;
//seed = PagestressFuncPtrs[randNum](seed, randNum);
seed = CallTestFunc(seed, randNum, randNum);
index ++;
}
}
//
// PerformTestThread
//
// This is the function that actually does the work.
// It is complicated a little because test.Printf can only be called from the first thread that calls it
// so if we are using multiple threads we need to use a message queue to pass the debug info from the
// child threads back to the parent for the parent to then call printf.
//
//
LOCAL_C void PerformTestThread(TInt aThreadIndex,
RMsgQueue<TBuf <64> > *aMsgQueue = NULL,
TBuf<64> *aBuffer = NULL,
RSemaphore *aTheSem = NULL)
{
TUint start = User::TickCount();
DEBUG_PRINT1((_L("%S : thread Starting %d\n"), &TestNameBuffer, aThreadIndex));
// now select how we do the test...
TInt iterIndex;
if (TEST_ALL == (TestWhichTests & TEST_ALL))
{
#define LOCAL_ORDER_INDEX1 6
#define LOCAL_ORDER_INDEX2 3
TInt order[LOCAL_ORDER_INDEX1][LOCAL_ORDER_INDEX2] = { {TEST_FORWARD, TEST_BACKWARD,TEST_RANDOM},
{TEST_FORWARD, TEST_RANDOM, TEST_BACKWARD},
{TEST_BACKWARD,TEST_FORWARD, TEST_RANDOM},
{TEST_BACKWARD,TEST_RANDOM, TEST_FORWARD},
{TEST_RANDOM, TEST_FORWARD, TEST_BACKWARD},
{TEST_RANDOM, TEST_BACKWARD,TEST_FORWARD}};
TInt whichOrder = 0;
for (iterIndex = 0; iterIndex < TestMaxLoops; iterIndex ++)
{
TInt selOrder = ((aThreadIndex + 1) * (iterIndex + 1)) % LOCAL_ORDER_INDEX1;
for (whichOrder = 0; whichOrder < LOCAL_ORDER_INDEX2; whichOrder ++)
{
switch (order[selOrder][whichOrder])
{
case TEST_FORWARD:
DEBUG_PRINT1((_L("%S : %d Iter %d Forward\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadForward();
break;
case TEST_BACKWARD:
DEBUG_PRINT1((_L("%S : %d Iter %d Backward\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadBackward();
break;
case TEST_RANDOM:
DEBUG_PRINT1((_L("%S : %d Iter %d Random\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadRandom();
break;
default: // this is really an error.
break;
}
}
}
}
else
{
if (TestWhichTests & TEST_FORWARD)
{
for (iterIndex = 0; iterIndex < TestMaxLoops; iterIndex ++)
{
DEBUG_PRINT1((_L("%S : %d Iter %d Forward\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadForward();
}
}
if (TestWhichTests & TEST_BACKWARD)
{
for (iterIndex = 0; iterIndex < TestMaxLoops; iterIndex ++)
{
DEBUG_PRINT1((_L("%S : %d Iter %d Backward\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadBackward();
}
}
if (TestWhichTests & TEST_RANDOM)
{
for (iterIndex = 0; iterIndex < TestMaxLoops; iterIndex ++)
{
DEBUG_PRINT1((_L("%S : %d Iter %d Random\n"), &TestNameBuffer, aThreadIndex, iterIndex));
RunThreadRandom();
}
}
}
DEBUG_PRINT1((_L("%S : thread Exiting %d (tickcount %u)\n"), &TestNameBuffer, aThreadIndex, User::TickCount() - start));
}
//
// MultipleTestThread
//
// Thread function, one created for each thread in a multiple thread test.
//
LOCAL_C TInt MultipleTestThread(TAny* aUseTb)
{
TBuf<64> localBuffer;
if (TestInterleave)
{
RThread thisThread;
thisThread.SetPriority((TThreadPriority) TEST_INTERLEAVE_PRIO);
}
PerformTestThread((TInt) aUseTb, &TestMsgQueue, &localBuffer, &TestMultiSem);
return KErrNone;
}
//
// DoSingleTest
//
// Perform the single thread test, spawning a number of threads.
//
LOCAL_C void DoSingleTest()
{
PerformTestThread((TInt) TestInstanceId);
}
//
// FindDriveNumber
//
// Find the first read write drive.
//
TInt FindDriveNumber(RFs fs)
{
TDriveInfo driveInfo;
for (TInt drvNum=0; drvNum<KMaxDrives; ++drvNum)
{
TInt r = fs.Drive(driveInfo, drvNum);
if (r >= 0)
{
if (driveInfo.iType == EMediaHardDisk)
return (drvNum);
}
}
return -1;
}
//
// FindFsNANDDrive
//
// Find the NAND drive
//
static TInt FindFsNANDDrive(RFs& aFs)
{
TDriveList driveList;
TDriveInfo driveInfo;
TInt r=aFs.DriveList(driveList);
if (r == KErrNone)
{
for (TInt drvNum= (DriveNumber<0)?0:DriveNumber; drvNum<KMaxDrives; ++drvNum)
{
if(!driveList[drvNum])
continue; //-- skip unexisting drive
if (aFs.Drive(driveInfo, drvNum) == KErrNone)
{
if(driveInfo.iMediaAtt&KMediaAttPageable)
{
TBool readOnly = driveInfo.iMediaAtt & KMediaAttWriteProtected; // skip ROFS partitions
if(!readOnly)
{
if ((drvNum==DriveNumber) || (DriveNumber<0)) // only test if running on this drive
{
return (drvNum);
}
}
}
}
}
}
return -1;
}
//
// FindMMCDriveNumber
//
// Find the first read write drive.
//
TInt FindMMCDriveNumber(RFs& aFs)
{
TDriveInfo driveInfo;
for (TInt drvNum=0; drvNum<KMaxDrives; ++drvNum)
{
TInt r = aFs.Drive(driveInfo, drvNum);
if (r >= 0)
{
if (driveInfo.iType == EMediaHardDisk)
return (drvNum);
}
}
return -1;
}
//
// PerformRomAndFileSystemAccess
//
// Access the rom and dump it out to one of the writeable partitions...
// really just to make the media server a little busy during the test.
//
TInt PerformRomAndFileSystemAccessThread(RMsgQueue<TBuf <64> > *aMsgQueue = NULL,
TBuf<64> *aBuffer = NULL,
RSemaphore *aTheSem = NULL)
{
TUint maxBytes = KMaxTUint;
TInt startTime = User::TickCount();
RFs fs;
RFile file;
if (KErrNone != fs.Connect())
{
DEBUG_PRINT(_L("PerformRomAndFileSystemAccessThread : Can't connect to the FS\n"));
return KErrGeneral;
}
// get info about the ROM...
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
TUint8* start;
TUint8* end;
if(romHeader->iPageableRomStart)
{
start = (TUint8*)romHeader + romHeader->iPageableRomStart;
end = start + romHeader->iPageableRomSize;
}
else
{
start = (TUint8*)romHeader;
end = start + romHeader->iUncompressedSize;
}
if (end <= start)
return KErrGeneral;
// read all ROM pages in a random order...and write out to file in ROFs,
TUint size = end - start - TestPageSize;
if(size > maxBytes)
size = maxBytes;
TUint32 random=1;
TPtrC8 rom;
TUint8 *theAddr;
TInt drvNum = TestBootedFromMmc ? FindMMCDriveNumber(fs) : FindFsNANDDrive(fs);
TBuf<32> filename = _L("d:\\Pageldrtst.tmp");
if (drvNum >= 0)
{
filename[0] = 'a' + drvNum;
DEBUG_PRINT((_L("%S : Filename %S\n"), &TestNameBuffer, &filename));
}
else
DEBUG_PRINT((_L("PerformRomAndFileSystemAccessThread : error getting drive num\n")));
for(TInt i=size/(TestPageSize); i>0; --i)
{
DEBUG_PRINT1((_L("%S : Opening the file\n"), &TestNameBuffer));
if (KErrNone != file.Replace(fs, filename, EFileWrite))
{
DEBUG_PRINT((_L("%S : Opening the file Failed!\n"), &TestNameBuffer));
}
random = random*69069+1;
theAddr = (TUint8*)(start+((TInt64(random)*TInt64(size))>>32));
if (theAddr + TestPageSize > end)
{
DEBUG_PRINT((_L("%S : address is past the end 0x%x / 0x%x\n"), &TestNameBuffer, (TInt)theAddr, (TInt)end));
}
rom.Set(theAddr,TestPageSize);
DEBUG_PRINT1((_L("%S : Writing the file\n"), &TestNameBuffer));
TInt ret = file.Write(rom);
if (ret != KErrNone)
{
DEBUG_PRINT1((_L("%S : Write returned error %d\n"), &TestNameBuffer, ret));
}
DEBUG_PRINT1((_L("%S : Closing the file\n"), &TestNameBuffer));
file.Close();
DEBUG_PRINT1((_L("%S : Deleting the file\n"), &TestNameBuffer));
ret = fs.Delete(filename);
if (KErrNone != ret)
{
DEBUG_PRINT((_L("%S : Delete returned error %d\n"), &TestNameBuffer, ret));
}
if (TestStopMedia)
break;
}
fs.Close();
DEBUG_PRINT1((_L("Done in %d ticks\n"), User::TickCount() - startTime));
return KErrNone;
}
//
// PerformRomAndFileSystemAccess
//
// Thread function, kicks off the file system access.
//
LOCAL_C TInt PerformRomAndFileSystemAccess(TAny* )
{
TBuf<64> localBuffer;
PerformRomAndFileSystemAccessThread(&TestMsgQueue, &localBuffer, &TestMultiSem);
return KErrNone;
}
//
// DoMultipleTest
//
// Perform the multiple thread test, spawning a number of threads.
// It is complicated a little because test.Printf can only be called from the first thread that calls it
// so if we are using multiple threads we need to use a message queue to pass the debug info from the
// child threads back to the parent for the parent to then call printf.
//
#define DOTEST(__operation, __condition)\
if (aLowMem) \
{\
__operation;\
while (!__condition)\
{\
Ldd.DoReleaseSomeRam(TEST_LM_BLOCKS_FREE);\
__operation;\
}\
RUNTEST1(__condition);\
}\
else\
{\
__operation;\
RUNTEST1(__condition);\
}
void DoMultipleTest(TBool aLowMem = EFalse)
{
TInt index;
RThread *pTheThreads = (RThread *)User::AllocZ(sizeof(RThread) * TestMultipleThreadCount);
TInt *pThreadInUse = (TInt *)User::AllocZ(sizeof(TInt) * TestMultipleThreadCount);
TRequestStatus mediaStatus;
RThread mediaThread;
TInt ret;
DOTEST((ret = TestMsgQueue.CreateLocal(TestMultipleThreadCount * 10, EOwnerProcess)),
(KErrNone == ret));
DOTEST((ret = TestMultiSem.CreateLocal(1)),
(KErrNone == ret));
// make sure we have a priority higher than that of the threads we spawn...
RThread thisThread;
TThreadPriority savedThreadPriority = thisThread.Priority();
const TThreadPriority KMainThreadPriority = EPriorityMuchMore;
__ASSERT_COMPILE(KMainThreadPriority>TEST_INTERLEAVE_PRIO);
thisThread.SetPriority(KMainThreadPriority);
if (TestMediaAccess)
{
TestStopMedia = EFalse;
mediaThread.Create(_L(""),PerformRomAndFileSystemAccess,KDefaultStackSize,NULL,NULL);
mediaThread.Logon(mediaStatus);
RUNTEST1(mediaStatus == KRequestPending);
mediaThread.Resume();
}
// spawn some processes to call the functions....
for (index = 0; index < TestMultipleThreadCount; index++)
{
DBGD_PRINT((_L("%S : Starting thread.%d!\n"), &TestNameBuffer, index));
DOTEST((ret = pTheThreads[index].Create(_L(""),MultipleTestThread,KDefaultStackSize,NULL,(TAny*) index)),
(ret == KErrNone));
pTheThreads[index].Resume();
pThreadInUse[index] = 1;
}
// now process any messages sent from the child threads.
TBool anyUsed = ETrue;
TBuf<64> localBuffer;
while(anyUsed)
{
anyUsed = EFalse;
// check the message queue and call printf if we get a message.
while (KErrNone == TestMsgQueue.Receive(localBuffer))
{
DBGS_PRINT((localBuffer));
}
// walk through the thread list to check which are still alive.
for (index = 0; index < TestMultipleThreadCount; index++)
{
if (pThreadInUse[index])
{
if (pTheThreads[index].ExitType() != EExitPending)
{
if (pTheThreads[index].ExitType() == EExitPanic)
{
DBGS_PRINT((_L("%S : Thread Panic'd %d...\n"), &TestNameBuffer, index));
}
pThreadInUse[index] = EFalse;
pTheThreads[index].Close();
}
else
{
anyUsed = ETrue;
}
}
}
User::AfterHighRes(50000);
}
if (TestMediaAccess)
{
TestStopMedia = ETrue;
DBGD_PRINT((_L("%S : Waiting for media thread to exit...\n"), &TestNameBuffer));
User::WaitForRequest(mediaStatus);
mediaThread.Close();
}
TestMsgQueue.Close();
TestMultiSem.Close();
// cleanup the resources and exit.
User::Free(pTheThreads);
User::Free(pThreadInUse);
thisThread.SetPriority(savedThreadPriority);
}
//
// ParseCommandLine
//
// read the arguments passed from the command line and set global variables to
// control the tests.
//
TBool ParseCommandLine()
{
TBuf<256> args;
User::CommandLine(args);
TLex lex(args);
TBool retVal = ETrue;
// initially test for arguments, the parse them, if not apply some sensible defaults.
TBool foundArgs = EFalse;
FOREVER
{
TPtrC token=lex.NextToken();
if(token.Length()!=0)
{
if ((token == _L("help")) || (token == _L("-h")) || (token == _L("-?")))
{
DBGS_PRINT((_L("\nUsage: %S [debug] [check] [single | multiple <numThreads>] [forward | backward | random | all] [iters <iters>] [media] [lowmem] [interleave]\n'-' indicated infinity.\n\n"), &TestNameBuffer));
test.Getch();
}
else if (token == _L("debug"))
{
if (!TestSilent)
{
TestDebug = ETrue;
TestPrioChange = ETrue;
}
}
else if (token == _L("silent"))
{
TestSilent = ETrue;
TestDebug = EFalse;
}
else if (token == _L("check"))
{
TestCheck = ETrue;
}
else if (token == _L("single"))
{
TestSingle = ETrue;
}
else if (token == _L("multiple"))
{
TPtrC val=lex.NextToken();
TLex lexv(val);
TInt value;
if (lexv.Val(value)==KErrNone)
{
if ((value <= 0) || (value > 100))
{
TestMultipleThreadCount = 10;
}
else
{
TestMultipleThreadCount = value;
}
}
else
{
DBGS_PRINT((_L("Bad value for thread count '%S' was ignored.\n"), &val));
retVal = EFalse;
break;
}
TestMultiple = ETrue;
}
else if (token == _L("prio"))
{
TestPrioChange = !TestPrioChange;
}
else if (token == _L("lowmem"))
{
TestLowMem = ETrue;
}
else if (token == _L("media"))
{
TestMediaAccess = ETrue;
}
else if (token == _L("forward"))
{
TestWhichTests = TEST_FORWARD;
}
else if (token == _L("backward"))
{
TestWhichTests = TEST_BACKWARD;
}
else if (token == _L("random"))
{
TestWhichTests = TEST_RANDOM;
}
else if (token == _L("all"))
{
TestWhichTests = TEST_ALL;
}
else if (token == _L("iters"))
{
TPtrC val=lex.NextToken();
TLex lexv(val);
TInt value;
if (val==_L("-"))
{
TestForever = ETrue;
TestMaxLoops = KMaxTInt;
}
else
{
if (lexv.Val(value)==KErrNone)
{
TestMaxLoops = value;
}
else
{
DBGS_PRINT((_L("Bad value for thread count '%S' was ignored.\n"), &val));
retVal = EFalse;
break;
}
}
}
else if (token == _L("interleave"))
{
TestInterleave = ETrue;
}
else if (token == _L("inst"))
{
TPtrC val=lex.NextToken();
TLex lexv(val);
TInt value;
if (lexv.Val(value)==KErrNone)
{
TestInstanceId = value;
}
}
else
{
if ((foundArgs == EFalse) && (token.Length() == 1))
{
// Single letter argument...only run on MMC drive
if (token.CompareF(_L("d")) == 0)
{
break;
}
else
{
if (!TestSilent)
{
test.Title();
test.Start(_L("Skipping non drive 'd' - Test Exiting."));
test.End();
}
foundArgs = ETrue;
TestExit = ETrue;
break;
}
}
DBGS_PRINT((_L("Unknown argument '%S' was ignored.\n"), &token));
break;
}
foundArgs = ETrue;
}
else
{
break;
}
}
if (!foundArgs)
{
retVal = EFalse;
}
return retVal;
}
//
// AreWeTheTestBase
//
// Test whether we are the root of the tests.
//
void AreWeTheTestBase(void)
{
if (!TestSilent)
{
TFileName filename(RProcess().FileName());
TParse myParse;
myParse.Set(filename, NULL, NULL);
TestNameBuffer.Zero();
TestNameBuffer.Append(myParse.Name());
TestNameBuffer.Append(_L(".exe"));
TestWeAreTheTestBase = !TestNameBuffer.Compare(_L("t_pagestress.exe"));
RFs fs;
if (KErrNone != fs.Connect())
{
TEntry anEntry;
TInt retVal = fs.Entry(_L("z:\\test\\mmcdemandpaginge32tests.bat"), anEntry);
if (retVal == KErrNone)
{
TestBootedFromMmc = ETrue;
}
else
{
TestBootedFromMmc = EFalse;
}
fs.Close();
}
}
else
{
TestNameBuffer.Zero();
TestNameBuffer.Append(_L("t_pagestress.exe"));
}
}
//
// PerformAutoTest
//
// Perform the autotest
//
void PerformAutoTest()
{
SVMCacheInfo tempPages;
if (TestIsDemandPaged)
{
UserSvr::HalFunction(EHalGroupVM,EVMHalGetCacheSize,&tempPages,0);
DBGS_PRINT((_L("PerformAutoTest : Start cache info: iMinSize %d iMaxSize %d iCurrentSize %d iMaxFreeSize %d\n"),
tempPages.iMinSize, tempPages.iMaxSize, tempPages.iCurrentSize ,tempPages.iMaxFreeSize));
}
TestInterleave = EFalse;
TestPrioChange = EFalse;
TestMediaAccess = EFalse;
#if defined __ARMCC__ || defined __X86__
// Currently we only build aligned DLLs on ARMV5 and X86 builds.
TEST_NEXT((_L("Alignment Check.")));
RUNTEST1(CheckAlignments() == KErrNone);
#endif
TestMaxLoops = 2;
TestWhichTests = TEST_RANDOM;
TEST_NEXT((_L("Single thread all.")));
DoSingleTest();
TEST_NEXT((_L("Multiple threads all.")));
DoMultipleTest();
TestPrioChange = ETrue;
TEST_NEXT((_L("Multiple threads all with prio.")));
DoMultipleTest();
TestPrioChange = EFalse;
TestMediaAccess = ETrue;
TEST_NEXT((_L("Multiple threads all with media activity.")));
DoMultipleTest();
TestPrioChange = ETrue;
TestMediaAccess = ETrue;
TEST_NEXT((_L("Multiple threads all with media activity and prio.")));
DoMultipleTest();
TestInterleave = ETrue;
TestPrioChange = EFalse;
TestMediaAccess = EFalse;
TEST_NEXT((_L("Multiple threads random with interleave.")));
DoMultipleTest();
TestPrioChange = ETrue;
TEST_NEXT((_L("Multiple threads random with interleave and prio.")));
DoMultipleTest();
TestMediaAccess = ETrue;
TEST_NEXT((_L("Multiple threads random with media interleave and prio.")));
DoMultipleTest();
if (TestIsDemandPaged)
{
UserSvr::HalFunction(EHalGroupVM,EVMHalGetCacheSize,&tempPages,0);
DBGS_PRINT((_L("PerformAutoTest : End cache info: iMinSize %d iMaxSize %d iCurrentSize %d iMaxFreeSize %d\n"),
tempPages.iMinSize, tempPages.iMaxSize, tempPages.iCurrentSize ,tempPages.iMaxFreeSize));
}
TestInterleave = EFalse;
TestPrioChange = EFalse;
TestMediaAccess = EFalse;
}
//
// DoLowMemTest
//
// Low Memory Test
//
void DoLowMemTest()
{
TInt r = User::LoadLogicalDevice(KPageStressTestLddName);
RUNTEST1(r==KErrNone || r==KErrAlreadyExists);
RUNTEST(Ldd.Open(),KErrNone);
SVMCacheInfo tempPages;
memset(&tempPages, 0, sizeof(tempPages));
if (TestIsDemandPaged)
{
// get the old cache info
UserSvr::HalFunction(EHalGroupVM,EVMHalGetCacheSize,&tempPages,0);
TInt minSize = 8 * 4096;
TInt maxSize = 256 * 4096;
UserSvr::HalFunction(EHalGroupVM,EVMHalSetCacheSize,(TAny*)minSize,(TAny*)maxSize);
}
// First load some pages onto the page cache
TestMaxLoops = 1;
TestWhichTests = TEST_RANDOM;
DoSingleTest();
Ldd.DoConsumeRamSetup(TEST_LM_NUM_FREE, TEST_LM_BLOCKSIZE);
TEST_NEXT((_L("Single thread with Low memory.")));
TestMultipleThreadCount = 25;
TestInterleave = EFalse;
TestMaxLoops = 20;
TestPrioChange = EFalse;
TestMediaAccess = EFalse;
TestWhichTests = TEST_ALL;
DoSingleTest();
Ldd.DoConsumeRamFinish();
TEST_NEXT((_L("Multiple thread with Low memory.")));
// First load some pages onto the page cache
TestMaxLoops = 1;
TestWhichTests = TEST_RANDOM;
DoSingleTest();
Ldd.DoConsumeRamSetup(TEST_LM_NUM_FREE, TEST_LM_BLOCKSIZE);
TestWhichTests = TEST_ALL;
TestMaxLoops = 10;
TestMultipleThreadCount = 25;
DoMultipleTest(ETrue);
Ldd.DoConsumeRamFinish();
TEST_NEXT((_L("Multiple thread with Low memory, with starting free ram.")));
// First load some pages onto the page cache
TestMaxLoops = 1;
TestWhichTests = TEST_RANDOM;
DoSingleTest();
Ldd.DoConsumeRamSetup(32, TEST_LM_BLOCKSIZE);
TestWhichTests = TEST_ALL;
TestMaxLoops = 10;
TestMultipleThreadCount = 25;
DoMultipleTest(ETrue);
Ldd.DoConsumeRamFinish();
TEST_NEXT((_L("Close test driver")));
Ldd.Close();
RUNTEST(User::FreeLogicalDevice(KPageStressTestLddName), KErrNone);
if (TestIsDemandPaged)
{
TInt minSize = tempPages.iMinSize;
TInt maxSize = tempPages.iMaxSize;
UserSvr::HalFunction(EHalGroupVM,EVMHalSetCacheSize,(TAny*)minSize,(TAny*)maxSize);
}
}
//
// E32Main
//
// Main entry point.
//
TInt E32Main()
{
#ifndef TEST_ON_UNPAGED
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
if(!romHeader->iPageableRomStart)
{
TestIsDemandPaged = EFalse;
}
#endif
TUint start = User::TickCount();
TBool parseResult = ParseCommandLine();
if (TestExit)
{
return KErrNone;
}
AreWeTheTestBase();
TInt minSize = 8 * 4096;
TInt maxSize = 64 * 4096;
SVMCacheInfo tempPages;
memset(&tempPages, 0, sizeof(tempPages));
if (TestIsDemandPaged)
{
// get the old cache info
UserSvr::HalFunction(EHalGroupVM,EVMHalGetCacheSize,&tempPages,0);
// set the cache to our test value
UserSvr::HalFunction(EHalGroupVM,EVMHalSetCacheSize,(TAny*)minSize,(TAny*)maxSize);
}
// get the page size.
UserSvr::HalFunction(EHalGroupKernel,EKernelHalPageSizeInBytes,&TestPageSize,0);
if (!TestSilent)
{
test.Title();
test.Start(_L("Demand Paging stress tests..."));
test.Printf(_L("%S\n"), &TestNameBuffer);
}
if (parseResult)
{
if (!TestSilent)
{
extern TInt *CheckLdmiaInstr(void);
test.Printf(_L("%S : CheckLdmiaInstr\n"), &TestNameBuffer);
TInt *theAddr = CheckLdmiaInstr();
test.Printf(_L("%S : CheckLdmiaInstr complete 0x%x...\n"), &TestNameBuffer, (TInt)theAddr);
}
if (TestCheck)
{
CheckAlignments();
}
if (TestLowMem)
{
DoLowMemTest();
}
if (TestSingle)
{
DoSingleTest();
}
if (TestMultiple)
{
DoMultipleTest();
}
}
else
{
PerformAutoTest();
DoLowMemTest();
if (TestWeAreTheTestBase)
{
RProcess theProcess;
TRequestStatus status;
TInt retVal = theProcess.Create(_L("t_pagestress_rom.exe"),_L(""));
if (retVal != KErrNotFound)
{
RUNTEST1(retVal == KErrNone);
theProcess.Logon(status);
RUNTEST1(status == KRequestPending);
theProcess.Resume();
User::WaitForRequest(status);
if (theProcess.ExitType() != EExitPending)
{
RUNTEST1(theProcess.ExitType() != EExitPanic);
}
}
}
}
if (TestIsDemandPaged)
{
minSize = tempPages.iMinSize;
maxSize = tempPages.iMaxSize;
// put the cache back to the the original values.
UserSvr::HalFunction(EHalGroupVM,EVMHalSetCacheSize,(TAny*)minSize,(TAny*)maxSize);
}
if (!TestSilent)
{
test.Printf(_L("%S : Complete (%u ticks)\n"), &TestNameBuffer, User::TickCount() - start);
test.End();
}
return 0;
}