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) 2008-2009 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\demandpaging\t_pagingexample.cpp
// Test device driver migration examples
//
//
#define __E32TEST_EXTENSION__
#include <e32test.h>
#include <dptest.h>
#include <e32hal.h>
#include <u32exec.h>
#include <e32svr.h>
#include <e32panic.h>
#include <e32rom.h>
#include <e32kpan.h>
#include "../mmu/t_codepaging_dll.h"
#include "d_pagingexample.h"
const TInt KBufferSize = KMaxTransferSize;
_LIT(KTCodePagingDll4, "t_codepaging_dll4.dll");
struct TTestData
{
TRequestStatus iStatus;
RPagingExample::TConfigData iConfig;
RPagingExample::TValueStruct iValue;
TInt iIntValue1;
TInt iIntValue2;
TPtr8 iPtr;
TUint8 iBuffer[KBufferSize];
public:
TTestData() : iPtr(NULL, 0) { }
};
RTest test(_L("T_PAGINGEXAMPLE"));
TInt PageSize = 0;
RLibrary PagedLibrary;
TTestData* UnpagedInputData = NULL;
TTestData* UnpagedOutputData = NULL;
TTestData* PagedInputData = NULL;
TTestData* PagedOutputData = NULL;
void InitInputData(TTestData* aData)
{
aData->iConfig.iParam1 = 2;
aData->iConfig.iParam2 = 3;
aData->iConfig.iParam3 = 5;
aData->iConfig.iParam4 = 7;
for (TInt i = 0 ; i < KBufferSize ; ++i)
aData->iBuffer[i] = (TUint8)(i + 123);
}
void DoTestDriver(const TDesC& aDriverName, const TTestData* aInputData, TTestData* aOutputData)
{
test.Start(_L("Load logical device"));
TInt r = User::LoadLogicalDevice(aDriverName);
test(r==KErrNone || r==KErrAlreadyExists);
test.Next(_L("Open logical device"));
RPagingExample ldd;
test_KErrNone(ldd.Open(aDriverName));
test.Next(_L("Set config"));
DPTest::FlushCache();
test_KErrNone(ldd.SetConfig(aInputData->iConfig));
test.Next(_L("Get config"));
Mem::FillZ(&aOutputData->iConfig, sizeof(RPagingExample::TConfigData));
DPTest::FlushCache();
test_KErrNone(ldd.GetConfig(aOutputData->iConfig));
test_Equal(0, Mem::Compare((TUint8*)&aInputData->iConfig, sizeof(RPagingExample::TConfigData),
(TUint8*)&aOutputData->iConfig, sizeof(RPagingExample::TConfigData)));
TRequestStatus& status = aOutputData->iStatus;
test.Next(_L("Notify"));
DPTest::FlushCache();
ldd.Notify(status);
DPTest::FlushCache();
User::WaitForRequest(status);
test_Equal(KErrNone, status.Int());
test.Next(_L("Async get value"));
memclr(&aOutputData->iValue, sizeof(RPagingExample::TValueStruct));
DPTest::FlushCache();
ldd.AsyncGetValue(status, aOutputData->iValue);
DPTest::FlushCache();
User::WaitForRequest(status);
test_Equal(KErrNone, status.Int());
test_Equal(1, aOutputData->iValue.iValue1);
test(aOutputData->iValue.iValue2 == _L8("shrt"));
test.Next(_L("Cancel async get value"));
ldd.AsyncGetValue(status, aOutputData->iValue);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Async get value 2"));
aOutputData->iIntValue1 = 0;
aOutputData->iIntValue2 = 0;
DPTest::FlushCache();
ldd.AsyncGetValue2(status, aOutputData->iIntValue1, aOutputData->iIntValue2);
DPTest::FlushCache();
User::WaitForRequest(status);
test_Equal(KErrNone, status.Int());
test_Equal(1, aOutputData->iIntValue1);
test_Equal(2, aOutputData->iIntValue2);
test.Next(_L("Cancel async get value 2"));
ldd.AsyncGetValue2(status, aOutputData->iIntValue1, aOutputData->iIntValue2);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Write buffer too short"));
ldd.Write(status, NULL, 0);
User::WaitForRequest(status);
test_Equal(KErrArgument, status.Int());
test.Next(_L("Write buffer too long"));
ldd.Write(status, NULL, KMaxTransferSize + 1);
User::WaitForRequest(status);
test_Equal(KErrArgument, status.Int());
test.Next(_L("Write"));
DPTest::FlushCache();
ldd.Write(status, aInputData->iBuffer, KBufferSize);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
test.Next(_L("Cancel write"));
ldd.Write(status, aInputData->iBuffer, KBufferSize);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Read buffer too short"));
ldd.Read(status, NULL, 0);
User::WaitForRequest(status);
test_Equal(KErrArgument, status.Int());
test.Next(_L("Read buffer too long"));
ldd.Read(status, NULL, KMaxTransferSize + 1);
User::WaitForRequest(status);
test_Equal(KErrArgument, status.Int());
test.Next(_L("Read"));
Mem::FillZ(aOutputData->iBuffer, KBufferSize);
DPTest::FlushCache();
ldd.Read(status, aOutputData->iBuffer, KBufferSize);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
test_Equal(0, Mem::Compare(aInputData->iBuffer, KBufferSize,
aOutputData->iBuffer, KBufferSize));
test.Next(_L("Cancel read"));
ldd.Read(status, aOutputData->iBuffer, KBufferSize);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Cancel nothing"));
ldd.Cancel();
test.Next(_L("Write while write pending"));
TRequestStatus status2;
ldd.Write(status, aInputData->iBuffer, KBufferSize);
ldd.Write(status2, aInputData->iBuffer, KBufferSize);
User::WaitForRequest(status);
test_KErrNone(status.Int());
User::WaitForRequest(status2);
test_Equal(KErrInUse, status2.Int());
test.Next(_L("Read while read pending"));
ldd.Read(status, aOutputData->iBuffer, KBufferSize);
ldd.Read(status2, aOutputData->iBuffer, KBufferSize);
User::WaitForRequest(status);
test_KErrNone(status.Int());
User::WaitForRequest(status2);
test_Equal(KErrInUse, status2.Int());
test.Next(_L("Write des"));
TPtrC8 writeDes(aInputData->iBuffer + 1, KBufferSize - 1);
DPTest::FlushCache();
ldd.WriteDes(status, writeDes);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
test.Next(_L("Cancel write des"));
ldd.WriteDes(status, writeDes);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Read des"));
TPtr8 readDes(aOutputData->iBuffer, KBufferSize - 1);
Mem::FillZ(aOutputData->iBuffer, KBufferSize);
DPTest::FlushCache();
ldd.ReadDes(status, readDes);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
test(readDes == writeDes);
test.Next(_L("Read des 2")); // has paged header but unpaged contnet, if output data is paged
aOutputData->iPtr.Set(UnpagedOutputData->iBuffer, 0, KBufferSize - 1);
Mem::FillZ(UnpagedOutputData->iBuffer, KBufferSize);
DPTest::FlushCache();
ldd.ReadDes(status, aOutputData->iPtr);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
test(aOutputData->iPtr == writeDes);
test.Next(_L("Cancel read des"));
ldd.ReadDes(status, readDes);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
test.Next(_L("Read and write at the same time"));
ldd.Write(status, aInputData->iBuffer, KBufferSize);
ldd.Read(status2, aOutputData->iBuffer, KBufferSize);
DPTest::FlushCache();
User::WaitForRequest(status);
test_KErrNone(status.Int());
User::WaitForRequest(status2);
test_KErrNone(status2.Int());
test.Next(_L("Cancel read and write"));
ldd.Write(status, aInputData->iBuffer, KBufferSize);
ldd.Read(status2, aOutputData->iBuffer, KBufferSize);
ldd.Cancel();
User::WaitForRequest(status);
test_Equal(KErrCancel, status.Int());
User::WaitForRequest(status2);
test_Equal(KErrCancel, status2.Int());
test.Next(_L("Close and free logical device"));
ldd.Close();
test_KErrNone(User::FreeLogicalDevice(aDriverName));
test.End();
}
void TestDriver(const TDesC& aDriverName, TBool aMigrated)
{
TBuf<64> string;
string.Format(_L("Testing driver %S"), &aDriverName);
test.Next(string);
test.Start(_L("Test reading from unpaged memory and writing to unpaged memory"));
DoTestDriver(aDriverName, UnpagedInputData, UnpagedOutputData);
if (aMigrated && PagedInputData)
{
if (PagedOutputData)
{
test.Next(_L("Test reading from paged memory and writing to paged memory"));
DoTestDriver(aDriverName, PagedInputData, PagedOutputData);
}
else
{
test.Next(_L("Test reading from paged memory and writing to unpaged memory"));
DoTestDriver(aDriverName, PagedInputData, UnpagedOutputData);
}
}
// todo: test pinning failures
test.End();
}
enum TTestAction
{
ETestRequestComplete,
ETestRawRead,
ETestRawWrite,
ETestDesRead,
ETestDesWrite
};
enum TTestAccess
{
EAccessUnpaged,
EAccessPaged
};
enum TTestOutcome
{
EOutcomeSuccess,
EOutcomeRealtimePanic
};
TInt RealtimeTestFunc(TAny* aArg)
{
TTestAction action = (TTestAction)((TUint)aArg & 255);
TTestAccess access = (TTestAccess)((TUint)aArg >> 8);
TTestData* inputData = access == EAccessPaged ? PagedInputData : UnpagedInputData;
TTestData* outputData = access == EAccessPaged ? PagedOutputData : UnpagedOutputData;
RPagingExample ldd;
TInt r = ldd.Open(KPagingExample1PreLdd);
if (r != KErrNone)
return r;
ldd.SetDfcThreadRealtimeState(ETrue);
TRequestStatus unpagedStatus;
TRequestStatus* status = &unpagedStatus;
switch(action)
{
case ETestRequestComplete:
{
RDebug::Printf("Test RequestComplete");
status = &outputData->iStatus;
RPagingExample::TValueStruct value;
DPTest::FlushCache();
ldd.AsyncGetValue(*status, value);
DPTest::FlushCache();
}
break;
case ETestRawRead:
RDebug::Printf("Test ThreadRawRead");
ldd.Write(*status, inputData->iBuffer, KBufferSize);
DPTest::FlushCache();
break;
case ETestRawWrite:
RDebug::Printf("Test ThreadRawWrite");
ldd.Read(*status, outputData->iBuffer, KBufferSize);
DPTest::FlushCache();
break;
case ETestDesRead:
{
RDebug::Printf("Test ThreadDesRead");
TPtrC8 writeDes(inputData->iBuffer, KBufferSize);
ldd.WriteDes(*status, writeDes);
DPTest::FlushCache();
}
break;
case ETestDesWrite:
{
RDebug::Printf("Test ThreadDesWrite");
TPtr8 readDes(outputData->iBuffer, KBufferSize);
ldd.ReadDes(*status, readDes);
DPTest::FlushCache();
}
break;
default:
return KErrArgument;
}
User::WaitForAnyRequest();
r = status->Int();
ldd.Close();
return r;
}
void RunRealtimeTestThread(TTestAction aTestAction, TTestAccess aAccess, TTestOutcome aExpectedOutcome)
{
RThread thread;
TUint arg = aTestAction | (aAccess << 8);
test_KErrNone(thread.Create(KNullDesC, RealtimeTestFunc, 4096, NULL, (TAny*)arg));
TRequestStatus status;
thread.Logon(status);
thread.Resume();
User::WaitForRequest(status);
switch (aExpectedOutcome)
{
case EOutcomeSuccess:
test_Equal(EExitKill, thread.ExitType());
test_Equal(KErrNone, thread.ExitReason());
break;
case EOutcomeRealtimePanic:
test_Equal(EExitPanic, thread.ExitType());
test_Equal(EIllegalFunctionForRealtimeThread, thread.ExitReason());
break;
default:
test(EFalse);
}
CLOSE_AND_WAIT(thread);
}
void TestPagedAccessInRealtimeThread()
{
// Test driver access to paged memory from realtime DFC thread. This can happen if a client
// passes paged memory to a driver that doesn't expect it, and has set its realtime state to
// enfore this. The client should be panicked in this case.
test.Start(_L("Test memory access from realtime threads"));
test.Next(_L("Load logical device"));
TInt r = User::LoadLogicalDevice(KPagingExample1PreLdd);
test(r==KErrNone || r==KErrAlreadyExists);
test.Next(_L("Test access to unpaged memory from realtime thread"));
RunRealtimeTestThread(ETestRequestComplete, EAccessUnpaged, EOutcomeSuccess);
RunRealtimeTestThread(ETestRawRead, EAccessUnpaged, EOutcomeSuccess);
RunRealtimeTestThread(ETestRawWrite, EAccessUnpaged, EOutcomeSuccess);
RunRealtimeTestThread(ETestDesRead, EAccessUnpaged, EOutcomeSuccess);
RunRealtimeTestThread(ETestDesWrite, EAccessUnpaged, EOutcomeSuccess);
test.Next(_L("Test access to paged memory from realtime thread"));
if (PagedInputData)
{
RunRealtimeTestThread(ETestRawRead, EAccessPaged, EOutcomeRealtimePanic);
RunRealtimeTestThread(ETestDesRead, EAccessPaged, EOutcomeRealtimePanic);
}
if (PagedOutputData)
{
RunRealtimeTestThread(ETestRequestComplete, EAccessPaged, EOutcomeRealtimePanic);
RunRealtimeTestThread(ETestRawWrite, EAccessPaged, EOutcomeRealtimePanic);
RunRealtimeTestThread(ETestDesWrite, EAccessPaged, EOutcomeRealtimePanic);
}
test.Next(_L("Close and free logical device"));
test_KErrNone(User::FreeLogicalDevice(KPagingExample1PreLdd));
test.End();
}
TInt E32Main()
{
test.Title();
test.Start(_L("Test device driver migration examples"));
UnpagedInputData = (TTestData*)User::Alloc(sizeof(TTestData));
test_NotNull(UnpagedInputData);
UnpagedOutputData = (TTestData*)User::Alloc(sizeof(TTestData));
test_NotNull(UnpagedOutputData);
test_KErrNone(UserSvr::HalFunction(EHalGroupKernel,EKernelHalPageSizeInBytes,&PageSize,0));
RChunk chunk;
if (DPTest::Attributes() & DPTest::EDataPaging)
{
TChunkCreateInfo info;
TInt size = (sizeof(TTestData) + PageSize - 1) & ~(PageSize - 1);
info.SetNormal(size, size);
info.SetPaging(TChunkCreateInfo::EPaged);
test_KErrNone(chunk.Create(info));
test(chunk.IsPaged());
PagedOutputData = (TTestData*)chunk.Base();
test.Printf(_L("Using data pagd output buffer at %08x\n"), PagedOutputData);
}
if (DPTest::Attributes() & DPTest::ERomPaging)
{
// use paged part of rom for read-only data
TRomHeader* romHeader = (TRomHeader*)UserSvr::RomHeaderAddress();
test(romHeader->iPageableRomStart);
// todo: for some reason the first part of page of paged rom doesn't seem to get paged out
// when we flush the paging cache, hence PagedInputData starts some way into this
PagedInputData = (TTestData*)((TUint8*)romHeader + romHeader->iPageableRomStart + 64 * PageSize);
TInt romDataSize = romHeader->iPageableRomSize - 64 * PageSize;
test(romDataSize >= (TInt)sizeof(TTestData));
test.Printf(_L("Using rom paged input data at %08x\n"), PagedInputData);
}
else if (DPTest::Attributes() & DPTest::ECodePaging)
{
// use code paged DLL for read-only buffer
test_KErrNone(PagedLibrary.Load(KTCodePagingDll4));
TGetAddressOfDataFunction func = (TGetAddressOfDataFunction)PagedLibrary.Lookup(KGetAddressOfDataFunctionOrdinal);
TInt codeDataSize;
PagedInputData = (TTestData*)func(codeDataSize);
test_NotNull(PagedInputData);
test(codeDataSize >= (TInt)sizeof(TTestData));
test.Printf(_L("Using code paged input data at %08x\n"), PagedInputData);
}
InitInputData(UnpagedInputData);
TestDriver(KPagingExample1PreLdd, EFalse);
TestDriver(KPagingExample1PostLdd, ETrue);
TestDriver(KPagingExample2PreLdd, EFalse);
TestDriver(KPagingExample2PostLdd, ETrue);
TestPagedAccessInRealtimeThread();
PagedLibrary.Close();
User::Free(UnpagedInputData);
User::Free(UnpagedOutputData);
test.End();
return 0;
}