// Copyright (c) 2003-2009 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\d_sharedio.cpp
// LDD for testing SharedIoBuffers
//
//
#include <kernel/kern_priv.h>
#include "d_sharedio.h"
//
// LDD factory
//
class DSharedIoTestFactory : public DLogicalDevice
{
public:
DSharedIoTestFactory();
~DSharedIoTestFactory();
virtual TInt Install();
virtual void GetCaps(TDes8& aDes) const;
virtual TInt Create(DLogicalChannelBase*& aChannel);
public:
DSharedIoBuffer* iGlobalBuffer;
};
//
// Logical Channel
//
class DSharedIoTest : public DLogicalChannelBase
{
public:
virtual ~DSharedIoTest();
protected:
virtual TInt DoCreate(TInt aUnit, const TDesC8* anInfo, const TVersion& aVer);
virtual TInt Request(TInt aFunction, TAny* a1, TAny* a2);
public:
DSharedIoBuffer* iIoBuffer;
DSharedIoBuffer* iGlobalBuffer;
DSharedIoTestFactory* iFactory;
#ifndef __WINS__
TPhysAddr iPhysAddress;
#endif
};
//
// LDD factory
//
DSharedIoTestFactory::DSharedIoTestFactory()
{
iGlobalBuffer=NULL;
}
DSharedIoTestFactory::~DSharedIoTestFactory()
{
delete iGlobalBuffer;
}
TInt DSharedIoTestFactory::Create(DLogicalChannelBase*& aChannel)
{
__KTRACE_OPT(KMMU,Kern::Printf(">DSharedIoTestFactory::Create iGlobalBuffer=%x",iGlobalBuffer));
if(!iGlobalBuffer)
{
#ifdef __WINS__
TUint aAttribs=0;
#else
TUint aAttribs=EMapAttrSupRw | EMapAttrFullyBlocking;
#endif
TInt r=DSharedIoBuffer::New(iGlobalBuffer,KSizeGlobalBuffer,aAttribs);
if(r!=KErrNone)
return r;
}
aChannel=new DSharedIoTest;
if(!aChannel)
return KErrNoMemory;
((DSharedIoTest*)aChannel)->iGlobalBuffer=iGlobalBuffer;
((DSharedIoTest*)aChannel)->iFactory=this;
__KTRACE_OPT(KMMU,Kern::Printf("<DSharedIoTestFactory::Create iGlobalBuffer=%x",iGlobalBuffer));
return KErrNone;
}
TInt DSharedIoTestFactory::Install()
{
return SetName(&KSharedIoTestLddName);
}
void DSharedIoTestFactory::GetCaps(TDes8& /* aDes */) const
{
//aDes.FillZ(aDes.MaxLength());
}
DECLARE_STANDARD_LDD()
{
return new DSharedIoTestFactory;
}
//
// Logical Channel
//
TInt DSharedIoTest::DoCreate(TInt /*aUnit*/, const TDesC8* /*aInfo*/, const TVersion& /*aVer*/)
{
return KErrNone;
}
DSharedIoTest::~DSharedIoTest()
{
delete iIoBuffer;
}
TInt checkBuffer(TAny* buffer, TUint32 aSize, TUint32 key)
{
TInt r=KErrNone;
TUint8* m=(TUint8*)buffer;
for(TUint32 size=0;size<aSize;size++,key+=5,m++)
{
if(*m!=(TUint8)(key%256))
{
r=KErrCorrupt;
break;
}
}
return r;
}
TInt fillBuffer(TAny* buffer, TUint32 aSize, TUint32 key)
{
TUint8* m=(TUint8*)buffer;
for(TUint32 size=0;size<aSize;size++,key+=5,m++)
{
*m=(TUint8)(key%256);
}
return KErrNone;
}
static void AppendNumToBuf(TDes8& aDes, const TDesC& aNum, TInt width, char fill)
{
TInt l = aNum.Length();
for (; l < width; ++l)
aDes.Append(TChar(fill));
aDes.Append(aNum);
}
static void DumpMemory(TUint8* aStart, TInt aSize)
{
TBuf8<80> line;
TBuf8<24> val;
TChar space(' ');
TInt i = (TInt)aStart & 0xF; // first byte in this line to dump
TInt n = 16; // end byte in this line
while (aSize > 0)
{
if (i + aSize < 16)
n = i + aSize;
val.Num((TUint32)aStart & ~0xF, EHex);
AppendNumToBuf(line, val, 8, '0');
line.Append(space);
line.Append(space);
TInt j;
for (j = 0; j < i; ++j)
{
line.Append(space);
line.Append(space);
line.Append(space);
if (j == 7) line.Append(space);
}
for (; j < n; ++j)
{
val.Num(aStart[j-i], EHex);
line.Append(space);
AppendNumToBuf(line, val, 2, '0');
if (j == 7) line.Append(space);
}
for (; j < 16; ++j)
{
line.Append(space);
line.Append(space);
line.Append(space);
if (j == 7) line.Append(space);
}
line.Append(space);
line.Append(space);
for (j = 0; j < i; ++j)
line.Append(space);
for (; j < n; ++j)
{
char c = aStart[j-i];
if (c < ' ' || c > 126) c = '.';
line.Append(TChar(c));
}
Kern::Printf("%S", &line);
line.SetLength(0);
aStart += (n - i);
aSize -= (n - i);
i = 0;
}
}
TBool CheckMemCleared(TLinAddr aAddress, TInt aSize)
{
TUint8* aPtr = (TUint8*)aAddress;
for(TInt i = 0; i<aSize; i++)
{
if(aPtr[i] != 0x03)
{
Kern::Printf("CheckMemCleared(0x%x, %d) failed at i = 0x%x", aAddress, aSize, i);
// Start on current line & ~0xF, run for 16 lines x 16 bytes
TUint8 *p = (TUint8*)((aAddress + i) & ~0x0F);
TInt n = 256;
if (p < aPtr) p = aPtr;
if (p - aPtr > aSize - n) // if (p + n > aPtr + aSize) rearranged (to avoid overflow)
n = aPtr + aSize - p;
DumpMemory(p, n);
return EFalse;
}
}
return ETrue;
}
TInt DSharedIoTest::Request(TInt aFunction, TAny* a1, TAny* a2)
{
TInt r=KErrNone;
switch (aFunction)
{
case RTestLdd::ECreateBuffer:
{
TUint32 size = (TUint32)a1;
r = KErrNoMemory;
#ifdef __WINS__
TUint aAttribs1=0;
TUint aAttribs2=0;
TUint aAttribs3=0;
#else
TUint aAttribs1=EMapAttrSupRw | EMapAttrBufferedNC;
TUint aAttribs2=EMapAttrSupRw | EMapAttrFullyBlocking;
TUint aAttribs3=EMapAttrSupRw | EMapAttrCachedMax;
#endif
NKern::ThreadEnterCS();
r=DSharedIoBuffer::New(iIoBuffer,size,aAttribs1);
if(r!=KErrNone)
{
Kern::Printf("Error creating buffer r=%d\n",r);
NKern::ThreadLeaveCS();
return r;
}
//Check the buffer is properly initialized (the previous content
//deleted by inserting all 0x03s)
if (!CheckMemCleared(iIoBuffer->iAddress, iIoBuffer->iSize))
{
Kern::Printf("Error memory zeroing test for shared io buffers");
NKern::ThreadLeaveCS();
return KErrCorrupt;
}
//just test that we can construct a second shared buffer
DSharedIoBuffer* ptr;
r=DSharedIoBuffer::New(ptr,size,aAttribs2);
if(r!=KErrNone)
{
Kern::Printf("Error creating the 2nd buffer r=%d\n",r);
delete iIoBuffer;
iIoBuffer=NULL;
NKern::ThreadLeaveCS();
return r;
}
delete ptr; //creation successfull, simply delete the object
// and the third one, this time fully cached.
r=DSharedIoBuffer::New(ptr,size,aAttribs3);
if(r!=KErrNone)
{
Kern::Printf("Error creating the 3rd buffer r=%d\n",r);
delete iIoBuffer;
iIoBuffer=NULL;
NKern::ThreadLeaveCS();
return r;
}
delete ptr; //creation successfull, simply delete the object
NKern::ThreadLeaveCS();
if(iIoBuffer->iSize!=size) // test
{
Kern::Printf("Error checking size iIoBuffer->iSize=%d size=%d\n",iIoBuffer->iSize,size);
return KErrGeneral;
}
memset((void*)iIoBuffer->iAddress,0,size);
}
return r;
case RTestLdd::EMapInGlobalBuffer:
{
if(!iGlobalBuffer)
return KErrGeneral;
TUint id;
kumemget32(&id,a1,sizeof(TUint));
NKern::ThreadEnterCS();
Kern::Containers()[EProcess]->Wait();
DProcess* process=Kern::ProcessFromId(id);
if(process)
process->Open();
Kern::Containers()[EProcess]->Signal();
if(process)
{
r=iGlobalBuffer->UserMap(process);
process->Close(0);
}
else
r = KErrGeneral;
NKern::ThreadLeaveCS();
if(r!=KErrNone)
return r;
if(iGlobalBuffer->UserToKernel(iGlobalBuffer->iUserAddress,iGlobalBuffer->iSize)!=iGlobalBuffer->iAddress)
return KErrGeneral;
if(iGlobalBuffer->UserToKernel(iGlobalBuffer->iUserAddress,iGlobalBuffer->iSize+1)!=NULL)
return KErrGeneral;
if(iGlobalBuffer->KernelToUser(iGlobalBuffer->iAddress)!=iGlobalBuffer->iUserAddress)
return KErrGeneral;
kumemput32(a1,&iGlobalBuffer->iUserAddress,sizeof(TAny*));
kumemput32(a2,&iGlobalBuffer->iSize,sizeof(TInt));
return KErrNone;
}
case RTestLdd::EMapOutGlobalBuffer:
{
if(!iGlobalBuffer)
return KErrGeneral;
r=iGlobalBuffer->UserUnmap();
if(r==KErrNone)
if(iGlobalBuffer->iUserProcess)
r = KErrGeneral;
return r;
}
case RTestLdd::EDestroyGlobalBuffer:
{
NKern::ThreadEnterCS();
delete iGlobalBuffer;
iGlobalBuffer = NULL;
iFactory->iGlobalBuffer=NULL;
NKern::ThreadLeaveCS();
return KErrNone;
}
case RTestLdd::ECreateBufferPhysAddr:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TUint32 size=Kern::RoundToPageSize(1);
NKern::ThreadEnterCS();
r=Epoc::AllocPhysicalRam(size,iPhysAddress);
Kern::Printf("phys addr = %X!\n",iPhysAddress);
if(r!=KErrNone)
{
NKern::ThreadLeaveCS();
return r;
}
r = KErrNoMemory;
//test that we can construct a fully cached sharedio
DSharedIoBuffer* ptr;
r=DSharedIoBuffer::New(ptr,iPhysAddress,size,EMapAttrSupRw|EMapAttrCachedMax);
if(r!=KErrNone)
{
Kern::Printf("Error creating the physical cached buffer r=%d\n",r);
Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return r;
}
delete ptr; //creation successfull, simply delete the object
r=DSharedIoBuffer::New(iIoBuffer,iPhysAddress,size,EMapAttrSupRw|EMapAttrFullyBlocking);
if(r!=KErrNone)
{
Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return r;
}
if(iIoBuffer->iSize!=size) // test
{
delete iIoBuffer;
iIoBuffer=NULL;
Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return KErrGeneral;
}
fillBuffer((TAny*)iIoBuffer->iAddress,size,180);
DPlatChunkHw* hwChunk;
r=DPlatChunkHw::New(hwChunk, iPhysAddress, size, EMapAttrSupRw|EMapAttrFullyBlocking);
if(r!=KErrNone)
{
delete iIoBuffer;
iIoBuffer=NULL;
Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return r;
}
r=checkBuffer((TAny*)hwChunk->LinearAddress(),size,180);
if(r!=KErrNone)
{
delete iIoBuffer;
iIoBuffer=NULL;
hwChunk->Close(NULL);
Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return r;
}
hwChunk->Close(NULL);
NKern::ThreadLeaveCS();
return r;
#endif
}
case RTestLdd::EDestroyBufferPhysAddr:
{
#ifdef __WINS__
return KErrNotSupported;
#else
TUint32 size=Kern::RoundToPageSize(1);
NKern::ThreadEnterCS();
delete iIoBuffer;
iIoBuffer = NULL;
r=Epoc::FreePhysicalRam(iPhysAddress,size);
iPhysAddress=0;
NKern::ThreadLeaveCS();
return r;
#endif
}
case RTestLdd::EMapInBuffer:
{
r=iIoBuffer->UserMap(&Kern::CurrentProcess());
if(r!=KErrNone)
return r;
TAny** p = (TAny**)iIoBuffer->iAddress;
TAny* ua = (TAny*)iIoBuffer->iUserAddress;
TAny** end = (TAny**)((TInt)p+iIoBuffer->iSize);
while(p<end)
{
*p++ = ua;
ua = (TAny*)((TInt)ua+sizeof(TAny*));
}
if(iIoBuffer->UserToKernel(iIoBuffer->iUserAddress,iIoBuffer->iSize)!=iIoBuffer->iAddress)
return KErrGeneral;
if(iIoBuffer->UserToKernel(iIoBuffer->iUserAddress,iIoBuffer->iSize+1)!=NULL)
return KErrGeneral;
if(iIoBuffer->KernelToUser(iIoBuffer->iAddress)!=iIoBuffer->iUserAddress)
return KErrGeneral;
kumemput32(a1,&iIoBuffer->iUserAddress,sizeof(TAny*));
kumemput32(a2,&iIoBuffer->iSize,sizeof(TInt));
return r;
}
case RTestLdd::EMapOutBuffer:
{
r=iIoBuffer->UserUnmap();
if(r==KErrNone)
if(iIoBuffer->iUserProcess)
r = KErrGeneral;
return r;
}
case RTestLdd::EDestroyBuffer:
NKern::ThreadEnterCS();
delete iIoBuffer;
iIoBuffer = NULL;
NKern::ThreadLeaveCS();
return KErrNone;
case RTestLdd::ECheckBuffer:
if(!iIoBuffer->iAddress || !iIoBuffer->iUserAddress || !iIoBuffer->iUserProcess)
return KErrGeneral;
return checkBuffer((TAny*)iIoBuffer->iAddress,iIoBuffer->iSize,(TUint32)a1);
case RTestLdd::EFillBuffer:
if(!iIoBuffer->iAddress || !iIoBuffer->iUserAddress || !iIoBuffer->iUserProcess)
return KErrGeneral;
return fillBuffer((TAny*)iIoBuffer->iAddress,iIoBuffer->iSize,(TUint32)a1);
case RTestLdd::EThreadRW:
{
TInt dummy;
TPckg<TInt> a(dummy);
DThread* pT;
if((TInt)a2==-1)
{
pT=&Kern::CurrentThread();
}
else
{
NKern::ThreadEnterCS();
DObjectCon* pC=Kern::Containers()[EThread];
pC->Wait();
pT=Kern::ThreadFromId((TInt)a2);
pC->Signal();
if(!pT)
return KErrNotFound;
NKern::ThreadLeaveCS();
}
r=Kern::ThreadDesRead(pT,a1,a,0,KChunkShiftBy0);
if(r!=KErrNone)
return r;
if(dummy!=KMagic1)
return KErrCorrupt;
dummy=KMagic2;
r=Kern::ThreadDesWrite(pT,a1,a,0,KChunkShiftBy0,&Kern::CurrentThread());
if(r!=KErrNone)
return r;
return KErrNone;
}
default:
r=KErrNotSupported;
break;
}
return r;
}