// 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:
// e32\e32test\demandpaging\d_pagingexample_1_post.cpp
// Demand paging migration example device driver d_pagingexample_1_post: a DLogicalChannel-dervied
// driver, post-migration
//
//
#include "d_pagingexample.h"
#include <kernel/kernel.h>
#include <kernel/kern_priv.h>
const TInt KDfcQThreadPriority = 25;
const TInt KBufferSize = KMaxTransferSize;
//
// Logical channel
//
class DExampleChannel : public DLogicalChannel
{
public:
typedef RPagingExample::TConfigData TConfigData;
typedef RPagingExample::TValueStruct TValueStruct;
public:
DExampleChannel();
~DExampleChannel();
virtual TInt DoCreate(TInt aUnit, const TDesC8* anInfo, const TVersion& aVer);
virtual TInt SendMsg(TMessageBase* aMsg);
TInt SendControl(TMessageBase* aMsg);
TInt SendRequest(TMessageBase* aMsg);
virtual void HandleMsg(TMessageBase* aMsg);
TInt DoControl(TInt aFunction, TAny* a1, TAny* a2);
void DoRequest(TInt aFunction, TRequestStatus* aStatus, TAny* a1, TAny* a2);
TInt DoCancel(TUint aMask);
private:
TDfcQue* DfcQ();
void Shutdown();
void SetConfig(const TConfigData&);
TInt PreNotify(TRequestStatus* aStatus);
void StartNotify();
TInt PreAsyncGetValue(TInt* aValue, TRequestStatus* aStatus);
void StartAsyncGetValue();
TInt PreAsyncGetValue2(TInt* aValue1, TInt* aValue2, TRequestStatus* aStatus);
void StartAsyncGetValue2();
TInt PreRead(TAny* aBuffer, TInt aLength, TRequestStatus* aStatus);
void StartRead();
TInt PreReadDes(TDes8* aDesOut, TRequestStatus* aStatus);
void StartReadDes();
TInt PreWrite(TAny* aBuffer, TInt aLength, TRequestStatus* aStatus);
void StartWrite();
TInt PreWriteDes(const TDesC8* aDesIn, TRequestStatus* aStatus);
void StartWriteDes();
void ReceiveToReadBuffer();
void SendFromWriteBuffer();
static void AsyncGetValueCompleteDfcFunc(TAny* aPtr);
static void AsyncGetValue2CompleteDfcFunc(TAny* aPtr);
static void ReceiveCompleteDfcFunc(TAny* aPtr);
static void SendCompleteDfcFunc(TAny* aPtr);
void CompleteNotify();
void CompleteAsyncGetValue();
void CompleteAsyncGetValue2();
void CompleteRead();
void CompleteWrite();
private:
TDynamicDfcQue* iDynamicDfcQ;
TConfigData iConfig;
DThread* iClient;
// Notify
TClientRequest* iNotifyRequest;
// Async get value
TClientDataRequest<TValueStruct>* iAsyncGetValueRequest;
NTimer iAsyncGetValueTimer;
TDfc iAsyncGetValueDfc;
// Async get value 2
TClientDataRequest2<TInt,TInt>* iAsyncGetValue2Request;
NTimer iAsyncGetValue2Timer;
TDfc iAsyncGetValue2Dfc;
// Read
TClientBufferRequest* iReadRequest;
NTimer iReadTimer;
TClientBuffer* iClientReadBuffer;
TDfc iCompleteReadDfc;
// Write
TClientBufferRequest* iWriteRequest;
NTimer iWriteTimer;
TClientBuffer* iClientWriteBuffer;
TDfc iCompleteWriteDfc;
TUint8 iBuffer[KBufferSize];
};
DExampleChannel::DExampleChannel() :
iAsyncGetValueTimer(NULL, this),
iAsyncGetValueDfc(AsyncGetValueCompleteDfcFunc, this, 0),
iAsyncGetValue2Timer(NULL, this),
iAsyncGetValue2Dfc(AsyncGetValue2CompleteDfcFunc, this, 0),
iReadTimer(NULL, this),
iCompleteReadDfc(ReceiveCompleteDfcFunc, this, 0),
iWriteTimer(NULL, this),
iCompleteWriteDfc(SendCompleteDfcFunc, this, 0)
{
iClient = &Kern::CurrentThread();
iClient->Open();
}
DExampleChannel::~DExampleChannel()
{
Kern::SafeClose((DObject*&)iClient, NULL);
if (iDynamicDfcQ)
iDynamicDfcQ->Destroy();
Kern::DestroyClientRequest(iNotifyRequest);
Kern::DestroyClientRequest(iAsyncGetValueRequest);
Kern::DestroyClientRequest(iAsyncGetValue2Request);
Kern::DestroyClientBufferRequest(iReadRequest);
Kern::DestroyClientBufferRequest(iWriteRequest);
}
TDfcQue* DExampleChannel::DfcQ()
{
return iDynamicDfcQ;
}
TInt DExampleChannel::DoCreate(TInt /*aUnit*/, const TDesC8* /*aInfo*/, const TVersion& /*aVer*/)
{
TInt r;
r = Kern::CreateClientRequest(iNotifyRequest);
if (r != KErrNone)
return r;
r = Kern::CreateClientDataRequest(iAsyncGetValueRequest);
if (r != KErrNone)
return r;
r = Kern::CreateClientDataRequest2(iAsyncGetValue2Request);
if (r != KErrNone)
return r;
r = Kern::CreateClientBufferRequest(iReadRequest, 1, TClientBufferRequest::EPinVirtual);
if (r != KErrNone)
return r;
r = Kern::CreateClientBufferRequest(iWriteRequest, 1, TClientBufferRequest::EPinVirtual);
if (r != KErrNone)
return r;
// create a dynamic DFC queue, which is used for handling client messages and for our own DFCs
r = Kern::DynamicDfcQCreate(iDynamicDfcQ, KDfcQThreadPriority, KPagingExample1PostLdd);
if (r != KErrNone)
return r;
// todo: this will be the default anyway
iDynamicDfcQ->SetRealtimeState(ERealtimeStateOn);
SetDfcQ(DfcQ());
iAsyncGetValueDfc.SetDfcQ(DfcQ());
iAsyncGetValue2Dfc.SetDfcQ(DfcQ());
iCompleteReadDfc.SetDfcQ(DfcQ());
iCompleteWriteDfc.SetDfcQ(DfcQ());
iMsgQ.Receive();
return KErrNone;
}
// override SendMsg method to allow pinning data in the context of the client thread
TInt DExampleChannel::SendMsg(TMessageBase* aMsg)
{
TThreadMessage& m=*(TThreadMessage*)aMsg;
TInt id = m.iValue;
// we only support one client
if (id != (TInt)ECloseMsg && m.Client() != iClient)
return KErrAccessDenied;
TInt r = KErrNone;
if (id != (TInt)ECloseMsg && id != KMaxTInt)
{
if (id<0)
{
TRequestStatus* pS=(TRequestStatus*)m.Ptr0();
r = SendRequest(aMsg);
if (r != KErrNone)
Kern::RequestComplete(pS,r);
}
else
r = SendControl(aMsg);
}
else
r = DLogicalChannel::SendMsg(aMsg);
return r;
}
void DExampleChannel::HandleMsg(TMessageBase* aMsg)
{
TThreadMessage& m=*(TThreadMessage*)aMsg;
TInt id=m.iValue;
if (id==(TInt)ECloseMsg)
{
Shutdown();
m.Complete(KErrNone,EFalse);
return;
}
else if (id==KMaxTInt)
{
// DoCancel
DoCancel(m.Int0());
m.Complete(KErrNone,ETrue);
return;
}
else if (id<0)
{
// DoRequest
TRequestStatus* pS=(TRequestStatus*)m.Ptr0();
DoRequest(~id,pS,m.Ptr1(),m.Ptr2());
m.Complete(KErrNone,ETrue);
}
else
{
// DoControl
TInt r=DoControl(id,m.Ptr0(),m.Ptr1());
m.Complete(r,ETrue);
}
}
TInt DExampleChannel::SendControl(TMessageBase* aMsg)
{
TThreadMessage& m=*(TThreadMessage*)aMsg;
TInt id=m.iValue;
// thread-local copy of configuration data
TConfigData kernelConfigBuffer;
TAny* userConfigPtr = m.Ptr0();
switch (id)
{
case RPagingExample::ESetConfig:
// copy config from client to local buffer in context of client thread
umemget32(&kernelConfigBuffer, userConfigPtr, sizeof(TConfigData));
// update message to point to kernel-side buffer
m.iArg[0] = &kernelConfigBuffer;
break;
case RPagingExample::EGetConfig:
// update message to point to kernel-side buffer
m.iArg[0] = &kernelConfigBuffer;
break;
}
TInt r = DLogicalChannel::SendMsg(aMsg);
if (r != KErrNone)
return r;
switch (id)
{
case RPagingExample::EGetConfig:
// copy config from local bufferto client in context of client thread
umemput32(userConfigPtr, &kernelConfigBuffer, sizeof(TConfigData));
break;
}
return r;
}
TInt DExampleChannel::DoControl(TInt aFunction,TAny* a1,TAny* /*a2*/)
{
TInt r = KErrNone;
TConfigData* configBuffer = (TConfigData*)a1;
switch (aFunction)
{
case RPagingExample::EGetConfig:
// copy current config into local buffer in context of DFC thread to avoid potential race conditions
*configBuffer = iConfig;
break;
case RPagingExample::ESetConfig:
// set config from copy in local buffer in context of DFC thread to avoid potential race conditions
SetConfig(*configBuffer);
break;
default:
r = KErrNotSupported;
}
return r;
}
TInt DExampleChannel::SendRequest(TMessageBase* aMsg)
{
TThreadMessage& m=*(TThreadMessage*)aMsg;
TInt function = ~m.iValue;
TRequestStatus* pS=(TRequestStatus*)m.Ptr0();
TAny* a1 = m.Ptr1();
TAny* a2 = m.Ptr2();
TInt r = KErrNotSupported;
switch (function)
{
case RPagingExample::ERequestNotify:
r = PreNotify(pS);
break;
case RPagingExample::ERequestAsyncGetValue:
r = PreAsyncGetValue((TInt*)a1, pS);
break;
case RPagingExample::ERequestAsyncGetValue2:
r = PreAsyncGetValue2((TInt*)a1, (TInt*)a2, pS);
break;
case RPagingExample::ERequestRead:
r = PreRead(a1, (TInt)a2, pS);
break;
case RPagingExample::ERequestReadDes:
r = PreReadDes((TDes8*)a1, pS);
break;
case RPagingExample::ERequestWrite:
r = PreWrite(a1, (TInt)a2, pS);
break;
case RPagingExample::ERequestWriteDes:
r = PreWriteDes((TDes8*)a1, pS);
break;
}
if (r == KErrNone)
r = DLogicalChannel::SendMsg(aMsg);
return r;
}
void DExampleChannel::DoRequest(TInt aFunction, TRequestStatus* /*aStatus*/, TAny* /*a1*/, TAny* /*a2*/)
{
switch (aFunction)
{
case RPagingExample::ERequestNotify:
StartNotify();
break;
case RPagingExample::ERequestAsyncGetValue:
StartAsyncGetValue();
break;
case RPagingExample::ERequestAsyncGetValue2:
StartAsyncGetValue2();
break;
case RPagingExample::ERequestRead:
StartRead();
break;
case RPagingExample::ERequestReadDes:
StartReadDes();
break;
case RPagingExample::ERequestWrite:
StartWrite();
break;
case RPagingExample::ERequestWriteDes:
StartWriteDes();
break;
default:
__NK_ASSERT_ALWAYS(EFalse); // we already validated the request number
}
}
TInt DExampleChannel::DoCancel(TUint /*aMask*/)
{
if (iAsyncGetValueRequest->IsReady())
{
iAsyncGetValueTimer.Cancel();
iAsyncGetValueDfc.Cancel();
Kern::QueueRequestComplete(iClient, iAsyncGetValueRequest, KErrCancel);
}
if (iAsyncGetValue2Request->IsReady())
{
iAsyncGetValue2Timer.Cancel();
iAsyncGetValue2Dfc.Cancel();
Kern::QueueRequestComplete(iClient, iAsyncGetValue2Request, KErrCancel);
}
if (iReadRequest->IsReady())
{
iReadTimer.Cancel();
iCompleteReadDfc.Cancel();
Kern::QueueBufferRequestComplete(iClient, iReadRequest, KErrCancel);
}
if (iWriteRequest->IsReady())
{
iWriteTimer.Cancel();
iCompleteWriteDfc.Cancel();
Kern::QueueBufferRequestComplete(iClient, iWriteRequest, KErrCancel);
}
return KErrNone;
}
void DExampleChannel::Shutdown()
{
}
void DExampleChannel::SetConfig(const TConfigData& aNewConfig)
{
iConfig = aNewConfig;
}
TInt DExampleChannel::PreNotify(TRequestStatus* aStatus)
{
return iNotifyRequest->SetStatus(aStatus);
}
void DExampleChannel::StartNotify()
{
CompleteNotify(); // example implementation completes the request immediately
}
void DExampleChannel::CompleteNotify()
{
Kern::QueueRequestComplete(iClient, iNotifyRequest, KErrNone);
}
TInt DExampleChannel::PreAsyncGetValue(TInt* aValue, TRequestStatus* aStatus)
{
TInt r = iAsyncGetValueRequest->SetStatus(aStatus);
if (r != KErrNone)
return r;
iAsyncGetValueRequest->SetDestPtr(aValue);
return KErrNone;
}
void DExampleChannel::StartAsyncGetValue()
{
// queue a timer to simulate an asynchronous operation
iAsyncGetValueTimer.OneShot(KAsyncDelay, iAsyncGetValueDfc);
}
void DExampleChannel::AsyncGetValueCompleteDfcFunc(TAny* aPtr)
{
DExampleChannel* self = (DExampleChannel*)aPtr;
self->CompleteAsyncGetValue();
}
void DExampleChannel::CompleteAsyncGetValue()
{
iAsyncGetValueRequest->Data().iValue1 = 1;
iAsyncGetValueRequest->Data().iValue2 = _L8("shrt");
Kern::QueueRequestComplete(iClient, iAsyncGetValueRequest, KErrNone);
}
TInt DExampleChannel::PreAsyncGetValue2(TInt* aValue1, TInt* aValue2, TRequestStatus* aStatus)
{
TInt r = iAsyncGetValue2Request->SetStatus(aStatus);
if (r != KErrNone)
return r;
iAsyncGetValue2Request->SetDestPtr1(aValue1);
iAsyncGetValue2Request->SetDestPtr2(aValue2);
return KErrNone;
}
void DExampleChannel::StartAsyncGetValue2()
{
// queue a timer to simulate an asynchronous operation
iAsyncGetValue2Timer.OneShot(KAsyncDelay, iAsyncGetValue2Dfc);
}
void DExampleChannel::AsyncGetValue2CompleteDfcFunc(TAny* aPtr)
{
DExampleChannel* self = (DExampleChannel*)aPtr;
self->CompleteAsyncGetValue2();
}
void DExampleChannel::CompleteAsyncGetValue2()
{
iAsyncGetValue2Request->Data1() = 1;
iAsyncGetValue2Request->Data2() = 2;
Kern::QueueRequestComplete(iClient, iAsyncGetValue2Request, KErrNone);
}
TInt DExampleChannel::PreRead(TAny* aBuffer, TInt aLength, TRequestStatus* aStatus)
{
// check length argument first
if (aLength < 1 || aLength > KBufferSize)
return KErrArgument;
// start request setup
TInt r = iReadRequest->StartSetup(aStatus);
if (r != KErrNone)
return r;
// add client buffer, this does pinning in context of client thread
r = iReadRequest->AddBuffer(iClientReadBuffer, (TLinAddr)aBuffer, aLength, ETrue);
if (r != KErrNone)
return KErrNoMemory;
iReadRequest->EndSetup();
return KErrNone;
}
void DExampleChannel::StartRead()
{
ReceiveToReadBuffer(); // called in DFC thread as may require serialised access to hardware
}
TInt DExampleChannel::PreReadDes(TDes8* aDesOut, TRequestStatus* aStatus)
{
// start request setup
TInt r = iReadRequest->StartSetup(aStatus);
if (r != KErrNone)
return r;
// add client descriptor, this does pinning in context of client thread
r = iReadRequest->AddBuffer(iClientReadBuffer, aDesOut);
if (r != KErrNone)
return r;
// can check length argument here
TInt length = iClientReadBuffer->MaxLength();
if (length < 1 || length > KBufferSize)
{
// need to reset object so it can be reused
iReadRequest->Reset();
return KErrArgument;
}
iReadRequest->EndSetup();
return KErrNone;
}
void DExampleChannel::StartReadDes()
{
ReceiveToReadBuffer(); // called in DFC thread as may require serialised access to hardware
}
TInt DExampleChannel::PreWrite(TAny* aBuffer, TInt aLength, TRequestStatus* aStatus)
{
// check length argument first
if (aLength < 1 || aLength > KBufferSize)
return KErrArgument;
// demonstrate use the single-buffer version of Setup
return iWriteRequest->Setup(iClientWriteBuffer, aStatus, (TLinAddr)aBuffer, aLength);
}
void DExampleChannel::StartWrite()
{
SendFromWriteBuffer(); // called in DFC thread as may require serialised access to hardware
}
TInt DExampleChannel::PreWriteDes(const TDesC8* aDesIn, TRequestStatus* aStatus)
{
// demonstrate use the single-buffer version of Setup
TInt r = iWriteRequest->Setup(iClientWriteBuffer, aStatus, (TAny*)aDesIn);
if (r != KErrNone)
return r;
// can check length argument here
TInt length = iClientWriteBuffer->Length();
if (length < 1 || length > KBufferSize)
{
// need to reset object so it can be reused
iWriteRequest->Reset();
return KErrArgument;
}
return KErrNone;
}
void DExampleChannel::StartWriteDes()
{
SendFromWriteBuffer(); // called in DFC thread as may require serialised access to hardware
}
void DExampleChannel::ReceiveToReadBuffer()
{
// just queue a timer to simulate an asynchronous receive operation
// actually will return the previous contents of the buffer
iReadTimer.OneShot(KAsyncDelay, iCompleteReadDfc);
}
void DExampleChannel::SendFromWriteBuffer()
{
// just queue a timer to simulate an asynchronous send operation
iWriteTimer.OneShot(KAsyncDelay, iCompleteWriteDfc);
}
void DExampleChannel::ReceiveCompleteDfcFunc(TAny* aPtr)
{
DExampleChannel* self = (DExampleChannel*)aPtr;
self->CompleteRead();
}
void DExampleChannel::SendCompleteDfcFunc(TAny* aPtr)
{
DExampleChannel* self = (DExampleChannel*)aPtr;
self->CompleteWrite();
}
void DExampleChannel::CompleteRead()
{
TPtrC8 des(iBuffer, iClientReadBuffer->MaxLength());
TInt r = Kern::ThreadBufWrite(iClient, iClientReadBuffer, des, 0, KChunkShiftBy0, iClient);
Kern::QueueBufferRequestComplete(iClient, iReadRequest, r);
}
void DExampleChannel::CompleteWrite()
{
TPtr8 des(iBuffer, iClientWriteBuffer->Length());
TInt r = Kern::ThreadBufRead(iClient, iClientWriteBuffer, des, 0, KChunkShiftBy0);
Kern::QueueBufferRequestComplete(iClient, iWriteRequest, r);
}
//
// Logical device
//
class DExampleFactory : public DLogicalDevice
{
public:
DExampleFactory();
virtual TInt Install();
virtual void GetCaps(TDes8& aDes) const;
virtual TInt Create(DLogicalChannelBase*& aChannel);
};
DExampleFactory::DExampleFactory()
{
iParseMask = 0;
iVersion = TVersion(1, 0, 0);
}
TInt DExampleFactory::Install()
{
return SetName(&KPagingExample1PostLdd);
}
void DExampleFactory::GetCaps(TDes8& /*aDes*/) const
{
// not used but required as DLogicalDevice::GetCaps is pure virtual
}
TInt DExampleFactory::Create(DLogicalChannelBase*& aChannel)
{
aChannel = new DExampleChannel;
return aChannel ? KErrNone : KErrNoMemory;
}
DECLARE_STANDARD_LDD()
{
return new DExampleFactory;
}