Convert Kernelhwsrv package from SFL to EPL
kernel\eka\compsupp is subject to the ARM EABI LICENSE
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// Copyright (c) 2002-2009 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\dma\dmasim.cpp
// DMA framework Platform Specific Layer (PSL) for software-emulated
// DMA controller used for testing the DMA framework PIL.
//
//
#include <drivers/dma.h>
#include <kernel/kern_priv.h>
const char KDmaPanicCat[] = "DMASIM";
const TInt KMaxTransferSize = 0x1FFF;
const TInt KMemAlignMask = 3; // memory addresses passed to DMAC must be multiple of 4
const TInt KBurstSize = 0x800;
typedef void (*TPseudoIsr)();
const TInt KChannelCount = 4; // # of channels per controller
const TInt KDesCount = 256; // # of descriptors allocated per controller
//////////////////////////////////////////////////////////////////////////////
// SOFTWARE DMA CONTROLLER SIMULATION
//////////////////////////////////////////////////////////////////////////////
class DmacSb
/** Single-buffer DMA controller software simulation */
{
public:
enum { ECsRun = 0x80000000 };
public:
static void DoTransfer();
private:
static void BurstTransfer();
private:
static TInt CurrentChannel;
public:
// pseudo registers
static TUint8* SrcAddr[KChannelCount];
static TUint8* DestAddr[KChannelCount];
static TInt Count[KChannelCount];
static TUint32 ControlStatus[KChannelCount];
static TUint32 CompletionInt;
static TUint32 ErrorInt;
// hook for pseudo ISR
static TPseudoIsr Isr;
// transfer failure simulation
static TInt FailCount[KChannelCount];
};
TUint8* DmacSb::SrcAddr[KChannelCount];
TUint8* DmacSb::DestAddr[KChannelCount];
TInt DmacSb::Count[KChannelCount];
TUint32 DmacSb::ControlStatus[KChannelCount];
TUint32 DmacSb::CompletionInt;
TUint32 DmacSb::ErrorInt;
TPseudoIsr DmacSb::Isr;
TInt DmacSb::FailCount[KChannelCount];
TInt DmacSb::CurrentChannel;
void DmacSb::DoTransfer()
{
if (ControlStatus[CurrentChannel] & ECsRun)
{
if (FailCount[CurrentChannel] > 0 && --FailCount[CurrentChannel] == 0)
{
ControlStatus[CurrentChannel] &= ~ECsRun;
ErrorInt |= 1 << CurrentChannel;
Isr();
}
else
{
//__KTRACE_OPT(KDMA, Kern::Printf("DmacSb::DoTransfer channel %d", CurrentChannel));
if (Count[CurrentChannel] == 0)
{
//__KTRACE_OPT(KDMA, Kern::Printf("DmacSb::DoTransfer transfer complete"));
ControlStatus[CurrentChannel] &= ~ECsRun;
CompletionInt |= 1 << CurrentChannel;
Isr();
}
else
BurstTransfer();
}
}
CurrentChannel++;
if (CurrentChannel >= KChannelCount)
CurrentChannel = 0;
}
void DmacSb::BurstTransfer()
{
//__KTRACE_OPT(KDMA, Kern::Printf("DmacSb::BurstTransfer"));
TInt s = Min(Count[CurrentChannel], KBurstSize);
memcpy(DestAddr[CurrentChannel], SrcAddr[CurrentChannel], s);
Count[CurrentChannel] -= s;
SrcAddr[CurrentChannel] += s;
DestAddr[CurrentChannel] += s;
}
//////////////////////////////////////////////////////////////////////////////
class DmacDb
/** Double-buffer DMA controller software simulation */
{
public:
enum { ECsRun = 0x80000000, ECsPrg = 0x40000000 };
public:
static void Enable(TInt aIdx);
static void DoTransfer();
private:
static TInt CurrentChannel;
private:
// internal pseudo-registers
static TUint8* ActSrcAddr[KChannelCount];
static TUint8* ActDestAddr[KChannelCount];
static TInt ActCount[KChannelCount];
public:
// externally accessible pseudo-registers
static TUint32 ControlStatus[KChannelCount];
static TUint8* PrgSrcAddr[KChannelCount];
static TUint8* PrgDestAddr[KChannelCount];
static TInt PrgCount[KChannelCount];
static TUint32 CompletionInt;
static TUint32 ErrorInt;
// hook for pseudo ISR
static TPseudoIsr Isr;
// transfer failure simulation
static TInt FailCount[KChannelCount];
static TInt InterruptsToMiss[KChannelCount];
};
TUint8* DmacDb::PrgSrcAddr[KChannelCount];
TUint8* DmacDb::PrgDestAddr[KChannelCount];
TInt DmacDb::PrgCount[KChannelCount];
TUint8* DmacDb::ActSrcAddr[KChannelCount];
TUint8* DmacDb::ActDestAddr[KChannelCount];
TInt DmacDb::ActCount[KChannelCount];
TUint32 DmacDb::ControlStatus[KChannelCount];
TUint32 DmacDb::CompletionInt;
TUint32 DmacDb::ErrorInt;
TPseudoIsr DmacDb::Isr;
TInt DmacDb::FailCount[KChannelCount];
TInt DmacDb::InterruptsToMiss[KChannelCount];
TInt DmacDb::CurrentChannel;
void DmacDb::Enable(TInt aIdx)
{
if (ControlStatus[aIdx] & ECsRun)
ControlStatus[aIdx] |= ECsPrg;
else
{
ActSrcAddr[aIdx] = PrgSrcAddr[aIdx];
ActDestAddr[aIdx] = PrgDestAddr[aIdx];
ActCount[aIdx] = PrgCount[aIdx];
ControlStatus[aIdx] |= ECsRun;
}
}
void DmacDb::DoTransfer()
{
if (ControlStatus[CurrentChannel] & ECsRun)
{
if (FailCount[CurrentChannel] > 0 && --FailCount[CurrentChannel] == 0)
{
ControlStatus[CurrentChannel] &= ~ECsRun;
ErrorInt |= 1 << CurrentChannel;
Isr();
}
else
{
if (ActCount[CurrentChannel] == 0)
{
if (ControlStatus[CurrentChannel] & ECsPrg)
{
ActSrcAddr[CurrentChannel] = PrgSrcAddr[CurrentChannel];
ActDestAddr[CurrentChannel] = PrgDestAddr[CurrentChannel];
ActCount[CurrentChannel] = PrgCount[CurrentChannel];
ControlStatus[CurrentChannel] &= ~ECsPrg;
}
else
ControlStatus[CurrentChannel] &= ~ECsRun;
if (InterruptsToMiss[CurrentChannel] > 0)
InterruptsToMiss[CurrentChannel]--;
else
{
CompletionInt |= 1 << CurrentChannel;
Isr();
}
}
else
{
TInt s = Min(ActCount[CurrentChannel], KBurstSize);
memcpy(ActDestAddr[CurrentChannel], ActSrcAddr[CurrentChannel], s);
ActCount[CurrentChannel] -= s;
ActSrcAddr[CurrentChannel] += s;
ActDestAddr[CurrentChannel] += s;
}
}
}
CurrentChannel++;
if (CurrentChannel >= KChannelCount)
CurrentChannel = 0;
}
//////////////////////////////////////////////////////////////////////////////
class DmacSg
/** Scatter/gather DMA controller software simulation */
{
public:
enum { EChannelBitRun = 0x80000000 };
enum { EDesBitInt = 1 };
struct SDes
{
TUint8* iSrcAddr;
TUint8* iDestAddr;
TInt iCount;
TUint iControl;
SDes* iNext;
};
public:
static void DoTransfer();
static void Enable(TInt aIdx);
private:
static TInt CurrentChannel;
static TBool IsDescriptorLoaded[KChannelCount];
public:
// externally accessible pseudo-registers
static TUint32 ChannelControl[KChannelCount];
static TUint8* SrcAddr[KChannelCount];
static TUint8* DestAddr[KChannelCount];
static TInt Count[KChannelCount];
static TUint Control[KChannelCount];
static SDes* NextDes[KChannelCount];
static TUint32 CompletionInt;
static TUint32 ErrorInt;
// hook for pseudo ISR
static TPseudoIsr Isr;
// transfer failure simulation
static TInt FailCount[KChannelCount];
static TInt InterruptsToMiss[KChannelCount];
};
TUint32 DmacSg::ChannelControl[KChannelCount];
TUint8* DmacSg::SrcAddr[KChannelCount];
TUint8* DmacSg::DestAddr[KChannelCount];
TInt DmacSg::Count[KChannelCount];
TUint DmacSg::Control[KChannelCount];
DmacSg::SDes* DmacSg::NextDes[KChannelCount];
TUint32 DmacSg::CompletionInt;
TUint32 DmacSg::ErrorInt;
TPseudoIsr DmacSg::Isr;
TInt DmacSg::FailCount[KChannelCount];
TInt DmacSg::InterruptsToMiss[KChannelCount];
TInt DmacSg::CurrentChannel;
TBool DmacSg::IsDescriptorLoaded[KChannelCount];
void DmacSg::DoTransfer()
{
if (ChannelControl[CurrentChannel] & EChannelBitRun)
{
if (FailCount[CurrentChannel] > 0 && --FailCount[CurrentChannel] == 0)
{
ChannelControl[CurrentChannel] &= ~EChannelBitRun;
ErrorInt |= 1 << CurrentChannel;
Isr();
}
else
{
if (IsDescriptorLoaded[CurrentChannel])
{
if (Count[CurrentChannel] == 0)
{
IsDescriptorLoaded[CurrentChannel] = EFalse;
if (Control[CurrentChannel] & EDesBitInt)
{
if (InterruptsToMiss[CurrentChannel] > 0)
InterruptsToMiss[CurrentChannel]--;
else
{
CompletionInt |= 1 << CurrentChannel;
Isr();
}
}
}
else
{
TInt s = Min(Count[CurrentChannel], KBurstSize);
memcpy(DestAddr[CurrentChannel], SrcAddr[CurrentChannel], s);
Count[CurrentChannel] -= s;
SrcAddr[CurrentChannel] += s;
DestAddr[CurrentChannel] += s;
}
}
// Need to test again as new descriptor must be loaded if
// completion has just occured.
if (! IsDescriptorLoaded[CurrentChannel])
{
if (NextDes[CurrentChannel] != NULL)
{
SrcAddr[CurrentChannel] = NextDes[CurrentChannel]->iSrcAddr;
DestAddr[CurrentChannel] = NextDes[CurrentChannel]->iDestAddr;
Count[CurrentChannel] = NextDes[CurrentChannel]->iCount;
Control[CurrentChannel] = NextDes[CurrentChannel]->iControl;
NextDes[CurrentChannel] = NextDes[CurrentChannel]->iNext;
IsDescriptorLoaded[CurrentChannel] = ETrue;
}
else
ChannelControl[CurrentChannel] &= ~EChannelBitRun;
}
}
}
CurrentChannel++;
if (CurrentChannel >= KChannelCount)
CurrentChannel = 0;
}
void DmacSg::Enable(TInt aIdx)
{
SrcAddr[aIdx] = NextDes[aIdx]->iSrcAddr;
DestAddr[aIdx] = NextDes[aIdx]->iDestAddr;
Count[aIdx] = NextDes[aIdx]->iCount;
Control[aIdx] = NextDes[aIdx]->iControl;
NextDes[aIdx] = NextDes[aIdx]->iNext;
IsDescriptorLoaded[aIdx] = ETrue;
ChannelControl[aIdx] |= EChannelBitRun;
}
//////////////////////////////////////////////////////////////////////////////
class DmacSim
/**
Harness calling the various DMA controller simulators periodically.
*/
{
public:
static void StartEmulation();
static void StopEmulation();
private:
enum { KPeriod = 1 }; // in ms
static void TickCB(TAny* aThis);
static NTimer Timer;
};
NTimer DmacSim::Timer;
void DmacSim::StartEmulation()
{
new (&Timer) NTimer(&TickCB, 0);
__DMA_ASSERTA(Timer.OneShot(KPeriod, EFalse) == KErrNone);
}
void DmacSim::StopEmulation()
{
Timer.Cancel();
}
void DmacSim::TickCB(TAny*)
{
DmacSb::DoTransfer();
DmacDb::DoTransfer();
DmacSg::DoTransfer();
__DMA_ASSERTA(Timer.Again(KPeriod) == KErrNone);
}
//////////////////////////////////////////////////////////////////////////////
// PSL FOR DMA SIMULATION
//////////////////////////////////////////////////////////////////////////////
class DSimSbController : public TDmac
{
public:
DSimSbController();
private:
static void Isr();
// from TDmac
virtual void Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr);
virtual void StopTransfer(const TDmaChannel& aChannel);
virtual TInt FailNext(const TDmaChannel& aChannel);
virtual TBool IsIdle(const TDmaChannel& aChannel);
virtual TInt MaxTransferSize(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
virtual TUint MemAlignMask(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
public:
static const SCreateInfo KInfo;
TDmaSbChannel iChannels[KChannelCount];
};
DSimSbController SbController;
const TDmac::SCreateInfo DSimSbController::KInfo =
{
KChannelCount,
KDesCount,
0,
sizeof(SDmaPseudoDes),
0,
};
DSimSbController::DSimSbController()
: TDmac(KInfo)
{
DmacSb::Isr = Isr;
}
void DSimSbController::Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr)
{
TUint32 i = aChannel.PslId();
const SDmaPseudoDes& des = HdrToDes(aHdr);
DmacSb::SrcAddr[i] = (TUint8*) des.iSrc;
DmacSb::DestAddr[i] = (TUint8*) des.iDest;
DmacSb::Count[i] = des.iCount;
DmacSb::ControlStatus[i] |= DmacSb::ECsRun;
}
void DSimSbController::StopTransfer(const TDmaChannel& aChannel)
{
__e32_atomic_and_ord32(&DmacSb::ControlStatus[aChannel.PslId()], (TUint32)~DmacSb::ECsRun);
}
TInt DSimSbController::FailNext(const TDmaChannel& aChannel)
{
DmacSb::FailCount[aChannel.PslId()] = 1;
return KErrNone;
}
TBool DSimSbController::IsIdle(const TDmaChannel& aChannel)
{
return (DmacSb::ControlStatus[aChannel.PslId()] & DmacSb::ECsRun) == 0;
}
TInt DSimSbController::MaxTransferSize(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMaxTransferSize;
}
TUint DSimSbController::MemAlignMask(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMemAlignMask;
}
void DSimSbController::Isr()
{
for (TInt i = 0; i < KChannelCount; i++)
{
TUint32 mask = (1 << i);
if (DmacSb::CompletionInt & mask)
{
DmacSb::CompletionInt &= ~mask;
HandleIsr(SbController.iChannels[i], ETrue);
}
if (DmacSb::ErrorInt & mask)
{
DmacSb::ErrorInt &= ~mask;
HandleIsr(SbController.iChannels[i], EFalse);
}
}
}
//////////////////////////////////////////////////////////////////////////////
class DSimDbController : public TDmac
{
public:
DSimDbController();
private:
static void Isr();
// from TDmac
virtual void Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr);
virtual void StopTransfer(const TDmaChannel& aChannel);
virtual TInt FailNext(const TDmaChannel& aChannel);
virtual TInt MissNextInterrupts(const TDmaChannel& aChannel, TInt aInterruptCount);
virtual TBool IsIdle(const TDmaChannel& aChannel);
virtual TInt MaxTransferSize(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
virtual TUint MemAlignMask(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
public:
static const SCreateInfo KInfo;
TDmaDbChannel iChannels[KChannelCount];
};
DSimDbController DbController;
const TDmac::SCreateInfo DSimDbController::KInfo =
{
KChannelCount,
KDesCount,
0,
sizeof(SDmaPseudoDes),
0,
};
DSimDbController::DSimDbController()
: TDmac(KInfo)
{
DmacDb::Isr = Isr;
}
void DSimDbController::Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr)
{
TUint32 i = aChannel.PslId();
const SDmaPseudoDes& des = HdrToDes(aHdr);
DmacDb::PrgSrcAddr[i] = (TUint8*) des.iSrc;
DmacDb::PrgDestAddr[i] = (TUint8*) des.iDest;
DmacDb::PrgCount[i] = des.iCount;
DmacDb::Enable(i);
}
void DSimDbController::StopTransfer(const TDmaChannel& aChannel)
{
__e32_atomic_and_ord32(&DmacDb::ControlStatus[aChannel.PslId()], (TUint32)~(DmacDb::ECsRun|DmacDb::ECsPrg));
}
TInt DSimDbController::FailNext(const TDmaChannel& aChannel)
{
DmacDb::FailCount[aChannel.PslId()] = 1;
return KErrNone;
}
TInt DSimDbController::MissNextInterrupts(const TDmaChannel& aChannel, TInt aInterruptCount)
{
__DMA_ASSERTD((DmacDb::ControlStatus[aChannel.PslId()] & DmacDb::ECsRun) == 0);
__DMA_ASSERTD(aInterruptCount >= 0);
// At most one interrupt can be missed with double-buffer controller
if (aInterruptCount == 1)
{
DmacDb::InterruptsToMiss[aChannel.PslId()] = aInterruptCount;
return KErrNone;
}
else
return KErrNotSupported;
}
TBool DSimDbController::IsIdle(const TDmaChannel& aChannel)
{
return (DmacDb::ControlStatus[aChannel.PslId()] & DmacDb::ECsRun) == 0;
}
TInt DSimDbController::MaxTransferSize(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMaxTransferSize;
}
TUint DSimDbController::MemAlignMask(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMemAlignMask;
}
void DSimDbController::Isr()
{
for (TInt i = 0; i < KChannelCount; i++)
{
TUint32 mask = (1 << i);
if (DmacDb::CompletionInt & mask)
{
DmacDb::CompletionInt &= ~mask;
HandleIsr(DbController.iChannels[i], ETrue);
}
if (DmacDb::ErrorInt & mask)
{
DmacDb::ErrorInt &= ~mask;
HandleIsr(DbController.iChannels[i], EFalse);
}
}
}
//////////////////////////////////////////////////////////////////////////////
class DSimSgController : public TDmac
{
public:
DSimSgController();
private:
static void Isr();
// from TDmac
virtual void Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr);
virtual void StopTransfer(const TDmaChannel& aChannel);
virtual TBool IsIdle(const TDmaChannel& aChannel);
virtual TInt MaxTransferSize(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
virtual TUint MemAlignMask(TDmaChannel& aChannel, TUint aFlags, TUint32 aPslInfo);
virtual void InitHwDes(const SDmaDesHdr& aHdr, TUint32 aSrc, TUint32 aDest, TInt aCount,
TUint aFlags, TUint32 aPslInfo, TUint32 aCookie);
virtual void ChainHwDes(const SDmaDesHdr& aHdr, const SDmaDesHdr& aNextHdr);
virtual void AppendHwDes(const TDmaChannel& aChannel, const SDmaDesHdr& aLastHdr,
const SDmaDesHdr& aNewHdr);
virtual void UnlinkHwDes(const TDmaChannel& aChannel, SDmaDesHdr& aHdr);
virtual TInt FailNext(const TDmaChannel& aChannel);
virtual TInt MissNextInterrupts(const TDmaChannel& aChannel, TInt aInterruptCount);
private:
inline DmacSg::SDes* HdrToHwDes(const SDmaDesHdr& aHdr);
public:
static const SCreateInfo KInfo;
TDmaSgChannel iChannels[KChannelCount];
};
DSimSgController SgController;
const TDmac::SCreateInfo DSimSgController::KInfo =
{
KChannelCount,
KDesCount,
KCapsBitHwDes,
sizeof(DmacSg::SDes),
#ifdef __WINS__
0,
#else
EMapAttrSupRw|EMapAttrFullyBlocking,
#endif
};
inline DmacSg::SDes* DSimSgController::HdrToHwDes(const SDmaDesHdr& aHdr)
{
return static_cast<DmacSg::SDes*>(TDmac::HdrToHwDes(aHdr));
}
DSimSgController::DSimSgController()
: TDmac(KInfo)
{
DmacSg::Isr = Isr;
}
void DSimSgController::Transfer(const TDmaChannel& aChannel, const SDmaDesHdr& aHdr)
{
TUint32 i = aChannel.PslId();
DmacSg::NextDes[i] = HdrToHwDes(aHdr);
DmacSg::Enable(i);
}
void DSimSgController::StopTransfer(const TDmaChannel& aChannel)
{
__e32_atomic_and_ord32(&DmacSg::ChannelControl[aChannel.PslId()], (TUint32)~DmacSg::EChannelBitRun);
}
void DSimSgController::InitHwDes(const SDmaDesHdr& aHdr, TUint32 aSrc, TUint32 aDest, TInt aCount,
TUint /*aFlags*/, TUint32 /*aPslInfo*/, TUint32 /*aCookie*/)
{
DmacSg::SDes& des = *HdrToHwDes(aHdr);
des.iSrcAddr = reinterpret_cast<TUint8*>(aSrc);
des.iDestAddr = reinterpret_cast<TUint8*>(aDest);
des.iCount = static_cast<TInt16>(aCount);
des.iControl |= DmacSg::EDesBitInt;
des.iNext = NULL;
}
void DSimSgController::ChainHwDes(const SDmaDesHdr& aHdr, const SDmaDesHdr& aNextHdr)
{
DmacSg::SDes& des = *HdrToHwDes(aHdr);
des.iControl &= ~DmacSg::EDesBitInt;
des.iNext = HdrToHwDes(aNextHdr);
}
void DSimSgController::AppendHwDes(const TDmaChannel& aChannel, const SDmaDesHdr& aLastHdr,
const SDmaDesHdr& aNewHdr)
{
TUint32 i = aChannel.PslId();
DmacSg::SDes* pNewDes = HdrToHwDes(aNewHdr);
TInt prevLevel = NKern::DisableAllInterrupts();
if ((DmacSg::ChannelControl[i] & DmacSg::EChannelBitRun) == 0)
{
DmacSg::NextDes[i] = pNewDes;
DmacSg::Enable(i);
}
else if (DmacSg::NextDes[i] == NULL)
DmacSg::NextDes[i] = pNewDes;
else
HdrToHwDes(aLastHdr)->iNext = pNewDes;
NKern::RestoreInterrupts(prevLevel);
}
void DSimSgController::UnlinkHwDes(const TDmaChannel& /*aChannel*/, SDmaDesHdr& aHdr)
{
DmacSg::SDes* pD = HdrToHwDes(aHdr);
pD->iNext = NULL;
pD->iControl |= DmacSg::EDesBitInt;
}
TInt DSimSgController::FailNext(const TDmaChannel& aChannel)
{
__DMA_ASSERTD((DmacSg::ChannelControl[aChannel.PslId()] & DmacSg::EChannelBitRun) == 0);
DmacSg::FailCount[aChannel.PslId()] = 1;
return KErrNone;
}
TInt DSimSgController::MissNextInterrupts(const TDmaChannel& aChannel, TInt aInterruptCount)
{
__DMA_ASSERTD((DmacSg::ChannelControl[aChannel.PslId()] & DmacSg::EChannelBitRun) == 0);
__DMA_ASSERTD(aInterruptCount >= 0);
DmacSg::InterruptsToMiss[aChannel.PslId()] = aInterruptCount;
return KErrNone;
}
TBool DSimSgController::IsIdle(const TDmaChannel& aChannel)
{
return (DmacSg::ChannelControl[aChannel.PslId()] & DmacSg::EChannelBitRun) == 0;
}
TInt DSimSgController::MaxTransferSize(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMaxTransferSize;
}
TUint DSimSgController::MemAlignMask(TDmaChannel& /*aChannel*/, TUint /*aFlags*/, TUint32 /*aPslInfo*/)
{
return KMemAlignMask;
}
void DSimSgController::Isr()
{
for (TInt i = 0; i < KChannelCount; i++)
{
TUint32 mask = (1 << i);
if (DmacSg::CompletionInt & mask)
{
DmacSg::CompletionInt &= ~mask;
HandleIsr(SgController.iChannels[i], ETrue);
}
if (DmacSg::ErrorInt & mask)
{
DmacSg::ErrorInt &= ~mask;
HandleIsr(SgController.iChannels[i], EFalse);
}
}
}
//////////////////////////////////////////////////////////////////////////////
// Channel opening/closing
enum TController { ESb=0, EDb=1, ESg=2 };
const TUint32 KControllerMask = 0x30;
const TUint32 KControllerShift = 4;
const TUint32 KChannelIdxMask = 3;
#define MKCHN(type, idx) (((type)<<KControllerShift)|idx)
static TUint32 TestSbChannels[] = { MKCHN(ESb,0), MKCHN(ESb,1), MKCHN(ESb,2), MKCHN(ESb,3) };
static TUint32 TestDbChannels[] = { MKCHN(EDb,0), MKCHN(EDb,1), MKCHN(EDb,2), MKCHN(EDb,3) };
static TUint32 TestSgChannels[] = { MKCHN(ESg,0), MKCHN(ESg,1), MKCHN(ESg,2), MKCHN(ESg,3) };
static TDmaTestInfo TestInfo =
{
KMaxTransferSize,
KMemAlignMask,
0,
KChannelCount,
TestSbChannels,
KChannelCount,
TestDbChannels,
KChannelCount,
TestSgChannels,
};
EXPORT_C const TDmaTestInfo& DmaTestInfo()
{
return TestInfo;
}
// Keep track of opened channels so Tick callback used to fake DMA
// transfers is enabled only when necessary.
static TInt OpenChannelCount = 0;
TDmaChannel* DmaChannelMgr::Open(TUint32 aOpenId)
{
TInt dmac = (aOpenId & KControllerMask) >> KControllerShift;
__DMA_ASSERTD(dmac < 3);
TInt i = aOpenId & KChannelIdxMask;
TDmaChannel* pC = NULL;
TDmac* controller = NULL;
switch (dmac)
{
case ESb:
pC = SbController.iChannels + i;
controller = &SbController;
break;
case EDb:
pC = DbController.iChannels + i;
controller = &DbController;
break;
case ESg:
pC = SgController.iChannels + i;
controller = &SgController;
break;
default:
__DMA_CANT_HAPPEN();
}
if (++OpenChannelCount == 1)
{
__KTRACE_OPT(KDMA, Kern::Printf("Enabling DMA simulation"));
DmacSim::StartEmulation();
}
if (pC->IsOpened())
return NULL;
pC->iController = controller;
pC->iPslId = i;
return pC;
}
void DmaChannelMgr::Close(TDmaChannel* /*aChannel*/)
{
if (--OpenChannelCount == 0)
{
DmacSim::StopEmulation();
__KTRACE_OPT(KDMA, Kern::Printf("Stopping DMA simulation"));
}
}
TInt DmaChannelMgr::StaticExtension(TInt /*aCmd*/, TAny* /*aArg*/)
{
return KErrNotSupported;
}
//////////////////////////////////////////////////////////////////////////////
//
// On hardware, this code is inside a kernel extension.
//
DECLARE_STANDARD_EXTENSION()
{
__KTRACE_OPT(KDMA, Kern::Printf("Starting DMA simulator..."));
TInt r;
r = SbController.Create(DSimSbController::KInfo);
if (r != KErrNone)
return r;
r = DbController.Create(DSimDbController::KInfo);
if (r != KErrNone)
return r;
r = SgController.Create(DSimSgController::KInfo);
if (r != KErrNone)
return r;
return KErrNone;
}
//
// On WINS, this code is inside a LDD (see mmp file) so we need some
// bootstrapping code to call the kernel extension entry point.
//
class DDummyLdd : public DLogicalDevice
{
public:
// from DLogicalDevice
TInt Install();
void GetCaps(TDes8& aDes) const;
TInt Create(DLogicalChannelBase*& aChannel);
};
TInt DDummyLdd::Create(DLogicalChannelBase*& aChannel)
{
aChannel=NULL;
return KErrNone;
}
TInt DDummyLdd::Install()
{
_LIT(KLddName, "DmaSim");
TInt r = SetName(&KLddName);
if (r == KErrNone)
r = InitExtension();
return r;
}
void DDummyLdd::GetCaps(TDes8& /*aDes*/) const
{
}
EXPORT_C DLogicalDevice* CreateLogicalDevice()
{
return new DDummyLdd;
}
//---