// Copyright (c) 1998-2009 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:
// template\template_assp\template_assp.cpp
//
//
#include <template_assp_priv.h>
//----------------------------------------------------------------------------
// Initialisation
void TTemplate::Init3()
//
// Phase 3 initialisation
//
{
//
// TO DO: (optional)
//
// Initialise any TTemplate class data members here
//
// Use assp-specific nano wait implementation
Kern::SetNanoWaitHandler(NanoWait);
}
EXPORT_C TMachineStartupType TTemplate::StartupReason()
//
// Read and return the Startup reason of the Hardware
//
{
//
// TO DO: (optional)
//
// Read the Reset reason from the hardware register map it to one of TMachineStartupType enumerated values
// and return this
//
return EStartupCold; // EXAMPLE ONLY
}
EXPORT_C TInt TTemplate::CpuVersionId()
//
// Read and return the the CPU ID
//
{
//
// TO DO: (optional)
//
// Read the CPU identification register (if one exists) mask off redundant bits and return this
//
return 0; // EXAMPLE ONLY
}
EXPORT_C TUint TTemplate::DebugPortAddr()
//
// Return Linear base address of debug UART (as selected in obey file or with eshell debugport command).
//
{
//
// TO DO: (optional)
//
// Read the iDebugPort field of the SuperPage, map the result to the corresponding Serial Port Linear
// address and return this, like the following EXAMPLE ONLY:
//
TUint debugPort;
switch (Kern::SuperPage().iDebugPort)
{
case 1:
debugPort=KHwBaseSerial1;
break;
case 2:
debugPort=KHwBaseSerial2;
break;
case 3:
debugPort=KHwBaseSerial3;
break;
default:
debugPort=KHwBaseSerial1;
break;
}
return debugPort;
}
EXPORT_C TUint TTemplate::ProcessorPeriodInPs()
//
// Return CPU clock period in picoseconds
//
{
//
// TO DO: (optional)
//
// Read the CPU clock speed and return its period in picoseconds. If only a limited range of speeds is possible
// it is preferable to use the masked speed reading as an index into a look up table containing the corresponding
// period
//
return 0; // EXAMPLE ONLY
}
EXPORT_C void TTemplate::SetIntMask(TUint aValue)
//
// Set the Hardware Interrupt masks
//
{
// the following is EXAMPLE ONLY
TInt irq=NKern::DisableAllInterrupts();
AsspRegister::Write32(KHwInterruptsMaskSet, aValue);
AsspRegister::Write32(KHwInterruptsMaskClear, ~aValue);
NKern::RestoreInterrupts(irq);
}
EXPORT_C void TTemplate::ModifyIntMask(TUint aClearMask,TUint aSetMask)
//
// Modify the Hardware Interrupt masks
//
{
// the following is EXAMPLE ONLY
TInt irq=NKern::DisableAllInterrupts();
AsspRegister::Write32(KHwInterruptsMaskSet, aSetMask);
AsspRegister::Write32(KHwInterruptsMaskClear, ~aClearMask);
NKern::RestoreInterrupts(irq);
}
EXPORT_C TUint TTemplate::IntsPending()
//
// Return the state of pending interrupts
//
{
// the following is EXAMPLE ONLY
return(AsspRegister::Read32(KHwInterruptsIrqPending));
}
EXPORT_C TUint TTemplate::RtcData()
//
// Return the current time of the RTC
//
{
//
// TO DO: (optional)
//
// Read the RTC current time register and return this time
//
return 0; // EXAMPLE ONLY
}
EXPORT_C void TTemplate::SetRtcData(TUint aValue)
//
// Set the RTC time
//
{
//
// TO DO: (optional)
//
// Set the RTC current time with aValue (may need formatting appropriately)
//
}
EXPORT_C TPhysAddr TTemplate::VideoRamPhys()
//
// Return the physical address of the video RAM
//
{
return TemplateAssp::VideoRamPhys;
}