/*
* Copyright (c) 2003-2005 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Gabe Black
* Kevin Lim
*/
#ifndef __SPARC_FAULTS_HH__
#define __SPARC_FAULTS_HH__
#include "config/full_system.hh"
#include "sim/faults.hh"
// The design of the "name" and "vect" functions is in sim/faults.hh
namespace SparcISA
{
typedef uint32_t TrapType;
typedef uint32_t FaultPriority;
class ITB;
class SparcFaultBase : public FaultBase
{
public:
enum PrivilegeLevel
{
U, User = U,
P, Privileged = P,
H, Hyperprivileged = H,
NumLevels,
SH = -1,
ShouldntHappen = SH
};
struct FaultVals
{
const FaultName name;
const TrapType trapType;
const FaultPriority priority;
const PrivilegeLevel nextPrivilegeLevel[NumLevels];
FaultStat count;
};
#if FULL_SYSTEM
void invoke(ThreadContext * tc);
#endif
virtual TrapType trapType() = 0;
virtual FaultPriority priority() = 0;
virtual FaultStat & countStat() = 0;
virtual PrivilegeLevel getNextLevel(PrivilegeLevel current) = 0;
};
template<typename T>
class SparcFault : public SparcFaultBase
{
protected:
static FaultVals vals;
public:
FaultName name() const {return vals.name;}
TrapType trapType() {return vals.trapType;}
FaultPriority priority() {return vals.priority;}
FaultStat & countStat() {return vals.count;}
PrivilegeLevel getNextLevel(PrivilegeLevel current)
{
return vals.nextPrivilegeLevel[current];
}
};
class PowerOnReset : public SparcFault<PowerOnReset>
{
void invoke(ThreadContext * tc);
};
class WatchDogReset : public SparcFault<WatchDogReset> {};
class ExternallyInitiatedReset : public SparcFault<ExternallyInitiatedReset> {};
class SoftwareInitiatedReset : public SparcFault<SoftwareInitiatedReset> {};
class REDStateException : public SparcFault<REDStateException> {};
class StoreError : public SparcFault<StoreError> {};
class InstructionAccessException : public SparcFault<InstructionAccessException> {};
//class InstructionAccessMMUMiss : public SparcFault<InstructionAccessMMUMiss> {};
class InstructionAccessError : public SparcFault<InstructionAccessError> {};
class IllegalInstruction : public SparcFault<IllegalInstruction> {};
class PrivilegedOpcode : public SparcFault<PrivilegedOpcode> {};
//class UnimplementedLDD : public SparcFault<UnimplementedLDD> {};
//class UnimplementedSTD : public SparcFault<UnimplementedSTD> {};
class FpDisabled : public SparcFault<FpDisabled> {};
class FpExceptionIEEE754 : public SparcFault<FpExceptionIEEE754> {};
class FpExceptionOther : public SparcFault<FpExceptionOther> {};
class TagOverflow : public SparcFault<TagOverflow> {};
class CleanWindow : public SparcFault<CleanWindow> {};
class DivisionByZero : public SparcFault<DivisionByZero> {};
class InternalProcessorError :
public SparcFault<InternalProcessorError>
{
public:
bool isMachineCheckFault() const {return true;}
};
class InstructionInvalidTSBEntry : public SparcFault<InstructionInvalidTSBEntry> {};
class DataInvalidTSBEntry : public SparcFault<DataInvalidTSBEntry> {};
class DataAccessException : public SparcFault<DataAccessException> {};
//class DataAccessMMUMiss : public SparcFault<DataAccessMMUMiss> {};
class DataAccessError : public SparcFault<DataAccessError> {};
class DataAccessProtection : public SparcFault<DataAccessProtection> {};
class MemAddressNotAligned :
public SparcFault<MemAddressNotAligned>
{
public:
bool isAlignmentFault() const {return true;}
};
class LDDFMemAddressNotAligned : public SparcFault<LDDFMemAddressNotAligned> {};
class STDFMemAddressNotAligned : public SparcFault<STDFMemAddressNotAligned> {};
class PrivilegedAction : public SparcFault<PrivilegedAction> {};
class LDQFMemAddressNotAligned : public SparcFault<LDQFMemAddressNotAligned> {};
class STQFMemAddressNotAligned : public SparcFault<STQFMemAddressNotAligned> {};
class InstructionRealTranslationMiss :
public SparcFault<InstructionRealTranslationMiss> {};
class DataRealTranslationMiss : public SparcFault<DataRealTranslationMiss> {};
//class AsyncDataError : public SparcFault<AsyncDataError> {};
template <class T>
class EnumeratedFault : public SparcFault<T>
{
protected:
uint32_t _n;
public:
EnumeratedFault(uint32_t n) : SparcFault<T>(), _n(n) {}
TrapType trapType() {return SparcFault<T>::trapType() + _n;}
};
class InterruptLevelN : public EnumeratedFault<InterruptLevelN>
{
public:
InterruptLevelN(uint32_t n) : EnumeratedFault<InterruptLevelN>(n) {;}
FaultPriority priority() {return 3200 - _n*100;}
};
class HstickMatch : public SparcFault<HstickMatch> {};
class TrapLevelZero : public SparcFault<TrapLevelZero> {};
class InterruptVector : public SparcFault<InterruptVector> {};
class PAWatchpoint : public SparcFault<PAWatchpoint> {};
class VAWatchpoint : public SparcFault<VAWatchpoint> {};
class FastInstructionAccessMMUMiss :
public SparcFault<FastInstructionAccessMMUMiss>
{
#if !FULL_SYSTEM
protected:
Addr vaddr;
public:
FastInstructionAccessMMUMiss(Addr addr) : vaddr(addr)
{}
void invoke(ThreadContext * tc);
#endif
};
class FastDataAccessMMUMiss : public SparcFault<FastDataAccessMMUMiss>
{
#if !FULL_SYSTEM
protected:
Addr vaddr;
public:
FastDataAccessMMUMiss(Addr addr) : vaddr(addr)
{}
void invoke(ThreadContext * tc);
#endif
};
class FastDataAccessProtection : public SparcFault<FastDataAccessProtection> {};
class InstructionBreakpoint : public SparcFault<InstructionBreakpoint> {};
class CpuMondo : public SparcFault<CpuMondo> {};
class DevMondo : public SparcFault<DevMondo> {};
class ResumableError : public SparcFault<ResumableError> {};
class SpillNNormal : public EnumeratedFault<SpillNNormal>
{
public:
SpillNNormal(uint32_t n) : EnumeratedFault<SpillNNormal>(n) {;}
//These need to be handled specially to enable spill traps in SE
#if !FULL_SYSTEM
void invoke(ThreadContext * tc);
#endif
};
class SpillNOther : public EnumeratedFault<SpillNOther>
{
public:
SpillNOther(uint32_t n) : EnumeratedFault<SpillNOther>(n) {;}
};
class FillNNormal : public EnumeratedFault<FillNNormal>
{
public:
FillNNormal(uint32_t n) : EnumeratedFault<FillNNormal>(n) {;}
//These need to be handled specially to enable fill traps in SE
#if !FULL_SYSTEM
void invoke(ThreadContext * tc);
#endif
};
class FillNOther : public EnumeratedFault<FillNOther>
{
public:
FillNOther(uint32_t n) : EnumeratedFault<FillNOther>(n) {;}
};
class TrapInstruction : public EnumeratedFault<TrapInstruction>
{
public:
TrapInstruction(uint32_t n) : EnumeratedFault<TrapInstruction>(n) {;}
//In SE, trap instructions are requesting services from the OS.
#if !FULL_SYSTEM
void invoke(ThreadContext * tc);
#endif
};
static inline Fault genMachineCheckFault()
{
return new InternalProcessorError;
}
} // SparcISA namespace
#endif // __SPARC_FAULTS_HH__