* Kevin Lim
*/
+#include "arch/sparc/faults.hh"
+
#include <algorithm>
-#include "arch/sparc/faults.hh"
#include "arch/sparc/isa_traits.hh"
+#include "arch/sparc/process.hh"
+#include "arch/sparc/tlb.hh"
#include "arch/sparc/types.hh"
#include "base/bitfield.hh"
#include "base/trace.hh"
-#include "config/full_system.hh"
#include "cpu/base.hh"
#include "cpu/thread_context.hh"
-#if !FULL_SYSTEM
-#include "arch/sparc/process.hh"
#include "mem/page_table.hh"
+#include "sim/full_system.hh"
#include "sim/process.hh"
-#endif
using namespace std;
{
template<> SparcFaultBase::FaultVals
- SparcFault<PowerOnReset>::vals =
- {"power_on_reset", 0x001, 0, {H, H, H}};
+ SparcFault<PowerOnReset>::vals
+("power_on_reset", 0x001, 0, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<WatchDogReset>::vals =
- {"watch_dog_reset", 0x002, 120, {H, H, H}};
+ SparcFault<WatchDogReset>::vals
+("watch_dog_reset", 0x002, 120, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<ExternallyInitiatedReset>::vals =
- {"externally_initiated_reset", 0x003, 110, {H, H, H}};
+ SparcFault<ExternallyInitiatedReset>::vals
+("externally_initiated_reset", 0x003, 110, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<SoftwareInitiatedReset>::vals =
- {"software_initiated_reset", 0x004, 130, {SH, SH, H}};
+ SparcFault<SoftwareInitiatedReset>::vals
+("software_initiated_reset", 0x004, 130, {{SH, SH, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<REDStateException>::vals =
- {"RED_state_exception", 0x005, 1, {H, H, H}};
+ SparcFault<REDStateException>::vals
+("RED_state_exception", 0x005, 1, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<StoreError>::vals =
- {"store_error", 0x007, 201, {H, H, H}};
+ SparcFault<StoreError>::vals
+("store_error", 0x007, 201, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<InstructionAccessException>::vals =
- {"instruction_access_exception", 0x008, 300, {H, H, H}};
+ SparcFault<InstructionAccessException>::vals
+("instruction_access_exception", 0x008, 300, {{H, H, H}});
//XXX This trap is apparently dropped from ua2005
/*template<> SparcFaultBase::FaultVals
- SparcFault<InstructionAccessMMUMiss>::vals =
- {"inst_mmu", 0x009, 2, {H, H, H}};*/
+ SparcFault<InstructionAccessMMUMiss>::vals
+ ("inst_mmu", 0x009, 2, {{H, H, H}});*/
template<> SparcFaultBase::FaultVals
- SparcFault<InstructionAccessError>::vals =
- {"instruction_access_error", 0x00A, 400, {H, H, H}};
+ SparcFault<InstructionAccessError>::vals
+("instruction_access_error", 0x00A, 400, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<IllegalInstruction>::vals =
- {"illegal_instruction", 0x010, 620, {H, H, H}};
+ SparcFault<IllegalInstruction>::vals
+("illegal_instruction", 0x010, 620, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<PrivilegedOpcode>::vals =
- {"privileged_opcode", 0x011, 700, {P, SH, SH}};
+ SparcFault<PrivilegedOpcode>::vals
+("privileged_opcode", 0x011, 700, {{P, SH, SH}});
//XXX This trap is apparently dropped from ua2005
/*template<> SparcFaultBase::FaultVals
- SparcFault<UnimplementedLDD>::vals =
- {"unimp_ldd", 0x012, 6, {H, H, H}};*/
+ SparcFault<UnimplementedLDD>::vals
+ ("unimp_ldd", 0x012, 6, {{H, H, H}});*/
//XXX This trap is apparently dropped from ua2005
/*template<> SparcFaultBase::FaultVals
- SparcFault<UnimplementedSTD>::vals =
- {"unimp_std", 0x013, 6, {H, H, H}};*/
+ SparcFault<UnimplementedSTD>::vals
+ ("unimp_std", 0x013, 6, {{H, H, H}});*/
+
+template<> SparcFaultBase::FaultVals
+ SparcFault<FpDisabled>::vals
+("fp_disabled", 0x020, 800, {{P, P, H}});
+/* SPARCv8 and SPARCv9 define just fp_disabled trap. SIMD is not contemplated
+ * as a separate part. Therefore, we use the same code and TT */
template<> SparcFaultBase::FaultVals
- SparcFault<FpDisabled>::vals =
- {"fp_disabled", 0x020, 800, {P, P, H}};
+ SparcFault<VecDisabled>::vals
+("fp_disabled", 0x020, 800, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<FpExceptionIEEE754>::vals =
- {"fp_exception_ieee_754", 0x021, 1110, {P, P, H}};
+ SparcFault<FpExceptionIEEE754>::vals
+("fp_exception_ieee_754", 0x021, 1110, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<FpExceptionOther>::vals =
- {"fp_exception_other", 0x022, 1110, {P, P, H}};
+ SparcFault<FpExceptionOther>::vals
+("fp_exception_other", 0x022, 1110, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<TagOverflow>::vals =
- {"tag_overflow", 0x023, 1400, {P, P, H}};
+ SparcFault<TagOverflow>::vals
+("tag_overflow", 0x023, 1400, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<CleanWindow>::vals =
- {"clean_window", 0x024, 1010, {P, P, H}};
+ SparcFault<CleanWindow>::vals
+("clean_window", 0x024, 1010, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<DivisionByZero>::vals =
- {"division_by_zero", 0x028, 1500, {P, P, H}};
+ SparcFault<DivisionByZero>::vals
+("division_by_zero", 0x028, 1500, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<InternalProcessorError>::vals =
- {"internal_processor_error", 0x029, 4, {H, H, H}};
+ SparcFault<InternalProcessorError>::vals
+("internal_processor_error", 0x029, 4, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<InstructionInvalidTSBEntry>::vals =
- {"instruction_invalid_tsb_entry", 0x02A, 210, {H, H, SH}};
+ SparcFault<InstructionInvalidTSBEntry>::vals
+("instruction_invalid_tsb_entry", 0x02A, 210, {{H, H, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<DataInvalidTSBEntry>::vals =
- {"data_invalid_tsb_entry", 0x02B, 1203, {H, H, H}};
+ SparcFault<DataInvalidTSBEntry>::vals
+("data_invalid_tsb_entry", 0x02B, 1203, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<DataAccessException>::vals =
- {"data_access_exception", 0x030, 1201, {H, H, H}};
+ SparcFault<DataAccessException>::vals
+("data_access_exception", 0x030, 1201, {{H, H, H}});
//XXX This trap is apparently dropped from ua2005
/*template<> SparcFaultBase::FaultVals
- SparcFault<DataAccessMMUMiss>::vals =
- {"data_mmu", 0x031, 12, {H, H, H}};*/
+ SparcFault<DataAccessMMUMiss>::vals
+ ("data_mmu", 0x031, 12, {{H, H, H}});*/
template<> SparcFaultBase::FaultVals
- SparcFault<DataAccessError>::vals =
- {"data_access_error", 0x032, 1210, {H, H, H}};
+ SparcFault<DataAccessError>::vals
+("data_access_error", 0x032, 1210, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<DataAccessProtection>::vals =
- {"data_access_protection", 0x033, 1207, {H, H, H}};
+ SparcFault<DataAccessProtection>::vals
+("data_access_protection", 0x033, 1207, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<MemAddressNotAligned>::vals =
- {"mem_address_not_aligned", 0x034, 1020, {H, H, H}};
+ SparcFault<MemAddressNotAligned>::vals
+("mem_address_not_aligned", 0x034, 1020, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<LDDFMemAddressNotAligned>::vals =
- {"LDDF_mem_address_not_aligned", 0x035, 1010, {H, H, H}};
+ SparcFault<LDDFMemAddressNotAligned>::vals
+("LDDF_mem_address_not_aligned", 0x035, 1010, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<STDFMemAddressNotAligned>::vals =
- {"STDF_mem_address_not_aligned", 0x036, 1010, {H, H, H}};
+ SparcFault<STDFMemAddressNotAligned>::vals
+("STDF_mem_address_not_aligned", 0x036, 1010, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<PrivilegedAction>::vals =
- {"privileged_action", 0x037, 1110, {H, H, SH}};
+ SparcFault<PrivilegedAction>::vals
+("privileged_action", 0x037, 1110, {{H, H, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<LDQFMemAddressNotAligned>::vals =
- {"LDQF_mem_address_not_aligned", 0x038, 1010, {H, H, H}};
+ SparcFault<LDQFMemAddressNotAligned>::vals
+("LDQF_mem_address_not_aligned", 0x038, 1010, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<STQFMemAddressNotAligned>::vals =
- {"STQF_mem_address_not_aligned", 0x039, 1010, {H, H, H}};
+ SparcFault<STQFMemAddressNotAligned>::vals
+("STQF_mem_address_not_aligned", 0x039, 1010, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<InstructionRealTranslationMiss>::vals =
- {"instruction_real_translation_miss", 0x03E, 208, {H, H, SH}};
+ SparcFault<InstructionRealTranslationMiss>::vals
+("instruction_real_translation_miss", 0x03E, 208, {{H, H, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<DataRealTranslationMiss>::vals =
- {"data_real_translation_miss", 0x03F, 1203, {H, H, H}};
+ SparcFault<DataRealTranslationMiss>::vals
+("data_real_translation_miss", 0x03F, 1203, {{H, H, H}});
//XXX This trap is apparently dropped from ua2005
/*template<> SparcFaultBase::FaultVals
- SparcFault<AsyncDataError>::vals =
- {"async_data", 0x040, 2, {H, H, H}};*/
+ SparcFault<AsyncDataError>::vals
+ ("async_data", 0x040, 2, {{H, H, H}});*/
template<> SparcFaultBase::FaultVals
- SparcFault<InterruptLevelN>::vals =
- {"interrupt_level_n", 0x041, 0, {P, P, SH}};
+ SparcFault<InterruptLevelN>::vals
+("interrupt_level_n", 0x040, 0, {{P, P, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<HstickMatch>::vals =
- {"hstick_match", 0x05E, 1601, {H, H, H}};
+ SparcFault<HstickMatch>::vals
+("hstick_match", 0x05E, 1601, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<TrapLevelZero>::vals =
- {"trap_level_zero", 0x05F, 202, {H, H, SH}};
+ SparcFault<TrapLevelZero>::vals
+("trap_level_zero", 0x05F, 202, {{H, H, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<PAWatchpoint>::vals =
- {"PA_watchpoint", 0x061, 1209, {H, H, H}};
+ SparcFault<InterruptVector>::vals
+("interrupt_vector", 0x060, 2630, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<VAWatchpoint>::vals =
- {"VA_watchpoint", 0x062, 1120, {P, P, SH}};
+ SparcFault<PAWatchpoint>::vals
+("PA_watchpoint", 0x061, 1209, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<FastInstructionAccessMMUMiss>::vals =
- {"fast_instruction_access_MMU_miss", 0x064, 208, {H, H, SH}};
+ SparcFault<VAWatchpoint>::vals
+("VA_watchpoint", 0x062, 1120, {{P, P, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<FastDataAccessMMUMiss>::vals =
- {"fast_data_access_MMU_miss", 0x068, 1203, {H, H, H}};
+ SparcFault<FastInstructionAccessMMUMiss>::vals
+("fast_instruction_access_MMU_miss", 0x064, 208, {{H, H, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<FastDataAccessProtection>::vals =
- {"fast_data_access_protection", 0x06C, 1207, {H, H, H}};
+ SparcFault<FastDataAccessMMUMiss>::vals
+("fast_data_access_MMU_miss", 0x068, 1203, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<InstructionBreakpoint>::vals =
- {"instruction_break", 0x076, 610, {H, H, H}};
+ SparcFault<FastDataAccessProtection>::vals
+("fast_data_access_protection", 0x06C, 1207, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<CpuMondo>::vals =
- {"cpu_mondo", 0x07C, 1608, {P, P, SH}};
+ SparcFault<InstructionBreakpoint>::vals
+("instruction_break", 0x076, 610, {{H, H, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<DevMondo>::vals =
- {"dev_mondo", 0x07D, 1611, {P, P, SH}};
+ SparcFault<CpuMondo>::vals
+("cpu_mondo", 0x07C, 1608, {{P, P, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<ResumeableError>::vals =
- {"resume_error", 0x07E, 3330, {P, P, SH}};
+ SparcFault<DevMondo>::vals
+("dev_mondo", 0x07D, 1611, {{P, P, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<SpillNNormal>::vals =
- {"spill_n_normal", 0x080, 900, {P, P, H}};
+ SparcFault<ResumableError>::vals
+("resume_error", 0x07E, 3330, {{P, P, SH}});
template<> SparcFaultBase::FaultVals
- SparcFault<SpillNOther>::vals =
- {"spill_n_other", 0x0A0, 900, {P, P, H}};
+ SparcFault<SpillNNormal>::vals
+("spill_n_normal", 0x080, 900, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<FillNNormal>::vals =
- {"fill_n_normal", 0x0C0, 900, {P, P, H}};
+ SparcFault<SpillNOther>::vals
+("spill_n_other", 0x0A0, 900, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<FillNOther>::vals =
- {"fill_n_other", 0x0E0, 900, {P, P, H}};
+ SparcFault<FillNNormal>::vals
+("fill_n_normal", 0x0C0, 900, {{P, P, H}});
template<> SparcFaultBase::FaultVals
- SparcFault<TrapInstruction>::vals =
- {"trap_instruction", 0x100, 1602, {P, P, H}};
+ SparcFault<FillNOther>::vals
+("fill_n_other", 0x0E0, 900, {{P, P, H}});
-#if !FULL_SYSTEM
template<> SparcFaultBase::FaultVals
- SparcFault<PageTableFault>::vals =
- {"page_table_fault", 0x0000, 0, {SH, SH, SH}};
-#endif
+ SparcFault<TrapInstruction>::vals
+("trap_instruction", 0x100, 1602, {{P, P, H}});
/**
* This causes the thread context to enter RED state. This causes the side
* effects which go with entering RED state because of a trap.
*/
-void enterREDState(ThreadContext *tc)
+void
+enterREDState(ThreadContext *tc)
{
//@todo Disable the mmu?
//@todo Disable watchpoints?
- MiscReg HPSTATE = tc->readMiscReg(MISCREG_HPSTATE);
- //HPSTATE.red = 1
- HPSTATE |= (1 << 5);
- //HPSTATE.hpriv = 1
- HPSTATE |= (1 << 2);
- tc->setMiscRegWithEffect(MISCREG_HPSTATE, HPSTATE);
- //PSTATE.priv is set to 1 here. The manual says it should be 0, but
- //Legion sets it to 1.
- MiscReg PSTATE = tc->readMiscReg(MISCREG_PSTATE);
- PSTATE |= (1 << 2);
- tc->setMiscRegWithEffect(MISCREG_PSTATE, PSTATE);
+ HPSTATE hpstate= tc->readMiscRegNoEffect(MISCREG_HPSTATE);
+ hpstate.red = 1;
+ hpstate.hpriv = 1;
+ tc->setMiscReg(MISCREG_HPSTATE, hpstate);
+ // PSTATE.priv is set to 1 here. The manual says it should be 0, but
+ // Legion sets it to 1.
+ PSTATE pstate = tc->readMiscRegNoEffect(MISCREG_PSTATE);
+ pstate.priv = 1;
+ tc->setMiscReg(MISCREG_PSTATE, pstate);
}
/**
* the handler.
*/
-void doREDFault(ThreadContext *tc, TrapType tt)
+void
+doREDFault(ThreadContext *tc, TrapType tt)
{
- MiscReg TL = tc->readMiscReg(MISCREG_TL);
- MiscReg TSTATE = tc->readMiscReg(MISCREG_TSTATE);
- MiscReg PSTATE = tc->readMiscReg(MISCREG_PSTATE);
- MiscReg HPSTATE = tc->readMiscReg(MISCREG_HPSTATE);
- //MiscReg CCR = tc->readMiscReg(MISCREG_CCR);
- MiscReg CCR = tc->readIntReg(NumIntArchRegs + 2);
- MiscReg ASI = tc->readMiscReg(MISCREG_ASI);
- MiscReg CWP = tc->readMiscReg(MISCREG_CWP);
- //MiscReg CANSAVE = tc->readMiscReg(MISCREG_CANSAVE);
- MiscReg CANSAVE = tc->readMiscReg(NumIntArchRegs + 3);
- MiscReg GL = tc->readMiscReg(MISCREG_GL);
- MiscReg PC = tc->readPC();
- MiscReg NPC = tc->readNextPC();
+ RegVal TL = tc->readMiscRegNoEffect(MISCREG_TL);
+ RegVal TSTATE = tc->readMiscRegNoEffect(MISCREG_TSTATE);
+ PSTATE pstate = tc->readMiscRegNoEffect(MISCREG_PSTATE);
+ HPSTATE hpstate = tc->readMiscRegNoEffect(MISCREG_HPSTATE);
+ RegVal CCR = tc->readIntReg(NumIntArchRegs + 2);
+ RegVal ASI = tc->readMiscRegNoEffect(MISCREG_ASI);
+ RegVal CWP = tc->readMiscRegNoEffect(MISCREG_CWP);
+ RegVal CANSAVE = tc->readMiscRegNoEffect(NumIntArchRegs + 3);
+ RegVal GL = tc->readMiscRegNoEffect(MISCREG_GL);
+ PCState pc = tc->pcState();
TL++;
- //set TSTATE.gl to gl
+ Addr pcMask = pstate.am ? mask(32) : mask(64);
+
+ // set TSTATE.gl to gl
replaceBits(TSTATE, 42, 40, GL);
- //set TSTATE.ccr to ccr
+ // set TSTATE.ccr to ccr
replaceBits(TSTATE, 39, 32, CCR);
- //set TSTATE.asi to asi
+ // set TSTATE.asi to asi
replaceBits(TSTATE, 31, 24, ASI);
- //set TSTATE.pstate to pstate
- replaceBits(TSTATE, 20, 8, PSTATE);
- //set TSTATE.cwp to cwp
+ // set TSTATE.pstate to pstate
+ replaceBits(TSTATE, 20, 8, pstate);
+ // set TSTATE.cwp to cwp
replaceBits(TSTATE, 4, 0, CWP);
- //Write back TSTATE
- tc->setMiscReg(MISCREG_TSTATE, TSTATE);
-
- //set TPC to PC
- tc->setMiscReg(MISCREG_TPC, PC);
- //set TNPC to NPC
- tc->setMiscReg(MISCREG_TNPC, NPC);
-
- //set HTSTATE.hpstate to hpstate
- tc->setMiscReg(MISCREG_HTSTATE, HPSTATE);
-
- //TT = trap type;
- tc->setMiscReg(MISCREG_TT, tt);
-
- //Update GL
- tc->setMiscRegWithEffect(MISCREG_GL, min<int>(GL+1, MaxGL));
-
- //set PSTATE.mm to 00
- //set PSTATE.pef to 1
- PSTATE |= (1 << 4);
- //set PSTATE.am to 0
- PSTATE &= ~(1 << 3);
-/* //set PSTATE.priv to 0
- PSTATE &= ~(1 << 2);*/
- //set PSTATE.ie to 0
- //PSTATE.priv is set to 1 here. The manual says it should be 0, but
- //Legion sets it to 1.
- PSTATE |= (1 << 2);
- //set PSTATE.cle to 0
- PSTATE &= ~(1 << 9);
- //PSTATE.tle is unchanged
- //XXX Where is the tct bit?
- //set PSTATE.tct to 0
- tc->setMiscReg(MISCREG_PSTATE, PSTATE);
-
- //set HPSTATE.red to 1
- HPSTATE |= (1 << 5);
- //set HPSTATE.hpriv to 1
- HPSTATE |= (1 << 2);
- //set HPSTATE.ibe to 0
- HPSTATE &= ~(1 << 10);
- //set HPSTATE.tlz to 0
- HPSTATE &= ~(1 << 0);
- tc->setMiscReg(MISCREG_HPSTATE, HPSTATE);
+ // Write back TSTATE
+ tc->setMiscRegNoEffect(MISCREG_TSTATE, TSTATE);
+
+ // set TPC to PC
+ tc->setMiscRegNoEffect(MISCREG_TPC, pc.pc() & pcMask);
+ // set TNPC to NPC
+ tc->setMiscRegNoEffect(MISCREG_TNPC, pc.npc() & pcMask);
+
+ // set HTSTATE.hpstate to hpstate
+ tc->setMiscRegNoEffect(MISCREG_HTSTATE, hpstate);
+
+ // TT = trap type;
+ tc->setMiscRegNoEffect(MISCREG_TT, tt);
+
+ // Update GL
+ tc->setMiscReg(MISCREG_GL, min<int>(GL+1, MaxGL));
+
+ bool priv = pstate.priv; // just save the priv bit
+ pstate = 0;
+ pstate.priv = priv;
+ pstate.pef = 1;
+ tc->setMiscRegNoEffect(MISCREG_PSTATE, pstate);
+
+ hpstate.red = 1;
+ hpstate.hpriv = 1;
+ hpstate.ibe = 0;
+ hpstate.tlz = 0;
+ tc->setMiscRegNoEffect(MISCREG_HPSTATE, hpstate);
bool changedCWP = true;
- if(tt == 0x24)
+ if (tt == 0x24)
CWP++;
- else if(0x80 <= tt && tt <= 0xbf)
+ else if (0x80 <= tt && tt <= 0xbf)
CWP += (CANSAVE + 2);
- else if(0xc0 <= tt && tt <= 0xff)
+ else if (0xc0 <= tt && tt <= 0xff)
CWP--;
else
changedCWP = false;
- if(changedCWP)
- {
+ if (changedCWP) {
CWP = (CWP + NWindows) % NWindows;
- tc->setMiscRegWithEffect(MISCREG_CWP, CWP);
+ tc->setMiscReg(MISCREG_CWP, CWP);
}
}
* the handler.
*/
-void doNormalFault(ThreadContext *tc, TrapType tt, bool gotoHpriv)
+void
+doNormalFault(ThreadContext *tc, TrapType tt, bool gotoHpriv)
{
- MiscReg TL = tc->readMiscReg(MISCREG_TL);
- MiscReg TSTATE = tc->readMiscReg(MISCREG_TSTATE);
- MiscReg PSTATE = tc->readMiscReg(MISCREG_PSTATE);
- MiscReg HPSTATE = tc->readMiscReg(MISCREG_HPSTATE);
- //MiscReg CCR = tc->readMiscReg(MISCREG_CCR);
- MiscReg CCR = tc->readIntReg(NumIntArchRegs + 2);
- MiscReg ASI = tc->readMiscReg(MISCREG_ASI);
- MiscReg CWP = tc->readMiscReg(MISCREG_CWP);
- //MiscReg CANSAVE = tc->readMiscReg(MISCREG_CANSAVE);
- MiscReg CANSAVE = tc->readIntReg(NumIntArchRegs + 3);
- MiscReg GL = tc->readMiscReg(MISCREG_GL);
- MiscReg PC = tc->readPC();
- MiscReg NPC = tc->readNextPC();
-
- //Increment the trap level
+ RegVal TL = tc->readMiscRegNoEffect(MISCREG_TL);
+ RegVal TSTATE = tc->readMiscRegNoEffect(MISCREG_TSTATE);
+ PSTATE pstate = tc->readMiscRegNoEffect(MISCREG_PSTATE);
+ HPSTATE hpstate = tc->readMiscRegNoEffect(MISCREG_HPSTATE);
+ RegVal CCR = tc->readIntReg(NumIntArchRegs + 2);
+ RegVal ASI = tc->readMiscRegNoEffect(MISCREG_ASI);
+ RegVal CWP = tc->readMiscRegNoEffect(MISCREG_CWP);
+ RegVal CANSAVE = tc->readIntReg(NumIntArchRegs + 3);
+ RegVal GL = tc->readMiscRegNoEffect(MISCREG_GL);
+ PCState pc = tc->pcState();
+
+ // Increment the trap level
TL++;
- tc->setMiscReg(MISCREG_TL, TL);
+ tc->setMiscRegNoEffect(MISCREG_TL, TL);
+
+ Addr pcMask = pstate.am ? mask(32) : mask(64);
- //Save off state
+ // Save off state
- //set TSTATE.gl to gl
+ // set TSTATE.gl to gl
replaceBits(TSTATE, 42, 40, GL);
- //set TSTATE.ccr to ccr
+ // set TSTATE.ccr to ccr
replaceBits(TSTATE, 39, 32, CCR);
- //set TSTATE.asi to asi
+ // set TSTATE.asi to asi
replaceBits(TSTATE, 31, 24, ASI);
- //set TSTATE.pstate to pstate
- replaceBits(TSTATE, 20, 8, PSTATE);
- //set TSTATE.cwp to cwp
+ // set TSTATE.pstate to pstate
+ replaceBits(TSTATE, 20, 8, pstate);
+ // set TSTATE.cwp to cwp
replaceBits(TSTATE, 4, 0, CWP);
- //Write back TSTATE
- tc->setMiscReg(MISCREG_TSTATE, TSTATE);
+ // Write back TSTATE
+ tc->setMiscRegNoEffect(MISCREG_TSTATE, TSTATE);
- //set TPC to PC
- tc->setMiscReg(MISCREG_TPC, PC);
- //set TNPC to NPC
- tc->setMiscReg(MISCREG_TNPC, NPC);
+ // set TPC to PC
+ tc->setMiscRegNoEffect(MISCREG_TPC, pc.pc() & pcMask);
+ // set TNPC to NPC
+ tc->setMiscRegNoEffect(MISCREG_TNPC, pc.npc() & pcMask);
- //set HTSTATE.hpstate to hpstate
- tc->setMiscReg(MISCREG_HTSTATE, HPSTATE);
+ // set HTSTATE.hpstate to hpstate
+ tc->setMiscRegNoEffect(MISCREG_HTSTATE, hpstate);
- //TT = trap type;
- tc->setMiscReg(MISCREG_TT, tt);
+ // TT = trap type;
+ tc->setMiscRegNoEffect(MISCREG_TT, tt);
- //Update the global register level
- if(!gotoHpriv)
- tc->setMiscRegWithEffect(MISCREG_GL, min<int>(GL+1, MaxPGL));
- else
- tc->setMiscRegWithEffect(MISCREG_GL, min<int>(GL+1, MaxGL));
-
- //PSTATE.mm is unchanged
- //PSTATE.pef = whether or not an fpu is present
- //XXX We'll say there's one present, even though there aren't
- //implementations for a decent number of the instructions
- PSTATE |= (1 << 4);
- //PSTATE.am = 0
- PSTATE &= ~(1 << 3);
- if(!gotoHpriv)
- {
- //PSTATE.priv = 1
- PSTATE |= (1 << 2);
- //PSTATE.cle = PSTATE.tle
- replaceBits(PSTATE, 9, 9, PSTATE >> 8);
- }
+ // Update the global register level
+ if (!gotoHpriv)
+ tc->setMiscReg(MISCREG_GL, min<int>(GL + 1, MaxPGL));
else
- {
- //PSTATE.priv = 0
- //PSTATE.priv is set to 1 here. The manual says it should be 0, but
- //Legion sets it to 1.
- PSTATE |= (1 << 2);
- //PSTATE.cle = 0
- PSTATE &= ~(1 << 9);
- }
- //PSTATE.ie = 0
- PSTATE &= ~(1 << 1);
- //PSTATE.tle is unchanged
- //PSTATE.tct = 0
- //XXX Where exactly is this field?
- tc->setMiscReg(MISCREG_PSTATE, PSTATE);
-
- if(gotoHpriv)
- {
- //HPSTATE.red = 0
- HPSTATE &= ~(1 << 5);
- //HPSTATE.hpriv = 1
- HPSTATE |= (1 << 2);
- //HPSTATE.ibe = 0
- HPSTATE &= ~(1 << 10);
- //HPSTATE.tlz is unchanged
- tc->setMiscReg(MISCREG_HPSTATE, HPSTATE);
+ tc->setMiscReg(MISCREG_GL, min<int>(GL + 1, MaxGL));
+
+ // pstate.mm is unchanged
+ pstate.pef = 1; // PSTATE.pef = whether or not an fpu is present
+ pstate.am = 0;
+ pstate.ie = 0;
+ // pstate.tle is unchanged
+ // pstate.tct = 0
+
+ if (gotoHpriv) {
+ pstate.cle = 0;
+ // The manual says PSTATE.priv should be 0, but Legion leaves it alone
+ hpstate.red = 0;
+ hpstate.hpriv = 1;
+ hpstate.ibe = 0;
+ // hpstate.tlz is unchanged
+ tc->setMiscRegNoEffect(MISCREG_HPSTATE, hpstate);
+ } else { // we are going to priv
+ pstate.priv = 1;
+ pstate.cle = pstate.tle;
}
+ tc->setMiscRegNoEffect(MISCREG_PSTATE, pstate);
+
bool changedCWP = true;
- if(tt == 0x24)
+ if (tt == 0x24)
CWP++;
- else if(0x80 <= tt && tt <= 0xbf)
+ else if (0x80 <= tt && tt <= 0xbf)
CWP += (CANSAVE + 2);
- else if(0xc0 <= tt && tt <= 0xff)
+ else if (0xc0 <= tt && tt <= 0xff)
CWP--;
else
changedCWP = false;
- if(changedCWP)
- {
+ if (changedCWP) {
CWP = (CWP + NWindows) % NWindows;
- tc->setMiscRegWithEffect(MISCREG_CWP, CWP);
+ tc->setMiscReg(MISCREG_CWP, CWP);
}
}
-void getREDVector(MiscReg TT, Addr & PC, Addr & NPC)
+void
+getREDVector(RegVal TT, Addr &PC, Addr &NPC)
{
//XXX The following constant might belong in a header file.
const Addr RSTVAddr = 0xFFF0000000ULL;
NPC = PC + sizeof(MachInst);
}
-void getHyperVector(ThreadContext * tc, Addr & PC, Addr & NPC, MiscReg TT)
+void
+getHyperVector(ThreadContext * tc, Addr &PC, Addr &NPC, RegVal TT)
{
- Addr HTBA = tc->readMiscReg(MISCREG_HTBA);
+ Addr HTBA = tc->readMiscRegNoEffect(MISCREG_HTBA);
PC = (HTBA & ~mask(14)) | ((TT << 5) & mask(14));
NPC = PC + sizeof(MachInst);
}
-void getPrivVector(ThreadContext * tc, Addr & PC, Addr & NPC, MiscReg TT, MiscReg TL)
+void
+getPrivVector(ThreadContext *tc, Addr &PC, Addr &NPC, RegVal TT, RegVal TL)
{
- Addr TBA = tc->readMiscReg(MISCREG_TBA);
+ Addr TBA = tc->readMiscRegNoEffect(MISCREG_TBA);
PC = (TBA & ~mask(15)) |
(TL > 1 ? (1 << 14) : 0) |
((TT << 5) & mask(14));
NPC = PC + sizeof(MachInst);
}
-#if FULL_SYSTEM
-
-void SparcFaultBase::invoke(ThreadContext * tc)
+void
+SparcFaultBase::invoke(ThreadContext * tc, const StaticInstPtr &inst)
{
- panic("Invoking a second fault!\n");
FaultBase::invoke(tc);
+ if (!FullSystem)
+ return;
+
countStat()++;
- //We can refer to this to see what the trap level -was-, but something
- //in the middle could change it in the regfile out from under us.
- MiscReg TL = tc->readMiscReg(MISCREG_TL);
- MiscReg TT = tc->readMiscReg(MISCREG_TT);
- MiscReg PSTATE = tc->readMiscReg(MISCREG_PSTATE);
- MiscReg HPSTATE = tc->readMiscReg(MISCREG_HPSTATE);
+ // We can refer to this to see what the trap level -was-, but something
+ // in the middle could change it in the regfile out from under us.
+ RegVal tl = tc->readMiscRegNoEffect(MISCREG_TL);
+ RegVal tt = tc->readMiscRegNoEffect(MISCREG_TT);
+ PSTATE pstate = tc->readMiscRegNoEffect(MISCREG_PSTATE);
+ HPSTATE hpstate = tc->readMiscRegNoEffect(MISCREG_HPSTATE);
Addr PC, NPC;
PrivilegeLevel current;
- if(HPSTATE & (1 << 2))
+ if (hpstate.hpriv)
current = Hyperprivileged;
- else if(PSTATE & (1 << 2))
+ else if (pstate.priv)
current = Privileged;
else
current = User;
PrivilegeLevel level = getNextLevel(current);
- if(HPSTATE & (1 << 5) || TL == MaxTL - 1)
- {
+ if (hpstate.red || (tl == MaxTL - 1)) {
getREDVector(5, PC, NPC);
- doREDFault(tc, TT);
- //This changes the hpstate and pstate, so we need to make sure we
- //save the old version on the trap stack in doREDFault.
+ doREDFault(tc, tt);
+ // This changes the hpstate and pstate, so we need to make sure we
+ // save the old version on the trap stack in doREDFault.
enterREDState(tc);
- }
- else if(TL == MaxTL)
- {
- //Do error_state somehow?
- //Probably inject a WDR fault using the interrupt mechanism.
- //What should the PC and NPC be set to?
- }
- else if(TL > MaxPTL && level == Privileged)
- {
- //guest_watchdog fault
+ } else if (tl == MaxTL) {
+ panic("Should go to error state here.. crap\n");
+ // Do error_state somehow?
+ // Probably inject a WDR fault using the interrupt mechanism.
+ // What should the PC and NPC be set to?
+ } else if (tl > MaxPTL && level == Privileged) {
+ // guest_watchdog fault
doNormalFault(tc, trapType(), true);
getHyperVector(tc, PC, NPC, 2);
- }
- else if(level == Hyperprivileged)
- {
+ } else if (level == Hyperprivileged ||
+ (level == Privileged && trapType() >= 384)) {
doNormalFault(tc, trapType(), true);
getHyperVector(tc, PC, NPC, trapType());
- }
- else
- {
+ } else {
doNormalFault(tc, trapType(), false);
- getPrivVector(tc, PC, NPC, trapType(), TL+1);
+ getPrivVector(tc, PC, NPC, trapType(), tl + 1);
}
- tc->setPC(PC);
- tc->setNextPC(NPC);
- tc->setNextNPC(NPC + sizeof(MachInst));
+ PCState pc;
+ pc.pc(PC);
+ pc.npc(NPC);
+ pc.nnpc(NPC + sizeof(MachInst));
+ pc.upc(0);
+ pc.nupc(1);
+ tc->pcState(pc);
}
-void PowerOnReset::invoke(ThreadContext * tc)
+void
+PowerOnReset::invoke(ThreadContext *tc, const StaticInstPtr &inst)
{
- //For SPARC, when a system is first started, there is a power
- //on reset Trap which sets the processor into the following state.
- //Bits that aren't set aren't defined on startup.
-
- tc->setMiscReg(MISCREG_TL, MaxTL);
- tc->setMiscReg(MISCREG_TT, trapType());
- tc->setMiscRegWithEffect(MISCREG_GL, MaxGL);
-
- //Turn on pef and priv, set everything else to 0
- tc->setMiscReg(MISCREG_PSTATE, (1 << 4) | (1 << 2));
-
- //Turn on red and hpriv, set everything else to 0
- MiscReg HPSTATE = tc->readMiscReg(MISCREG_HPSTATE);
- //HPSTATE.red = 1
- HPSTATE |= (1 << 5);
- //HPSTATE.hpriv = 1
- HPSTATE |= (1 << 2);
- //HPSTATE.ibe = 0
- HPSTATE &= ~(1 << 10);
- //HPSTATE.tlz = 0
- HPSTATE &= ~(1 << 0);
- tc->setMiscReg(MISCREG_HPSTATE, HPSTATE);
-
- //The tick register is unreadable by nonprivileged software
- tc->setMiscReg(MISCREG_TICK, 1ULL << 63);
-
- //Enter RED state. We do this last so that the actual state preserved in
- //the trap stack is the state from before this fault.
+ // For SPARC, when a system is first started, there is a power
+ // on reset Trap which sets the processor into the following state.
+ // Bits that aren't set aren't defined on startup.
+
+ tc->setMiscRegNoEffect(MISCREG_TL, MaxTL);
+ tc->setMiscRegNoEffect(MISCREG_TT, trapType());
+ tc->setMiscReg(MISCREG_GL, MaxGL);
+
+ PSTATE pstate = 0;
+ pstate.pef = 1;
+ pstate.priv = 1;
+ tc->setMiscRegNoEffect(MISCREG_PSTATE, pstate);
+
+ // Turn on red and hpriv, set everything else to 0
+ HPSTATE hpstate = tc->readMiscRegNoEffect(MISCREG_HPSTATE);
+ hpstate.red = 1;
+ hpstate.hpriv = 1;
+ hpstate.ibe = 0;
+ hpstate.tlz = 0;
+ tc->setMiscRegNoEffect(MISCREG_HPSTATE, hpstate);
+
+ // The tick register is unreadable by nonprivileged software
+ tc->setMiscRegNoEffect(MISCREG_TICK, 1ULL << 63);
+
+ // Enter RED state. We do this last so that the actual state preserved in
+ // the trap stack is the state from before this fault.
enterREDState(tc);
Addr PC, NPC;
getREDVector(trapType(), PC, NPC);
- tc->setPC(PC);
- tc->setNextPC(NPC);
- tc->setNextNPC(NPC + sizeof(MachInst));
- //These registers are specified as "undefined" after a POR, and they
- //should have reasonable values after the miscregfile is reset
+ PCState pc;
+ pc.pc(PC);
+ pc.npc(NPC);
+ pc.nnpc(NPC + sizeof(MachInst));
+ pc.upc(0);
+ pc.nupc(1);
+ tc->pcState(pc);
+
+ // These registers are specified as "undefined" after a POR, and they
+ // should have reasonable values after the miscregfile is reset
/*
// Clear all the soft interrupt bits
softint = 0;
// disable timer compare interrupts, reset tick_cmpr
- tc->setMiscReg(MISCREG_
+ tc->setMiscRegNoEffect(MISCREG_
tick_cmprFields.int_dis = 1;
tick_cmprFields.tick_cmpr = 0; // Reset to 0 for pretty printing
- stickFields.npt = 1; //The TICK register is unreadable by by !priv
+ stickFields.npt = 1; // The TICK register is unreadable by by !priv
stick_cmprFields.int_dis = 1; // disable timer compare interrupts
stick_cmprFields.tick_cmpr = 0; // Reset to 0 for pretty printing
*/
}
-#else // !FULL_SYSTEM
+void
+FastInstructionAccessMMUMiss::invoke(ThreadContext *tc,
+ const StaticInstPtr &inst)
+{
+ if (FullSystem) {
+ SparcFaultBase::invoke(tc, inst);
+ return;
+ }
+
+ Process *p = tc->getProcessPtr();
+ const EmulationPageTable::Entry *pte = p->pTable->lookup(vaddr);
+ panic_if(!pte, "Tried to execute unmapped address %#x.\n", vaddr);
+
+ Addr alignedvaddr = p->pTable->pageAlign(vaddr);
+
+ // Grab fields used during instruction translation to figure out
+ // which context to use.
+ uint64_t tlbdata = tc->readMiscRegNoEffect(MISCREG_TLB_DATA);
+
+ // Inside a VM, a real address is the address that guest OS would
+ // interpret to be a physical address. To map to the physical address,
+ // it still needs to undergo a translation. The instruction
+ // translation code in the SPARC ITLB code assumes that the context is
+ // zero (kernel-level) if real addressing is being used.
+ bool is_real_address = !bits(tlbdata, 4);
+
+ // The SPARC ITLB code assumes that traps are executed in context
+ // zero so we carry that assumption through here.
+ bool trapped = bits(tlbdata, 18, 16) > 0;
+
+ // The primary context acts as a PASID. It allows the MMU to
+ // distinguish between virtual addresses that would alias to the
+ // same physical address (if two or more processes shared the same
+ // virtual address mapping).
+ int primary_context = bits(tlbdata, 47, 32);
+
+ // The partition id distinguishes between virtualized environments.
+ int const partition_id = 0;
+
+ // Given the assumptions in the translateInst code in the SPARC ITLB,
+ // the logic works out to the following for the context.
+ int context_id = (is_real_address || trapped) ? 0 : primary_context;
+
+ TlbEntry entry(p->pTable->pid(), alignedvaddr, pte->paddr,
+ pte->flags & EmulationPageTable::Uncacheable,
+ pte->flags & EmulationPageTable::ReadOnly);
+
+ // Insert the TLB entry.
+ // The entry specifying whether the address is "real" is set to
+ // false for syscall emulation mode regardless of whether the
+ // address is real in preceding code. Not sure sure that this is
+ // correct, but also not sure if it matters at all.
+ dynamic_cast<TLB *>(tc->getITBPtr())->
+ insert(alignedvaddr, partition_id, context_id, false, entry.pte);
+}
+
+void
+FastDataAccessMMUMiss::invoke(ThreadContext *tc, const StaticInstPtr &inst)
+{
+ if (FullSystem) {
+ SparcFaultBase::invoke(tc, inst);
+ return;
+ }
+
+ Process *p = tc->getProcessPtr();
+ const EmulationPageTable::Entry *pte = p->pTable->lookup(vaddr);
+ if (!pte && p->fixupStackFault(vaddr))
+ pte = p->pTable->lookup(vaddr);
+ panic_if(!pte, "Tried to access unmapped address %#x.\n", vaddr);
+
+ Addr alignedvaddr = p->pTable->pageAlign(vaddr);
+
+ // Grab fields used during data translation to figure out
+ // which context to use.
+ uint64_t tlbdata = tc->readMiscRegNoEffect(MISCREG_TLB_DATA);
+
+ // The primary context acts as a PASID. It allows the MMU to
+ // distinguish between virtual addresses that would alias to the
+ // same physical address (if two or more processes shared the same
+ // virtual address mapping). There's a secondary context used in the
+ // DTLB translation code, but it should __probably__ be zero for
+ // syscall emulation code. (The secondary context is used by Solaris
+ // to allow kernel privilege code to access user space code:
+ // [ISBN 0-13-022496-0]:PG199.)
+ int primary_context = bits(tlbdata, 47, 32);
+
+ // "Hyper-Privileged Mode" is in use. There are three main modes of
+ // operation for Sparc: Hyper-Privileged Mode, Privileged Mode, and
+ // User Mode.
+ int hpriv = bits(tlbdata, 0);
+
+ // Reset, Error and Debug state is in use. Something horrible has
+ // happened or the system is operating in Reset Mode.
+ int red = bits(tlbdata, 1);
+
+ // Inside a VM, a real address is the address that guest OS would
+ // interpret to be a physical address. To map to the physical address,
+ // it still needs to undergo a translation. The instruction
+ // translation code in the SPARC ITLB code assumes that the context is
+ // zero (kernel-level) if real addressing is being used.
+ int is_real_address = !bits(tlbdata, 5);
+
+ // Grab the address space identifier register from the thread context.
+ // XXX: Inspecting how setMiscReg and setMiscRegNoEffect behave for
+ // MISCREG_ASI causes me to think that the ASI register implementation
+ // might be bugged. The NoEffect variant changes the ASI register
+ // value in the architectural state while the normal variant changes
+ // the context field in the thread context's currently decoded request
+ // but does not directly affect the ASI register value in the
+ // architectural state. The ASI values and the context field in the
+ // request packet seem to have completely different uses.
+ RegVal reg_asi = tc->readMiscRegNoEffect(MISCREG_ASI);
+ ASI asi = static_cast<ASI>(reg_asi);
+
+ // The SPARC DTLB code assumes that traps are executed in context
+ // zero if the asi value is ASI_IMPLICIT (which is 0x0). There's also
+ // an assumption that the nucleus address space is being used, but
+ // the context is the relevant issue since we need to pass it to TLB.
+ bool trapped = bits(tlbdata, 18, 16) > 0;
+
+ // Given the assumptions in the translateData code in the SPARC DTLB,
+ // the logic works out to the following for the context.
+ int context_id = ((!hpriv && !red && is_real_address) ||
+ asiIsReal(asi) ||
+ (trapped && asi == ASI_IMPLICIT))
+ ? 0 : primary_context;
+
+ // The partition id distinguishes between virtualized environments.
+ int const partition_id = 0;
+
+ TlbEntry entry(p->pTable->pid(), alignedvaddr, pte->paddr,
+ pte->flags & EmulationPageTable::Uncacheable,
+ pte->flags & EmulationPageTable::ReadOnly);
+
+ // Insert the TLB entry.
+ // The entry specifying whether the address is "real" is set to
+ // false for syscall emulation mode regardless of whether the
+ // address is real in preceding code. Not sure sure that this is
+ // correct, but also not sure if it matters at all.
+ dynamic_cast<TLB *>(tc->getDTBPtr())->
+ insert(alignedvaddr, partition_id, context_id, false, entry.pte);
+}
-void SpillNNormal::invoke(ThreadContext *tc)
+void
+SpillNNormal::invoke(ThreadContext *tc, const StaticInstPtr &inst)
{
+ if (FullSystem) {
+ SparcFaultBase::invoke(tc, inst);
+ return;
+ }
+
doNormalFault(tc, trapType(), false);
Process *p = tc->getProcessPtr();
- //XXX This will only work in faults from a SparcLiveProcess
- SparcLiveProcess *lp = dynamic_cast<SparcLiveProcess *>(p);
- assert(lp);
+ SparcProcess *sp = dynamic_cast<SparcProcess *>(p);
+ assert(sp);
- //Then adjust the PC and NPC
- Addr spillStart = lp->readSpillStart();
- tc->setPC(spillStart);
- tc->setNextPC(spillStart + sizeof(MachInst));
- tc->setNextNPC(spillStart + 2*sizeof(MachInst));
+ // Then adjust the PC and NPC
+ tc->pcState(sp->readSpillStart());
}
-void FillNNormal::invoke(ThreadContext *tc)
+void
+FillNNormal::invoke(ThreadContext *tc, const StaticInstPtr &inst)
{
+ if (FullSystem) {
+ SparcFaultBase::invoke(tc, inst);
+ return;
+ }
+
doNormalFault(tc, trapType(), false);
- Process * p = tc->getProcessPtr();
+ Process *p = tc->getProcessPtr();
- //XXX This will only work in faults from a SparcLiveProcess
- SparcLiveProcess *lp = dynamic_cast<SparcLiveProcess *>(p);
- assert(lp);
+ SparcProcess *sp = dynamic_cast<SparcProcess *>(p);
+ assert(sp);
- //Then adjust the PC and NPC
- Addr fillStart = lp->readFillStart();
- tc->setPC(fillStart);
- tc->setNextPC(fillStart + sizeof(MachInst));
- tc->setNextNPC(fillStart + 2*sizeof(MachInst));
+ // Then adjust the PC and NPC
+ tc->pcState(sp->readFillStart());
}
-void PageTableFault::invoke(ThreadContext *tc)
+void
+TrapInstruction::invoke(ThreadContext *tc, const StaticInstPtr &inst)
{
+ if (FullSystem) {
+ SparcFaultBase::invoke(tc, inst);
+ return;
+ }
+
+ // In SE, this mechanism is how the process requests a service from
+ // the operating system. We'll get the process object from the thread
+ // context and let it service the request.
+
Process *p = tc->getProcessPtr();
- // address is higher than the stack region or in the current stack region
- if (vaddr > p->stack_base || vaddr > p->stack_min)
- FaultBase::invoke(tc);
-
- // We've accessed the next page
- if (vaddr > p->stack_min - PageBytes) {
- p->stack_min -= PageBytes;
- if (p->stack_base - p->stack_min > 8*1024*1024)
- fatal("Over max stack size for one thread\n");
- p->pTable->allocate(p->stack_min, PageBytes);
- warn("Increasing stack size by one page.");
- } else {
- FaultBase::invoke(tc);
- }
-}
+ SparcProcess *sp = dynamic_cast<SparcProcess *>(p);
+ assert(sp);
+
+ Fault fault;
+ sp->handleTrap(_n, tc, &fault);
-#endif
+ // We need to explicitly advance the pc, since that's not done for us
+ // on a faulting instruction
+ PCState pc = tc->pcState();
+ pc.advance();
+ tc->pcState(pc);
+}
} // namespace SparcISA