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/*
* Copyright (c) 2009 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
*/
#include "arch/sparc/isa.hh"
#include "arch/sparc/asi.hh"
#include "arch/sparc/decoder.hh"
#include "arch/sparc/interrupts.hh"
#include "base/bitfield.hh"
#include "base/trace.hh"
#include "cpu/base.hh"
#include "cpu/thread_context.hh"
#include "debug/MiscRegs.hh"
#include "debug/Timer.hh"
#include "params/SparcISA.hh"
namespace SparcISA
{
static PSTATE
buildPstateMask()
{
PSTATE mask = 0;
mask.ie = 1;
mask.priv = 1;
mask.am = 1;
mask.pef = 1;
mask.mm = 3;
mask.tle = 1;
mask.cle = 1;
mask.pid1 = 1;
return mask;
}
static const PSTATE PstateMask = buildPstateMask();
ISA::ISA(Params *p) : BaseISA(p)
{
tickCompare = NULL;
sTickCompare = NULL;
hSTickCompare = NULL;
clear();
}
const SparcISAParams *
ISA::params() const
{
return dynamic_cast<const Params *>(_params);
}
void
ISA::reloadRegMap()
{
installGlobals(gl, CurrentGlobalsOffset);
installWindow(cwp, CurrentWindowOffset);
// Microcode registers.
for (int i = 0; i < NumMicroIntRegs; i++)
intRegMap[MicroIntOffset + i] = i + TotalGlobals + NWindows * 16;
installGlobals(gl, NextGlobalsOffset);
installWindow(cwp - 1, NextWindowOffset);
installGlobals(gl, PreviousGlobalsOffset);
installWindow(cwp + 1, PreviousWindowOffset);
}
void
ISA::installWindow(int cwp, int offset)
{
assert(offset >= 0 && offset + NumWindowedRegs <= NumIntRegs);
RegIndex *mapChunk = intRegMap + offset;
for (int i = 0; i < NumWindowedRegs; i++)
mapChunk[i] = TotalGlobals +
((i - cwp * RegsPerWindow + TotalWindowed) % (TotalWindowed));
}
void
ISA::installGlobals(int gl, int offset)
{
assert(offset >= 0 && offset + NumGlobalRegs <= NumIntRegs);
RegIndex *mapChunk = intRegMap + offset;
mapChunk[0] = 0;
for (int i = 1; i < NumGlobalRegs; i++)
mapChunk[i] = i + gl * NumGlobalRegs;
}
void
ISA::clear()
{
cwp = 0;
gl = 0;
reloadRegMap();
// y = 0;
// ccr = 0;
asi = 0;
tick = ULL(1) << 63;
fprs = 0;
gsr = 0;
softint = 0;
tick_cmpr = 0;
stick = 0;
stick_cmpr = 0;
memset(tpc, 0, sizeof(tpc));
memset(tnpc, 0, sizeof(tnpc));
memset(tstate, 0, sizeof(tstate));
memset(tt, 0, sizeof(tt));
tba = 0;
pstate = 0;
tl = 0;
pil = 0;
// cansave = 0;
// canrestore = 0;
// cleanwin = 0;
// otherwin = 0;
// wstate = 0;
// In a T1, bit 11 is apparently always 1
hpstate = 0;
hpstate.id = 1;
memset(htstate, 0, sizeof(htstate));
hintp = 0;
htba = 0;
hstick_cmpr = 0;
// This is set this way in Legion for some reason
strandStatusReg = 0x50000;
fsr = 0;
priContext = 0;
secContext = 0;
partId = 0;
lsuCtrlReg = 0;
memset(scratchPad, 0, sizeof(scratchPad));
cpu_mondo_head = 0;
cpu_mondo_tail = 0;
dev_mondo_head = 0;
dev_mondo_tail = 0;
res_error_head = 0;
res_error_tail = 0;
nres_error_head = 0;
nres_error_tail = 0;
// If one of these events is active, it's not obvious to me how to get
// rid of it cleanly. For now we'll just assert that they're not.
if (tickCompare != NULL && sTickCompare != NULL && hSTickCompare != NULL)
panic("Tick comparison event active when clearing the ISA object.\n");
}
RegVal
ISA::readMiscRegNoEffect(int miscReg) const
{
// The three miscRegs are moved up from the switch statement
// due to more frequent calls.
if (miscReg == MISCREG_GL)
return gl;
if (miscReg == MISCREG_CWP)
return cwp;
if (miscReg == MISCREG_TLB_DATA) {
/* Package up all the data for the tlb:
* 6666555555555544444444443333333333222222222211111111110000000000
* 3210987654321098765432109876543210987654321098765432109876543210
* secContext | priContext | |tl|partid| |||||^hpriv
* ||||^red
* |||^priv
* ||^am
* |^lsuim
* ^lsudm
*/
return (uint64_t)hpstate.hpriv |
(uint64_t)hpstate.red << 1 |
(uint64_t)pstate.priv << 2 |
(uint64_t)pstate.am << 3 |
bits((uint64_t)lsuCtrlReg,3,2) << 4 |
bits((uint64_t)partId,7,0) << 8 |
bits((uint64_t)tl,2,0) << 16 |
(uint64_t)priContext << 32 |
(uint64_t)secContext << 48;
}
switch (miscReg) {
// case MISCREG_TLB_DATA:
// [original contents see above]
// case MISCREG_Y:
// return y;
// case MISCREG_CCR:
// return ccr;
case MISCREG_ASI:
return asi;
case MISCREG_FPRS:
return fprs;
case MISCREG_TICK:
return tick;
case MISCREG_PCR:
panic("PCR not implemented\n");
case MISCREG_PIC:
panic("PIC not implemented\n");
case MISCREG_GSR:
return gsr;
case MISCREG_SOFTINT:
return softint;
case MISCREG_TICK_CMPR:
return tick_cmpr;
case MISCREG_STICK:
return stick;
case MISCREG_STICK_CMPR:
return stick_cmpr;
/** Privilged Registers */
case MISCREG_TPC:
return tpc[tl-1];
case MISCREG_TNPC:
return tnpc[tl-1];
case MISCREG_TSTATE:
return tstate[tl-1];
case MISCREG_TT:
return tt[tl-1];
case MISCREG_PRIVTICK:
panic("Priviliged access to tick registers not implemented\n");
case MISCREG_TBA:
return tba;
case MISCREG_PSTATE:
return (RegVal)pstate;
case MISCREG_TL:
return tl;
case MISCREG_PIL:
return pil;
// CWP, GL moved
// case MISCREG_CWP:
// return cwp;
// case MISCREG_CANSAVE:
// return cansave;
// case MISCREG_CANRESTORE:
// return canrestore;
// case MISCREG_CLEANWIN:
// return cleanwin;
// case MISCREG_OTHERWIN:
// return otherwin;
// case MISCREG_WSTATE:
// return wstate;
// case MISCREG_GL:
// return gl;
/** Hyper privileged registers */
case MISCREG_HPSTATE:
return (RegVal)hpstate;
case MISCREG_HTSTATE:
return htstate[tl-1];
case MISCREG_HINTP:
return hintp;
case MISCREG_HTBA:
return htba;
case MISCREG_STRAND_STS_REG:
return strandStatusReg;
case MISCREG_HSTICK_CMPR:
return hstick_cmpr;
/** Floating Point Status Register */
case MISCREG_FSR:
DPRINTF(MiscRegs, "FSR read as: %#x\n", fsr);
return fsr;
case MISCREG_MMU_P_CONTEXT:
return priContext;
case MISCREG_MMU_S_CONTEXT:
return secContext;
case MISCREG_MMU_PART_ID:
return partId;
case MISCREG_MMU_LSU_CTRL:
return lsuCtrlReg;
case MISCREG_SCRATCHPAD_R0:
return scratchPad[0];
case MISCREG_SCRATCHPAD_R1:
return scratchPad[1];
case MISCREG_SCRATCHPAD_R2:
return scratchPad[2];
case MISCREG_SCRATCHPAD_R3:
return scratchPad[3];
case MISCREG_SCRATCHPAD_R4:
return scratchPad[4];
case MISCREG_SCRATCHPAD_R5:
return scratchPad[5];
case MISCREG_SCRATCHPAD_R6:
return scratchPad[6];
case MISCREG_SCRATCHPAD_R7:
return scratchPad[7];
case MISCREG_QUEUE_CPU_MONDO_HEAD:
return cpu_mondo_head;
case MISCREG_QUEUE_CPU_MONDO_TAIL:
return cpu_mondo_tail;
case MISCREG_QUEUE_DEV_MONDO_HEAD:
return dev_mondo_head;
case MISCREG_QUEUE_DEV_MONDO_TAIL:
return dev_mondo_tail;
case MISCREG_QUEUE_RES_ERROR_HEAD:
return res_error_head;
case MISCREG_QUEUE_RES_ERROR_TAIL:
return res_error_tail;
case MISCREG_QUEUE_NRES_ERROR_HEAD:
return nres_error_head;
case MISCREG_QUEUE_NRES_ERROR_TAIL:
return nres_error_tail;
default:
panic("Miscellaneous register %d not implemented\n", miscReg);
}
}
RegVal
ISA::readMiscReg(int miscReg, ThreadContext * tc)
{
switch (miscReg) {
// tick and stick are aliased to each other in niagra
// well store the tick data in stick and the interrupt bit in tick
case MISCREG_STICK:
case MISCREG_TICK:
case MISCREG_PRIVTICK:
// I'm not sure why legion ignores the lowest two bits, but we'll go
// with it
// change from curCycle() to instCount() until we're done with legion
DPRINTF(Timer, "Instruction Count when TICK read: %#X stick=%#X\n",
tc->getCpuPtr()->instCount(), stick);
return mbits(tc->getCpuPtr()->instCount() + (int64_t)stick,62,2) |
mbits(tick,63,63);
case MISCREG_FPRS:
// in legion if fp is enabled du and dl are set
return fprs | 0x3;
case MISCREG_PCR:
case MISCREG_PIC:
panic("Performance Instrumentation not impl\n");
case MISCREG_SOFTINT_CLR:
case MISCREG_SOFTINT_SET:
panic("Can read from softint clr/set\n");
case MISCREG_SOFTINT:
case MISCREG_TICK_CMPR:
case MISCREG_STICK_CMPR:
case MISCREG_HINTP:
case MISCREG_HTSTATE:
case MISCREG_HTBA:
case MISCREG_HVER:
case MISCREG_STRAND_STS_REG:
case MISCREG_HSTICK_CMPR:
case MISCREG_QUEUE_CPU_MONDO_HEAD:
case MISCREG_QUEUE_CPU_MONDO_TAIL:
case MISCREG_QUEUE_DEV_MONDO_HEAD:
case MISCREG_QUEUE_DEV_MONDO_TAIL:
case MISCREG_QUEUE_RES_ERROR_HEAD:
case MISCREG_QUEUE_RES_ERROR_TAIL:
case MISCREG_QUEUE_NRES_ERROR_HEAD:
case MISCREG_QUEUE_NRES_ERROR_TAIL:
case MISCREG_HPSTATE:
return readFSReg(miscReg, tc);
}
return readMiscRegNoEffect(miscReg);
}
void
ISA::setMiscRegNoEffect(int miscReg, RegVal val)
{
switch (miscReg) {
// case MISCREG_Y:
// y = val;
// break;
// case MISCREG_CCR:
// ccr = val;
// break;
case MISCREG_ASI:
asi = val;
break;
case MISCREG_FPRS:
fprs = val;
break;
case MISCREG_TICK:
tick = val;
break;
case MISCREG_PCR:
panic("PCR not implemented\n");
case MISCREG_PIC:
panic("PIC not implemented\n");
case MISCREG_GSR:
gsr = val;
break;
case MISCREG_SOFTINT:
softint = val;
break;
case MISCREG_TICK_CMPR:
tick_cmpr = val;
break;
case MISCREG_STICK:
stick = val;
break;
case MISCREG_STICK_CMPR:
stick_cmpr = val;
break;
/** Privilged Registers */
case MISCREG_TPC:
tpc[tl-1] = val;
break;
case MISCREG_TNPC:
tnpc[tl-1] = val;
break;
case MISCREG_TSTATE:
tstate[tl-1] = val;
break;
case MISCREG_TT:
tt[tl-1] = val;
break;
case MISCREG_PRIVTICK:
panic("Priviliged access to tick regesiters not implemented\n");
case MISCREG_TBA:
// clear lower 7 bits on writes.
tba = val & ULL(~0x7FFF);
break;
case MISCREG_PSTATE:
pstate = (val & PstateMask);
break;
case MISCREG_TL:
tl = val;
break;
case MISCREG_PIL:
pil = val;
break;
case MISCREG_CWP:
cwp = val;
break;
// case MISCREG_CANSAVE:
// cansave = val;
// break;
// case MISCREG_CANRESTORE:
// canrestore = val;
// break;
// case MISCREG_CLEANWIN:
// cleanwin = val;
// break;
// case MISCREG_OTHERWIN:
// otherwin = val;
// break;
// case MISCREG_WSTATE:
// wstate = val;
// break;
case MISCREG_GL:
gl = val;
break;
/** Hyper privileged registers */
case MISCREG_HPSTATE:
hpstate = val;
break;
case MISCREG_HTSTATE:
htstate[tl-1] = val;
break;
case MISCREG_HINTP:
hintp = val;
break;
case MISCREG_HTBA:
htba = val;
break;
case MISCREG_STRAND_STS_REG:
strandStatusReg = val;
break;
case MISCREG_HSTICK_CMPR:
hstick_cmpr = val;
break;
/** Floating Point Status Register */
case MISCREG_FSR:
fsr = val;
DPRINTF(MiscRegs, "FSR written with: %#x\n", fsr);
break;
case MISCREG_MMU_P_CONTEXT:
priContext = val;
break;
case MISCREG_MMU_S_CONTEXT:
secContext = val;
break;
case MISCREG_MMU_PART_ID:
partId = val;
break;
case MISCREG_MMU_LSU_CTRL:
lsuCtrlReg = val;
break;
case MISCREG_SCRATCHPAD_R0:
scratchPad[0] = val;
break;
case MISCREG_SCRATCHPAD_R1:
scratchPad[1] = val;
break;
case MISCREG_SCRATCHPAD_R2:
scratchPad[2] = val;
break;
case MISCREG_SCRATCHPAD_R3:
scratchPad[3] = val;
break;
case MISCREG_SCRATCHPAD_R4:
scratchPad[4] = val;
break;
case MISCREG_SCRATCHPAD_R5:
scratchPad[5] = val;
break;
case MISCREG_SCRATCHPAD_R6:
scratchPad[6] = val;
break;
case MISCREG_SCRATCHPAD_R7:
scratchPad[7] = val;
break;
case MISCREG_QUEUE_CPU_MONDO_HEAD:
cpu_mondo_head = val;
break;
case MISCREG_QUEUE_CPU_MONDO_TAIL:
cpu_mondo_tail = val;
break;
case MISCREG_QUEUE_DEV_MONDO_HEAD:
dev_mondo_head = val;
break;
case MISCREG_QUEUE_DEV_MONDO_TAIL:
dev_mondo_tail = val;
break;
case MISCREG_QUEUE_RES_ERROR_HEAD:
res_error_head = val;
break;
case MISCREG_QUEUE_RES_ERROR_TAIL:
res_error_tail = val;
break;
case MISCREG_QUEUE_NRES_ERROR_HEAD:
nres_error_head = val;
break;
case MISCREG_QUEUE_NRES_ERROR_TAIL:
nres_error_tail = val;
break;
default:
panic("Miscellaneous register %d not implemented\n", miscReg);
}
}
void
ISA::setMiscReg(int miscReg, RegVal val, ThreadContext * tc)
{
RegVal new_val = val;
switch (miscReg) {
case MISCREG_ASI:
tc->getDecoderPtr()->setContext(val);
break;
case MISCREG_STICK:
case MISCREG_TICK:
// stick and tick are same thing on niagra
// use stick for offset and tick for holding intrrupt bit
stick = mbits(val,62,0) - tc->getCpuPtr()->instCount();
tick = mbits(val,63,63);
DPRINTF(Timer, "Writing TICK=%#X\n", val);
break;
case MISCREG_FPRS:
// Configure the fpu based on the fprs
break;
case MISCREG_PCR:
// Set up performance counting based on pcr value
break;
case MISCREG_PSTATE:
pstate = val & PstateMask;
return;
case MISCREG_TL:
{
tl = val;
if (hpstate.tlz && tl == 0 && !hpstate.hpriv)
tc->getCpuPtr()->postInterrupt(0, IT_TRAP_LEVEL_ZERO, 0);
else
tc->getCpuPtr()->clearInterrupt(0, IT_TRAP_LEVEL_ZERO, 0);
return;
}
case MISCREG_CWP:
new_val = val >= NWindows ? NWindows - 1 : val;
if (val >= NWindows)
new_val = NWindows - 1;
installWindow(new_val, CurrentWindowOffset);
installWindow(new_val - 1, NextWindowOffset);
installWindow(new_val + 1, PreviousWindowOffset);
break;
case MISCREG_GL:
installGlobals(val, CurrentGlobalsOffset);
installGlobals(val, NextGlobalsOffset);
installGlobals(val, PreviousGlobalsOffset);
break;
case MISCREG_PIL:
case MISCREG_SOFTINT:
case MISCREG_SOFTINT_SET:
case MISCREG_SOFTINT_CLR:
case MISCREG_TICK_CMPR:
case MISCREG_STICK_CMPR:
case MISCREG_HINTP:
case MISCREG_HTSTATE:
case MISCREG_HTBA:
case MISCREG_HVER:
case MISCREG_STRAND_STS_REG:
case MISCREG_HSTICK_CMPR:
case MISCREG_QUEUE_CPU_MONDO_HEAD:
case MISCREG_QUEUE_CPU_MONDO_TAIL:
case MISCREG_QUEUE_DEV_MONDO_HEAD:
case MISCREG_QUEUE_DEV_MONDO_TAIL:
case MISCREG_QUEUE_RES_ERROR_HEAD:
case MISCREG_QUEUE_RES_ERROR_TAIL:
case MISCREG_QUEUE_NRES_ERROR_HEAD:
case MISCREG_QUEUE_NRES_ERROR_TAIL:
case MISCREG_HPSTATE:
setFSReg(miscReg, val, tc);
return;
}
setMiscRegNoEffect(miscReg, new_val);
}
void
ISA::serialize(CheckpointOut &cp) const
{
SERIALIZE_SCALAR(asi);
SERIALIZE_SCALAR(tick);
SERIALIZE_SCALAR(fprs);
SERIALIZE_SCALAR(gsr);
SERIALIZE_SCALAR(softint);
SERIALIZE_SCALAR(tick_cmpr);
SERIALIZE_SCALAR(stick);
SERIALIZE_SCALAR(stick_cmpr);
SERIALIZE_ARRAY(tpc,MaxTL);
SERIALIZE_ARRAY(tnpc,MaxTL);
SERIALIZE_ARRAY(tstate,MaxTL);
SERIALIZE_ARRAY(tt,MaxTL);
SERIALIZE_SCALAR(tba);
SERIALIZE_SCALAR(pstate);
SERIALIZE_SCALAR(tl);
SERIALIZE_SCALAR(pil);
SERIALIZE_SCALAR(cwp);
SERIALIZE_SCALAR(gl);
SERIALIZE_SCALAR(hpstate);
SERIALIZE_ARRAY(htstate,MaxTL);
SERIALIZE_SCALAR(hintp);
SERIALIZE_SCALAR(htba);
SERIALIZE_SCALAR(hstick_cmpr);
SERIALIZE_SCALAR(strandStatusReg);
SERIALIZE_SCALAR(fsr);
SERIALIZE_SCALAR(priContext);
SERIALIZE_SCALAR(secContext);
SERIALIZE_SCALAR(partId);
SERIALIZE_SCALAR(lsuCtrlReg);
SERIALIZE_ARRAY(scratchPad,8);
SERIALIZE_SCALAR(cpu_mondo_head);
SERIALIZE_SCALAR(cpu_mondo_tail);
SERIALIZE_SCALAR(dev_mondo_head);
SERIALIZE_SCALAR(dev_mondo_tail);
SERIALIZE_SCALAR(res_error_head);
SERIALIZE_SCALAR(res_error_tail);
SERIALIZE_SCALAR(nres_error_head);
SERIALIZE_SCALAR(nres_error_tail);
Tick tick_cmp = 0, stick_cmp = 0, hstick_cmp = 0;
ThreadContext *tc = NULL;
BaseCPU *cpu = NULL;
int tc_num = 0;
bool tick_intr_sched = true;
if (tickCompare)
tc = tickCompare->getTC();
else if (sTickCompare)
tc = sTickCompare->getTC();
else if (hSTickCompare)
tc = hSTickCompare->getTC();
else
tick_intr_sched = false;
SERIALIZE_SCALAR(tick_intr_sched);
if (tc) {
cpu = tc->getCpuPtr();
tc_num = cpu->findContext(tc);
if (tickCompare && tickCompare->scheduled())
tick_cmp = tickCompare->when();
if (sTickCompare && sTickCompare->scheduled())
stick_cmp = sTickCompare->when();
if (hSTickCompare && hSTickCompare->scheduled())
hstick_cmp = hSTickCompare->when();
SERIALIZE_OBJPTR(cpu);
SERIALIZE_SCALAR(tc_num);
SERIALIZE_SCALAR(tick_cmp);
SERIALIZE_SCALAR(stick_cmp);
SERIALIZE_SCALAR(hstick_cmp);
}
}
void
ISA::unserialize(CheckpointIn &cp)
{
UNSERIALIZE_SCALAR(asi);
UNSERIALIZE_SCALAR(tick);
UNSERIALIZE_SCALAR(fprs);
UNSERIALIZE_SCALAR(gsr);
UNSERIALIZE_SCALAR(softint);
UNSERIALIZE_SCALAR(tick_cmpr);
UNSERIALIZE_SCALAR(stick);
UNSERIALIZE_SCALAR(stick_cmpr);
UNSERIALIZE_ARRAY(tpc,MaxTL);
UNSERIALIZE_ARRAY(tnpc,MaxTL);
UNSERIALIZE_ARRAY(tstate,MaxTL);
UNSERIALIZE_ARRAY(tt,MaxTL);
UNSERIALIZE_SCALAR(tba);
{
uint16_t pstate;
UNSERIALIZE_SCALAR(pstate);
this->pstate = pstate;
}
UNSERIALIZE_SCALAR(tl);
UNSERIALIZE_SCALAR(pil);
UNSERIALIZE_SCALAR(cwp);
UNSERIALIZE_SCALAR(gl);
reloadRegMap();
{
uint64_t hpstate;
UNSERIALIZE_SCALAR(hpstate);
this->hpstate = hpstate;
}
UNSERIALIZE_ARRAY(htstate,MaxTL);
UNSERIALIZE_SCALAR(hintp);
UNSERIALIZE_SCALAR(htba);
UNSERIALIZE_SCALAR(hstick_cmpr);
UNSERIALIZE_SCALAR(strandStatusReg);
UNSERIALIZE_SCALAR(fsr);
UNSERIALIZE_SCALAR(priContext);
UNSERIALIZE_SCALAR(secContext);
UNSERIALIZE_SCALAR(partId);
UNSERIALIZE_SCALAR(lsuCtrlReg);
UNSERIALIZE_ARRAY(scratchPad,8);
UNSERIALIZE_SCALAR(cpu_mondo_head);
UNSERIALIZE_SCALAR(cpu_mondo_tail);
UNSERIALIZE_SCALAR(dev_mondo_head);
UNSERIALIZE_SCALAR(dev_mondo_tail);
UNSERIALIZE_SCALAR(res_error_head);
UNSERIALIZE_SCALAR(res_error_tail);
UNSERIALIZE_SCALAR(nres_error_head);
UNSERIALIZE_SCALAR(nres_error_tail);
Tick tick_cmp = 0, stick_cmp = 0, hstick_cmp = 0;
ThreadContext *tc = NULL;
BaseCPU *cpu = NULL;
int tc_num;
bool tick_intr_sched;
UNSERIALIZE_SCALAR(tick_intr_sched);
if (tick_intr_sched) {
UNSERIALIZE_OBJPTR(cpu);
if (cpu) {
UNSERIALIZE_SCALAR(tc_num);
UNSERIALIZE_SCALAR(tick_cmp);
UNSERIALIZE_SCALAR(stick_cmp);
UNSERIALIZE_SCALAR(hstick_cmp);
tc = cpu->getContext(tc_num);
if (tick_cmp) {
tickCompare = new TickCompareEvent(this, tc);
schedule(tickCompare, tick_cmp);
}
if (stick_cmp) {
sTickCompare = new STickCompareEvent(this, tc);
schedule(sTickCompare, stick_cmp);
}
if (hstick_cmp) {
hSTickCompare = new HSTickCompareEvent(this, tc);
schedule(hSTickCompare, hstick_cmp);
}
}
}
}
}
SparcISA::ISA *
SparcISAParams::create()
{
return new SparcISA::ISA(this);
}