#include "common.h"
#include "config.h"
#include "sim.h"
-#include "htif.h"
+#include "mmu.h"
#include "disasm.h"
#include <cinttypes>
#include <cmath>
#undef STATE
#define STATE state
-processor_t::processor_t(const char* isa, sim_t* sim, uint32_t id)
- : sim(sim), ext(NULL), disassembler(new disassembler_t),
- id(id), run(false), debug(false)
+processor_t::processor_t(const char* isa, sim_t* sim, uint32_t id,
+ bool halt_on_reset)
+ : debug(false), halt_request(false), sim(sim), ext(NULL), id(id),
+ halt_on_reset(halt_on_reset)
{
parse_isa_string(isa);
+ register_base_instructions();
- mmu = new mmu_t(sim->mem, sim->memsz);
- mmu->set_processor(this);
-
- reset(true);
+ mmu = new mmu_t(sim, this);
+ disassembler = new disassembler_t(max_xlen);
- register_base_instructions();
+ reset();
}
processor_t::~processor_t()
const char* all_subsets = "imafdc";
max_xlen = 64;
- cpuid = reg_t(2) << 62;
+ isa = reg_t(2) << 62;
if (strncmp(p, "rv32", 4) == 0)
- max_xlen = 32, cpuid = 0, p += 4;
+ max_xlen = 32, isa = reg_t(1) << 30, p += 4;
else if (strncmp(p, "rv64", 4) == 0)
p += 4;
else if (strncmp(p, "rv", 2) == 0)
bad_isa_string(str);
}
- isa = "rv" + std::to_string(max_xlen) + p;
- cpuid |= 1L << ('s' - 'a'); // advertise support for supervisor mode
+ isa_string = "rv" + std::to_string(max_xlen) + p;
+ isa |= 1L << ('s' - 'a'); // advertise support for supervisor mode
+ isa |= 1L << ('u' - 'a'); // advertise support for user mode
while (*p) {
- cpuid |= 1L << (*p - 'a');
+ isa |= 1L << (*p - 'a');
if (auto next = strchr(all_subsets, *p)) {
all_subsets = next + 1;
if (supports_extension('D') && !supports_extension('F'))
bad_isa_string(str);
+
+ // advertise support for supervisor and user modes
+ isa |= 1L << ('s' - 'a');
+ isa |= 1L << ('u' - 'a');
+
+ max_isa = isa;
}
void state_t::reset()
{
memset(this, 0, sizeof(*this));
prv = PRV_M;
- pc = DEFAULT_MTVEC + 0x100;
+ pc = DEFAULT_RSTVEC;
+ mtvec = DEFAULT_MTVEC;
load_reservation = -1;
+ tselect = 0;
+ for (unsigned int i = 0; i < num_triggers; i++)
+ mcontrol[i].type = 2;
}
void processor_t::set_debug(bool value)
#endif
}
-void processor_t::reset(bool value)
+void processor_t::reset()
{
- if (run == !value)
- return;
- run = !value;
-
state.reset();
+ state.dcsr.halt = halt_on_reset;
+ halt_on_reset = false;
set_csr(CSR_MSTATUS, state.mstatus);
if (ext)
throw trap_t(((reg_t)1 << (max_xlen-1)) | which);
}
+// Count number of contiguous 0 bits starting from the LSB.
static int ctz(reg_t val)
{
int res = 0;
void processor_t::take_interrupt()
{
- check_timer();
+ reg_t pending_interrupts = state.mip & state.mie;
- reg_t interrupts = state.mip & state.mie;
-
- reg_t m_interrupts = interrupts & ~state.mideleg;
reg_t mie = get_field(state.mstatus, MSTATUS_MIE);
- if ((state.prv < PRV_M || (state.prv == PRV_M && mie)) && m_interrupts)
- raise_interrupt(ctz(m_interrupts));
+ reg_t m_enabled = state.prv < PRV_M || (state.prv == PRV_M && mie);
+ reg_t enabled_interrupts = pending_interrupts & ~state.mideleg & -m_enabled;
- reg_t s_interrupts = interrupts & state.mideleg;
reg_t sie = get_field(state.mstatus, MSTATUS_SIE);
- if ((state.prv < PRV_S || (state.prv == PRV_S && sie)) && s_interrupts)
- raise_interrupt(ctz(s_interrupts));
-}
-
-void processor_t::check_timer()
-{
- if (sim->rtc >= state.mtimecmp)
- state.mip |= MIP_MTIP;
-}
+ reg_t s_enabled = state.prv < PRV_S || (state.prv == PRV_S && sie);
+ enabled_interrupts |= pending_interrupts & state.mideleg & -s_enabled;
-static bool validate_priv(reg_t priv)
-{
- return priv == PRV_U || priv == PRV_S || priv == PRV_M;
+ if (enabled_interrupts)
+ raise_interrupt(ctz(enabled_interrupts));
}
void processor_t::set_privilege(reg_t prv)
{
- assert(validate_priv(prv));
+ assert(prv <= PRV_M);
+ if (prv == PRV_H)
+ prv = PRV_U;
mmu->flush_tlb();
state.prv = prv;
}
+void processor_t::enter_debug_mode(uint8_t cause)
+{
+ state.dcsr.cause = cause;
+ state.dcsr.prv = state.prv;
+ set_privilege(PRV_M);
+ state.dpc = state.pc;
+ state.pc = debug_rom_entry();
+}
+
void processor_t::take_trap(trap_t& t, reg_t epc)
{
- if (debug)
+ if (debug) {
fprintf(stderr, "core %3d: exception %s, epc 0x%016" PRIx64 "\n",
id, t.name(), epc);
+ if (t.has_badaddr())
+ fprintf(stderr, "core %3d: badaddr 0x%016" PRIx64 "\n", id,
+ t.get_badaddr());
+ }
+
+ if (state.dcsr.cause) {
+ if (t.cause() == CAUSE_BREAKPOINT) {
+ state.pc = debug_rom_entry();
+ } else {
+ state.pc = DEBUG_ROM_EXCEPTION;
+ }
+ return;
+ }
+
+ if (t.cause() == CAUSE_BREAKPOINT && (
+ (state.prv == PRV_M && state.dcsr.ebreakm) ||
+ (state.prv == PRV_H && state.dcsr.ebreakh) ||
+ (state.prv == PRV_S && state.dcsr.ebreaks) ||
+ (state.prv == PRV_U && state.dcsr.ebreaku))) {
+ enter_debug_mode(DCSR_CAUSE_SWBP);
+ return;
+ }
// by default, trap to M-mode, unless delegated to S-mode
reg_t bit = t.cause();
set_csr(CSR_MSTATUS, s);
set_privilege(PRV_S);
} else {
- state.pc = DEFAULT_MTVEC + 0x40 * state.prv;
- state.mcause = t.cause();
+ state.pc = state.mtvec;
state.mepc = epc;
+ state.mcause = t.cause();
if (t.has_badaddr())
state.mbadaddr = t.get_badaddr();
void processor_t::disasm(insn_t insn)
{
+ static uint64_t last_pc = 1, last_bits;
+ static uint64_t executions = 1;
+
uint64_t bits = insn.bits() & ((1ULL << (8 * insn_length(insn.bits()))) - 1);
- fprintf(stderr, "core %3d: 0x%016" PRIx64 " (0x%08" PRIx64 ") %s\n",
- id, state.pc, bits, disassembler->disassemble(insn).c_str());
+ if (last_pc != state.pc || last_bits != bits) {
+ if (executions != 1) {
+ fprintf(stderr, "core %3d: Executed %" PRIx64 " times\n", id, executions);
+ }
+
+ fprintf(stderr, "core %3d: 0x%016" PRIx64 " (0x%08" PRIx64 ") %s\n",
+ id, state.pc, bits, disassembler->disassemble(insn).c_str());
+ last_pc = state.pc;
+ last_bits = bits;
+ executions = 1;
+ } else {
+ executions++;
+ }
}
static bool validate_vm(int max_xlen, reg_t vm)
return vm == VM_MBARE;
}
+int processor_t::paddr_bits()
+{
+ assert(xlen == max_xlen);
+ return max_xlen == 64 ? 50 : 34;
+}
+
void processor_t::set_csr(int which, reg_t val)
{
- reg_t all_ints = MIP_SSIP | MIP_MSIP | MIP_STIP | MIP_MTIP | (1UL << IRQ_HOST);
- reg_t s_ints = MIP_SSIP | MIP_STIP;
+ val = zext_xlen(val);
+ reg_t delegable_ints = MIP_SSIP | MIP_STIP | MIP_SEIP | (1 << IRQ_COP);
+ reg_t all_ints = delegable_ints | MIP_MSIP | MIP_MTIP;
switch (which)
{
case CSR_FFLAGS:
state.fflags = (val & FSR_AEXC) >> FSR_AEXC_SHIFT;
state.frm = (val & FSR_RD) >> FSR_RD_SHIFT;
break;
- case CSR_MTIME:
- case CSR_STIMEW:
- // this implementation ignores writes to MTIME
- break;
- case CSR_MTIMEH:
- case CSR_STIMEHW:
- // this implementation ignores writes to MTIME
- break;
- case CSR_TIMEW:
- val -= sim->rtc;
- if (xlen == 32)
- state.sutime_delta = (uint32_t)val | (state.sutime_delta >> 32 << 32);
- else
- state.sutime_delta = val;
- break;
- case CSR_TIMEHW:
- val = ((val << 32) - sim->rtc) >> 32;
- state.sutime_delta = (val << 32) | (uint32_t)state.sutime_delta;
- break;
- case CSR_CYCLEW:
- case CSR_INSTRETW:
- val -= state.minstret;
- if (xlen == 32)
- state.suinstret_delta = (uint32_t)val | (state.suinstret_delta >> 32 << 32);
- else
- state.suinstret_delta = val;
- break;
- case CSR_CYCLEHW:
- case CSR_INSTRETHW:
- val = ((val << 32) - state.minstret) >> 32;
- state.suinstret_delta = (val << 32) | (uint32_t)state.suinstret_delta;
- break;
case CSR_MSTATUS: {
- if ((val ^ state.mstatus) & (MSTATUS_VM | MSTATUS_MPP | MSTATUS_MPRV))
+ if ((val ^ state.mstatus) &
+ (MSTATUS_VM | MSTATUS_MPP | MSTATUS_MPRV | MSTATUS_PUM | MSTATUS_MXR))
mmu->flush_tlb();
reg_t mask = MSTATUS_SIE | MSTATUS_SPIE | MSTATUS_MIE | MSTATUS_MPIE
- | MSTATUS_SPP | MSTATUS_MPRV | MSTATUS_FS
- | (ext ? MSTATUS_XS : 0);
+ | MSTATUS_SPP | MSTATUS_FS | MSTATUS_MPRV | MSTATUS_PUM
+ | MSTATUS_MPP | MSTATUS_MXR | (ext ? MSTATUS_XS : 0);
if (validate_vm(max_xlen, get_field(val, MSTATUS_VM)))
mask |= MSTATUS_VM;
- if (validate_priv(get_field(val, MSTATUS_MPP)))
- mask |= MSTATUS_MPP;
state.mstatus = (state.mstatus & ~mask) | (val & mask);
break;
}
case CSR_MIP: {
- reg_t mask = all_ints &~ MIP_MTIP;
+ reg_t mask = MIP_SSIP | MIP_STIP;
state.mip = (state.mip & ~mask) | (val & mask);
break;
}
- case CSR_MIPI:
- state.mip = set_field(state.mip, MIP_MSIP, val & 1);
- break;
case CSR_MIE:
state.mie = (state.mie & ~all_ints) | (val & all_ints);
break;
case CSR_MIDELEG:
- state.mideleg = (state.mideleg & ~s_ints) | (val & s_ints);
+ state.mideleg = (state.mideleg & ~delegable_ints) | (val & delegable_ints);
break;
case CSR_MEDELEG: {
reg_t mask = 0;
state.medeleg = (state.medeleg & ~mask) | (val & mask);
break;
}
+ case CSR_MINSTRET:
+ case CSR_MCYCLE:
+ if (xlen == 32)
+ state.minstret = (state.minstret >> 32 << 32) | (val & 0xffffffffU);
+ else
+ state.minstret = val;
+ break;
+ case CSR_MINSTRETH:
+ case CSR_MCYCLEH:
+ state.minstret = (val << 32) | (state.minstret << 32 >> 32);
+ break;
+ case CSR_MUCOUNTEREN:
+ state.mucounteren = val;
+ break;
+ case CSR_MSCOUNTEREN:
+ state.mscounteren = val;
+ break;
case CSR_SSTATUS: {
reg_t mask = SSTATUS_SIE | SSTATUS_SPIE | SSTATUS_SPP | SSTATUS_FS
- | SSTATUS_XS;
- set_csr(CSR_MSTATUS, (state.mstatus & ~mask) | (val & mask));
- break;
+ | SSTATUS_XS | SSTATUS_PUM;
+ return set_csr(CSR_MSTATUS, (state.mstatus & ~mask) | (val & mask));
}
case CSR_SIP: {
- reg_t mask = s_ints &~ MIP_STIP;
- state.mip = (state.mip & ~mask) | (val & mask);
- break;
+ reg_t mask = MIP_SSIP & state.mideleg;
+ return set_csr(CSR_MIP, (state.mip & ~mask) | (val & mask));
}
- case CSR_SIE: {
- reg_t mask = s_ints;
- state.mie = (state.mie & ~mask) | (val & mask);
+ case CSR_SIE:
+ return set_csr(CSR_MIE,
+ (state.mie & ~state.mideleg) | (val & state.mideleg));
+ case CSR_SPTBR: {
+ // upper bits of sptbr are the ASID; we only support ASID = 0
+ state.sptbr = val & (((reg_t)1 << (paddr_bits() - PGSHIFT)) - 1);
break;
}
case CSR_SEPC: state.sepc = val; break;
case CSR_STVEC: state.stvec = val >> 2 << 2; break;
- case CSR_SPTBR: state.sptbr = zext_xlen(val & -PGSIZE); break;
case CSR_SSCRATCH: state.sscratch = val; break;
case CSR_SCAUSE: state.scause = val; break;
case CSR_SBADADDR: state.sbadaddr = val; break;
case CSR_MEPC: state.mepc = val; break;
+ case CSR_MTVEC: state.mtvec = val >> 2 << 2; break;
case CSR_MSCRATCH: state.mscratch = val; break;
case CSR_MCAUSE: state.mcause = val; break;
case CSR_MBADADDR: state.mbadaddr = val; break;
- case CSR_MTIMECMP:
- state.mip &= ~MIP_MTIP;
- state.mtimecmp = val;
+ case CSR_MISA: {
+ if (!(val & (1L << ('F' - 'A'))))
+ val &= ~(1L << ('D' - 'A'));
+
+ // allow MAFDC bits in MISA to be modified
+ reg_t mask = 0;
+ mask |= 1L << ('M' - 'A');
+ mask |= 1L << ('A' - 'A');
+ mask |= 1L << ('F' - 'A');
+ mask |= 1L << ('D' - 'A');
+ mask |= 1L << ('C' - 'A');
+ mask &= max_isa;
+
+ isa = (val & mask) | (isa & ~mask);
break;
- case CSR_MTOHOST:
- if (state.tohost == 0)
- state.tohost = val;
+ }
+ case CSR_TSELECT:
+ if (val < state.num_triggers) {
+ state.tselect = val;
+ }
break;
- case CSR_MFROMHOST:
- state.mip = (state.mip & ~(1 << IRQ_HOST)) | (val ? (1 << IRQ_HOST) : 0);
- state.fromhost = val;
+ case CSR_TDATA1:
+ {
+ mcontrol_t *mc = &state.mcontrol[state.tselect];
+ if (mc->dmode && !state.dcsr.cause) {
+ break;
+ }
+ mc->dmode = get_field(val, MCONTROL_DMODE(xlen));
+ mc->select = get_field(val, MCONTROL_SELECT);
+ mc->timing = get_field(val, MCONTROL_TIMING);
+ mc->action = (mcontrol_action_t) get_field(val, MCONTROL_ACTION);
+ mc->chain = get_field(val, MCONTROL_CHAIN);
+ mc->match = (mcontrol_match_t) get_field(val, MCONTROL_MATCH);
+ mc->m = get_field(val, MCONTROL_M);
+ mc->h = get_field(val, MCONTROL_H);
+ mc->s = get_field(val, MCONTROL_S);
+ mc->u = get_field(val, MCONTROL_U);
+ mc->execute = get_field(val, MCONTROL_EXECUTE);
+ mc->store = get_field(val, MCONTROL_STORE);
+ mc->load = get_field(val, MCONTROL_LOAD);
+ // Assume we're here because of csrw.
+ if (mc->execute)
+ mc->timing = 0;
+ trigger_updated();
+ }
+ break;
+ case CSR_TDATA2:
+ if (state.mcontrol[state.tselect].dmode && !state.dcsr.cause) {
+ break;
+ }
+ if (state.tselect < state.num_triggers) {
+ state.tdata2[state.tselect] = val;
+ }
+ break;
+ case CSR_DCSR:
+ state.dcsr.prv = get_field(val, DCSR_PRV);
+ state.dcsr.step = get_field(val, DCSR_STEP);
+ // TODO: ndreset and fullreset
+ state.dcsr.ebreakm = get_field(val, DCSR_EBREAKM);
+ state.dcsr.ebreakh = get_field(val, DCSR_EBREAKH);
+ state.dcsr.ebreaks = get_field(val, DCSR_EBREAKS);
+ state.dcsr.ebreaku = get_field(val, DCSR_EBREAKU);
+ state.dcsr.halt = get_field(val, DCSR_HALT);
+ break;
+ case CSR_DPC:
+ state.dpc = val;
+ break;
+ case CSR_DSCRATCH:
+ state.dscratch = val;
break;
}
}
reg_t processor_t::get_csr(int which)
{
+ reg_t ctr_en = state.prv == PRV_U ? state.mucounteren :
+ state.prv == PRV_S ? state.mscounteren : -1U;
+ bool ctr_ok = (ctr_en >> (which & 31)) & 1;
+
+ if (ctr_ok) {
+ if (which >= CSR_HPMCOUNTER3 && which <= CSR_HPMCOUNTER31)
+ return 0;
+ if (xlen == 32 && which >= CSR_HPMCOUNTER3H && which <= CSR_HPMCOUNTER31H)
+ return 0;
+ }
+ if (which >= CSR_MHPMCOUNTER3 && which <= CSR_MHPMCOUNTER31)
+ return 0;
+ if (xlen == 32 && which >= CSR_MHPMCOUNTER3 && which <= CSR_MHPMCOUNTER31)
+ return 0;
+ if (which >= CSR_MHPMEVENT3 && which <= CSR_MHPMEVENT31)
+ return 0;
+
switch (which)
{
case CSR_FFLAGS:
if (!supports_extension('F'))
break;
return (state.fflags << FSR_AEXC_SHIFT) | (state.frm << FSR_RD_SHIFT);
- case CSR_MTIME:
- case CSR_STIME:
- case CSR_STIMEW:
- return sim->rtc;
- case CSR_MTIMEH:
- case CSR_STIMEH:
- case CSR_STIMEHW:
- return sim->rtc >> 32;
- case CSR_TIME:
- case CSR_TIMEW:
- return sim->rtc + state.sutime_delta;
- case CSR_CYCLE:
- case CSR_CYCLEW:
case CSR_INSTRET:
- case CSR_INSTRETW:
- return state.minstret + state.suinstret_delta;
- case CSR_TIMEH:
- case CSR_TIMEHW:
- if (xlen == 64)
- break;
- return (sim->rtc + state.sutime_delta) >> 32;
- case CSR_CYCLEH:
- case CSR_INSTRETH:
- case CSR_CYCLEHW:
- case CSR_INSTRETHW:
- if (xlen == 64)
- break;
- return (state.minstret + state.suinstret_delta) >> 32;
+ case CSR_CYCLE:
+ if (ctr_ok)
+ return state.minstret;
+ break;
+ case CSR_MINSTRET:
+ case CSR_MCYCLE:
+ return state.minstret;
+ case CSR_MINSTRETH:
+ case CSR_MCYCLEH:
+ if (xlen == 32)
+ return state.minstret >> 32;
+ break;
+ case CSR_MUCOUNTEREN: return state.mucounteren;
+ case CSR_MSCOUNTEREN: return state.mscounteren;
case CSR_SSTATUS: {
- reg_t sstatus = state.mstatus &
- (SSTATUS_SIE | SSTATUS_SPIE | SSTATUS_SPP | SSTATUS_FS | SSTATUS_XS);
+ reg_t mask = SSTATUS_SIE | SSTATUS_SPIE | SSTATUS_SPP | SSTATUS_FS
+ | SSTATUS_XS | SSTATUS_PUM;
+ reg_t sstatus = state.mstatus & mask;
if ((sstatus & SSTATUS_FS) == SSTATUS_FS ||
(sstatus & SSTATUS_XS) == SSTATUS_XS)
sstatus |= (xlen == 32 ? SSTATUS32_SD : SSTATUS64_SD);
return sstatus;
}
- case CSR_SIP: return state.mip & (MIP_SSIP | MIP_STIP);
- case CSR_SIE: return state.mie & (MIP_SSIP | MIP_STIP);
+ case CSR_SIP: return state.mip & state.mideleg;
+ case CSR_SIE: return state.mie & state.mideleg;
case CSR_SEPC: return state.sepc;
case CSR_SBADADDR: return state.sbadaddr;
case CSR_STVEC: return state.stvec;
return state.scause | ((state.scause >> (max_xlen-1)) << (xlen-1));
return state.scause;
case CSR_SPTBR: return state.sptbr;
- case CSR_SASID: return 0;
case CSR_SSCRATCH: return state.sscratch;
case CSR_MSTATUS: return state.mstatus;
case CSR_MIP: return state.mip;
- case CSR_MIPI: return 0;
case CSR_MIE: return state.mie;
case CSR_MEPC: return state.mepc;
case CSR_MSCRATCH: return state.mscratch;
case CSR_MCAUSE: return state.mcause;
case CSR_MBADADDR: return state.mbadaddr;
- case CSR_MTIMECMP: return state.mtimecmp;
- case CSR_MCPUID: return cpuid;
- case CSR_MIMPID: return IMPL_ROCKET;
+ case CSR_MISA: return isa;
+ case CSR_MARCHID: return 0;
+ case CSR_MIMPID: return 0;
+ case CSR_MVENDORID: return 0;
case CSR_MHARTID: return id;
- case CSR_MTVEC: return DEFAULT_MTVEC;
+ case CSR_MTVEC: return state.mtvec;
case CSR_MEDELEG: return state.medeleg;
case CSR_MIDELEG: return state.mideleg;
- case CSR_MTOHOST:
- sim->get_htif()->tick(); // not necessary, but faster
- return state.tohost;
- case CSR_MFROMHOST:
- sim->get_htif()->tick(); // not necessary, but faster
- return state.fromhost;
- case CSR_MIOBASE: return sim->memsz;
- case CSR_UARCH0:
- case CSR_UARCH1:
- case CSR_UARCH2:
- case CSR_UARCH3:
- case CSR_UARCH4:
- case CSR_UARCH5:
- case CSR_UARCH6:
- case CSR_UARCH7:
- case CSR_UARCH8:
- case CSR_UARCH9:
- case CSR_UARCH10:
- case CSR_UARCH11:
- case CSR_UARCH12:
- case CSR_UARCH13:
- case CSR_UARCH14:
- case CSR_UARCH15:
- return 0;
+ case CSR_TSELECT: return state.tselect;
+ case CSR_TDATA1:
+ if (state.tselect < state.num_triggers) {
+ reg_t v = 0;
+ mcontrol_t *mc = &state.mcontrol[state.tselect];
+ v = set_field(v, MCONTROL_TYPE(xlen), mc->type);
+ v = set_field(v, MCONTROL_DMODE(xlen), mc->dmode);
+ v = set_field(v, MCONTROL_MASKMAX(xlen), mc->maskmax);
+ v = set_field(v, MCONTROL_SELECT, mc->select);
+ v = set_field(v, MCONTROL_TIMING, mc->timing);
+ v = set_field(v, MCONTROL_ACTION, mc->action);
+ v = set_field(v, MCONTROL_CHAIN, mc->chain);
+ v = set_field(v, MCONTROL_MATCH, mc->match);
+ v = set_field(v, MCONTROL_M, mc->m);
+ v = set_field(v, MCONTROL_H, mc->h);
+ v = set_field(v, MCONTROL_S, mc->s);
+ v = set_field(v, MCONTROL_U, mc->u);
+ v = set_field(v, MCONTROL_EXECUTE, mc->execute);
+ v = set_field(v, MCONTROL_STORE, mc->store);
+ v = set_field(v, MCONTROL_LOAD, mc->load);
+ return v;
+ } else {
+ return 0;
+ }
+ break;
+ case CSR_TDATA2:
+ if (state.tselect < state.num_triggers) {
+ return state.tdata2[state.tselect];
+ } else {
+ return 0;
+ }
+ break;
+ case CSR_TDATA3: return 0;
+ case CSR_DCSR:
+ {
+ uint32_t v = 0;
+ v = set_field(v, DCSR_XDEBUGVER, 1);
+ v = set_field(v, DCSR_EBREAKM, state.dcsr.ebreakm);
+ v = set_field(v, DCSR_EBREAKH, state.dcsr.ebreakh);
+ v = set_field(v, DCSR_EBREAKS, state.dcsr.ebreaks);
+ v = set_field(v, DCSR_EBREAKU, state.dcsr.ebreaku);
+ v = set_field(v, DCSR_STOPCYCLE, 0);
+ v = set_field(v, DCSR_STOPTIME, 0);
+ v = set_field(v, DCSR_CAUSE, state.dcsr.cause);
+ v = set_field(v, DCSR_STEP, state.dcsr.step);
+ v = set_field(v, DCSR_PRV, state.dcsr.prv);
+ return v;
+ }
+ case CSR_DPC:
+ return state.dpc;
+ case CSR_DSCRATCH:
+ return state.dscratch;
}
throw trap_illegal_instruction();
}
std::sort(instructions.begin(), instructions.end(), cmp());
for (size_t i = 0; i < OPCODE_CACHE_SIZE; i++)
- opcode_cache[i] = {1, 0, &illegal_instruction, &illegal_instruction};
+ opcode_cache[i] = {0, 0, &illegal_instruction, &illegal_instruction};
}
void processor_t::register_extension(extension_t* x)
bool processor_t::load(reg_t addr, size_t len, uint8_t* bytes)
{
- try {
- auto res = get_csr(addr / (max_xlen / 8));
- memcpy(bytes, &res, len);
- return true;
- } catch (trap_illegal_instruction& t) {
- return false;
- }
+ return false;
}
bool processor_t::store(reg_t addr, size_t len, const uint8_t* bytes)
{
- try {
- reg_t value = 0;
- memcpy(&value, bytes, len);
- set_csr(addr / (max_xlen / 8), value);
- return true;
- } catch (trap_illegal_instruction& t) {
- return false;
+ switch (addr)
+ {
+ case 0:
+ state.mip &= ~MIP_MSIP;
+ if (bytes[0] & 1)
+ state.mip |= MIP_MSIP;
+ return true;
+
+ default:
+ return false;
+ }
+}
+
+void processor_t::trigger_updated()
+{
+ mmu->flush_tlb();
+ mmu->check_triggers_fetch = false;
+ mmu->check_triggers_load = false;
+ mmu->check_triggers_store = false;
+
+ for (unsigned i = 0; i < state.num_triggers; i++) {
+ if (state.mcontrol[i].execute) {
+ mmu->check_triggers_fetch = true;
+ }
+ if (state.mcontrol[i].load) {
+ mmu->check_triggers_load = true;
+ }
+ if (state.mcontrol[i].store) {
+ mmu->check_triggers_store = true;
+ }
}
}