1 // See LICENSE for license details.
22 processor_t::processor_t(const char* isa
, simif_t
* sim
, uint32_t id
,
24 : debug(false), halt_request(false), sim(sim
), ext(NULL
), id(id
),
25 halt_on_reset(halt_on_reset
), last_pc(1), executions(1)
27 disassembler
= new disassembler_t(max_xlen
);
28 parse_isa_string(isa
);
29 register_base_instructions();
31 mmu
= new mmu_t(sim
, this);
36 processor_t::~processor_t()
38 #ifdef RISCV_ENABLE_HISTOGRAM
39 if (histogram_enabled
)
41 fprintf(stderr
, "PC Histogram size:%zu\n", pc_histogram
.size());
42 for (auto it
: pc_histogram
)
43 fprintf(stderr
, "%0" PRIx64
" %" PRIu64
"\n", it
.first
, it
.second
);
51 static void bad_isa_string(const char* isa
)
53 fprintf(stderr
, "error: bad --isa option %s\n", isa
);
57 void processor_t::parse_isa_string(const char* str
)
59 std::string lowercase
, tmp
;
60 for (const char *r
= str
; *r
; r
++)
61 lowercase
+= std::tolower(*r
);
63 const char* p
= lowercase
.c_str();
64 const char* all_subsets
= "imafdqc";
67 state
.misa
= reg_t(2) << 62;
69 if (strncmp(p
, "rv32", 4) == 0)
70 max_xlen
= 32, state
.misa
= reg_t(1) << 30, p
+= 4;
71 else if (strncmp(p
, "rv64", 4) == 0)
73 else if (strncmp(p
, "rv", 2) == 0)
78 } else if (*p
== 'g') { // treat "G" as "IMAFD"
79 tmp
= std::string("imafd") + (p
+1);
81 } else if (*p
!= 'i') {
85 isa_string
= "rv" + std::to_string(max_xlen
) + p
;
86 state
.misa
|= 1L << ('s' - 'a'); // advertise support for supervisor mode
87 state
.misa
|= 1L << ('u' - 'a'); // advertise support for user mode
90 state
.misa
|= 1L << (*p
- 'a');
92 if (auto next
= strchr(all_subsets
, *p
)) {
93 all_subsets
= next
+ 1;
95 } else if (*p
== 'x') {
96 const char* ext
= p
+1, *end
= ext
;
99 register_extension(find_extension(std::string(ext
, end
- ext
).c_str())());
106 if (supports_extension('D') && !supports_extension('F'))
109 if (supports_extension('Q') && !supports_extension('D'))
112 if (supports_extension('Q') && max_xlen
< 64)
115 max_isa
= state
.misa
;
118 void state_t::reset(reg_t max_isa
)
120 memset(this, 0, sizeof(*this));
125 for (unsigned int i
= 0; i
< num_triggers
; i
++)
126 mcontrol
[i
].type
= 2;
129 void processor_t::set_debug(bool value
)
133 ext
->set_debug(value
);
136 void processor_t::set_histogram(bool value
)
138 histogram_enabled
= value
;
139 #ifndef RISCV_ENABLE_HISTOGRAM
141 fprintf(stderr
, "PC Histogram support has not been properly enabled;");
142 fprintf(stderr
, " please re-build the riscv-isa-run project using \"configure --enable-histogram\".\n");
147 void processor_t::reset()
149 state
.reset(max_isa
);
150 state
.dcsr
.halt
= halt_on_reset
;
151 halt_on_reset
= false;
152 set_csr(CSR_MSTATUS
, state
.mstatus
);
155 ext
->reset(); // reset the extension
161 // Count number of contiguous 0 bits starting from the LSB.
162 static int ctz(reg_t val
)
166 while ((val
& 1) == 0)
171 void processor_t::take_interrupt(reg_t pending_interrupts
)
173 reg_t mie
= get_field(state
.mstatus
, MSTATUS_MIE
);
174 reg_t m_enabled
= state
.prv
< PRV_M
|| (state
.prv
== PRV_M
&& mie
);
175 reg_t enabled_interrupts
= pending_interrupts
& ~state
.mideleg
& -m_enabled
;
177 reg_t sie
= get_field(state
.mstatus
, MSTATUS_SIE
);
178 reg_t s_enabled
= state
.prv
< PRV_S
|| (state
.prv
== PRV_S
&& sie
);
179 // M-ints have highest priority; consider S-ints only if no M-ints pending
180 if (enabled_interrupts
== 0)
181 enabled_interrupts
= pending_interrupts
& state
.mideleg
& -s_enabled
;
183 if (state
.dcsr
.cause
== 0 && enabled_interrupts
) {
184 // nonstandard interrupts have highest priority
185 if (enabled_interrupts
>> IRQ_M_EXT
)
186 enabled_interrupts
= enabled_interrupts
>> IRQ_M_EXT
<< IRQ_M_EXT
;
187 // external interrupts have next-highest priority
188 else if (enabled_interrupts
& (MIP_MEIP
| MIP_SEIP
))
189 enabled_interrupts
= enabled_interrupts
& (MIP_MEIP
| MIP_SEIP
);
190 // software interrupts have next-highest priority
191 else if (enabled_interrupts
& (MIP_MSIP
| MIP_SSIP
))
192 enabled_interrupts
= enabled_interrupts
& (MIP_MSIP
| MIP_SSIP
);
193 // timer interrupts have next-highest priority
194 else if (enabled_interrupts
& (MIP_MTIP
| MIP_STIP
))
195 enabled_interrupts
= enabled_interrupts
& (MIP_MTIP
| MIP_STIP
);
199 throw trap_t(((reg_t
)1 << (max_xlen
-1)) | ctz(enabled_interrupts
));
203 static int xlen_to_uxl(int xlen
)
212 reg_t
processor_t::legalize_privilege(reg_t prv
)
214 assert(prv
<= PRV_M
);
216 if (!supports_extension('U'))
219 if (prv
== PRV_H
|| !supports_extension('S'))
225 void processor_t::set_privilege(reg_t prv
)
228 state
.prv
= legalize_privilege(prv
);
231 void processor_t::enter_debug_mode(uint8_t cause
)
233 state
.dcsr
.cause
= cause
;
234 state
.dcsr
.prv
= state
.prv
;
235 set_privilege(PRV_M
);
236 state
.dpc
= state
.pc
;
237 state
.pc
= DEBUG_ROM_ENTRY
;
240 void processor_t::take_trap(trap_t
& t
, reg_t epc
)
243 fprintf(stderr
, "core %3d: exception %s, epc 0x%016" PRIx64
"\n",
246 fprintf(stderr
, "core %3d: tval 0x%016" PRIx64
"\n", id
,
250 if (state
.dcsr
.cause
) {
251 if (t
.cause() == CAUSE_BREAKPOINT
) {
252 state
.pc
= DEBUG_ROM_ENTRY
;
254 state
.pc
= DEBUG_ROM_TVEC
;
259 if (t
.cause() == CAUSE_BREAKPOINT
&& (
260 (state
.prv
== PRV_M
&& state
.dcsr
.ebreakm
) ||
261 (state
.prv
== PRV_S
&& state
.dcsr
.ebreaks
) ||
262 (state
.prv
== PRV_U
&& state
.dcsr
.ebreaku
))) {
263 enter_debug_mode(DCSR_CAUSE_SWBP
);
267 // by default, trap to M-mode, unless delegated to S-mode
268 reg_t bit
= t
.cause();
269 reg_t deleg
= state
.medeleg
;
270 bool interrupt
= (bit
& ((reg_t
)1 << (max_xlen
-1))) != 0;
272 deleg
= state
.mideleg
, bit
&= ~((reg_t
)1 << (max_xlen
-1));
273 if (state
.prv
<= PRV_S
&& bit
< max_xlen
&& ((deleg
>> bit
) & 1)) {
274 // handle the trap in S-mode
275 state
.pc
= state
.stvec
;
276 state
.scause
= t
.cause();
278 state
.stval
= t
.get_tval();
280 reg_t s
= state
.mstatus
;
281 s
= set_field(s
, MSTATUS_SPIE
, get_field(s
, MSTATUS_SIE
));
282 s
= set_field(s
, MSTATUS_SPP
, state
.prv
);
283 s
= set_field(s
, MSTATUS_SIE
, 0);
284 set_csr(CSR_MSTATUS
, s
);
285 set_privilege(PRV_S
);
287 reg_t vector
= (state
.mtvec
& 1) && interrupt
? 4*bit
: 0;
288 state
.pc
= (state
.mtvec
& ~(reg_t
)1) + vector
;
290 state
.mcause
= t
.cause();
291 state
.mtval
= t
.get_tval();
293 reg_t s
= state
.mstatus
;
294 s
= set_field(s
, MSTATUS_MPIE
, get_field(s
, MSTATUS_MIE
));
295 s
= set_field(s
, MSTATUS_MPP
, state
.prv
);
296 s
= set_field(s
, MSTATUS_MIE
, 0);
297 set_csr(CSR_MSTATUS
, s
);
298 set_privilege(PRV_M
);
302 void processor_t::disasm(insn_t insn
)
304 uint64_t bits
= insn
.bits() & ((1ULL << (8 * insn_length(insn
.bits()))) - 1);
305 if (last_pc
!= state
.pc
|| last_bits
!= bits
) {
306 if (executions
!= 1) {
307 fprintf(stderr
, "core %3d: Executed %" PRIx64
" times\n", id
, executions
);
310 fprintf(stderr
, "core %3d: 0x%016" PRIx64
" (0x%08" PRIx64
") %s\n",
311 id
, state
.pc
, bits
, disassembler
->disassemble(insn
).c_str());
320 int processor_t::paddr_bits()
322 assert(xlen
== max_xlen
);
323 return max_xlen
== 64 ? 50 : 34;
326 void processor_t::set_csr(int which
, reg_t val
)
328 val
= zext_xlen(val
);
329 reg_t delegable_ints
= MIP_SSIP
| MIP_STIP
| MIP_SEIP
| (1 << IRQ_COP
);
330 reg_t all_ints
= delegable_ints
| MIP_MSIP
| MIP_MTIP
;
335 state
.fflags
= val
& (FSR_AEXC
>> FSR_AEXC_SHIFT
);
339 state
.frm
= val
& (FSR_RD
>> FSR_RD_SHIFT
);
343 state
.fflags
= (val
& FSR_AEXC
) >> FSR_AEXC_SHIFT
;
344 state
.frm
= (val
& FSR_RD
) >> FSR_RD_SHIFT
;
347 if ((val
^ state
.mstatus
) &
348 (MSTATUS_MPP
| MSTATUS_MPRV
| MSTATUS_SUM
| MSTATUS_MXR
))
351 reg_t mask
= MSTATUS_SIE
| MSTATUS_SPIE
| MSTATUS_MIE
| MSTATUS_MPIE
352 | MSTATUS_FS
| MSTATUS_MPRV
| MSTATUS_SUM
353 | MSTATUS_MXR
| MSTATUS_TW
| MSTATUS_TVM
354 | MSTATUS_TSR
| MSTATUS_UXL
| MSTATUS_SXL
|
355 (ext
? MSTATUS_XS
: 0);
357 reg_t requested_mpp
= legalize_privilege(get_field(val
, MSTATUS_MPP
));
358 state
.mstatus
= set_field(state
.mstatus
, MSTATUS_MPP
, requested_mpp
);
359 if (supports_extension('S'))
362 state
.mstatus
= (state
.mstatus
& ~mask
) | (val
& mask
);
364 bool dirty
= (state
.mstatus
& MSTATUS_FS
) == MSTATUS_FS
;
365 dirty
|= (state
.mstatus
& MSTATUS_XS
) == MSTATUS_XS
;
367 state
.mstatus
= set_field(state
.mstatus
, MSTATUS32_SD
, dirty
);
369 state
.mstatus
= set_field(state
.mstatus
, MSTATUS64_SD
, dirty
);
371 state
.mstatus
= set_field(state
.mstatus
, MSTATUS_UXL
, xlen_to_uxl(max_xlen
));
372 state
.mstatus
= set_field(state
.mstatus
, MSTATUS_UXL
, xlen_to_uxl(max_xlen
));
373 state
.mstatus
= set_field(state
.mstatus
, MSTATUS_SXL
, xlen_to_uxl(max_xlen
));
374 // U-XLEN == S-XLEN == M-XLEN
379 reg_t mask
= MIP_SSIP
| MIP_STIP
;
380 state
.mip
= (state
.mip
& ~mask
) | (val
& mask
);
384 state
.mie
= (state
.mie
& ~all_ints
) | (val
& all_ints
);
387 state
.mideleg
= (state
.mideleg
& ~delegable_ints
) | (val
& delegable_ints
);
391 (1 << CAUSE_MISALIGNED_FETCH
) |
392 (1 << CAUSE_BREAKPOINT
) |
393 (1 << CAUSE_USER_ECALL
) |
394 (1 << CAUSE_FETCH_PAGE_FAULT
) |
395 (1 << CAUSE_LOAD_PAGE_FAULT
) |
396 (1 << CAUSE_STORE_PAGE_FAULT
);
397 state
.medeleg
= (state
.medeleg
& ~mask
) | (val
& mask
);
403 state
.minstret
= (state
.minstret
>> 32 << 32) | (val
& 0xffffffffU
);
405 state
.minstret
= val
;
409 state
.minstret
= (val
<< 32) | (state
.minstret
<< 32 >> 32);
412 state
.scounteren
= val
;
415 state
.mcounteren
= val
;
418 reg_t mask
= SSTATUS_SIE
| SSTATUS_SPIE
| SSTATUS_SPP
| SSTATUS_FS
419 | SSTATUS_XS
| SSTATUS_SUM
| SSTATUS_MXR
;
420 return set_csr(CSR_MSTATUS
, (state
.mstatus
& ~mask
) | (val
& mask
));
423 reg_t mask
= MIP_SSIP
& state
.mideleg
;
424 return set_csr(CSR_MIP
, (state
.mip
& ~mask
) | (val
& mask
));
427 return set_csr(CSR_MIE
,
428 (state
.mie
& ~state
.mideleg
) | (val
& state
.mideleg
));
432 state
.satp
= val
& (SATP32_PPN
| SATP32_MODE
);
433 if (max_xlen
== 64 && (get_field(val
, SATP64_MODE
) == SATP_MODE_OFF
||
434 get_field(val
, SATP64_MODE
) == SATP_MODE_SV39
||
435 get_field(val
, SATP64_MODE
) == SATP_MODE_SV48
))
436 state
.satp
= val
& (SATP64_PPN
| SATP64_MODE
);
439 case CSR_SEPC
: state
.sepc
= val
& ~(reg_t
)1; break;
440 case CSR_STVEC
: state
.stvec
= val
>> 2 << 2; break;
441 case CSR_SSCRATCH
: state
.sscratch
= val
; break;
442 case CSR_SCAUSE
: state
.scause
= val
; break;
443 case CSR_STVAL
: state
.stval
= val
; break;
444 case CSR_MEPC
: state
.mepc
= val
& ~(reg_t
)1; break;
445 case CSR_MTVEC
: state
.mtvec
= val
& ~(reg_t
)2; break;
446 case CSR_MSCRATCH
: state
.mscratch
= val
; break;
447 case CSR_MCAUSE
: state
.mcause
= val
; break;
448 case CSR_MTVAL
: state
.mtval
= val
; break;
450 // the write is ignored if increasing IALIGN would misalign the PC
451 if (!(val
& (1L << ('C' - 'A'))) && (state
.pc
& 2))
454 if (!(val
& (1L << ('F' - 'A'))))
455 val
&= ~(1L << ('D' - 'A'));
457 // allow MAFDC bits in MISA to be modified
459 mask
|= 1L << ('M' - 'A');
460 mask
|= 1L << ('A' - 'A');
461 mask
|= 1L << ('F' - 'A');
462 mask
|= 1L << ('D' - 'A');
463 mask
|= 1L << ('C' - 'A');
466 state
.misa
= (val
& mask
) | (state
.misa
& ~mask
);
470 if (val
< state
.num_triggers
) {
476 mcontrol_t
*mc
= &state
.mcontrol
[state
.tselect
];
477 if (mc
->dmode
&& !state
.dcsr
.cause
) {
480 mc
->dmode
= get_field(val
, MCONTROL_DMODE(xlen
));
481 mc
->select
= get_field(val
, MCONTROL_SELECT
);
482 mc
->timing
= get_field(val
, MCONTROL_TIMING
);
483 mc
->action
= (mcontrol_action_t
) get_field(val
, MCONTROL_ACTION
);
484 mc
->chain
= get_field(val
, MCONTROL_CHAIN
);
485 mc
->match
= (mcontrol_match_t
) get_field(val
, MCONTROL_MATCH
);
486 mc
->m
= get_field(val
, MCONTROL_M
);
487 mc
->h
= get_field(val
, MCONTROL_H
);
488 mc
->s
= get_field(val
, MCONTROL_S
);
489 mc
->u
= get_field(val
, MCONTROL_U
);
490 mc
->execute
= get_field(val
, MCONTROL_EXECUTE
);
491 mc
->store
= get_field(val
, MCONTROL_STORE
);
492 mc
->load
= get_field(val
, MCONTROL_LOAD
);
493 // Assume we're here because of csrw.
500 if (state
.mcontrol
[state
.tselect
].dmode
&& !state
.dcsr
.cause
) {
503 if (state
.tselect
< state
.num_triggers
) {
504 state
.tdata2
[state
.tselect
] = val
;
508 state
.dcsr
.prv
= get_field(val
, DCSR_PRV
);
509 state
.dcsr
.step
= get_field(val
, DCSR_STEP
);
510 // TODO: ndreset and fullreset
511 state
.dcsr
.ebreakm
= get_field(val
, DCSR_EBREAKM
);
512 state
.dcsr
.ebreakh
= get_field(val
, DCSR_EBREAKH
);
513 state
.dcsr
.ebreaks
= get_field(val
, DCSR_EBREAKS
);
514 state
.dcsr
.ebreaku
= get_field(val
, DCSR_EBREAKU
);
515 state
.dcsr
.halt
= get_field(val
, DCSR_HALT
);
518 state
.dpc
= val
& ~(reg_t
)1;
521 state
.dscratch
= val
;
526 reg_t
processor_t::get_csr(int which
)
528 uint32_t ctr_en
= -1;
529 if (state
.prv
< PRV_M
)
530 ctr_en
&= state
.mcounteren
;
531 if (state
.prv
< PRV_S
)
532 ctr_en
&= state
.scounteren
;
533 bool ctr_ok
= (ctr_en
>> (which
& 31)) & 1;
536 if (which
>= CSR_HPMCOUNTER3
&& which
<= CSR_HPMCOUNTER31
)
538 if (xlen
== 32 && which
>= CSR_HPMCOUNTER3H
&& which
<= CSR_HPMCOUNTER31H
)
541 if (which
>= CSR_MHPMCOUNTER3
&& which
<= CSR_MHPMCOUNTER31
)
543 if (xlen
== 32 && which
>= CSR_MHPMCOUNTER3H
&& which
<= CSR_MHPMCOUNTER31H
)
545 if (which
>= CSR_MHPMEVENT3
&& which
<= CSR_MHPMEVENT31
)
552 if (!supports_extension('F'))
557 if (!supports_extension('F'))
562 if (!supports_extension('F'))
564 return (state
.fflags
<< FSR_AEXC_SHIFT
) | (state
.frm
<< FSR_RD_SHIFT
);
568 return state
.minstret
;
572 return state
.minstret
;
575 if (ctr_ok
&& xlen
== 32)
576 return state
.minstret
>> 32;
581 return state
.minstret
>> 32;
583 case CSR_SCOUNTEREN
: return state
.scounteren
;
584 case CSR_MCOUNTEREN
: return state
.mcounteren
;
586 reg_t mask
= SSTATUS_SIE
| SSTATUS_SPIE
| SSTATUS_SPP
| SSTATUS_FS
587 | SSTATUS_XS
| SSTATUS_SUM
| SSTATUS_UXL
;
588 reg_t sstatus
= state
.mstatus
& mask
;
589 if ((sstatus
& SSTATUS_FS
) == SSTATUS_FS
||
590 (sstatus
& SSTATUS_XS
) == SSTATUS_XS
)
591 sstatus
|= (xlen
== 32 ? SSTATUS32_SD
: SSTATUS64_SD
);
594 case CSR_SIP
: return state
.mip
& state
.mideleg
;
595 case CSR_SIE
: return state
.mie
& state
.mideleg
;
596 case CSR_SEPC
: return state
.sepc
& pc_alignment_mask();
597 case CSR_STVAL
: return state
.stval
;
598 case CSR_STVEC
: return state
.stvec
;
601 return state
.scause
| ((state
.scause
>> (max_xlen
-1)) << (xlen
-1));
604 if (get_field(state
.mstatus
, MSTATUS_TVM
))
605 require_privilege(PRV_M
);
607 case CSR_SSCRATCH
: return state
.sscratch
;
608 case CSR_MSTATUS
: return state
.mstatus
;
609 case CSR_MIP
: return state
.mip
;
610 case CSR_MIE
: return state
.mie
;
611 case CSR_MEPC
: return state
.mepc
& pc_alignment_mask();
612 case CSR_MSCRATCH
: return state
.mscratch
;
613 case CSR_MCAUSE
: return state
.mcause
;
614 case CSR_MTVAL
: return state
.mtval
;
615 case CSR_MISA
: return state
.misa
;
616 case CSR_MARCHID
: return 0;
617 case CSR_MIMPID
: return 0;
618 case CSR_MVENDORID
: return 0;
619 case CSR_MHARTID
: return id
;
620 case CSR_MTVEC
: return state
.mtvec
;
621 case CSR_MEDELEG
: return state
.medeleg
;
622 case CSR_MIDELEG
: return state
.mideleg
;
623 case CSR_TSELECT
: return state
.tselect
;
625 if (state
.tselect
< state
.num_triggers
) {
627 mcontrol_t
*mc
= &state
.mcontrol
[state
.tselect
];
628 v
= set_field(v
, MCONTROL_TYPE(xlen
), mc
->type
);
629 v
= set_field(v
, MCONTROL_DMODE(xlen
), mc
->dmode
);
630 v
= set_field(v
, MCONTROL_MASKMAX(xlen
), mc
->maskmax
);
631 v
= set_field(v
, MCONTROL_SELECT
, mc
->select
);
632 v
= set_field(v
, MCONTROL_TIMING
, mc
->timing
);
633 v
= set_field(v
, MCONTROL_ACTION
, mc
->action
);
634 v
= set_field(v
, MCONTROL_CHAIN
, mc
->chain
);
635 v
= set_field(v
, MCONTROL_MATCH
, mc
->match
);
636 v
= set_field(v
, MCONTROL_M
, mc
->m
);
637 v
= set_field(v
, MCONTROL_H
, mc
->h
);
638 v
= set_field(v
, MCONTROL_S
, mc
->s
);
639 v
= set_field(v
, MCONTROL_U
, mc
->u
);
640 v
= set_field(v
, MCONTROL_EXECUTE
, mc
->execute
);
641 v
= set_field(v
, MCONTROL_STORE
, mc
->store
);
642 v
= set_field(v
, MCONTROL_LOAD
, mc
->load
);
649 if (state
.tselect
< state
.num_triggers
) {
650 return state
.tdata2
[state
.tselect
];
655 case CSR_TDATA3
: return 0;
659 v
= set_field(v
, DCSR_XDEBUGVER
, 1);
660 v
= set_field(v
, DCSR_EBREAKM
, state
.dcsr
.ebreakm
);
661 v
= set_field(v
, DCSR_EBREAKH
, state
.dcsr
.ebreakh
);
662 v
= set_field(v
, DCSR_EBREAKS
, state
.dcsr
.ebreaks
);
663 v
= set_field(v
, DCSR_EBREAKU
, state
.dcsr
.ebreaku
);
664 v
= set_field(v
, DCSR_STOPCYCLE
, 0);
665 v
= set_field(v
, DCSR_STOPTIME
, 0);
666 v
= set_field(v
, DCSR_CAUSE
, state
.dcsr
.cause
);
667 v
= set_field(v
, DCSR_STEP
, state
.dcsr
.step
);
668 v
= set_field(v
, DCSR_PRV
, state
.dcsr
.prv
);
672 return state
.dpc
& pc_alignment_mask();
674 return state
.dscratch
;
676 throw trap_illegal_instruction(0);
679 reg_t
illegal_instruction(processor_t
* p
, insn_t insn
, reg_t pc
)
681 throw trap_illegal_instruction(0);
684 insn_func_t
processor_t::decode_insn(insn_t insn
)
686 // look up opcode in hash table
687 size_t idx
= insn
.bits() % OPCODE_CACHE_SIZE
;
688 insn_desc_t desc
= opcode_cache
[idx
];
690 if (unlikely(insn
.bits() != desc
.match
)) {
691 // fall back to linear search
692 insn_desc_t
* p
= &instructions
[0];
693 while ((insn
.bits() & p
->mask
) != p
->match
)
697 if (p
->mask
!= 0 && p
> &instructions
[0]) {
698 if (p
->match
!= (p
-1)->match
&& p
->match
!= (p
+1)->match
) {
699 // move to front of opcode list to reduce miss penalty
700 while (--p
>= &instructions
[0])
702 instructions
[0] = desc
;
706 opcode_cache
[idx
] = desc
;
707 opcode_cache
[idx
].match
= insn
.bits();
710 return xlen
== 64 ? desc
.rv64
: desc
.rv32
;
713 void processor_t::register_insn(insn_desc_t desc
)
715 instructions
.push_back(desc
);
718 void processor_t::build_opcode_map()
721 bool operator()(const insn_desc_t
& lhs
, const insn_desc_t
& rhs
) {
722 if (lhs
.match
== rhs
.match
)
723 return lhs
.mask
> rhs
.mask
;
724 return lhs
.match
> rhs
.match
;
727 std::sort(instructions
.begin(), instructions
.end(), cmp());
729 for (size_t i
= 0; i
< OPCODE_CACHE_SIZE
; i
++)
730 opcode_cache
[i
] = {0, 0, &illegal_instruction
, &illegal_instruction
};
733 void processor_t::register_extension(extension_t
* x
)
735 for (auto insn
: x
->get_instructions())
738 for (auto disasm_insn
: x
->get_disasms())
739 disassembler
->add_insn(disasm_insn
);
741 throw std::logic_error("only one extension may be registered");
743 x
->set_processor(this);
746 void processor_t::register_base_instructions()
748 #define DECLARE_INSN(name, match, mask) \
749 insn_bits_t name##_match = (match), name##_mask = (mask);
750 #include "encoding.h"
753 #define DEFINE_INSN(name) \
754 REGISTER_INSN(this, name, name##_match, name##_mask)
755 #include "insn_list.h"
758 register_insn({0, 0, &illegal_instruction
, &illegal_instruction
});
762 bool processor_t::load(reg_t addr
, size_t len
, uint8_t* bytes
)
768 memset(bytes
, 0, len
);
769 bytes
[0] = get_field(state
.mip
, MIP_MSIP
);
778 bool processor_t::store(reg_t addr
, size_t len
, const uint8_t* bytes
)
784 state
.mip
= set_field(state
.mip
, MIP_MSIP
, bytes
[0]);
793 void processor_t::trigger_updated()
796 mmu
->check_triggers_fetch
= false;
797 mmu
->check_triggers_load
= false;
798 mmu
->check_triggers_store
= false;
800 for (unsigned i
= 0; i
< state
.num_triggers
; i
++) {
801 if (state
.mcontrol
[i
].execute
) {
802 mmu
->check_triggers_fetch
= true;
804 if (state
.mcontrol
[i
].load
) {
805 mmu
->check_triggers_load
= true;
807 if (state
.mcontrol
[i
].store
) {
808 mmu
->check_triggers_store
= true;