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// See LICENSE for license details.
#include "processor.h"
#include "mmu.h"
#include <cassert>
#ifdef RISCV_ENABLE_COMMITLOG
static void commit_log_reset(processor_t* p)
{
p->get_state()->log_reg_write.clear();
p->get_state()->log_mem_read.clear();
p->get_state()->log_mem_write.clear();
}
static void commit_log_stash_privilege(processor_t* p)
{
state_t* state = p->get_state();
state->last_inst_priv = state->prv;
state->last_inst_xlen = p->get_xlen();
state->last_inst_flen = p->get_flen();
}
static void commit_log_print_value(FILE *log_file, int width, const void *data)
{
assert(log_file);
const uint64_t *arr = (const uint64_t *)data;
fprintf(log_file, "0x");
for (int idx = width / 64 - 1; idx >= 0; --idx) {
fprintf(log_file, "%016" PRIx64, arr[idx]);
}
}
static void commit_log_print_value(FILE *log_file,
int width, uint64_t hi, uint64_t lo)
{
assert(log_file);
switch (width) {
case 8:
fprintf(log_file, "0x%01" PRIx8, (uint8_t)lo);
break;
case 16:
fprintf(log_file, "0x%04" PRIx16, (uint16_t)lo);
break;
case 32:
fprintf(log_file, "0x%08" PRIx32, (uint32_t)lo);
break;
case 64:
fprintf(log_file, "0x%016" PRIx64, lo);
break;
case 128:
fprintf(log_file, "0x%016" PRIx64 "%016" PRIx64, hi, lo);
break;
default:
abort();
}
}
static void commit_log_print_insn(processor_t *p, reg_t pc, insn_t insn)
{
FILE *log_file = p->get_log_file();
auto& reg = p->get_state()->log_reg_write;
auto& load = p->get_state()->log_mem_read;
auto& store = p->get_state()->log_mem_write;
int priv = p->get_state()->last_inst_priv;
int xlen = p->get_state()->last_inst_xlen;
int flen = p->get_state()->last_inst_flen;
fprintf(log_file, "%1d ", priv);
commit_log_print_value(log_file, xlen, 0, pc);
fprintf(log_file, " (");
commit_log_print_value(log_file, insn.length() * 8, 0, insn.bits());
fprintf(log_file, ")");
bool show_vec = false;
for (auto item : reg) {
if (item.first == 0)
continue;
char prefix;
int size;
int rd = item.first >> 2;
bool is_vec = false;
bool is_vreg = false;
switch (item.first & 3) {
case 0:
size = xlen;
prefix = 'x';
break;
case 1:
size = flen;
prefix = 'f';
break;
case 2:
size = p->VU.VLEN;
prefix = 'v';
is_vreg = true;
break;
case 3:
is_vec = true;
break;
default:
assert("can't been here" && 0);
break;
}
if (!show_vec && (is_vreg || is_vec)) {
fprintf(log_file, " e%ld %s%ld l%ld",
p->VU.vsew,
p->VU.vflmul < 0 ? "mf" : "m",
p->VU.vflmul < 0 ? (reg_t)(1 / p->VU.vflmul) : (reg_t)p->VU.vflmul,
p->VU.vl);
show_vec = true;
}
if (!is_vec) {
fprintf(log_file, " %c%2d ", prefix, rd);
if (is_vreg)
commit_log_print_value(log_file, size, &p->VU.elt<uint8_t>(rd, 0));
else
commit_log_print_value(log_file, size, item.second.v[1], item.second.v[0]);
}
}
for (auto item : load) {
fprintf(log_file, " mem ");
commit_log_print_value(log_file, xlen, 0, std::get<0>(item));
}
for (auto item : store) {
fprintf(log_file, " mem ");
commit_log_print_value(log_file, xlen, 0, std::get<0>(item));
fprintf(log_file, " ");
commit_log_print_value(log_file, std::get<2>(item) << 3, 0, std::get<1>(item));
}
fprintf(log_file, "\n");
}
#else
static void commit_log_reset(processor_t* p) {}
static void commit_log_stash_privilege(processor_t* p) {}
static void commit_log_print_insn(processor_t* p, reg_t pc, insn_t insn) {}
#endif
inline void processor_t::update_histogram(reg_t pc)
{
#ifdef RISCV_ENABLE_HISTOGRAM
pc_histogram[pc]++;
#endif
}
// This is expected to be inlined by the compiler so each use of execute_insn
// includes a duplicated body of the function to get separate fetch.func
// function calls.
static reg_t execute_insn(processor_t* p, reg_t pc, insn_fetch_t fetch)
{
commit_log_reset(p);
commit_log_stash_privilege(p);
reg_t npc;
try {
npc = fetch.func(p, fetch.insn, pc);
if (npc != PC_SERIALIZE_BEFORE) {
#ifdef RISCV_ENABLE_COMMITLOG
if (p->get_log_commits_enabled()) {
commit_log_print_insn(p, pc, fetch.insn);
}
#endif
}
#ifdef RISCV_ENABLE_COMMITLOG
} catch(mem_trap_t& t) {
//handle segfault in midlle of vector load/store
if (p->get_log_commits_enabled()) {
for (auto item : p->get_state()->log_reg_write) {
if ((item.first & 3) == 3) {
commit_log_print_insn(p, pc, fetch.insn);
break;
}
}
}
throw;
#endif
} catch(...) {
throw;
}
p->update_histogram(pc);
return npc;
}
bool processor_t::slow_path()
{
return debug || state.single_step != state.STEP_NONE || state.debug_mode;
}
// fetch/decode/execute loop
void processor_t::step(size_t n)
{
if (!state.debug_mode) {
if (halt_request == HR_REGULAR) {
enter_debug_mode(DCSR_CAUSE_DEBUGINT);
} else if (halt_request == HR_GROUP) {
enter_debug_mode(DCSR_CAUSE_GROUP);
} // !!!The halt bit in DCSR is deprecated.
else if (state.dcsr.halt) {
enter_debug_mode(DCSR_CAUSE_HALT);
}
}
while (n > 0) {
size_t instret = 0;
reg_t pc = state.pc;
mmu_t* _mmu = mmu;
#define advance_pc() \
if (unlikely(invalid_pc(pc))) { \
switch (pc) { \
case PC_SERIALIZE_BEFORE: state.serialized = true; break; \
case PC_SERIALIZE_AFTER: ++instret; break; \
case PC_SERIALIZE_WFI: n = ++instret; break; \
default: abort(); \
} \
pc = state.pc; \
break; \
} else { \
state.pc = pc; \
instret++; \
}
try
{
take_pending_interrupt();
if (unlikely(slow_path()))
{
while (instret < n)
{
if (unlikely(!state.serialized && state.single_step == state.STEP_STEPPED)) {
state.single_step = state.STEP_NONE;
if (!state.debug_mode) {
enter_debug_mode(DCSR_CAUSE_STEP);
// enter_debug_mode changed state.pc, so we can't just continue.
break;
}
}
if (unlikely(state.single_step == state.STEP_STEPPING)) {
state.single_step = state.STEP_STEPPED;
}
insn_fetch_t fetch = mmu->load_insn(pc);
if (debug && !state.serialized)
disasm(fetch.insn);
pc = execute_insn(this, pc, fetch);
advance_pc();
}
}
else while (instret < n)
{
// This code uses a modified Duff's Device to improve the performance
// of executing instructions. While typical Duff's Devices are used
// for software pipelining, the switch statement below primarily
// benefits from separate call points for the fetch.func function call
// found in each execute_insn. This function call is an indirect jump
// that depends on the current instruction. By having an indirect jump
// dedicated for each icache entry, you improve the performance of the
// host's next address predictor. Each case in the switch statement
// allows for the program flow to contine to the next case if it
// corresponds to the next instruction in the program and instret is
// still less than n.
//
// According to Andrew Waterman's recollection, this optimization
// resulted in approximately a 2x performance increase.
// This figures out where to jump to in the switch statement
size_t idx = _mmu->icache_index(pc);
// This gets the cached decoded instruction from the MMU. If the MMU
// does not have the current pc cached, it will refill the MMU and
// return the correct entry. ic_entry->data.func is the C++ function
// corresponding to the instruction.
auto ic_entry = _mmu->access_icache(pc);
// This macro is included in "icache.h" included within the switch
// statement below. The indirect jump corresponding to the instruction
// is located within the execute_insn() function call.
#define ICACHE_ACCESS(i) { \
insn_fetch_t fetch = ic_entry->data; \
pc = execute_insn(this, pc, fetch); \
ic_entry = ic_entry->next; \
if (i == mmu_t::ICACHE_ENTRIES-1) break; \
if (unlikely(ic_entry->tag != pc)) break; \
if (unlikely(instret+1 == n)) break; \
instret++; \
state.pc = pc; \
}
// This switch statement implements the modified Duff's device as
// explained above.
switch (idx) {
// "icache.h" is generated by the gen_icache script
#include "icache.h"
}
advance_pc();
}
}
catch(trap_t& t)
{
take_trap(t, pc);
n = instret;
if (unlikely(state.single_step == state.STEP_STEPPED)) {
state.single_step = state.STEP_NONE;
enter_debug_mode(DCSR_CAUSE_STEP);
}
}
catch (trigger_matched_t& t)
{
if (mmu->matched_trigger) {
// This exception came from the MMU. That means the instruction hasn't
// fully executed yet. We start it again, but this time it won't throw
// an exception because matched_trigger is already set. (All memory
// instructions are idempotent so restarting is safe.)
insn_fetch_t fetch = mmu->load_insn(pc);
pc = execute_insn(this, pc, fetch);
advance_pc();
delete mmu->matched_trigger;
mmu->matched_trigger = NULL;
}
switch (state.mcontrol[t.index].action) {
case ACTION_DEBUG_MODE:
enter_debug_mode(DCSR_CAUSE_HWBP);
break;
case ACTION_DEBUG_EXCEPTION: {
mem_trap_t trap(CAUSE_BREAKPOINT, t.address);
take_trap(trap, pc);
break;
}
default:
abort();
}
}
catch (wait_for_interrupt_t &t)
{
// Return to the outer simulation loop, which gives other devices/harts a
// chance to generate interrupts.
//
// In the debug ROM this prevents us from wasting time looping, but also
// allows us to switch to other threads only once per idle loop in case
// there is activity.
n = instret;
}
state.minstret += instret;
n -= instret;
}
}
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