binutils-gdb/sim/erc32/func.c
Joel Brobecker 61baf725ec update copyright year range in GDB files
This applies the second part of GDB's End of Year Procedure, which
updates the copyright year range in all of GDB's files.

gdb/ChangeLog:

        Update copyright year range in all GDB files.
2017-01-01 10:52:34 +04:00

1135 lines
28 KiB
C

/* This file is part of SIS (SPARC instruction simulator)
Copyright (C) 1995-2017 Free Software Foundation, Inc.
Contributed by Jiri Gaisler, European Space Agency
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>. */
#include "config.h"
#include <signal.h>
#include <string.h>
#include <stdio.h>
#include <stdlib.h>
#include <ctype.h>
#include "sis.h"
#include <dis-asm.h>
#include "sim-config.h"
#include <inttypes.h>
#define VAL(x) strtoul(x,(char **)NULL,0)
struct disassemble_info dinfo;
struct pstate sregs;
extern struct estate ebase;
int ctrl_c = 0;
int sis_verbose = 0;
char *sis_version = "2.7.5";
int nfp = 0;
int ift = 0;
int wrp = 0;
int rom8 = 0;
int uben = 0;
int termsave;
int sparclite = 0; /* emulating SPARClite instructions? */
int sparclite_board = 0; /* emulating SPARClite board RAM? */
char uart_dev1[128] = "";
char uart_dev2[128] = "";
extern int ext_irl;
uint32 last_load_addr = 0;
#ifdef ERRINJ
uint32 errcnt = 0;
uint32 errper = 0;
uint32 errtt = 0;
uint32 errftt = 0;
uint32 errmec = 0;
#endif
/* Forward declarations */
static int batch (struct pstate *sregs, char *fname);
static void set_rega (struct pstate *sregs, char *reg, uint32 rval);
static void disp_reg (struct pstate *sregs, char *reg);
static uint32 limcalc (float32 freq);
static void int_handler (int32 sig);
static void init_event (void);
static int disp_fpu (struct pstate *sregs);
static void disp_regs (struct pstate *sregs, int cwp);
static void disp_ctrl (struct pstate *sregs);
static void disp_mem (uint32 addr, uint32 len);
static int
batch(sregs, fname)
struct pstate *sregs;
char *fname;
{
FILE *fp;
char *lbuf = NULL;
size_t len = 0;
size_t slen;
if ((fp = fopen(fname, "r")) == NULL) {
fprintf(stderr, "couldn't open batch file %s\n", fname);
return 0;
}
while (getline(&lbuf, &len, fp) > -1) {
slen = strlen(lbuf);
if (slen && (lbuf[slen - 1] == '\n')) {
lbuf[slen - 1] = 0;
printf("sis> %s\n", lbuf);
exec_cmd(sregs, lbuf);
}
}
free(lbuf);
fclose(fp);
return 1;
}
void
set_regi(sregs, reg, rval)
struct pstate *sregs;
int32 reg;
uint32 rval;
{
uint32 cwp;
cwp = ((sregs->psr & 0x7) << 4);
if ((reg > 0) && (reg < 8)) {
sregs->g[reg] = rval;
} else if ((reg >= 8) && (reg < 32)) {
sregs->r[(cwp + reg) & 0x7f] = rval;
} else if ((reg >= 32) && (reg < 64)) {
sregs->fsi[reg - 32] = rval;
} else {
switch (reg) {
case 64:
sregs->y = rval;
break;
case 65:
sregs->psr = rval;
break;
case 66:
sregs->wim = rval;
break;
case 67:
sregs->tbr = rval;
break;
case 68:
sregs->pc = rval;
break;
case 69:
sregs->npc = rval;
break;
case 70:
sregs->fsr = rval;
set_fsr(rval);
break;
default:break;
}
}
}
void
get_regi(struct pstate * sregs, int32 reg, char *buf)
{
uint32 cwp;
uint32 rval = 0;
cwp = ((sregs->psr & 0x7) << 4);
if ((reg >= 0) && (reg < 8)) {
rval = sregs->g[reg];
} else if ((reg >= 8) && (reg < 32)) {
rval = sregs->r[(cwp + reg) & 0x7f];
} else if ((reg >= 32) && (reg < 64)) {
rval = sregs->fsi[reg - 32];
} else {
switch (reg) {
case 64:
rval = sregs->y;
break;
case 65:
rval = sregs->psr;
break;
case 66:
rval = sregs->wim;
break;
case 67:
rval = sregs->tbr;
break;
case 68:
rval = sregs->pc;
break;
case 69:
rval = sregs->npc;
break;
case 70:
rval = sregs->fsr;
break;
default:break;
}
}
buf[0] = (rval >> 24) & 0x0ff;
buf[1] = (rval >> 16) & 0x0ff;
buf[2] = (rval >> 8) & 0x0ff;
buf[3] = rval & 0x0ff;
}
static void
set_rega(sregs, reg, rval)
struct pstate *sregs;
char *reg;
uint32 rval;
{
uint32 cwp;
int32 err = 0;
cwp = ((sregs->psr & 0x7) << 4);
if (strcmp(reg, "psr") == 0)
sregs->psr = (rval = (rval & 0x00f03fff));
else if (strcmp(reg, "tbr") == 0)
sregs->tbr = (rval = (rval & 0xfffffff0));
else if (strcmp(reg, "wim") == 0)
sregs->wim = (rval = (rval & 0x0ff));
else if (strcmp(reg, "y") == 0)
sregs->y = rval;
else if (strcmp(reg, "pc") == 0)
sregs->pc = rval;
else if (strcmp(reg, "npc") == 0)
sregs->npc = rval;
else if (strcmp(reg, "fsr") == 0) {
sregs->fsr = rval;
set_fsr(rval);
} else if (strcmp(reg, "g0") == 0)
err = 2;
else if (strcmp(reg, "g1") == 0)
sregs->g[1] = rval;
else if (strcmp(reg, "g2") == 0)
sregs->g[2] = rval;
else if (strcmp(reg, "g3") == 0)
sregs->g[3] = rval;
else if (strcmp(reg, "g4") == 0)
sregs->g[4] = rval;
else if (strcmp(reg, "g5") == 0)
sregs->g[5] = rval;
else if (strcmp(reg, "g6") == 0)
sregs->g[6] = rval;
else if (strcmp(reg, "g7") == 0)
sregs->g[7] = rval;
else if (strcmp(reg, "o0") == 0)
sregs->r[(cwp + 8) & 0x7f] = rval;
else if (strcmp(reg, "o1") == 0)
sregs->r[(cwp + 9) & 0x7f] = rval;
else if (strcmp(reg, "o2") == 0)
sregs->r[(cwp + 10) & 0x7f] = rval;
else if (strcmp(reg, "o3") == 0)
sregs->r[(cwp + 11) & 0x7f] = rval;
else if (strcmp(reg, "o4") == 0)
sregs->r[(cwp + 12) & 0x7f] = rval;
else if (strcmp(reg, "o5") == 0)
sregs->r[(cwp + 13) & 0x7f] = rval;
else if (strcmp(reg, "o6") == 0)
sregs->r[(cwp + 14) & 0x7f] = rval;
else if (strcmp(reg, "o7") == 0)
sregs->r[(cwp + 15) & 0x7f] = rval;
else if (strcmp(reg, "l0") == 0)
sregs->r[(cwp + 16) & 0x7f] = rval;
else if (strcmp(reg, "l1") == 0)
sregs->r[(cwp + 17) & 0x7f] = rval;
else if (strcmp(reg, "l2") == 0)
sregs->r[(cwp + 18) & 0x7f] = rval;
else if (strcmp(reg, "l3") == 0)
sregs->r[(cwp + 19) & 0x7f] = rval;
else if (strcmp(reg, "l4") == 0)
sregs->r[(cwp + 20) & 0x7f] = rval;
else if (strcmp(reg, "l5") == 0)
sregs->r[(cwp + 21) & 0x7f] = rval;
else if (strcmp(reg, "l6") == 0)
sregs->r[(cwp + 22) & 0x7f] = rval;
else if (strcmp(reg, "l7") == 0)
sregs->r[(cwp + 23) & 0x7f] = rval;
else if (strcmp(reg, "i0") == 0)
sregs->r[(cwp + 24) & 0x7f] = rval;
else if (strcmp(reg, "i1") == 0)
sregs->r[(cwp + 25) & 0x7f] = rval;
else if (strcmp(reg, "i2") == 0)
sregs->r[(cwp + 26) & 0x7f] = rval;
else if (strcmp(reg, "i3") == 0)
sregs->r[(cwp + 27) & 0x7f] = rval;
else if (strcmp(reg, "i4") == 0)
sregs->r[(cwp + 28) & 0x7f] = rval;
else if (strcmp(reg, "i5") == 0)
sregs->r[(cwp + 29) & 0x7f] = rval;
else if (strcmp(reg, "i6") == 0)
sregs->r[(cwp + 30) & 0x7f] = rval;
else if (strcmp(reg, "i7") == 0)
sregs->r[(cwp + 31) & 0x7f] = rval;
else
err = 1;
switch (err) {
case 0:
printf("%s = %d (0x%08x)\n", reg, rval, rval);
break;
case 1:
printf("no such regiser: %s\n", reg);
break;
case 2:
printf("cannot set g0\n");
break;
default:
break;
}
}
static void
disp_reg(sregs, reg)
struct pstate *sregs;
char *reg;
{
if (strncmp(reg, "w",1) == 0)
disp_regs(sregs, VAL(&reg[1]));
}
#ifdef ERRINJ
void
errinj()
{
int err;
switch (err = (random() % 12)) {
case 0: errtt = 0x61; break;
case 1: errtt = 0x62; break;
case 2: errtt = 0x63; break;
case 3: errtt = 0x64; break;
case 4: errtt = 0x65; break;
case 5:
case 6:
case 7: errftt = err;
break;
case 8: errmec = 1; break;
case 9: errmec = 2; break;
case 10: errmec = 5; break;
case 11: errmec = 6; break;
}
errcnt++;
if (errper) event(errinj, 0, (random()%errper));
}
void
errinjstart()
{
if (errper) event(errinj, 0, (random()%errper));
}
#endif
static uint32
limcalc (freq)
float32 freq;
{
uint32 unit, lim;
double flim;
char *cmd1, *cmd2;
unit = 1;
lim = -1;
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
lim = VAL(cmd1);
if ((cmd2 = strtok(NULL, " \t\n\r")) != NULL) {
if (strcmp(cmd2,"us")==0) unit = 1;
if (strcmp(cmd2,"ms")==0) unit = 1000;
if (strcmp(cmd2,"s")==0) unit = 1000000;
}
flim = (double) lim * (double) unit * (double) freq +
(double) ebase.simtime;
if ((flim > ebase.simtime) && (flim < 4294967296.0)) {
lim = (uint32) flim;
} else {
printf("error in expression\n");
lim = -1;
}
}
return lim;
}
int
exec_cmd(struct pstate *sregs, const char *cmd)
{
char *cmd1, *cmd2;
int32 stat;
uint32 len, i, clen, j;
static uint32 daddr = 0;
char *cmdsave, *cmdsave2 = NULL;
stat = OK;
cmdsave = strdup(cmd);
cmdsave2 = strdup (cmd);
if ((cmd1 = strtok (cmdsave2, " \t")) != NULL) {
clen = strlen(cmd1);
if (strncmp(cmd1, "bp", clen) == 0) {
for (i = 0; i < sregs->bptnum; i++) {
printf(" %d : 0x%08x\n", i + 1, sregs->bpts[i]);
}
} else if (strncmp(cmd1, "+bp", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
sregs->bpts[sregs->bptnum] = VAL(cmd1) & ~0x3;
printf("added breakpoint %d at 0x%08x\n",
sregs->bptnum + 1, sregs->bpts[sregs->bptnum]);
sregs->bptnum += 1;
}
} else if (strncmp(cmd1, "-bp", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
i = VAL(cmd1) - 1;
if ((i >= 0) && (i < sregs->bptnum)) {
printf("deleted breakpoint %d at 0x%08x\n", i + 1,
sregs->bpts[i]);
for (; i < sregs->bptnum - 1; i++) {
sregs->bpts[i] = sregs->bpts[i + 1];
}
sregs->bptnum -= 1;
}
}
} else if (strncmp(cmd1, "batch", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
printf("no file specified\n");
} else {
batch(sregs, cmd1);
}
} else if (strncmp(cmd1, "cont", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
stat = run_sim(sregs, UINT64_MAX, 0);
} else {
stat = run_sim(sregs, VAL(cmd1), 0);
}
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "debug", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
sis_verbose = VAL(cmd1);
}
printf("Debug level = %d\n",sis_verbose);
} else if (strncmp(cmd1, "dis", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
daddr = VAL(cmd1);
}
if ((cmd2 = strtok(NULL, " \t\n\r")) != NULL) {
len = VAL(cmd2);
} else
len = 16;
printf("\n");
dis_mem(daddr, len, &dinfo);
printf("\n");
daddr += len * 4;
} else if (strncmp(cmd1, "echo", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
printf("%s\n", (&cmdsave[clen+1]));
}
#ifdef ERRINJ
} else if (strncmp(cmd1, "error", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
errper = VAL(cmd1);
if (errper) {
event(errinj, 0, (len = (random()%errper)));
printf("Error injection started with period %d\n",len);
}
} else printf("Injected errors: %d\n",errcnt);
#endif
} else if (strncmp(cmd1, "float", clen) == 0) {
stat = disp_fpu(sregs);
} else if (strncmp(cmd1, "go", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
len = last_load_addr;
} else {
len = VAL(cmd1);
}
sregs->pc = len & ~3;
sregs->npc = sregs->pc + 4;
if ((sregs->pc != 0) && (ebase.simtime == 0))
boot_init();
printf("resuming at 0x%08x\n",sregs->pc);
if ((cmd2 = strtok(NULL, " \t\n\r")) != NULL) {
stat = run_sim(sregs, VAL(cmd2), 0);
} else {
stat = run_sim(sregs, UINT64_MAX, 0);
}
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "help", clen) == 0) {
gen_help();
} else if (strncmp(cmd1, "history", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
sregs->histlen = VAL(cmd1);
if (sregs->histbuf != NULL)
free(sregs->histbuf);
sregs->histbuf = (struct histype *) calloc(sregs->histlen, sizeof(struct histype));
printf("trace history length = %d\n\r", sregs->histlen);
sregs->histind = 0;
} else {
j = sregs->histind;
for (i = 0; i < sregs->histlen; i++) {
if (j >= sregs->histlen)
j = 0;
printf(" %8d ", sregs->histbuf[j].time);
dis_mem(sregs->histbuf[j].addr, 1, &dinfo);
j++;
}
}
} else if (strncmp(cmd1, "load", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
last_load_addr = bfd_load(cmd1);
while ((cmd1 = strtok(NULL, " \t\n\r")) != NULL)
last_load_addr = bfd_load(cmd1);
} else {
printf("load: no file specified\n");
}
} else if (strncmp(cmd1, "mem", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL)
daddr = VAL(cmd1);
if ((cmd2 = strtok(NULL, " \t\n\r")) != NULL)
len = VAL(cmd2);
else
len = 64;
disp_mem(daddr, len);
daddr += len;
} else if (strncmp(cmd1, "perf", clen) == 0) {
cmd1 = strtok(NULL, " \t\n\r");
if ((cmd1 != NULL) &&
(strncmp(cmd1, "reset", strlen(cmd1)) == 0)) {
reset_stat(sregs);
} else
show_stat(sregs);
} else if (strncmp(cmd1, "quit", clen) == 0) {
exit(0);
} else if (strncmp(cmd1, "reg", clen) == 0) {
cmd1 = strtok(NULL, " \t\n\r");
cmd2 = strtok(NULL, " \t\n\r");
if (cmd2 != NULL)
set_rega(sregs, cmd1, VAL(cmd2));
else if (cmd1 != NULL)
disp_reg(sregs, cmd1);
else {
disp_regs(sregs,sregs->psr);
disp_ctrl(sregs);
}
} else if (strncmp(cmd1, "reset", clen) == 0) {
ebase.simtime = 0;
reset_all();
reset_stat(sregs);
} else if (strncmp(cmd1, "run", clen) == 0) {
ebase.simtime = 0;
reset_all();
reset_stat(sregs);
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
stat = run_sim(sregs, UINT64_MAX, 0);
} else {
stat = run_sim(sregs, VAL(cmd1), 0);
}
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "shell", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) != NULL) {
if (system(&cmdsave[clen])) {
/* Silence unused return value warning. */
}
}
} else if (strncmp(cmd1, "step", clen) == 0) {
stat = run_sim(sregs, 1, 1);
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "tcont", clen) == 0) {
sregs->tlimit = limcalc(sregs->freq);
stat = run_sim(sregs, UINT64_MAX, 0);
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "tgo", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
len = last_load_addr;
} else {
len = VAL(cmd1);
sregs->tlimit = limcalc(sregs->freq);
}
sregs->pc = len & ~3;
sregs->npc = sregs->pc + 4;
printf("resuming at 0x%08x\n",sregs->pc);
stat = run_sim(sregs, UINT64_MAX, 0);
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "tlimit", clen) == 0) {
sregs->tlimit = limcalc(sregs->freq);
if (sregs->tlimit != (uint32) -1)
printf("simulation limit = %u (%.3f ms)\n",(uint32) sregs->tlimit,
sregs->tlimit / sregs->freq / 1000);
} else if (strncmp(cmd1, "tra", clen) == 0) {
if ((cmd1 = strtok(NULL, " \t\n\r")) == NULL) {
stat = run_sim(sregs, UINT64_MAX, 1);
} else {
stat = run_sim(sregs, VAL(cmd1), 1);
}
printf("\n");
daddr = sregs->pc;
sim_halt();
} else if (strncmp(cmd1, "trun", clen) == 0) {
ebase.simtime = 0;
reset_all();
reset_stat(sregs);
sregs->tlimit = limcalc(sregs->freq);
stat = run_sim(sregs, UINT64_MAX, 0);
daddr = sregs->pc;
sim_halt();
} else
printf("syntax error\n");
}
if (cmdsave2 != NULL)
free(cmdsave2);
if (cmdsave != NULL)
free(cmdsave);
return stat;
}
void
reset_stat(sregs)
struct pstate *sregs;
{
sregs->tottime = 0.0;
sregs->pwdtime = 0;
sregs->ninst = 0;
sregs->fholdt = 0;
sregs->holdt = 0;
sregs->icntt = 0;
sregs->finst = 0;
sregs->nstore = 0;
sregs->nload = 0;
sregs->nbranch = 0;
sregs->simstart = ebase.simtime;
}
void
show_stat(sregs)
struct pstate *sregs;
{
uint32 iinst;
uint32 stime;
if (sregs->tottime == 0.0)
sregs->tottime += 1E-6;
stime = ebase.simtime - sregs->simstart; /* Total simulated time */
#ifdef STAT
iinst = sregs->ninst - sregs->finst - sregs->nload - sregs->nstore -
sregs->nbranch;
#endif
printf("\n Cycles : %9" PRIu64 "\n\r", ebase.simtime - sregs->simstart);
printf(" Instructions : %9" PRIu64 "\n", sregs->ninst);
#ifdef STAT
printf(" integer : %9.2f %%\n", 100.0 * (float) iinst / (float) sregs->ninst);
printf(" load : %9.2f %%\n",
100.0 * (float) sregs->nload / (float) sregs->ninst);
printf(" store : %9.2f %%\n",
100.0 * (float) sregs->nstore / (float) sregs->ninst);
printf(" branch : %9.2f %%\n",
100.0 * (float) sregs->nbranch / (float) sregs->ninst);
printf(" float : %9.2f %%\n",
100.0 * (float) sregs->finst / (float) sregs->ninst);
printf(" Integer CPI : %9.2f\n",
((float) (stime - sregs->pwdtime - sregs->fholdt - sregs->finst))
/
(float) (sregs->ninst - sregs->finst));
printf(" Float CPI : %9.2f\n",
((float) sregs->fholdt / (float) sregs->finst) + 1.0);
#endif
printf(" Overall CPI : %9.2f\n",
(float) (stime - sregs->pwdtime) / (float) sregs->ninst);
printf("\n ERC32 performance (%4.1f MHz): %5.2f MOPS (%5.2f MIPS, %5.2f MFLOPS)\n",
sregs->freq, sregs->freq * (float) sregs->ninst / (float) (stime - sregs->pwdtime),
sregs->freq * (float) (sregs->ninst - sregs->finst) /
(float) (stime - sregs->pwdtime),
sregs->freq * (float) sregs->finst / (float) (stime - sregs->pwdtime));
printf(" Simulated ERC32 time : %.2f s\n",
(float) (ebase.simtime - sregs->simstart) / 1000000.0 / sregs->freq);
printf(" Processor utilisation : %.2f %%\n",
100.0 * (1.0 - ((float) sregs->pwdtime / (float) stime)));
printf(" Real-time performance : %.2f %%\n",
100.0 / (sregs->tottime / ((double) (stime) / (sregs->freq * 1.0E6))));
printf(" Simulator performance : %.2f MIPS\n",
(double)(sregs->ninst) / sregs->tottime / 1E6);
printf(" Used time (sys + user) : %.2f s\n\n", sregs->tottime);
}
void
init_bpt(sregs)
struct pstate *sregs;
{
sregs->bptnum = 0;
sregs->histlen = 0;
sregs->histind = 0;
sregs->histbuf = NULL;
sregs->tlimit = -1;
}
static void
int_handler(sig)
int32 sig;
{
if (sig != 2)
printf("\n\n Signal handler error (%d)\n\n", sig);
ctrl_c = 1;
}
void
init_signals()
{
typedef void (*PFI) ();
static PFI int_tab[2];
int_tab[0] = signal(SIGTERM, int_handler);
int_tab[1] = signal(SIGINT, int_handler);
}
extern struct disassemble_info dinfo;
struct estate ebase;
struct evcell evbuf[EVENT_MAX];
struct irqcell irqarr[16];
static int
disp_fpu(sregs)
struct pstate *sregs;
{
int i;
float t;
printf("\n fsr: %08X\n\n", sregs->fsr);
#ifdef HOST_LITTLE_ENDIAN
for (i = 0; i < 32; i++)
sregs->fdp[i ^ 1] = sregs->fs[i];
#endif
for (i = 0; i < 32; i++) {
t = sregs->fs[i];
printf(" f%02d %08x %14e ", i, sregs->fsi[i], sregs->fs[i]);
if (!(i & 1))
printf("%14e\n", sregs->fd[i >> 1]);
else
printf("\n");
}
printf("\n");
return OK;
}
static void
disp_regs(sregs,cwp)
struct pstate *sregs;
int cwp;
{
int i;
cwp = ((cwp & 0x7) << 4);
printf("\n\t INS LOCALS OUTS GLOBALS\n");
for (i = 0; i < 8; i++) {
printf(" %d: %08X %08X %08X %08X\n", i,
sregs->r[(cwp + i + 24) & 0x7f],
sregs->r[(cwp + i + 16) & 0x7f], sregs->r[(cwp + i + 8) & 0x7f],
sregs->g[i]);
}
}
static void print_insn_sparc_sis(uint32 addr, struct disassemble_info *info)
{
unsigned char i[4];
sis_memory_read(addr, i, 4);
dinfo.buffer_vma = addr;
dinfo.buffer_length = 4;
dinfo.buffer = i;
print_insn_sparc(addr, info);
}
static void
disp_ctrl(sregs)
struct pstate *sregs;
{
uint32 i;
printf("\n psr: %08X wim: %08X tbr: %08X y: %08X\n",
sregs->psr, sregs->wim, sregs->tbr, sregs->y);
sis_memory_read (sregs->pc, (char *) &i, 4);
printf ("\n pc: %08X = %08X ", sregs->pc, i);
print_insn_sparc_sis(sregs->pc, &dinfo);
sis_memory_read (sregs->npc, (char *) &i, 4);
printf ("\n npc: %08X = %08X ", sregs->npc, i);
print_insn_sparc_sis(sregs->npc, &dinfo);
if (sregs->err_mode)
printf("\n IU in error mode");
printf("\n\n");
}
static void
disp_mem(addr, len)
uint32 addr;
uint32 len;
{
uint32 i;
union {
unsigned char u8[4];
uint32 u32;
} data;
uint32 mem[4], j;
char *p;
for (i = addr & ~3; i < ((addr + len) & ~3); i += 16) {
printf("\n %8X ", i);
for (j = 0; j < 4; j++) {
sis_memory_read ((i + (j * 4)), data.u8, 4);
printf ("%08x ", data.u32);
mem[j] = data.u32;
}
printf(" ");
p = (char *) mem;
for (j = 0; j < 16; j++) {
if (isprint (p[j ^ EBT]))
putchar (p[j ^ EBT]);
else
putchar('.');
}
}
printf("\n\n");
}
void
dis_mem(addr, len, info)
uint32 addr;
uint32 len;
struct disassemble_info *info;
{
uint32 i;
union {
unsigned char u8[4];
uint32 u32;
} data;
for (i = addr & -3; i < ((addr & -3) + (len << 2)); i += 4) {
sis_memory_read (i, data.u8, 4);
printf (" %08x %08x ", i, data.u32);
print_insn_sparc_sis(i, info);
if (i >= 0xfffffffc) break;
printf("\n");
}
}
/* Add event to event queue */
void
event(cfunc, arg, delta)
void (*cfunc) ();
int32 arg;
uint64 delta;
{
struct evcell *ev1, *evins;
if (ebase.freeq == NULL) {
printf("Error, too many events in event queue\n");
return;
}
ev1 = &ebase.eq;
delta += ebase.simtime;
while ((ev1->nxt != NULL) && (ev1->nxt->time <= delta)) {
ev1 = ev1->nxt;
}
if (ev1->nxt == NULL) {
ev1->nxt = ebase.freeq;
ebase.freeq = ebase.freeq->nxt;
ev1->nxt->nxt = NULL;
} else {
evins = ebase.freeq;
ebase.freeq = ebase.freeq->nxt;
evins->nxt = ev1->nxt;
ev1->nxt = evins;
}
ev1->nxt->time = delta;
ev1->nxt->cfunc = cfunc;
ev1->nxt->arg = arg;
}
#if 0 /* apparently not used */
void
stop_event()
{
}
#endif
void
init_event()
{
int32 i;
ebase.eq.nxt = NULL;
ebase.freeq = evbuf;
for (i = 0; i < EVENT_MAX; i++) {
evbuf[i].nxt = &evbuf[i + 1];
}
evbuf[EVENT_MAX - 1].nxt = NULL;
}
void
set_int(level, callback, arg)
int32 level;
void (*callback) ();
int32 arg;
{
irqarr[level & 0x0f].callback = callback;
irqarr[level & 0x0f].arg = arg;
}
/* Advance simulator time */
void
advance_time(sregs)
struct pstate *sregs;
{
struct evcell *evrem;
void (*cfunc) ();
uint32 arg;
uint64 endtime;
#ifdef STAT
sregs->fholdt += sregs->fhold;
sregs->holdt += sregs->hold;
sregs->icntt += sregs->icnt;
#endif
endtime = ebase.simtime + sregs->icnt + sregs->hold + sregs->fhold;
while ((ebase.eq.nxt->time <= (endtime)) && (ebase.eq.nxt != NULL)) {
ebase.simtime = ebase.eq.nxt->time;
cfunc = ebase.eq.nxt->cfunc;
arg = ebase.eq.nxt->arg;
evrem = ebase.eq.nxt;
ebase.eq.nxt = ebase.eq.nxt->nxt;
evrem->nxt = ebase.freeq;
ebase.freeq = evrem;
cfunc(arg);
}
ebase.simtime = endtime;
}
uint32
now()
{
return ebase.simtime;
}
/* Advance time until an external interrupt is seen */
int
wait_for_irq()
{
struct evcell *evrem;
void (*cfunc) ();
int32 arg;
uint64 endtime;
if (ebase.eq.nxt == NULL)
printf("Warning: event queue empty - power-down mode not entered\n");
endtime = ebase.simtime;
while (!ext_irl && (ebase.eq.nxt != NULL)) {
ebase.simtime = ebase.eq.nxt->time;
cfunc = ebase.eq.nxt->cfunc;
arg = ebase.eq.nxt->arg;
evrem = ebase.eq.nxt;
ebase.eq.nxt = ebase.eq.nxt->nxt;
evrem->nxt = ebase.freeq;
ebase.freeq = evrem;
cfunc(arg);
if (ctrl_c) {
printf("\bwarning: power-down mode interrupted\n");
break;
}
}
sregs.pwdtime += ebase.simtime - endtime;
return ebase.simtime - endtime;
}
int
check_bpt(sregs)
struct pstate *sregs;
{
int32 i;
if ((sregs->bphit) || (sregs->annul))
return 0;
for (i = 0; i < (int32) sregs->bptnum; i++) {
if (sregs->pc == sregs->bpts[i])
return BPT_HIT;
}
return 0;
}
void
reset_all()
{
init_event(); /* Clear event queue */
init_regs(&sregs);
reset();
#ifdef ERRINJ
errinjstart();
#endif
}
void
sys_reset()
{
reset_all();
sregs.trap = 256; /* Force fake reset trap */
}
void
sys_halt()
{
sregs.trap = 257; /* Force fake halt trap */
}
#include "ansidecl.h"
#include <stdarg.h>
#include "libiberty.h"
#include "bfd.h"
#define min(A, B) (((A) < (B)) ? (A) : (B))
#define LOAD_ADDRESS 0
int
bfd_load (const char *fname)
{
asection *section;
bfd *pbfd;
const bfd_arch_info_type *arch;
int i;
pbfd = bfd_openr(fname, 0);
if (pbfd == NULL) {
printf("open of %s failed\n", fname);
return -1;
}
if (!bfd_check_format(pbfd, bfd_object)) {
printf("file %s doesn't seem to be an object file\n", fname);
return -1;
}
arch = bfd_get_arch_info (pbfd);
if (sis_verbose)
printf("loading %s:", fname);
for (section = pbfd->sections; section; section = section->next) {
if (bfd_get_section_flags(pbfd, section) & SEC_ALLOC) {
bfd_vma section_address;
unsigned long section_size;
const char *section_name;
section_name = bfd_get_section_name(pbfd, section);
section_address = bfd_get_section_vma(pbfd, section);
/*
* Adjust sections from a.out files, since they don't carry their
* addresses with.
*/
if (bfd_get_flavour(pbfd) == bfd_target_aout_flavour) {
if (strcmp (section_name, ".text") == 0)
section_address = bfd_get_start_address (pbfd);
else if (strcmp (section_name, ".data") == 0) {
/* Read the first 8 bytes of the data section.
There should be the string 'DaTa' followed by
a word containing the actual section address. */
struct data_marker
{
char signature[4]; /* 'DaTa' */
unsigned char sdata[4]; /* &sdata */
} marker;
bfd_get_section_contents (pbfd, section, &marker, 0,
sizeof (marker));
if (strncmp (marker.signature, "DaTa", 4) == 0)
{
section_address = bfd_getb32 (marker.sdata);
}
}
}
section_size = bfd_section_size(pbfd, section);
if (sis_verbose)
printf("\nsection %s at 0x%08lx (0x%lx bytes)",
section_name, section_address, section_size);
/* Text, data or lit */
if (bfd_get_section_flags(pbfd, section) & SEC_LOAD) {
file_ptr fptr;
fptr = 0;
while (section_size > 0) {
char buffer[1024];
int count;
count = min(section_size, 1024);
bfd_get_section_contents(pbfd, section, buffer, fptr, count);
for (i = 0; i < count; i++)
sis_memory_write ((section_address + i) ^ EBT, &buffer[i], 1);
section_address += count;
fptr += count;
section_size -= count;
}
} else /* BSS */
if (sis_verbose)
printf("(not loaded)");
}
}
if (sis_verbose)
printf("\n");
return bfd_get_start_address (pbfd);
}
double get_time (void)
{
double usec;
struct timeval tm;
gettimeofday (&tm, NULL);
usec = ((double) tm.tv_sec) * 1E6 + ((double) tm.tv_usec);
return usec / 1E6;
}