/* * func.c, misc simulator functions. This file is part of SIS. * * SIS, SPARC instruction simulator V1.8 Copyright (C) 1995 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 2 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, write to the Free Software Foundation, Inc., 675 * Mass Ave, Cambridge, MA 02139, USA. * */ #include #include #include #include #include #include "sis.h" #include "end.h" #include #include "sim-config.h" #define VAL(x) strtoul(x,(char **)NULL,0) extern int current_target_byte_order; 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 PARAMS ((struct pstate *sregs, char *fname)); static void set_rega PARAMS ((struct pstate *sregs, char *reg, uint32 rval)); static void disp_reg PARAMS ((struct pstate *sregs, char *reg)); static uint32 limcalc PARAMS ((float32 freq)); static void int_handler PARAMS ((int32 sig)); static void init_event PARAMS ((void)); static int disp_fpu PARAMS ((struct pstate *sregs)); static void disp_regs PARAMS ((struct pstate *sregs, int cwp)); static void disp_ctrl PARAMS ((struct pstate *sregs)); static void disp_mem PARAMS ((uint32 addr, uint32 len)); static int batch(sregs, fname) struct pstate *sregs; char *fname; { FILE *fp; char lbuf[1024]; if ((fp = fopen(fname, "r")) == NULL) { fprintf(stderr, "couldn't open batch file %s\n", fname); return (0); } while (!feof(fp)) { lbuf[0] = 0; fgets(lbuf, 1023, fp); if ((strlen(lbuf) > 0) && (lbuf[strlen(lbuf) - 1] == '\n')) lbuf[strlen(lbuf) - 1] = 0; printf("sis> %s\n", lbuf); exec_cmd(sregs, 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; } } if (current_target_byte_order == BIG_ENDIAN) { buf[0] = (rval >> 24) & 0x0ff; buf[1] = (rval >> 16) & 0x0ff; buf[2] = (rval >> 8) & 0x0ff; buf[3] = rval & 0x0ff; } else { buf[3] = (rval >> 24) & 0x0ff; buf[2] = (rval >> 16) & 0x0ff; buf[1] = (rval >> 8) & 0x0ff; buf[0] = 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(®[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(sregs, cmd) char *cmd; struct pstate *sregs; { char *cmd1, *cmd2; int32 stat; uint32 len, i, clen, j; static uint32 daddr = 0; char *cmdsave; stat = OK; cmdsave = strdup(cmd); if ((cmd1 = strtok(cmd, " \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, -1, 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; 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, -1, 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, -1, 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) { system(&cmdsave[clen]); } } 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, -1, 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, -1, 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, -1, 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, -1, 0); daddr = sregs->pc; sim_halt(); } else printf("syntax error\n"); } if (cmdsave != NULL) free(cmdsave); return (stat); } void reset_stat(sregs) struct pstate *sregs; { sregs->tottime = 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, tottime; if (sregs->tottime == 0) tottime = 1; else tottime = sregs->tottime; 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 : %9d\n\r", ebase.simtime - sregs->simstart); printf(" Instructions : %9d\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 : %5.2f ms\n", (float) (ebase.simtime - sregs->simstart) / 1000.0 / sregs->freq); printf(" Processor utilisation : %5.2f %%\n", 100.0 * (1.0 - ((float) sregs->pwdtime / (float) stime))); printf(" Real-time / simulator-time : 1/%.2f \n", ((float) sregs->tottime) / ((float) (stime) / (sregs->freq * 1.0E6))); printf(" Simulator performance : %d KIPS\n",sregs->ninst/tottime/1000); printf(" Used time (sys + user) : %3d 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_FLOAT 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 disp_ctrl(sregs) struct pstate *sregs; { unsigned char i[4]; printf("\n psr: %08X wim: %08X tbr: %08X y: %08X\n", sregs->psr, sregs->wim, sregs->tbr, sregs->y); sis_memory_read(sregs->pc, i, 4); printf("\n pc: %08X = %02X%02X%02X%02X ", sregs->pc,i[0],i[1],i[2],i[3]); print_insn_sparc(sregs->pc, &dinfo); sis_memory_read(sregs->npc, i, 4); printf("\n npc: %08X = %02X%02X%02X%02X ",sregs->npc,i[0],i[1],i[2],i[3]); print_insn_sparc(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; unsigned char data[4]; 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, 4); printf("%02x%02x%02x%02x ", data[0],data[1],data[2],data[3]); mem[j] = *((int *) &data); } printf(" "); p = (char *) mem; for (j = 0; j < 16; j++) { if (isprint(p[j])) putchar(p[j]); else putchar('.'); } } printf("\n\n"); } void dis_mem(addr, len, info) uint32 addr; uint32 len; struct disassemble_info *info; { uint32 i; unsigned char data[4]; for (i = addr & -3; i < ((addr & -3) + (len << 2)); i += 4) { sis_memory_read(i, data, 4); printf(" %08x %02x%02x%02x%02x ", i, data[0],data[1],data[2],data[3]); print_insn_sparc(i, info); if (i >= 0xfffffffc) break; printf("\n"); } } /* Add event to event queue */ void event(cfunc, arg, delta) void (*cfunc) (); int32 arg; uint32 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, 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, 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" #ifdef ANSI_PROTOTYPES #include #else #include #endif #include "libiberty.h" #include "bfd.h" #define min(A, B) (((A) < (B)) ? (A) : (B)) #define LOAD_ADDRESS 0 int bfd_load(fname) char *fname; { asection *section; bfd *pbfd; const bfd_arch_info_type *arch; 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 (bfd_little_endian (pbfd) || arch->mach == bfd_mach_sparc_sparclite_le) current_target_byte_order = LITTLE_ENDIAN; else current_target_byte_order = BIG_ENDIAN; if (sis_verbose) printf("file %s is %s-endian.\n", fname, current_target_byte_order == BIG_ENDIAN ? "big" : "little"); 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) { if (current_target_byte_order == BIG_ENDIAN) section_address = bfd_getb32 (marker.sdata); else section_address = bfd_getl32 (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); sis_memory_write(section_address, buffer, count); 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)); }