/* mem.c --- memory for M32C simulator. Copyright (C) 2005, 2007, 2008, 2009 Free Software Foundation, Inc. Contributed by Red Hat, Inc. This file is part of the GNU simulators. 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 . */ #include "config.h" #include #include #include #include #include #include #include #ifdef HAVE_SYS_SELECT_H #include #endif #ifdef HAVE_TERMIOS_H #include #endif #include "mem.h" #include "cpu.h" #include "syscalls.h" #include "misc.h" #ifdef TIMER_A #include "int.h" #include "timer_a.h" #endif #define L1_BITS (10) #define L2_BITS (10) #define OFF_BITS (12) #define L1_LEN (1 << L1_BITS) #define L2_LEN (1 << L2_BITS) #define OFF_LEN (1 << OFF_BITS) static unsigned char **pt[L1_LEN]; #ifdef HAVE_TERMIOS_H int m32c_console_ifd = 0; #endif int m32c_console_ofd = 1; #ifdef HAVE_TERMIOS_H int m32c_use_raw_console = 0; #endif #ifdef TIMER_A Timer_A timer_a; #endif /* [ get=0/put=1 ][ byte size ] */ static unsigned int mem_counters[2][5]; #define COUNT(isput,bytes) \ if (verbose && enable_counting) mem_counters[isput][bytes]++ void init_mem (void) { int i, j; for (i = 0; i < L1_LEN; i++) if (pt[i]) { for (j = 0; j < L2_LEN; j++) if (pt[i][j]) free (pt[i][j]); free (pt[i]); } memset (pt, 0, sizeof (pt)); memset (mem_counters, 0, sizeof (mem_counters)); } static unsigned char * mem_ptr (address) { static int recursing = 0; int pt1 = (address >> (L2_BITS + OFF_BITS)) & ((1 << L1_BITS) - 1); int pt2 = (address >> OFF_BITS) & ((1 << L2_BITS) - 1); int pto = address & ((1 << OFF_BITS) - 1); if (address == 0 && !recursing) { recursing = 1; put_reg (pc, m32c_opcode_pc); printf ("NULL pointer dereference at pc=0x%x\n", get_reg (pc)); step_result = M32C_MAKE_HIT_BREAK (); #if 0 /* This code can be re-enabled to help diagnose NULL pointer bugs that aren't debuggable in GDB. */ m32c_dump_all_registers (); exit (1); #endif } if (pt[pt1] == 0) pt[pt1] = (unsigned char **) calloc (L2_LEN, sizeof (char **)); if (pt[pt1][pt2] == 0) { pt[pt1][pt2] = (unsigned char *) malloc (OFF_LEN); memset (pt[pt1][pt2], 0, OFF_LEN); } return pt[pt1][pt2] + pto; } static void used (int rstart, int i, int j) { int rend = i << (L2_BITS + OFF_BITS); rend += j << OFF_BITS; if (rstart == 0xe0000 && rend == 0xe1000) return; printf ("mem: %08x - %08x (%dk bytes)\n", rstart, rend - 1, (rend - rstart) / 1024); } static char * mcs (int isput, int bytes) { return comma (mem_counters[isput][bytes]); } void mem_usage_stats () { int i, j; int rstart = 0; int pending = 0; for (i = 0; i < L1_LEN; i++) if (pt[i]) { for (j = 0; j < L2_LEN; j++) if (pt[i][j]) { if (!pending) { pending = 1; rstart = (i << (L2_BITS + OFF_BITS)) + (j << OFF_BITS); } } else if (pending) { pending = 0; used (rstart, i, j); } } else { if (pending) { pending = 0; used (rstart, i, 0); } } /* mem foo: 123456789012 123456789012 123456789012 123456789012 123456789012 */ printf (" byte short pointer long" " fetch\n"); printf ("mem get: %12s %12s %12s %12s %12s\n", mcs (0, 1), mcs (0, 2), mcs (0, 3), mcs (0, 4), mcs (0, 0)); printf ("mem put: %12s %12s %12s %12s\n", mcs (1, 1), mcs (1, 2), mcs (1, 3), mcs (1, 4)); } static int tpr = 0; static void s (int address, char *dir) { if (tpr == 0) printf ("MEM[%0*x] %s", membus_mask == 0xfffff ? 5 : 6, address, dir); tpr++; } #define S(d) if (trace) s(address, d) static void e () { if (!trace) return; tpr--; if (tpr == 0) printf ("\n"); } #define E() if (trace) e() extern int m32c_disassemble; void mem_put_byte (int address, unsigned char value) { unsigned char *m; address &= membus_mask; m = mem_ptr (address); if (trace) printf (" %02x", value); *m = value; switch (address) { case 0x00e1: { static int old_led = -1; static char *led_on[] = { "\033[31m O ", "\033[32m O ", "\033[34m O " }; static char *led_off[] = { "\033[0m · ", "\033[0m · ", "\033[0m · " }; int i; if (old_led != value) { fputs (" ", stdout); for (i = 0; i < 3; i++) if (value & (1 << i)) fputs (led_off[i], stdout); else fputs (led_on[i], stdout); fputs ("\033[0m\r", stdout); fflush (stdout); old_led = value; } } break; #ifdef TIMER_A /* M32C Timer A */ case 0x346: /* TA0low */ timer_a.count = (timer_a.count & 0xff00) | value; timer_a.reload = timer_a.count; break; case 0x347: /* TA0high */ timer_a.count = (timer_a.count & 0x00ff) | (value << 8); timer_a.reload = timer_a.count; break; case 0x340: /* TABSR */ timer_a.bsr = value; break; case 0x356: /* TA0MR */ timer_a.mode = value; break; case 0x35f: /* TCSPR */ timer_a.tcspr = value; break; case 0x006c: /* TA0IC */ timer_a.ic = value; break; /* R8C Timer RA */ case 0x100: /* TRACR */ timer_a.bsr = value; break; case 0x102: /* TRAMR */ timer_a.mode = value; break; case 0x104: /* TRA */ timer_a.count = value; timer_a.reload = value; break; case 0x103: /* TRAPRE */ timer_a.tcspr = value; break; case 0x0056: /* TA0IC */ timer_a.ic = value; break; #endif case 0x2ea: /* m32c uart1tx */ case 0x3aa: /* m16c uart1tx */ { static int pending_exit = 0; if (value == 0) { if (pending_exit) { step_result = M32C_MAKE_EXITED (value); return; } pending_exit = 1; } else { write (m32c_console_ofd, &value, 1); } } break; case 0x400: m32c_syscall (value); break; case 0x401: putchar (value); break; case 0x402: printf ("SimTrace: %06lx %02x\n", regs.r_pc, value); break; case 0x403: printf ("SimTrap: %06lx %02x\n", regs.r_pc, value); abort (); } } void mem_put_qi (int address, unsigned char value) { S ("<="); mem_put_byte (address, value & 0xff); E (); COUNT (1, 1); } void mem_put_hi (int address, unsigned short value) { if (address == 0x402) { printf ("SimTrace: %06lx %04x\n", regs.r_pc, value); return; } S ("<="); mem_put_byte (address, value & 0xff); mem_put_byte (address + 1, value >> 8); E (); COUNT (1, 2); } void mem_put_psi (int address, unsigned long value) { S ("<="); mem_put_byte (address, value & 0xff); mem_put_byte (address + 1, (value >> 8) & 0xff); mem_put_byte (address + 2, value >> 16); E (); COUNT (1, 3); } void mem_put_si (int address, unsigned long value) { S ("<="); mem_put_byte (address, value & 0xff); mem_put_byte (address + 1, (value >> 8) & 0xff); mem_put_byte (address + 2, (value >> 16) & 0xff); mem_put_byte (address + 3, (value >> 24) & 0xff); E (); COUNT (1, 4); } void mem_put_blk (int address, void *bufptr, int nbytes) { S ("<="); if (enable_counting) mem_counters[1][1] += nbytes; while (nbytes--) mem_put_byte (address++, *(unsigned char *) bufptr++); E (); } unsigned char mem_get_pc () { unsigned char *m = mem_ptr (regs.r_pc & membus_mask); COUNT (0, 0); return *m; } #ifdef HAVE_TERMIOS_H static int console_raw = 0; static struct termios oattr; static int stdin_ready () { fd_set ifd; int n; struct timeval t; t.tv_sec = 0; t.tv_usec = 0; FD_ZERO (&ifd); FD_SET (m32c_console_ifd, &ifd); n = select (1, &ifd, 0, 0, &t); return n > 0; } void m32c_sim_restore_console () { if (console_raw) tcsetattr (m32c_console_ifd, TCSANOW, &oattr); console_raw = 0; } #endif static unsigned char mem_get_byte (int address) { unsigned char *m; address &= membus_mask; m = mem_ptr (address); switch (address) { #ifdef HAVE_TERMIOS_H case 0x2ed: /* m32c uart1c1 */ case 0x3ad: /* m16c uart1c1 */ if (!console_raw && m32c_use_raw_console) { struct termios attr; tcgetattr (m32c_console_ifd, &attr); tcgetattr (m32c_console_ifd, &oattr); /* We want each key to be sent as the user presses them. */ attr.c_lflag &= ~(ICANON | ECHO | ECHOE); tcsetattr (m32c_console_ifd, TCSANOW, &attr); console_raw = 1; atexit (m32c_sim_restore_console); } if (stdin_ready ()) return 0x02; /* tx empty and rx full */ else return 0x0a; /* transmitter empty */ case 0x2ee: /* m32c uart1 rx */ { char c; read (m32c_console_ifd, &c, 1); if (m32c_console_ifd == 0 && c == 3) /* Ctrl-C */ { printf ("Ctrl-C!\n"); exit (0); } if (m32c_console_ifd != 1) { if (isgraph (c)) printf ("\033[31m%c\033[0m", c); else printf ("\033[31m%02x\033[0m", c); } return c; } #endif #ifdef TIMER_A case 0x346: /* TA0low */ return timer_a.count & 0xff; case 0x347: /* TA0high */ return (timer_a.count >> 8) & 0xff; case 0x104: /* TRA */ return timer_a.count; #endif default: /* In case both cases above are not included. */ ; } S ("=>"); if (trace) printf (" %02x", *m); E (); return *m; } unsigned char mem_get_qi (int address) { unsigned char rv; S ("=>"); rv = mem_get_byte (address); COUNT (0, 1); E (); return rv; } unsigned short mem_get_hi (int address) { unsigned short rv; S ("=>"); rv = mem_get_byte (address); rv |= mem_get_byte (address + 1) * 256; COUNT (0, 2); E (); return rv; } unsigned long mem_get_psi (int address) { unsigned long rv; S ("=>"); rv = mem_get_byte (address); rv |= mem_get_byte (address + 1) * 256; rv |= mem_get_byte (address + 2) * 65536; COUNT (0, 3); E (); return rv; } unsigned long mem_get_si (int address) { unsigned long rv; S ("=>"); rv = mem_get_byte (address); rv |= mem_get_byte (address + 1) << 8; rv |= mem_get_byte (address + 2) << 16; rv |= mem_get_byte (address + 3) << 24; COUNT (0, 4); E (); return rv; } void mem_get_blk (int address, void *bufptr, int nbytes) { S ("=>"); if (enable_counting) mem_counters[0][1] += nbytes; while (nbytes--) *(char *) bufptr++ = mem_get_byte (address++); E (); } int sign_ext (int v, int bits) { if (bits < 32) { v &= (1 << bits) - 1; if (v & (1 << (bits - 1))) v -= (1 << bits); } return v; } #if TIMER_A void update_timer_a () { if (timer_a.bsr & 1) { timer_a.prescale--; if (timer_a.prescale < 0) { if (A24) { switch (timer_a.mode & 0xc0) { case 0x00: timer_a.prescale = 0; break; case 0x40: timer_a.prescale = 8; break; case 0x80: timer_a.prescale = timer_a.tcspr & 0x0f; break; case 0xc0: timer_a.prescale = 32; break; } } else { timer_a.prescale = timer_a.tcspr; } timer_a.count--; if (timer_a.count < 0) { timer_a.count = timer_a.reload; if (timer_a.ic & 7) { if (A24) mem_put_qi (0x6c, timer_a.ic | 0x08); else mem_put_qi (0x56, timer_a.ic | 0x08); } } } } if (regs.r_flags & FLAGBIT_I /* interrupts enabled */ && timer_a.ic & 0x08 /* timer A interrupt triggered */ && (timer_a.ic & 0x07) > ((regs.r_flags >> 12) & 0x07)) { if (A24) trigger_peripheral_interrupt (12, 0x06c); else trigger_peripheral_interrupt (22, 0x056); } } #endif