/* gdb-if.c -- sim interface to GDB. Copyright (C) 2008, 2009, 2010 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 #include #include #include #include #include #include "ansidecl.h" #include "gdb/callback.h" #include "gdb/remote-sim.h" #include "gdb/signals.h" #include "gdb/sim-rx.h" #include "cpu.h" #include "mem.h" #include "load.h" #include "syscalls.h" #include "err.h" /* Ideally, we'd wrap up all the minisim's data structures in an object and pass that around. However, neither GDB nor run needs that ability. So we just have one instance, that lives in global variables, and each time we open it, we re-initialize it. */ struct sim_state { const char *message; }; static struct sim_state the_minisim = { "This is the sole rx minisim instance. See libsim.a's global variables." }; static int open; SIM_DESC sim_open (SIM_OPEN_KIND kind, struct host_callback_struct *callback, struct bfd *abfd, char **argv) { if (open) fprintf (stderr, "rx minisim: re-opened sim\n"); /* The 'run' interface doesn't use this function, so we don't care about KIND; it's always SIM_OPEN_DEBUG. */ if (kind != SIM_OPEN_DEBUG) fprintf (stderr, "rx minisim: sim_open KIND != SIM_OPEN_DEBUG: %d\n", kind); set_callbacks (callback); /* We don't expect any command-line arguments. */ init_mem (); init_regs (); execution_error_init_debugger (); sim_disasm_init (abfd); open = 1; return &the_minisim; } static void check_desc (SIM_DESC sd) { if (sd != &the_minisim) fprintf (stderr, "rx minisim: desc != &the_minisim\n"); } void sim_close (SIM_DESC sd, int quitting) { check_desc (sd); /* Not much to do. At least free up our memory. */ init_mem (); open = 0; } static bfd * open_objfile (const char *filename) { bfd *prog = bfd_openr (filename, 0); if (!prog) { fprintf (stderr, "Can't read %s\n", filename); return 0; } if (!bfd_check_format (prog, bfd_object)) { fprintf (stderr, "%s not a rx program\n", filename); return 0; } return prog; } static struct swap_list { bfd_vma start, end; struct swap_list *next; } *swap_list = NULL; static void free_swap_list (void) { while (swap_list) { struct swap_list *next = swap_list->next; free (swap_list); swap_list = next; } } /* When running in big endian mode, we must do an additional byte swap of memory areas used to hold instructions. See the comment preceding rx_load in load.c to see why this is so. Construct a list of memory areas that must be byte swapped. This list will be consulted when either reading or writing memory. */ static void build_swap_list (struct bfd *abfd) { asection *s; free_swap_list (); /* Nothing to do when in little endian mode. */ if (!rx_big_endian) return; for (s = abfd->sections; s; s = s->next) { if ((s->flags & SEC_LOAD) && (s->flags & SEC_CODE)) { struct swap_list *sl; bfd_size_type size; size = bfd_get_section_size (s); if (size <= 0) continue; sl = malloc (sizeof (struct swap_list)); assert (sl != NULL); sl->next = swap_list; sl->start = bfd_section_lma (abfd, s); sl->end = sl->start + size; swap_list = sl; } } } static int addr_in_swap_list (bfd_vma addr) { struct swap_list *s; for (s = swap_list; s; s = s->next) { if (s->start <= addr && addr < s->end) return 1; } return 0; } SIM_RC sim_load (SIM_DESC sd, char *prog, struct bfd *abfd, int from_tty) { check_desc (sd); if (!abfd) abfd = open_objfile (prog); if (!abfd) return SIM_RC_FAIL; rx_load (abfd); build_swap_list (abfd); return SIM_RC_OK; } SIM_RC sim_create_inferior (SIM_DESC sd, struct bfd *abfd, char **argv, char **env) { check_desc (sd); if (abfd) { rx_load (abfd); build_swap_list (abfd); } return SIM_RC_OK; } int sim_read (SIM_DESC sd, SIM_ADDR mem, unsigned char *buf, int length) { int i; check_desc (sd); if (mem == 0) return 0; execution_error_clear_last_error (); for (i = 0; i < length; i++) { bfd_vma addr = mem + i; int do_swap = addr_in_swap_list (addr); buf[i] = mem_get_qi (addr ^ (do_swap ? 3 : 0)); if (execution_error_get_last_error () != SIM_ERR_NONE) return i; } return length; } int sim_write (SIM_DESC sd, SIM_ADDR mem, const unsigned char *buf, int length) { int i; check_desc (sd); execution_error_clear_last_error (); for (i = 0; i < length; i++) { bfd_vma addr = mem + i; int do_swap = addr_in_swap_list (addr); mem_put_qi (addr ^ (do_swap ? 3 : 0), buf[i]); if (execution_error_get_last_error () != SIM_ERR_NONE) return i; } return length; } /* Read the LENGTH bytes at BUF as an little-endian value. */ static DI get_le (unsigned char *buf, int length) { DI acc = 0; while (--length >= 0) acc = (acc << 8) + buf[length]; return acc; } /* Read the LENGTH bytes at BUF as a big-endian value. */ static DI get_be (unsigned char *buf, int length) { DI acc = 0; while (length-- > 0) acc = (acc << 8) + *buf++; return acc; } /* Store VAL as a little-endian value in the LENGTH bytes at BUF. */ static void put_le (unsigned char *buf, int length, DI val) { int i; for (i = 0; i < length; i++) { buf[i] = val & 0xff; val >>= 8; } } /* Store VAL as a big-endian value in the LENGTH bytes at BUF. */ static void put_be (unsigned char *buf, int length, DI val) { int i; for (i = length-1; i >= 0; i--) { buf[i] = val & 0xff; val >>= 8; } } static int check_regno (enum sim_rx_regnum regno) { return 0 <= regno && regno < sim_rx_num_regs; } static size_t reg_size (enum sim_rx_regnum regno) { size_t size; switch (regno) { case sim_rx_r0_regnum: size = sizeof (regs.r[0]); break; case sim_rx_r1_regnum: size = sizeof (regs.r[1]); break; case sim_rx_r2_regnum: size = sizeof (regs.r[2]); break; case sim_rx_r3_regnum: size = sizeof (regs.r[3]); break; case sim_rx_r4_regnum: size = sizeof (regs.r[4]); break; case sim_rx_r5_regnum: size = sizeof (regs.r[5]); break; case sim_rx_r6_regnum: size = sizeof (regs.r[6]); break; case sim_rx_r7_regnum: size = sizeof (regs.r[7]); break; case sim_rx_r8_regnum: size = sizeof (regs.r[8]); break; case sim_rx_r9_regnum: size = sizeof (regs.r[9]); break; case sim_rx_r10_regnum: size = sizeof (regs.r[10]); break; case sim_rx_r11_regnum: size = sizeof (regs.r[11]); break; case sim_rx_r12_regnum: size = sizeof (regs.r[12]); break; case sim_rx_r13_regnum: size = sizeof (regs.r[13]); break; case sim_rx_r14_regnum: size = sizeof (regs.r[14]); break; case sim_rx_r15_regnum: size = sizeof (regs.r[15]); break; case sim_rx_isp_regnum: size = sizeof (regs.r_isp); break; case sim_rx_usp_regnum: size = sizeof (regs.r_usp); break; case sim_rx_intb_regnum: size = sizeof (regs.r_intb); break; case sim_rx_pc_regnum: size = sizeof (regs.r_pc); break; case sim_rx_ps_regnum: size = sizeof (regs.r_psw); break; case sim_rx_bpc_regnum: size = sizeof (regs.r_bpc); break; case sim_rx_bpsw_regnum: size = sizeof (regs.r_bpsw); break; case sim_rx_fintv_regnum: size = sizeof (regs.r_fintv); break; case sim_rx_fpsw_regnum: size = sizeof (regs.r_fpsw); break; default: size = 0; break; } return size; } int sim_fetch_register (SIM_DESC sd, int regno, unsigned char *buf, int length) { size_t size; DI val; check_desc (sd); if (!check_regno (regno)) return 0; size = reg_size (regno); if (length != size) return 0; switch (regno) { case sim_rx_r0_regnum: val = get_reg (0); break; case sim_rx_r1_regnum: val = get_reg (1); break; case sim_rx_r2_regnum: val = get_reg (2); break; case sim_rx_r3_regnum: val = get_reg (3); break; case sim_rx_r4_regnum: val = get_reg (4); break; case sim_rx_r5_regnum: val = get_reg (5); break; case sim_rx_r6_regnum: val = get_reg (6); break; case sim_rx_r7_regnum: val = get_reg (7); break; case sim_rx_r8_regnum: val = get_reg (8); break; case sim_rx_r9_regnum: val = get_reg (9); break; case sim_rx_r10_regnum: val = get_reg (10); break; case sim_rx_r11_regnum: val = get_reg (11); break; case sim_rx_r12_regnum: val = get_reg (12); break; case sim_rx_r13_regnum: val = get_reg (13); break; case sim_rx_r14_regnum: val = get_reg (14); break; case sim_rx_r15_regnum: val = get_reg (15); break; case sim_rx_isp_regnum: val = get_reg (isp); break; case sim_rx_usp_regnum: val = get_reg (usp); break; case sim_rx_intb_regnum: val = get_reg (intb); break; case sim_rx_pc_regnum: val = get_reg (pc); break; case sim_rx_ps_regnum: val = get_reg (psw); break; case sim_rx_bpc_regnum: val = get_reg (bpc); break; case sim_rx_bpsw_regnum: val = get_reg (bpsw); break; case sim_rx_fintv_regnum: val = get_reg (fintv); break; case sim_rx_fpsw_regnum: val = get_reg (fpsw); break; default: fprintf (stderr, "rx minisim: unrecognized register number: %d\n", regno); return -1; } if (rx_big_endian) put_be (buf, length, val); else put_le (buf, length, val); return size; } int sim_store_register (SIM_DESC sd, int regno, unsigned char *buf, int length) { size_t size; DI val; check_desc (sd); if (!check_regno (regno)) return 0; size = reg_size (regno); if (length != size) return 0; if (rx_big_endian) val = get_be (buf, length); else val = get_le (buf, length); switch (regno) { case sim_rx_r0_regnum: put_reg (0, val); break; case sim_rx_r1_regnum: put_reg (1, val); break; case sim_rx_r2_regnum: put_reg (2, val); break; case sim_rx_r3_regnum: put_reg (3, val); break; case sim_rx_r4_regnum: put_reg (4, val); break; case sim_rx_r5_regnum: put_reg (5, val); break; case sim_rx_r6_regnum: put_reg (6, val); break; case sim_rx_r7_regnum: put_reg (7, val); break; case sim_rx_r8_regnum: put_reg (8, val); break; case sim_rx_r9_regnum: put_reg (9, val); break; case sim_rx_r10_regnum: put_reg (10, val); break; case sim_rx_r11_regnum: put_reg (11, val); break; case sim_rx_r12_regnum: put_reg (12, val); break; case sim_rx_r13_regnum: put_reg (13, val); break; case sim_rx_r14_regnum: put_reg (14, val); break; case sim_rx_r15_regnum: put_reg (15, val); break; case sim_rx_isp_regnum: put_reg (isp, val); break; case sim_rx_usp_regnum: put_reg (usp, val); break; case sim_rx_intb_regnum: put_reg (intb, val); break; case sim_rx_pc_regnum: put_reg (pc, val); break; case sim_rx_ps_regnum: put_reg (psw, val); break; case sim_rx_bpc_regnum: put_reg (bpc, val); break; case sim_rx_bpsw_regnum: put_reg (bpsw, val); break; case sim_rx_fintv_regnum: put_reg (fintv, val); break; case sim_rx_fpsw_regnum: put_reg (fpsw, val); break; default: fprintf (stderr, "rx minisim: unrecognized register number: %d\n", regno); return -1; } return size; } void sim_info (SIM_DESC sd, int verbose) { check_desc (sd); printf ("The rx minisim doesn't collect any statistics.\n"); } static volatile int stop; static enum sim_stop reason; int siggnal; /* Given a signal number used by the RX bsp (that is, newlib), return a host signal number. (Oddly, the gdb/sim interface uses host signal numbers...) */ int rx_signal_to_host (int rx) { switch (rx) { case 4: #ifdef SIGILL return SIGILL; #else return SIGSEGV; #endif case 5: return SIGTRAP; case 10: #ifdef SIGBUS return SIGBUS; #else return SIGSEGV; #endif case 11: return SIGSEGV; case 24: #ifdef SIGXCPU return SIGXCPU; #else break; #endif case 2: return SIGINT; case 8: #ifdef SIGFPE return SIGFPE; #else break; #endif case 6: return SIGABRT; } return 0; } /* Take a step return code RC and set up the variables consulted by sim_stop_reason appropriately. */ void handle_step (int rc) { if (execution_error_get_last_error () != SIM_ERR_NONE) { reason = sim_stopped; siggnal = TARGET_SIGNAL_SEGV; } if (RX_STEPPED (rc) || RX_HIT_BREAK (rc)) { reason = sim_stopped; siggnal = TARGET_SIGNAL_TRAP; } else if (RX_STOPPED (rc)) { reason = sim_stopped; siggnal = rx_signal_to_host (RX_STOP_SIG (rc)); } else { assert (RX_EXITED (rc)); reason = sim_exited; siggnal = RX_EXIT_STATUS (rc); } } void sim_resume (SIM_DESC sd, int step, int sig_to_deliver) { check_desc (sd); if (sig_to_deliver != 0) { fprintf (stderr, "Warning: the rx minisim does not implement " "signal delivery yet.\n" "Resuming with no signal.\n"); } execution_error_clear_last_error (); if (step) handle_step (decode_opcode ()); else { /* We don't clear 'stop' here, because then we would miss interrupts that arrived on the way here. Instead, we clear the flag in sim_stop_reason, after GDB has disabled the interrupt signal handler. */ for (;;) { if (stop) { stop = 0; reason = sim_stopped; siggnal = TARGET_SIGNAL_INT; break; } int rc = decode_opcode (); if (execution_error_get_last_error () != SIM_ERR_NONE) { reason = sim_stopped; siggnal = TARGET_SIGNAL_SEGV; break; } if (!RX_STEPPED (rc)) { handle_step (rc); break; } } } } int sim_stop (SIM_DESC sd) { stop = 1; return 1; } void sim_stop_reason (SIM_DESC sd, enum sim_stop *reason_p, int *sigrc_p) { check_desc (sd); *reason_p = reason; *sigrc_p = siggnal; } void sim_do_command (SIM_DESC sd, char *cmd) { check_desc (sd); char *p = cmd; /* Skip leading whitespace. */ while (isspace (*p)) p++; /* Find the extent of the command word. */ for (p = cmd; *p; p++) if (isspace (*p)) break; /* Null-terminate the command word, and record the start of any further arguments. */ char *args; if (*p) { *p = '\0'; args = p + 1; while (isspace (*args)) args++; } else args = p; if (strcmp (cmd, "trace") == 0) { if (strcmp (args, "on") == 0) trace = 1; else if (strcmp (args, "off") == 0) trace = 0; else printf ("The 'sim trace' command expects 'on' or 'off' " "as an argument.\n"); } else if (strcmp (cmd, "verbose") == 0) { if (strcmp (args, "on") == 0) verbose = 1; else if (strcmp (args, "noisy") == 0) verbose = 2; else if (strcmp (args, "off") == 0) verbose = 0; else printf ("The 'sim verbose' command expects 'on', 'noisy', or 'off'" " as an argument.\n"); } else printf ("The 'sim' command expects either 'trace' or 'verbose'" " as a subcommand.\n"); }