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[/] [or1k/] [branches/] [oc/] [gdb-5.0/] [sim/] [mn10300/] [interp.c] - Rev 1765
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#include <signal.h> #if WITH_COMMON #include "sim-main.h" #include "sim-options.h" #include "sim-hw.h" #else #include "mn10300_sim.h" #endif #include "sysdep.h" #include "bfd.h" #include "sim-assert.h" #ifdef HAVE_STDLIB_H #include <stdlib.h> #endif #ifdef HAVE_STRING_H #include <string.h> #else #ifdef HAVE_STRINGS_H #include <strings.h> #endif #endif #include "bfd.h" #ifndef INLINE #ifdef __GNUC__ #define INLINE inline #else #define INLINE #endif #endif host_callback *mn10300_callback; int mn10300_debug; struct _state State; /* simulation target board. NULL=default configuration */ static char* board = NULL; static DECLARE_OPTION_HANDLER (mn10300_option_handler); enum { OPTION_BOARD = OPTION_START, }; static SIM_RC mn10300_option_handler (sd, cpu, opt, arg, is_command) SIM_DESC sd; sim_cpu *cpu; int opt; char *arg; int is_command; { int cpu_nr; switch (opt) { case OPTION_BOARD: { if (arg) { board = zalloc(strlen(arg) + 1); strcpy(board, arg); } return SIM_RC_OK; } } return SIM_RC_OK; } static const OPTION mn10300_options[] = { #define BOARD_AM32 "stdeval1" { {"board", required_argument, NULL, OPTION_BOARD}, '\0', "none" /* rely on compile-time string concatenation for other options */ "|" BOARD_AM32 , "Customize simulation for a particular board.", mn10300_option_handler }, { {NULL, no_argument, NULL, 0}, '\0', NULL, NULL, NULL } }; #if WITH_COMMON #else static void dispatch PARAMS ((uint32, uint32, int)); static long hash PARAMS ((long)); static void init_system PARAMS ((void)); static SIM_OPEN_KIND sim_kind; static char *myname; #define MAX_HASH 127 struct hash_entry { struct hash_entry *next; long opcode; long mask; struct simops *ops; #ifdef HASH_STAT unsigned long count; #endif }; static int max_mem = 0; struct hash_entry hash_table[MAX_HASH+1]; /* This probably doesn't do a very good job at bucket filling, but it's simple... */ static INLINE long hash(insn) long insn; { /* These are one byte insns, we special case these since, in theory, they should be the most heavily used. */ if ((insn & 0xffffff00) == 0) { switch (insn & 0xf0) { case 0x00: return 0x70; case 0x40: return 0x71; case 0x10: return 0x72; case 0x30: return 0x73; case 0x50: return 0x74; case 0x60: return 0x75; case 0x70: return 0x76; case 0x80: return 0x77; case 0x90: return 0x78; case 0xa0: return 0x79; case 0xb0: return 0x7a; case 0xe0: return 0x7b; default: return 0x7c; } } /* These are two byte insns */ if ((insn & 0xffff0000) == 0) { if ((insn & 0xf000) == 0x2000 || (insn & 0xf000) == 0x5000) return ((insn & 0xfc00) >> 8) & 0x7f; if ((insn & 0xf000) == 0x4000) return ((insn & 0xf300) >> 8) & 0x7f; if ((insn & 0xf000) == 0x8000 || (insn & 0xf000) == 0x9000 || (insn & 0xf000) == 0xa000 || (insn & 0xf000) == 0xb000) return ((insn & 0xf000) >> 8) & 0x7f; if ((insn & 0xff00) == 0xf000 || (insn & 0xff00) == 0xf100 || (insn & 0xff00) == 0xf200 || (insn & 0xff00) == 0xf500 || (insn & 0xff00) == 0xf600) return ((insn & 0xfff0) >> 4) & 0x7f; if ((insn & 0xf000) == 0xc000) return ((insn & 0xff00) >> 8) & 0x7f; return ((insn & 0xffc0) >> 6) & 0x7f; } /* These are three byte insns. */ if ((insn & 0xff000000) == 0) { if ((insn & 0xf00000) == 0x000000) return ((insn & 0xf30000) >> 16) & 0x7f; if ((insn & 0xf00000) == 0x200000 || (insn & 0xf00000) == 0x300000) return ((insn & 0xfc0000) >> 16) & 0x7f; if ((insn & 0xff0000) == 0xf80000) return ((insn & 0xfff000) >> 12) & 0x7f; if ((insn & 0xff0000) == 0xf90000) return ((insn & 0xfffc00) >> 10) & 0x7f; return ((insn & 0xff0000) >> 16) & 0x7f; } /* These are four byte or larger insns. */ if ((insn & 0xf0000000) == 0xf0000000) return ((insn & 0xfff00000) >> 20) & 0x7f; return ((insn & 0xff000000) >> 24) & 0x7f; } static INLINE void dispatch (insn, extension, length) uint32 insn; uint32 extension; int length; { struct hash_entry *h; h = &hash_table[hash(insn)]; while ((insn & h->mask) != h->opcode || (length != h->ops->length)) { if (!h->next) { (*mn10300_callback->printf_filtered) (mn10300_callback, "ERROR looking up hash for 0x%x, PC=0x%x\n", insn, PC); exit(1); } h = h->next; } #ifdef HASH_STAT h->count++; #endif /* Now call the right function. */ (h->ops->func)(insn, extension); PC += length; } void sim_size (power) int power; { if (State.mem) free (State.mem); max_mem = 1 << power; State.mem = (uint8 *) calloc (1, 1 << power); if (!State.mem) { (*mn10300_callback->printf_filtered) (mn10300_callback, "Allocation of main memory failed.\n"); exit (1); } } static void init_system () { if (!State.mem) sim_size(19); } int sim_write (sd, addr, buffer, size) SIM_DESC sd; SIM_ADDR addr; unsigned char *buffer; int size; { int i; init_system (); for (i = 0; i < size; i++) store_byte (addr + i, buffer[i]); return size; } /* Compare two opcode table entries for qsort. */ static int compare_simops (arg1, arg2) const PTR arg1; const PTR arg2; { unsigned long code1 = ((struct simops *)arg1)->opcode; unsigned long code2 = ((struct simops *)arg2)->opcode; if (code1 < code2) return -1; if (code2 < code1) return 1; return 0; } SIM_DESC sim_open (kind, cb, abfd, argv) SIM_OPEN_KIND kind; host_callback *cb; struct _bfd *abfd; char **argv; { struct simops *s; struct hash_entry *h; char **p; int i; mn10300_callback = cb; /* Sort the opcode array from smallest opcode to largest. This will generally improve simulator performance as the smaller opcodes are generally preferred to the larger opcodes. */ for (i = 0, s = Simops; s->func; s++, i++) ; qsort (Simops, i, sizeof (Simops[0]), compare_simops); sim_kind = kind; myname = argv[0]; for (p = argv + 1; *p; ++p) { if (strcmp (*p, "-E") == 0) ++p; /* ignore endian spec */ else #ifdef DEBUG if (strcmp (*p, "-t") == 0) mn10300_debug = DEBUG; else #endif (*mn10300_callback->printf_filtered) (mn10300_callback, "ERROR: unsupported option(s): %s\n",*p); } /* put all the opcodes in the hash table */ for (s = Simops; s->func; s++) { h = &hash_table[hash(s->opcode)]; /* go to the last entry in the chain */ while (h->next) { /* Don't insert the same opcode more than once. */ if (h->opcode == s->opcode && h->mask == s->mask && h->ops == s) break; else h = h->next; } /* Don't insert the same opcode more than once. */ if (h->opcode == s->opcode && h->mask == s->mask && h->ops == s) continue; if (h->ops) { h->next = calloc(1,sizeof(struct hash_entry)); h = h->next; } h->ops = s; h->mask = s->mask; h->opcode = s->opcode; #if HASH_STAT h->count = 0; #endif } /* fudge our descriptor for now */ return (SIM_DESC) 1; } void sim_close (sd, quitting) SIM_DESC sd; int quitting; { /* nothing to do */ } void sim_set_profile (n) int n; { (*mn10300_callback->printf_filtered) (mn10300_callback, "sim_set_profile %d\n", n); } void sim_set_profile_size (n) int n; { (*mn10300_callback->printf_filtered) (mn10300_callback, "sim_set_profile_size %d\n", n); } int sim_stop (sd) SIM_DESC sd; { return 0; } void sim_resume (sd, step, siggnal) SIM_DESC sd; int step, siggnal; { uint32 inst; reg_t oldpc; struct hash_entry *h; if (step) State.exception = SIGTRAP; else State.exception = 0; State.exited = 0; do { unsigned long insn, extension; /* Fetch the current instruction. */ inst = load_mem_big (PC, 2); oldpc = PC; /* Using a giant case statement may seem like a waste because of the code/rodata size the table itself will consume. However, using a giant case statement speeds up the simulator by 10-15% by avoiding cascading if/else statements or cascading case statements. */ switch ((inst >> 8) & 0xff) { /* All the single byte insns except 0x80, 0x90, 0xa0, 0xb0 which must be handled specially. */ case 0x00: case 0x04: case 0x08: case 0x0c: case 0x10: case 0x11: case 0x12: case 0x13: case 0x14: case 0x15: case 0x16: case 0x17: case 0x18: case 0x19: case 0x1a: case 0x1b: case 0x1c: case 0x1d: case 0x1e: case 0x1f: case 0x3c: case 0x3d: case 0x3e: case 0x3f: case 0x40: case 0x41: case 0x44: case 0x45: case 0x48: case 0x49: case 0x4c: case 0x4d: case 0x50: case 0x51: case 0x52: case 0x53: case 0x54: case 0x55: case 0x56: case 0x57: case 0x60: case 0x61: case 0x62: case 0x63: case 0x64: case 0x65: case 0x66: case 0x67: case 0x68: case 0x69: case 0x6a: case 0x6b: case 0x6c: case 0x6d: case 0x6e: case 0x6f: case 0x70: case 0x71: case 0x72: case 0x73: case 0x74: case 0x75: case 0x76: case 0x77: case 0x78: case 0x79: case 0x7a: case 0x7b: case 0x7c: case 0x7d: case 0x7e: case 0x7f: case 0xcb: case 0xd0: case 0xd1: case 0xd2: case 0xd3: case 0xd4: case 0xd5: case 0xd6: case 0xd7: case 0xd8: case 0xd9: case 0xda: case 0xdb: case 0xe0: case 0xe1: case 0xe2: case 0xe3: case 0xe4: case 0xe5: case 0xe6: case 0xe7: case 0xe8: case 0xe9: case 0xea: case 0xeb: case 0xec: case 0xed: case 0xee: case 0xef: case 0xff: insn = (inst >> 8) & 0xff; extension = 0; dispatch (insn, extension, 1); break; /* Special cases where dm == dn is used to encode a different instruction. */ case 0x80: case 0x85: case 0x8a: case 0x8f: case 0x90: case 0x95: case 0x9a: case 0x9f: case 0xa0: case 0xa5: case 0xaa: case 0xaf: case 0xb0: case 0xb5: case 0xba: case 0xbf: insn = inst; extension = 0; dispatch (insn, extension, 2); break; case 0x81: case 0x82: case 0x83: case 0x84: case 0x86: case 0x87: case 0x88: case 0x89: case 0x8b: case 0x8c: case 0x8d: case 0x8e: case 0x91: case 0x92: case 0x93: case 0x94: case 0x96: case 0x97: case 0x98: case 0x99: case 0x9b: case 0x9c: case 0x9d: case 0x9e: case 0xa1: case 0xa2: case 0xa3: case 0xa4: case 0xa6: case 0xa7: case 0xa8: case 0xa9: case 0xab: case 0xac: case 0xad: case 0xae: case 0xb1: case 0xb2: case 0xb3: case 0xb4: case 0xb6: case 0xb7: case 0xb8: case 0xb9: case 0xbb: case 0xbc: case 0xbd: case 0xbe: insn = (inst >> 8) & 0xff; extension = 0; dispatch (insn, extension, 1); break; /* The two byte instructions. */ case 0x20: case 0x21: case 0x22: case 0x23: case 0x28: case 0x29: case 0x2a: case 0x2b: case 0x42: case 0x43: case 0x46: case 0x47: case 0x4a: case 0x4b: case 0x4e: case 0x4f: case 0x58: case 0x59: case 0x5a: case 0x5b: case 0x5c: case 0x5d: case 0x5e: case 0x5f: case 0xc0: case 0xc1: case 0xc2: case 0xc3: case 0xc4: case 0xc5: case 0xc6: case 0xc7: case 0xc8: case 0xc9: case 0xca: case 0xce: case 0xcf: case 0xf0: case 0xf1: case 0xf2: case 0xf3: case 0xf4: case 0xf5: case 0xf6: insn = inst; extension = 0; dispatch (insn, extension, 2); break; /* The three byte insns with a 16bit operand in little endian format. */ case 0x01: case 0x02: case 0x03: case 0x05: case 0x06: case 0x07: case 0x09: case 0x0a: case 0x0b: case 0x0d: case 0x0e: case 0x0f: case 0x24: case 0x25: case 0x26: case 0x27: case 0x2c: case 0x2d: case 0x2e: case 0x2f: case 0x30: case 0x31: case 0x32: case 0x33: case 0x34: case 0x35: case 0x36: case 0x37: case 0x38: case 0x39: case 0x3a: case 0x3b: case 0xcc: insn = load_byte (PC); insn <<= 16; insn |= load_half (PC + 1); extension = 0; dispatch (insn, extension, 3); break; /* The three byte insns without 16bit operand. */ case 0xde: case 0xdf: case 0xf8: case 0xf9: insn = load_mem_big (PC, 3); extension = 0; dispatch (insn, extension, 3); break; /* Four byte insns. */ case 0xfa: case 0xfb: if ((inst & 0xfffc) == 0xfaf0 || (inst & 0xfffc) == 0xfaf4 || (inst & 0xfffc) == 0xfaf8) insn = load_mem_big (PC, 4); else { insn = inst; insn <<= 16; insn |= load_half (PC + 2); extension = 0; } dispatch (insn, extension, 4); break; /* Five byte insns. */ case 0xcd: insn = load_byte (PC); insn <<= 24; insn |= (load_half (PC + 1) << 8); insn |= load_byte (PC + 3); extension = load_byte (PC + 4); dispatch (insn, extension, 5); break; case 0xdc: insn = load_byte (PC); insn <<= 24; extension = load_word (PC + 1); insn |= (extension & 0xffffff00) >> 8; extension &= 0xff; dispatch (insn, extension, 5); break; /* Six byte insns. */ case 0xfc: case 0xfd: insn = (inst << 16); extension = load_word (PC + 2); insn |= ((extension & 0xffff0000) >> 16); extension &= 0xffff; dispatch (insn, extension, 6); break; case 0xdd: insn = load_byte (PC) << 24; extension = load_word (PC + 1); insn |= ((extension >> 8) & 0xffffff); extension = (extension & 0xff) << 16; extension |= load_byte (PC + 5) << 8; extension |= load_byte (PC + 6); dispatch (insn, extension, 7); break; case 0xfe: insn = inst << 16; extension = load_word (PC + 2); insn |= ((extension >> 16) & 0xffff); extension <<= 8; extension &= 0xffff00; extension |= load_byte (PC + 6); dispatch (insn, extension, 7); break; default: abort (); } } while (!State.exception); #ifdef HASH_STAT { int i; for (i = 0; i < MAX_HASH; i++) { struct hash_entry *h; h = &hash_table[i]; printf("hash 0x%x:\n", i); while (h) { printf("h->opcode = 0x%x, count = 0x%x\n", h->opcode, h->count); h = h->next; } printf("\n\n"); } fflush (stdout); } #endif } int sim_trace (sd) SIM_DESC sd; { #ifdef DEBUG mn10300_debug = DEBUG; #endif sim_resume (sd, 0, 0); return 1; } void sim_info (sd, verbose) SIM_DESC sd; int verbose; { (*mn10300_callback->printf_filtered) (mn10300_callback, "sim_info\n"); } SIM_RC sim_create_inferior (sd, abfd, argv, env) SIM_DESC sd; struct _bfd *abfd; char **argv; char **env; { if (abfd != NULL) PC = bfd_get_start_address (abfd); else PC = 0; return SIM_RC_OK; } void sim_set_callbacks (p) host_callback *p; { mn10300_callback = p; } /* All the code for exiting, signals, etc needs to be revamped. This is enough to get c-torture limping though. */ void sim_stop_reason (sd, reason, sigrc) SIM_DESC sd; enum sim_stop *reason; int *sigrc; { if (State.exited) *reason = sim_exited; else *reason = sim_stopped; if (State.exception == SIGQUIT) *sigrc = 0; else *sigrc = State.exception; } int sim_read (sd, addr, buffer, size) SIM_DESC sd; SIM_ADDR addr; unsigned char *buffer; int size; { int i; for (i = 0; i < size; i++) buffer[i] = load_byte (addr + i); return size; } void sim_do_command (sd, cmd) SIM_DESC sd; char *cmd; { (*mn10300_callback->printf_filtered) (mn10300_callback, "\"%s\" is not a valid mn10300 simulator command.\n", cmd); } SIM_RC sim_load (sd, prog, abfd, from_tty) SIM_DESC sd; char *prog; bfd *abfd; int from_tty; { extern bfd *sim_load_file (); /* ??? Don't know where this should live. */ bfd *prog_bfd; prog_bfd = sim_load_file (sd, myname, mn10300_callback, prog, abfd, sim_kind == SIM_OPEN_DEBUG, 0, sim_write); if (prog_bfd == NULL) return SIM_RC_FAIL; if (abfd == NULL) bfd_close (prog_bfd); return SIM_RC_OK; } #endif /* not WITH_COMMON */ #if WITH_COMMON /* For compatibility */ SIM_DESC simulator; /* These default values correspond to expected usage for the chip. */ SIM_DESC sim_open (kind, cb, abfd, argv) SIM_OPEN_KIND kind; host_callback *cb; struct _bfd *abfd; char **argv; { SIM_DESC sd = sim_state_alloc (kind, cb); mn10300_callback = cb; SIM_ASSERT (STATE_MAGIC (sd) == SIM_MAGIC_NUMBER); /* for compatibility */ simulator = sd; /* FIXME: should be better way of setting up interrupts. For moment, only support watchpoints causing a breakpoint (gdb halt). */ STATE_WATCHPOINTS (sd)->pc = &(PC); STATE_WATCHPOINTS (sd)->sizeof_pc = sizeof (PC); STATE_WATCHPOINTS (sd)->interrupt_handler = NULL; STATE_WATCHPOINTS (sd)->interrupt_names = NULL; if (sim_pre_argv_init (sd, argv[0]) != SIM_RC_OK) return 0; sim_add_option_table (sd, NULL, mn10300_options); /* Allocate core managed memory */ sim_do_command (sd, "memory region 0,0x100000"); sim_do_command (sd, "memory region 0x40000000,0x200000"); /* getopt will print the error message so we just have to exit if this fails. FIXME: Hmmm... in the case of gdb we need getopt to call print_filtered. */ if (sim_parse_args (sd, argv) != SIM_RC_OK) { /* Uninstall the modules to avoid memory leaks, file descriptor leaks, etc. */ sim_module_uninstall (sd); return 0; } if ( NULL != board && (strcmp(board, BOARD_AM32) == 0 ) ) { /* environment */ STATE_ENVIRONMENT (sd) = OPERATING_ENVIRONMENT; sim_do_command (sd, "memory region 0x44000000,0x40000"); sim_do_command (sd, "memory region 0x48000000,0x400000"); /* device support for mn1030002 */ /* interrupt controller */ sim_hw_parse (sd, "/mn103int@0x34000100/reg 0x34000100 0x7C 0x34000200 0x8 0x34000280 0x8"); /* DEBUG: NMI input's */ sim_hw_parse (sd, "/glue@0x30000000/reg 0x30000000 12"); sim_hw_parse (sd, "/glue@0x30000000 > int0 nmirq /mn103int"); sim_hw_parse (sd, "/glue@0x30000000 > int1 watchdog /mn103int"); sim_hw_parse (sd, "/glue@0x30000000 > int2 syserr /mn103int"); /* DEBUG: ACK input */ sim_hw_parse (sd, "/glue@0x30002000/reg 0x30002000 4"); sim_hw_parse (sd, "/glue@0x30002000 > int ack /mn103int"); /* DEBUG: LEVEL output */ sim_hw_parse (sd, "/glue@0x30004000/reg 0x30004000 8"); sim_hw_parse (sd, "/mn103int > nmi int0 /glue@0x30004000"); sim_hw_parse (sd, "/mn103int > level int1 /glue@0x30004000"); /* DEBUG: A bunch of interrupt inputs */ sim_hw_parse (sd, "/glue@0x30006000/reg 0x30006000 32"); sim_hw_parse (sd, "/glue@0x30006000 > int0 irq-0 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int1 irq-1 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int2 irq-2 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int3 irq-3 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int4 irq-4 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int5 irq-5 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int6 irq-6 /mn103int"); sim_hw_parse (sd, "/glue@0x30006000 > int7 irq-7 /mn103int"); /* processor interrupt device */ /* the device */ sim_hw_parse (sd, "/mn103cpu@0x20000000"); sim_hw_parse (sd, "/mn103cpu@0x20000000/reg 0x20000000 0x42"); /* DEBUG: ACK output wired upto a glue device */ sim_hw_parse (sd, "/glue@0x20002000"); sim_hw_parse (sd, "/glue@0x20002000/reg 0x20002000 4"); sim_hw_parse (sd, "/mn103cpu > ack int0 /glue@0x20002000"); /* DEBUG: RESET/NMI/LEVEL wired up to a glue device */ sim_hw_parse (sd, "/glue@0x20004000"); sim_hw_parse (sd, "/glue@0x20004000/reg 0x20004000 12"); sim_hw_parse (sd, "/glue@0x20004000 > int0 reset /mn103cpu"); sim_hw_parse (sd, "/glue@0x20004000 > int1 nmi /mn103cpu"); sim_hw_parse (sd, "/glue@0x20004000 > int2 level /mn103cpu"); /* REAL: The processor wired up to the real interrupt controller */ sim_hw_parse (sd, "/mn103cpu > ack ack /mn103int"); sim_hw_parse (sd, "/mn103int > level level /mn103cpu"); sim_hw_parse (sd, "/mn103int > nmi nmi /mn103cpu"); /* PAL */ /* the device */ sim_hw_parse (sd, "/pal@0x31000000"); sim_hw_parse (sd, "/pal@0x31000000/reg 0x31000000 64"); sim_hw_parse (sd, "/pal@0x31000000/poll? true"); /* DEBUG: PAL wired up to a glue device */ sim_hw_parse (sd, "/glue@0x31002000"); sim_hw_parse (sd, "/glue@0x31002000/reg 0x31002000 16"); sim_hw_parse (sd, "/pal@0x31000000 > countdown int0 /glue@0x31002000"); sim_hw_parse (sd, "/pal@0x31000000 > timer int1 /glue@0x31002000"); sim_hw_parse (sd, "/pal@0x31000000 > int int2 /glue@0x31002000"); sim_hw_parse (sd, "/glue@0x31002000 > int0 int3 /glue@0x31002000"); sim_hw_parse (sd, "/glue@0x31002000 > int1 int3 /glue@0x31002000"); sim_hw_parse (sd, "/glue@0x31002000 > int2 int3 /glue@0x31002000"); /* REAL: The PAL wired up to the real interrupt controller */ sim_hw_parse (sd, "/pal@0x31000000 > countdown irq-0 /mn103int"); sim_hw_parse (sd, "/pal@0x31000000 > timer irq-1 /mn103int"); sim_hw_parse (sd, "/pal@0x31000000 > int irq-2 /mn103int"); /* 8 and 16 bit timers */ sim_hw_parse (sd, "/mn103tim@0x34001000/reg 0x34001000 36 0x34001080 100 0x34004000 16"); /* Hook timer interrupts up to interrupt controller */ sim_hw_parse (sd, "/mn103tim > timer-0-underflow timer-0-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-1-underflow timer-1-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-2-underflow timer-2-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-3-underflow timer-3-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-4-underflow timer-4-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-5-underflow timer-5-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-6-underflow timer-6-underflow /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-6-compare-a timer-6-compare-a /mn103int"); sim_hw_parse (sd, "/mn103tim > timer-6-compare-b timer-6-compare-b /mn103int"); /* Serial devices 0,1,2 */ sim_hw_parse (sd, "/mn103ser@0x34000800/reg 0x34000800 48"); sim_hw_parse (sd, "/mn103ser@0x34000800/poll? true"); /* Hook serial interrupts up to interrupt controller */ sim_hw_parse (sd, "/mn103ser > serial-0-receive serial-0-receive /mn103int"); sim_hw_parse (sd, "/mn103ser > serial-0-transmit serial-0-transmit /mn103int"); sim_hw_parse (sd, "/mn103ser > serial-1-receive serial-1-receive /mn103int"); sim_hw_parse (sd, "/mn103ser > serial-1-transmit serial-1-transmit /mn103int"); sim_hw_parse (sd, "/mn103ser > serial-2-receive serial-2-receive /mn103int"); sim_hw_parse (sd, "/mn103ser > serial-2-transmit serial-2-transmit /mn103int"); sim_hw_parse (sd, "/mn103iop@0x36008000/reg 0x36008000 8 0x36008020 8 0x36008040 0xc 0x36008060 8 0x36008080 8"); /* Memory control registers */ sim_do_command (sd, "memory region 0x32000020,0x30"); /* Cache control register */ sim_do_command (sd, "memory region 0x20000070,0x4"); /* Cache purge regions */ sim_do_command (sd, "memory region 0x28400000,0x800"); sim_do_command (sd, "memory region 0x28401000,0x800"); /* DMA registers */ sim_do_command (sd, "memory region 0x32000100,0xF"); sim_do_command (sd, "memory region 0x32000200,0xF"); sim_do_command (sd, "memory region 0x32000400,0xF"); sim_do_command (sd, "memory region 0x32000800,0xF"); } else { if (board != NULL) { sim_io_eprintf (sd, "Error: Board `%s' unknown.\n", board); return 0; } } /* check for/establish the a reference program image */ if (sim_analyze_program (sd, (STATE_PROG_ARGV (sd) != NULL ? *STATE_PROG_ARGV (sd) : NULL), abfd) != SIM_RC_OK) { sim_module_uninstall (sd); return 0; } /* establish any remaining configuration options */ if (sim_config (sd) != SIM_RC_OK) { sim_module_uninstall (sd); return 0; } if (sim_post_argv_init (sd) != SIM_RC_OK) { /* Uninstall the modules to avoid memory leaks, file descriptor leaks, etc. */ sim_module_uninstall (sd); return 0; } /* set machine specific configuration */ /* STATE_CPU (sd, 0)->psw_mask = (PSW_NP | PSW_EP | PSW_ID | PSW_SAT */ /* | PSW_CY | PSW_OV | PSW_S | PSW_Z); */ return sd; } void sim_close (sd, quitting) SIM_DESC sd; int quitting; { sim_module_uninstall (sd); } SIM_RC sim_create_inferior (sd, prog_bfd, argv, env) SIM_DESC sd; struct _bfd *prog_bfd; char **argv; char **env; { memset (&State, 0, sizeof (State)); if (prog_bfd != NULL) { PC = bfd_get_start_address (prog_bfd); } else { PC = 0; } CIA_SET (STATE_CPU (sd, 0), (unsigned64) PC); return SIM_RC_OK; } void sim_do_command (sd, cmd) SIM_DESC sd; char *cmd; { char *mm_cmd = "memory-map"; char *int_cmd = "interrupt"; if (sim_args_command (sd, cmd) != SIM_RC_OK) { if (strncmp (cmd, mm_cmd, strlen (mm_cmd) == 0)) sim_io_eprintf (sd, "`memory-map' command replaced by `sim memory'\n"); else if (strncmp (cmd, int_cmd, strlen (int_cmd)) == 0) sim_io_eprintf (sd, "`interrupt' command replaced by `sim watch'\n"); else sim_io_eprintf (sd, "Unknown command `%s'\n", cmd); } } #endif /* WITH_COMMON */ /* FIXME These would more efficient to use than load_mem/store_mem, but need to be changed to use the memory map. */ uint8 get_byte (x) uint8 *x; { return *x; } uint16 get_half (x) uint8 *x; { uint8 *a = x; return (a[1] << 8) + (a[0]); } uint32 get_word (x) uint8 *x; { uint8 *a = x; return (a[3]<<24) + (a[2]<<16) + (a[1]<<8) + (a[0]); } void put_byte (addr, data) uint8 *addr; uint8 data; { uint8 *a = addr; a[0] = data; } void put_half (addr, data) uint8 *addr; uint16 data; { uint8 *a = addr; a[0] = data & 0xff; a[1] = (data >> 8) & 0xff; } void put_word (addr, data) uint8 *addr; uint32 data; { uint8 *a = addr; a[0] = data & 0xff; a[1] = (data >> 8) & 0xff; a[2] = (data >> 16) & 0xff; a[3] = (data >> 24) & 0xff; } int sim_fetch_register (sd, rn, memory, length) SIM_DESC sd; int rn; unsigned char *memory; int length; { put_word (memory, State.regs[rn]); return -1; } int sim_store_register (sd, rn, memory, length) SIM_DESC sd; int rn; unsigned char *memory; int length; { State.regs[rn] = get_word (memory); return -1; } void mn10300_core_signal (SIM_DESC sd, sim_cpu *cpu, sim_cia cia, unsigned map, int nr_bytes, address_word addr, transfer_type transfer, sim_core_signals sig) { const char *copy = (transfer == read_transfer ? "read" : "write"); address_word ip = CIA_ADDR (cia); switch (sig) { case sim_core_unmapped_signal: sim_io_eprintf (sd, "mn10300-core: %d byte %s to unmapped address 0x%lx at 0x%lx\n", nr_bytes, copy, (unsigned long) addr, (unsigned long) ip); program_interrupt(sd, cpu, cia, SIM_SIGSEGV); break; case sim_core_unaligned_signal: sim_io_eprintf (sd, "mn10300-core: %d byte %s to unaligned address 0x%lx at 0x%lx\n", nr_bytes, copy, (unsigned long) addr, (unsigned long) ip); program_interrupt(sd, cpu, cia, SIM_SIGBUS); break; default: sim_engine_abort (sd, cpu, cia, "mn10300_core_signal - internal error - bad switch"); } } void program_interrupt (SIM_DESC sd, sim_cpu *cpu, sim_cia cia, SIM_SIGNAL sig) { int status; struct hw *device; static int in_interrupt = 0; #ifdef SIM_CPU_EXCEPTION_TRIGGER SIM_CPU_EXCEPTION_TRIGGER(sd,cpu,cia); #endif /* avoid infinite recursion */ if (in_interrupt) { (*mn10300_callback->printf_filtered) (mn10300_callback, "ERROR: recursion in program_interrupt during software exception dispatch."); } else { in_interrupt = 1; /* copy NMI handler code from dv-mn103cpu.c */ store_word (SP - 4, CIA_GET (cpu)); store_half (SP - 8, PSW); /* Set the SYSEF flag in NMICR by backdoor method. See dv-mn103int.c:write_icr(). This is necessary because software exceptions are not modelled by actually talking to the interrupt controller, so it cannot set its own SYSEF flag. */ if ((NULL != board) && (strcmp(board, BOARD_AM32) == 0)) store_byte (0x34000103, 0x04); } PSW &= ~PSW_IE; SP = SP - 8; CIA_SET (cpu, 0x40000008); in_interrupt = 0; sim_engine_halt(sd, cpu, NULL, cia, sim_stopped, sig); } void mn10300_cpu_exception_trigger(SIM_DESC sd, sim_cpu* cpu, address_word cia) { ASSERT(cpu != NULL); if(State.exc_suspended > 0) sim_io_eprintf(sd, "Warning, nested exception triggered (%d)\n", State.exc_suspended); CIA_SET (cpu, cia); memcpy(State.exc_trigger_regs, State.regs, sizeof(State.exc_trigger_regs)); State.exc_suspended = 0; } void mn10300_cpu_exception_suspend(SIM_DESC sd, sim_cpu* cpu, int exception) { ASSERT(cpu != NULL); if(State.exc_suspended > 0) sim_io_eprintf(sd, "Warning, nested exception signal (%d then %d)\n", State.exc_suspended, exception); memcpy(State.exc_suspend_regs, State.regs, sizeof(State.exc_suspend_regs)); memcpy(State.regs, State.exc_trigger_regs, sizeof(State.regs)); CIA_SET (cpu, PC); /* copy PC back from new State.regs */ State.exc_suspended = exception; } void mn10300_cpu_exception_resume(SIM_DESC sd, sim_cpu* cpu, int exception) { ASSERT(cpu != NULL); if(exception == 0 && State.exc_suspended > 0) { if(State.exc_suspended != SIGTRAP) /* warn not for breakpoints */ sim_io_eprintf(sd, "Warning, resuming but ignoring pending exception signal (%d)\n", State.exc_suspended); } else if(exception != 0 && State.exc_suspended > 0) { if(exception != State.exc_suspended) sim_io_eprintf(sd, "Warning, resuming with mismatched exception signal (%d vs %d)\n", State.exc_suspended, exception); memcpy(State.regs, State.exc_suspend_regs, sizeof(State.regs)); CIA_SET (cpu, PC); /* copy PC back from new State.regs */ } else if(exception != 0 && State.exc_suspended == 0) { sim_io_eprintf(sd, "Warning, ignoring spontanous exception signal (%d)\n", exception); } State.exc_suspended = 0; }