URL
https://opencores.org/ocsvn/openrisc_me/openrisc_me/trunk
Subversion Repositories openrisc_me
[/] [openrisc/] [trunk/] [gnu-src/] [gdb-7.1/] [sim/] [m68hc11/] [m68hc11_sim.c] - Rev 299
Go to most recent revision | Compare with Previous | Blame | View Log
/* m6811_cpu.c -- 68HC11&68HC12 CPU Emulation Copyright 1999, 2000, 2001, 2002, 2003, 2007, 2008, 2009, 2010 Free Software Foundation, Inc. Written by Stephane Carrez (stcarrez@nerim.fr) This file is part of GDB, GAS, and the GNU binutils. 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 "sim-main.h" #include "sim-assert.h" #include "sim-module.h" #include "sim-options.h" enum { OPTION_CPU_RESET = OPTION_START, OPTION_EMUL_OS, OPTION_CPU_CONFIG, OPTION_CPU_BOOTSTRAP, OPTION_CPU_MODE }; static DECLARE_OPTION_HANDLER (cpu_option_handler); static const OPTION cpu_options[] = { { {"cpu-reset", no_argument, NULL, OPTION_CPU_RESET }, '\0', NULL, "Reset the CPU", cpu_option_handler }, { {"emulos", no_argument, NULL, OPTION_EMUL_OS }, '\0', NULL, "Emulate some OS system calls (read, write, ...)", cpu_option_handler }, { {"cpu-config", required_argument, NULL, OPTION_CPU_CONFIG }, '\0', NULL, "Specify the initial CPU configuration register", cpu_option_handler }, { {"bootstrap", no_argument, NULL, OPTION_CPU_BOOTSTRAP }, '\0', NULL, "Start the processing in bootstrap mode", cpu_option_handler }, { {NULL, no_argument, NULL, 0}, '\0', NULL, NULL, NULL } }; static SIM_RC cpu_option_handler (SIM_DESC sd, sim_cpu *cpu, int opt, char *arg, int is_command) { int val; cpu = STATE_CPU (sd, 0); switch (opt) { case OPTION_CPU_RESET: sim_board_reset (sd); break; case OPTION_EMUL_OS: cpu->cpu_emul_syscall = 1; break; case OPTION_CPU_CONFIG: if (sscanf(arg, "0x%x", &val) == 1 || sscanf(arg, "%d", &val) == 1) { cpu->cpu_config = val; cpu->cpu_use_local_config = 1; } else cpu->cpu_use_local_config = 0; break; case OPTION_CPU_BOOTSTRAP: cpu->cpu_start_mode = "bootstrap"; break; case OPTION_CPU_MODE: break; } return SIM_RC_OK; } void cpu_call (sim_cpu *cpu, uint16 addr) { cpu_set_pc (cpu, addr); } void cpu_return (sim_cpu *cpu) { } /* Set the stack pointer and re-compute the current frame. */ void cpu_set_sp (sim_cpu *cpu, uint16 val) { cpu->cpu_regs.sp = val; } uint16 cpu_get_reg (sim_cpu* cpu, uint8 reg) { switch (reg) { case 0: return cpu_get_x (cpu); case 1: return cpu_get_y (cpu); case 2: return cpu_get_sp (cpu); case 3: return cpu_get_pc (cpu); default: return 0; } } uint16 cpu_get_src_reg (sim_cpu* cpu, uint8 reg) { switch (reg) { case 0: return cpu_get_a (cpu); case 1: return cpu_get_b (cpu); case 2: return cpu_get_ccr (cpu); case 3: return cpu_get_tmp3 (cpu); case 4: return cpu_get_d (cpu); case 5: return cpu_get_x (cpu); case 6: return cpu_get_y (cpu); case 7: return cpu_get_sp (cpu); default: return 0; } } void cpu_set_dst_reg (sim_cpu* cpu, uint8 reg, uint16 val) { switch (reg) { case 0: cpu_set_a (cpu, val); break; case 1: cpu_set_b (cpu, val); break; case 2: cpu_set_ccr (cpu, val); break; case 3: cpu_set_tmp2 (cpu, val); break; case 4: cpu_set_d (cpu, val); break; case 5: cpu_set_x (cpu, val); break; case 6: cpu_set_y (cpu, val); break; case 7: cpu_set_sp (cpu, val); break; default: break; } } void cpu_set_reg (sim_cpu* cpu, uint8 reg, uint16 val) { switch (reg) { case 0: cpu_set_x (cpu, val); break; case 1: cpu_set_y (cpu, val); break; case 2: cpu_set_sp (cpu, val); break; case 3: cpu_set_pc (cpu, val); break; default: break; } } /* Returns the address of a 68HC12 indexed operand. Pre and post modifications are handled on the source register. */ uint16 cpu_get_indexed_operand_addr (sim_cpu* cpu, int restrict) { uint8 reg; uint16 sval; uint16 addr; uint8 code; code = cpu_fetch8 (cpu); /* n,r with 5-bit signed constant. */ if ((code & 0x20) == 0) { reg = (code >> 6) & 3; sval = (code & 0x1f); if (code & 0x10) sval |= 0xfff0; addr = cpu_get_reg (cpu, reg); addr += sval; } /* Auto pre/post increment/decrement. */ else if ((code & 0xc0) != 0xc0) { reg = (code >> 6) & 3; sval = (code & 0x0f); if (sval & 0x8) { sval |= 0xfff0; } else { sval = sval + 1; } addr = cpu_get_reg (cpu, reg); cpu_set_reg (cpu, reg, addr + sval); if ((code & 0x10) == 0) { addr += sval; } } /* [n,r] 16-bits offset indexed indirect. */ else if ((code & 0x07) == 3) { if (restrict) { return 0; } reg = (code >> 3) & 0x03; addr = cpu_get_reg (cpu, reg); addr += cpu_fetch16 (cpu); addr = memory_read16 (cpu, addr); cpu_add_cycles (cpu, 1); } else if ((code & 0x4) == 0) { if (restrict) { return 0; } reg = (code >> 3) & 0x03; addr = cpu_get_reg (cpu, reg); if (code & 0x2) { sval = cpu_fetch16 (cpu); cpu_add_cycles (cpu, 1); } else { sval = cpu_fetch8 (cpu); if (code & 0x1) sval |= 0xff00; cpu_add_cycles (cpu, 1); } addr += sval; } else { reg = (code >> 3) & 0x03; addr = cpu_get_reg (cpu, reg); switch (code & 3) { case 0: addr += cpu_get_a (cpu); break; case 1: addr += cpu_get_b (cpu); break; case 2: addr += cpu_get_d (cpu); break; case 3: default: addr += cpu_get_d (cpu); addr = memory_read16 (cpu, addr); cpu_add_cycles (cpu, 1); break; } } return addr; } uint8 cpu_get_indexed_operand8 (sim_cpu* cpu, int restrict) { uint16 addr; addr = cpu_get_indexed_operand_addr (cpu, restrict); return memory_read8 (cpu, addr); } uint16 cpu_get_indexed_operand16 (sim_cpu* cpu, int restrict) { uint16 addr; addr = cpu_get_indexed_operand_addr (cpu, restrict); return memory_read16 (cpu, addr); } void cpu_move8 (sim_cpu *cpu, uint8 code) { uint8 src; uint16 addr; switch (code) { case 0x0b: src = cpu_fetch8 (cpu); addr = cpu_fetch16 (cpu); break; case 0x08: addr = cpu_get_indexed_operand_addr (cpu, 1); src = cpu_fetch8 (cpu); break; case 0x0c: addr = cpu_fetch16 (cpu); src = memory_read8 (cpu, addr); addr = cpu_fetch16 (cpu); break; case 0x09: addr = cpu_get_indexed_operand_addr (cpu, 1); src = memory_read8 (cpu, cpu_fetch16 (cpu)); break; case 0x0d: src = cpu_get_indexed_operand8 (cpu, 1); addr = cpu_fetch16 (cpu); break; case 0x0a: src = cpu_get_indexed_operand8 (cpu, 1); addr = cpu_get_indexed_operand_addr (cpu, 1); break; default: sim_engine_abort (CPU_STATE (cpu), cpu, 0, "Invalid code 0x%0x -- internal error?", code); return; } memory_write8 (cpu, addr, src); } void cpu_move16 (sim_cpu *cpu, uint8 code) { uint16 src; uint16 addr; switch (code) { case 0x03: src = cpu_fetch16 (cpu); addr = cpu_fetch16 (cpu); break; case 0x00: addr = cpu_get_indexed_operand_addr (cpu, 1); src = cpu_fetch16 (cpu); break; case 0x04: addr = cpu_fetch16 (cpu); src = memory_read16 (cpu, addr); addr = cpu_fetch16 (cpu); break; case 0x01: addr = cpu_get_indexed_operand_addr (cpu, 1); src = memory_read16 (cpu, cpu_fetch16 (cpu)); break; case 0x05: src = cpu_get_indexed_operand16 (cpu, 1); addr = cpu_fetch16 (cpu); break; case 0x02: src = cpu_get_indexed_operand16 (cpu, 1); addr = cpu_get_indexed_operand_addr (cpu, 1); break; default: sim_engine_abort (CPU_STATE (cpu), cpu, 0, "Invalid code 0x%0x -- internal error?", code); return; } memory_write16 (cpu, addr, src); } int cpu_initialize (SIM_DESC sd, sim_cpu *cpu) { sim_add_option_table (sd, 0, cpu_options); memset (&cpu->cpu_regs, 0, sizeof(cpu->cpu_regs)); cpu->cpu_absolute_cycle = 0; cpu->cpu_current_cycle = 0; cpu->cpu_emul_syscall = 1; cpu->cpu_running = 1; cpu->cpu_stop_on_interrupt = 0; cpu->cpu_frequency = 8 * 1000 * 1000; cpu->cpu_use_elf_start = 0; cpu->cpu_elf_start = 0; cpu->cpu_use_local_config = 0; cpu->bank_start = 0; cpu->bank_end = 0; cpu->bank_shift = 0; cpu->cpu_config = M6811_NOSEC | M6811_NOCOP | M6811_ROMON | M6811_EEON; interrupts_initialize (sd, cpu); cpu->cpu_is_initialized = 1; return 0; } /* Reinitialize the processor after a reset. */ int cpu_reset (sim_cpu *cpu) { /* Initialize the config register. It is only initialized at reset time. */ memset (cpu->ios, 0, sizeof (cpu->ios)); if (cpu->cpu_configured_arch->arch == bfd_arch_m68hc11) cpu->ios[M6811_INIT] = 0x1; else cpu->ios[M6811_INIT] = 0; /* Output compare registers set to 0xFFFF. */ cpu->ios[M6811_TOC1_H] = 0xFF; cpu->ios[M6811_TOC1_L] = 0xFF; cpu->ios[M6811_TOC2_H] = 0xFF; cpu->ios[M6811_TOC2_L] = 0xFF; cpu->ios[M6811_TOC3_H] = 0xFF; cpu->ios[M6811_TOC4_L] = 0xFF; cpu->ios[M6811_TOC5_H] = 0xFF; cpu->ios[M6811_TOC5_L] = 0xFF; /* Setup the processor registers. */ memset (&cpu->cpu_regs, 0, sizeof(cpu->cpu_regs)); cpu->cpu_absolute_cycle = 0; cpu->cpu_current_cycle = 0; cpu->cpu_is_initialized = 0; /* Reset interrupts. */ interrupts_reset (&cpu->cpu_interrupts); /* Reinitialize the CPU operating mode. */ cpu->ios[M6811_HPRIO] = cpu->cpu_mode; return 0; } /* Reinitialize the processor after a reset. */ int cpu_restart (sim_cpu *cpu) { uint16 addr; /* Get CPU starting address depending on the CPU mode. */ if (cpu->cpu_use_elf_start == 0) { switch ((cpu->ios[M6811_HPRIO]) & (M6811_SMOD | M6811_MDA)) { /* Single Chip */ default: case 0 : addr = memory_read16 (cpu, 0xFFFE); break; /* Expanded Multiplexed */ case M6811_MDA: addr = memory_read16 (cpu, 0xFFFE); break; /* Special Bootstrap */ case M6811_SMOD: addr = 0; break; /* Factory Test */ case M6811_MDA | M6811_SMOD: addr = memory_read16 (cpu, 0xFFFE); break; } } else { addr = cpu->cpu_elf_start; } /* Setup the processor registers. */ cpu->cpu_insn_pc = addr; cpu->cpu_regs.pc = addr; cpu->cpu_regs.ccr = M6811_X_BIT | M6811_I_BIT | M6811_S_BIT; cpu->cpu_absolute_cycle = 0; cpu->cpu_is_initialized = 1; cpu->cpu_current_cycle = 0; cpu_call (cpu, addr); return 0; } void print_io_reg_desc (SIM_DESC sd, io_reg_desc *desc, int val, int mode) { while (desc->mask) { if (val & desc->mask) sim_io_printf (sd, "%s", mode == 0 ? desc->short_name : desc->long_name); desc++; } } void print_io_byte (SIM_DESC sd, const char *name, io_reg_desc *desc, uint8 val, uint16 addr) { sim_io_printf (sd, " %-9.9s @ 0x%04x 0x%02x ", name, addr, val); if (desc) print_io_reg_desc (sd, desc, val, 0); } void print_io_word (SIM_DESC sd, const char *name, io_reg_desc *desc, uint16 val, uint16 addr) { sim_io_printf (sd, " %-9.9s @ 0x%04x 0x%04x ", name, addr, val); if (desc) print_io_reg_desc (sd, desc, val, 0); } void cpu_ccr_update_tst8 (sim_cpu *proc, uint8 val) { cpu_set_ccr_V (proc, 0); cpu_set_ccr_N (proc, val & 0x80 ? 1 : 0); cpu_set_ccr_Z (proc, val == 0 ? 1 : 0); } uint16 cpu_fetch_relbranch (sim_cpu *cpu) { uint16 addr = (uint16) cpu_fetch8 (cpu); if (addr & 0x0080) { addr |= 0xFF00; } addr += cpu->cpu_regs.pc; return addr; } uint16 cpu_fetch_relbranch16 (sim_cpu *cpu) { uint16 addr = cpu_fetch16 (cpu); addr += cpu->cpu_regs.pc; return addr; } /* Push all the CPU registers (when an interruption occurs). */ void cpu_push_all (sim_cpu *cpu) { if (cpu->cpu_configured_arch->arch == bfd_arch_m68hc11) { cpu_m68hc11_push_uint16 (cpu, cpu->cpu_regs.pc); cpu_m68hc11_push_uint16 (cpu, cpu->cpu_regs.iy); cpu_m68hc11_push_uint16 (cpu, cpu->cpu_regs.ix); cpu_m68hc11_push_uint16 (cpu, cpu->cpu_regs.d); cpu_m68hc11_push_uint8 (cpu, cpu->cpu_regs.ccr); } else { cpu_m68hc12_push_uint16 (cpu, cpu->cpu_regs.pc); cpu_m68hc12_push_uint16 (cpu, cpu->cpu_regs.iy); cpu_m68hc12_push_uint16 (cpu, cpu->cpu_regs.ix); cpu_m68hc12_push_uint16 (cpu, cpu->cpu_regs.d); cpu_m68hc12_push_uint8 (cpu, cpu->cpu_regs.ccr); } } /* Simulation of the dbcc/ibcc/tbcc 68HC12 conditional branch operations. */ void cpu_dbcc (sim_cpu* cpu) { uint8 code; uint16 addr; uint16 inc; uint16 reg; code = cpu_fetch8 (cpu); switch (code & 0xc0) { case 0x80: /* ibcc */ inc = 1; break; case 0x40: /* tbcc */ inc = 0; break; case 0: /* dbcc */ inc = -1; break; default: abort (); break; } addr = cpu_fetch8 (cpu); if (code & 0x10) addr |= 0xff00; addr += cpu_get_pc (cpu); reg = cpu_get_src_reg (cpu, code & 0x07); reg += inc; /* Branch according to register value. */ if ((reg != 0 && (code & 0x20)) || (reg == 0 && !(code & 0x20))) { cpu_set_pc (cpu, addr); } cpu_set_dst_reg (cpu, code & 0x07, reg); } void cpu_exg (sim_cpu* cpu, uint8 code) { uint8 r1, r2; uint16 src1; uint16 src2; r1 = (code >> 4) & 0x07; r2 = code & 0x07; if (code & 0x80) { src1 = cpu_get_src_reg (cpu, r1); src2 = cpu_get_src_reg (cpu, r2); if (r2 == 1 || r2 == 2) src2 |= 0xff00; cpu_set_dst_reg (cpu, r2, src1); cpu_set_dst_reg (cpu, r1, src2); } else { src1 = cpu_get_src_reg (cpu, r1); /* Sign extend the 8-bit registers (A, B, CCR). */ if ((r1 == 0 || r1 == 1 || r1 == 2) && (src1 & 0x80)) src1 |= 0xff00; cpu_set_dst_reg (cpu, r2, src1); } } /* Handle special instructions. */ void cpu_special (sim_cpu *cpu, enum M6811_Special special) { switch (special) { case M6811_RTI: { uint8 ccr; ccr = cpu_m68hc11_pop_uint8 (cpu); cpu_set_ccr (cpu, ccr); cpu_set_d (cpu, cpu_m68hc11_pop_uint16 (cpu)); cpu_set_x (cpu, cpu_m68hc11_pop_uint16 (cpu)); cpu_set_y (cpu, cpu_m68hc11_pop_uint16 (cpu)); cpu_set_pc (cpu, cpu_m68hc11_pop_uint16 (cpu)); cpu_return (cpu); break; } case M6812_RTI: { uint8 ccr; ccr = cpu_m68hc12_pop_uint8 (cpu); cpu_set_ccr (cpu, ccr); cpu_set_d (cpu, cpu_m68hc12_pop_uint16 (cpu)); cpu_set_x (cpu, cpu_m68hc12_pop_uint16 (cpu)); cpu_set_y (cpu, cpu_m68hc12_pop_uint16 (cpu)); cpu_set_pc (cpu, cpu_m68hc12_pop_uint16 (cpu)); cpu_return (cpu); break; } case M6811_WAI: /* In the ELF-start mode, we are in a special mode where the WAI corresponds to an exit. */ if (cpu->cpu_use_elf_start) { cpu_set_pc (cpu, cpu->cpu_insn_pc); sim_engine_halt (CPU_STATE (cpu), cpu, NULL, NULL_CIA, sim_exited, cpu_get_d (cpu)); return; } /* SCz: not correct... */ cpu_push_all (cpu); break; case M6811_SWI: interrupts_raise (&cpu->cpu_interrupts, M6811_INT_SWI); interrupts_process (&cpu->cpu_interrupts); break; case M6811_EMUL_SYSCALL: case M6811_ILLEGAL: if (cpu->cpu_emul_syscall) { uint8 op = memory_read8 (cpu, cpu_get_pc (cpu) - 1); if (op == 0x41) { cpu_set_pc (cpu, cpu->cpu_insn_pc); sim_engine_halt (CPU_STATE (cpu), cpu, NULL, NULL_CIA, sim_exited, cpu_get_d (cpu)); return; } else { emul_os (op, cpu); } return; } interrupts_raise (&cpu->cpu_interrupts, M6811_INT_ILLEGAL); interrupts_process (&cpu->cpu_interrupts); break; case M6811_TEST: case M6812_BGND: { SIM_DESC sd; sd = CPU_STATE (cpu); /* Breakpoint instruction if we are under gdb. */ if (STATE_OPEN_KIND (sd) == SIM_OPEN_DEBUG) { cpu->cpu_regs.pc --; sim_engine_halt (CPU_STATE (cpu), cpu, 0, cpu_get_pc (cpu), sim_stopped, SIM_SIGTRAP); } /* else this is a nop but not in test factory mode. */ break; } case M6812_IDIVS: { int32 src1 = (int16) cpu_get_d (cpu); int32 src2 = (int16) cpu_get_x (cpu); if (src2 == 0) { cpu_set_ccr_C (cpu, 1); } else { cpu_set_d (cpu, src1 % src2); src1 = src1 / src2; cpu_set_x (cpu, src1); cpu_set_ccr_C (cpu, 0); cpu_set_ccr_Z (cpu, src1 == 0); cpu_set_ccr_N (cpu, src1 & 0x8000); cpu_set_ccr_V (cpu, src1 >= 32768 || src1 < -32768); } } break; case M6812_EDIV: { uint32 src1 = (uint32) cpu_get_x (cpu); uint32 src2 = (uint32) (cpu_get_y (cpu) << 16) | (uint32) (cpu_get_d (cpu)); if (src1 == 0) { cpu_set_ccr_C (cpu, 1); } else { cpu_set_ccr_C (cpu, 0); cpu_set_d (cpu, src2 % src1); src2 = src2 / src1; cpu_set_y (cpu, src2); cpu_set_ccr_Z (cpu, src2 == 0); cpu_set_ccr_N (cpu, (src2 & 0x8000) != 0); cpu_set_ccr_V (cpu, (src2 & 0xffff0000) != 0); } } break; case M6812_EDIVS: { int32 src1 = (int16) cpu_get_x (cpu); int32 src2 = (uint32) (cpu_get_y (cpu) << 16) | (uint32) (cpu_get_d (cpu)); if (src1 == 0) { cpu_set_ccr_C (cpu, 1); } else { cpu_set_ccr_C (cpu, 0); cpu_set_d (cpu, src2 % src1); src2 = src2 / src1; cpu_set_y (cpu, src2); cpu_set_ccr_Z (cpu, src2 == 0); cpu_set_ccr_N (cpu, (src2 & 0x8000) != 0); cpu_set_ccr_V (cpu, src2 > 32767 || src2 < -32768); } } break; case M6812_EMULS: { int32 src1, src2; src1 = (int16) cpu_get_d (cpu); src2 = (int16) cpu_get_y (cpu); src1 = src1 * src2; cpu_set_d (cpu, src1 & 0x0ffff); cpu_set_y (cpu, src1 >> 16); cpu_set_ccr_Z (cpu, src1 == 0); cpu_set_ccr_N (cpu, (src1 & 0x80000000) != 0); cpu_set_ccr_C (cpu, (src1 & 0x00008000) != 0); } break; case M6812_EMACS: { int32 src1, src2; uint16 addr; addr = cpu_fetch16 (cpu); src1 = (int16) memory_read16 (cpu, cpu_get_x (cpu)); src2 = (int16) memory_read16 (cpu, cpu_get_y (cpu)); src1 = src1 * src2; src2 = (((uint32) memory_read16 (cpu, addr)) << 16) | (uint32) memory_read16 (cpu, addr + 2); memory_write16 (cpu, addr, (src1 + src2) >> 16); memory_write16 (cpu, addr + 2, (src1 + src2)); } break; case M6812_CALL: { uint8 page; uint16 addr; addr = cpu_fetch16 (cpu); page = cpu_fetch8 (cpu); cpu_m68hc12_push_uint16 (cpu, cpu_get_pc (cpu)); cpu_m68hc12_push_uint8 (cpu, cpu_get_page (cpu)); cpu_set_page (cpu, page); cpu_set_pc (cpu, addr); } break; case M6812_CALL_INDIRECT: { uint8 code; uint16 addr; uint8 page; code = memory_read8 (cpu, cpu_get_pc (cpu)); /* Indirect addressing call has the page specified in the memory location pointed to by the address. */ if ((code & 0xE3) == 0xE3) { addr = cpu_get_indexed_operand_addr (cpu, 0); page = memory_read8 (cpu, addr + 2); addr = memory_read16 (cpu, addr); } else { /* Otherwise, page is in the opcode. */ addr = cpu_get_indexed_operand16 (cpu, 0); page = cpu_fetch8 (cpu); } cpu_m68hc12_push_uint16 (cpu, cpu_get_pc (cpu)); cpu_m68hc12_push_uint8 (cpu, cpu_get_page (cpu)); cpu_set_page (cpu, page); cpu_set_pc (cpu, addr); } break; case M6812_RTC: { uint8 page = cpu_m68hc12_pop_uint8 (cpu); uint16 addr = cpu_m68hc12_pop_uint16 (cpu); cpu_set_page (cpu, page); cpu_set_pc (cpu, addr); } break; case M6812_ETBL: default: sim_engine_halt (CPU_STATE (cpu), cpu, NULL, cpu_get_pc (cpu), sim_stopped, SIM_SIGILL); break; } } void cpu_single_step (sim_cpu *cpu) { cpu->cpu_current_cycle = 0; cpu->cpu_insn_pc = cpu_get_pc (cpu); /* Handle the pending interrupts. If an interrupt is handled, treat this as an single step. */ if (interrupts_process (&cpu->cpu_interrupts)) { cpu->cpu_absolute_cycle += cpu->cpu_current_cycle; return; } /* printf("PC = 0x%04x\n", cpu_get_pc (cpu));*/ cpu->cpu_interpretor (cpu); cpu->cpu_absolute_cycle += cpu->cpu_current_cycle; } /* VARARGS */ void sim_memory_error (sim_cpu *cpu, SIM_SIGNAL excep, uint16 addr, const char *message, ...) { char buf[1024]; va_list args; va_start (args, message); vsprintf (buf, message, args); va_end (args); sim_io_printf (CPU_STATE (cpu), "%s\n", buf); cpu_memory_exception (cpu, excep, addr, buf); } void cpu_memory_exception (sim_cpu *cpu, SIM_SIGNAL excep, uint16 addr, const char *message) { if (cpu->cpu_running == 0) return; cpu_set_pc (cpu, cpu->cpu_insn_pc); sim_engine_halt (CPU_STATE (cpu), cpu, NULL, cpu_get_pc (cpu), sim_stopped, excep); #if 0 cpu->mem_exception = excep; cpu->fault_addr = addr; cpu->fault_msg = strdup (message); if (cpu->cpu_use_handler) { longjmp (&cpu->cpu_exception_handler, 1); } (* cpu->callback->printf_filtered) (cpu->callback, "Fault at 0x%04x: %s\n", addr, message); #endif } void cpu_info (SIM_DESC sd, sim_cpu *cpu) { sim_io_printf (sd, "CPU info:\n"); sim_io_printf (sd, " Absolute cycle: %s\n", cycle_to_string (cpu, cpu->cpu_absolute_cycle, PRINT_TIME | PRINT_CYCLE)); sim_io_printf (sd, " Syscall emulation: %s\n", cpu->cpu_emul_syscall ? "yes, via 0xcd <n>" : "no"); sim_io_printf (sd, " Memory errors detection: %s\n", cpu->cpu_check_memory ? "yes" : "no"); sim_io_printf (sd, " Stop on interrupt: %s\n", cpu->cpu_stop_on_interrupt ? "yes" : "no"); }
Go to most recent revision | Compare with Previous | Blame | View Log