#include #include #include #include #include #include #include #include #include "sim.h" #include "m68k.h" void disassemble_program(); #define ADDRESS_MASK 0xffffffff #define RAM_BASE 0x08000000 #define RAM_TOP 0x08100000 #define BRK_TOP (RAM_TOP - 0x1000) #define INIT_SP RAM_TOP #define INIT_PC 0x08000054 /* Read/write macros */ #define READ_BYTE(BASE, ADDR) (BASE)[ADDR] #define READ_WORD(BASE, ADDR) (((BASE)[ADDR]<<8) | \ (BASE)[(ADDR)+1]) #define READ_LONG(BASE, ADDR) (((BASE)[ADDR]<<24) | \ ((BASE)[(ADDR)+1]<<16) | \ ((BASE)[(ADDR)+2]<<8) | \ (BASE)[(ADDR)+3]) #define WRITE_BYTE(BASE, ADDR, VAL) (BASE)[ADDR] = (VAL)&0xff #define WRITE_WORD(BASE, ADDR, VAL) (BASE)[ADDR] = ((VAL)>>8) & 0xff; \ (BASE)[(ADDR)+1] = (VAL)&0xff #define WRITE_LONG(BASE, ADDR, VAL) (BASE)[ADDR] = ((VAL)>>24) & 0xff; \ (BASE)[(ADDR)+1] = ((VAL)>>16)&0xff; \ (BASE)[(ADDR)+2] = ((VAL)>>8)&0xff; \ (BASE)[(ADDR)+3] = (VAL)&0xff static void exit_error(char* fmt, ...); static void emulated_syscall(void); uint32_t cpu_read_byte(uint32_t address); uint32_t cpu_read_word(uint32_t address); uint32_t cpu_read_long(uint32_t address); void cpu_write_byte(uint32_t address, uint32_t value); void cpu_write_word(uint32_t address, uint32_t value); void cpu_write_long(uint32_t address, uint32_t value); unsigned char g_ram[RAM_TOP - RAM_BASE]; uint32_t brkbase = RAM_BASE; uint32_t brkpos = RAM_BASE; uint32_t entrypoint = RAM_BASE; /* Exit with an error message. Use printf syntax. */ void exit_error(char* fmt, ...) { static int guard_val = 0; char buff[100]; uint32_t pc; va_list args; if(guard_val) return; else guard_val = 1; va_start(args, fmt); vfprintf(stderr, fmt, args); va_end(args); fprintf(stderr, "\n"); pc = m68k_get_reg(NULL, M68K_REG_PPC); m68k_disassemble(buff, pc, M68K_CPU_TYPE_68020); fprintf(stderr, "At %04x: %s\n", pc, buff); exit(EXIT_FAILURE); } static inline uint32_t transform_address(uint32_t address) { uint32_t i = (address & ADDRESS_MASK) - RAM_BASE; if (i >= (uint32_t)(RAM_TOP - RAM_BASE)) exit_error("Attempted to read from RAM address %08x", address); return i; } uint32_t cpu_read_long(uint32_t address) { switch (address) { case 0x00: return INIT_SP; case 0x04: return entrypoint; case 0x80: emulated_syscall(); return 0x10000; case 0x10000: return 0x4e734e73; /* rte; rte */ case 0x10004: return 0; default: { uint32_t value = READ_LONG(g_ram, transform_address(address)); #if 0 printf("read %08x from %08x\n", value, address); #endif return value; } } } uint32_t cpu_read_word(uint32_t address) { uint32_t l = cpu_read_long(address & ~3); l >>= 16 - (address & 2)*8; return l & 0xffff; } uint32_t cpu_read_byte(uint32_t address) { uint32_t l = cpu_read_long(address & ~3); l >>= 24 - (address & 3)*8; return l & 0xff; } uint32_t cpu_read_word_dasm(uint32_t address) { return cpu_read_word(address); } uint32_t cpu_read_long_dasm(uint32_t address) { return cpu_read_long(address); } /* Write data to RAM or a device */ void cpu_write_byte(uint32_t address, uint32_t value) { WRITE_BYTE(g_ram, transform_address(address), value); } void cpu_write_word(uint32_t address, uint32_t value) { WRITE_WORD(g_ram, transform_address(address), value); } void cpu_write_long(uint32_t address, uint32_t value) { WRITE_LONG(g_ram, transform_address(address), value); } /* Disassembler */ void make_hex(char* buff, uint32_t pc, uint32_t length) { char* ptr = buff; for(;length>0;length -= 2) { sprintf(ptr, "%04x", cpu_read_word_dasm(pc)); pc += 2; ptr += 4; if(length > 2) *ptr++ = ' '; } } void disassemble_program() { uint32_t pc; uint32_t instr_size; char buff[100]; char buff2[100]; pc = cpu_read_long_dasm(4); while(pc <= 0x16e) { instr_size = m68k_disassemble(buff, pc, M68K_CPU_TYPE_68000); make_hex(buff2, pc, instr_size); printf("%03x: %-20s: %s\n", pc, buff2, buff); pc += instr_size; } fflush(stdout); } void cpu_instr_callback() { uint32_t pc = m68k_get_reg(NULL, M68K_REG_PC); if (pc == 0xc) exit_error("address exception"); /* The following code would print out instructions as they are executed */ #if 0 static char buff[100]; static char buff2[100]; static uint32_t instr_size; instr_size = m68k_disassemble(buff, pc, M68K_CPU_TYPE_68020); make_hex(buff2, pc, instr_size); printf("E %03x: %-20s: %s\n", pc, buff2, buff); printf(" d0: %08x d1: %08x d2: %08x d3: %08x d4: %08x d5: %08x d6: %08x d7: %08x\n", m68k_get_reg(NULL, M68K_REG_D0), m68k_get_reg(NULL, M68K_REG_D1), m68k_get_reg(NULL, M68K_REG_D2), m68k_get_reg(NULL, M68K_REG_D3), m68k_get_reg(NULL, M68K_REG_D4), m68k_get_reg(NULL, M68K_REG_D5), m68k_get_reg(NULL, M68K_REG_D6), m68k_get_reg(NULL, M68K_REG_D7)); printf(" a0: %08x a1: %08x a2: %08x a3: %08x a4: %08x a5: %08x a6: %08x a7: %08x\n", m68k_get_reg(NULL, M68K_REG_A0), m68k_get_reg(NULL, M68K_REG_A1), m68k_get_reg(NULL, M68K_REG_A2), m68k_get_reg(NULL, M68K_REG_A3), m68k_get_reg(NULL, M68K_REG_A4), m68k_get_reg(NULL, M68K_REG_A5), m68k_get_reg(NULL, M68K_REG_A6), m68k_get_reg(NULL, M68K_REG_A7)); fflush(stdout); #endif } static void emulated_syscall(void) { int s = m68k_get_reg(NULL, M68K_REG_D0); switch (s) { case 1: /* exit */ exit(m68k_get_reg(NULL, M68K_REG_D1)); case 4: /* write */ { uint32_t fd = m68k_get_reg(NULL, M68K_REG_D1); uint32_t ptr = m68k_get_reg(NULL, M68K_REG_D2); uint32_t len = m68k_get_reg(NULL, M68K_REG_D3); m68k_set_reg(M68K_REG_D0, write(fd, g_ram + transform_address(ptr), len)); break; } case 45: /* brk */ { uint32_t newpos = m68k_get_reg(NULL, M68K_REG_D1); if (newpos == 0) m68k_set_reg(M68K_REG_D0, brkpos); else if ((newpos < brkbase) || (newpos >= BRK_TOP)) m68k_set_reg(M68K_REG_D0, -ENOMEM); else { brkpos = newpos; m68k_set_reg(M68K_REG_D0, 0); } break; } case 20: /* getpid */ case 48: /* signal */ case 54: /* ioctl */ case 78: /* gettimeofday */ m68k_set_reg(M68K_REG_D0, 0); break; default: exit_error("unknown system call %d", s); } } static void load_program(FILE* fd) { fseek(fd, 0, SEEK_SET); if (fread(g_ram, 1, 0x34, fd) != 0x34) exit_error("couldn't read ELF header"); uint32_t phoff = READ_LONG(g_ram, 0x1c); uint16_t phentsize = READ_WORD(g_ram, 0x2a); uint16_t phnum = READ_WORD(g_ram, 0x2c); entrypoint = READ_LONG(g_ram, 0x18); if ((phentsize != 0x20) || (phnum != 1)) exit_error("unsupported ELF file"); fseek(fd, phoff, SEEK_SET); if (fread(g_ram, 1, phentsize, fd) != phentsize) exit_error("couldn't read program header"); uint32_t offset = READ_LONG(g_ram, 0x04); uint32_t vaddr = READ_LONG(g_ram, 0x08); uint32_t filesz = READ_LONG(g_ram, 0x10); uint32_t memsz = READ_LONG(g_ram, 0x14); brkbase = brkpos = vaddr + memsz; uint32_t vaddroffset = transform_address(vaddr); transform_address(vaddr + memsz); /* bounds check */ memset(g_ram+vaddroffset, 0, memsz); fseek(fd, offset, SEEK_SET); if (fread(g_ram+vaddroffset, 1, filesz, fd) != filesz) exit_error("couldn't read program data"); } /* The main loop */ int main(int argc, char* argv[]) { FILE* fhandle; if(argc != 2) { printf("Usage: sim \n"); exit(-1); } if((fhandle = fopen(argv[1], "rb")) == NULL) exit_error("Unable to open %s", argv[1]); load_program(fhandle); // disassemble_program(); m68k_set_cpu_type(M68K_CPU_TYPE_68020); m68k_init(); m68k_pulse_reset(); /* On entry, the Linux stack looks like this. * * sp+.. NULL * sp+8+(4*argc) env (X quads) * sp+4+(4*argc) NULL * sp+4 argv (argc quads) * sp argc * * We'll set it up with a bodgy stack frame with argc=0 just to keep the * startup code happy. */ { uint32_t sp = INIT_SP; cpu_write_long(sp -= 4, 0); uint32_t envp = sp; cpu_write_long(sp -= 4, envp); cpu_write_long(sp -= 4, 0); unsigned long argv = sp; cpu_write_long(sp -= 4, argv); cpu_write_long(sp -= 4, 0); m68k_set_reg(M68K_REG_SP, sp); } for (;;) m68k_execute(100000); return 0; }