/* Capstone Disassembler Engine */ /* By Nguyen Anh Quynh , 2013-2014 */ #include #include #include #include struct platform { cs_arch arch; cs_mode mode; unsigned char* code; size_t size; const char* comment; }; static csh handle; static void print_string_hex(const char* comment, unsigned char* str, size_t len) { unsigned char *c; printf("%s", comment); for (c = str; c < str + len; c++) { printf("0x%02x ", *c & 0xff); } printf("\n"); } const char* s_addressing_modes[] = { "", "Register Direct - Data", "Register Direct - Address", "Register Indirect - Address", "Register Indirect - Address with Postincrement", "Register Indirect - Address with Predecrement", "Register Indirect - Address with Displacement", "Address Register Indirect With Index - 8-bit displacement", "Address Register Indirect With Index - Base displacement", "Memory indirect - Postindex", "Memory indirect - Preindex", "Program Counter Indirect - with Displacement", "Program Counter Indirect with Index - with 8-Bit Displacement", "Program Counter Indirect with Index - with Base Displacement", "Program Counter Memory Indirect - Postindexed", "Program Counter Memory Indirect - Preindexed", "Absolute Data Addressing - Short", "Absolute Data Addressing - Long", "Immediate value", }; static void print_read_write_regs(cs_detail* detail) { int i; for (i = 0; i < detail->regs_read_count; ++i) { uint16_t reg_id = detail->regs_read[i]; const char* reg_name = cs_reg_name(handle, reg_id); printf("\treading from reg: %s\n", reg_name); } for (i = 0; i < detail->regs_write_count; ++i) { uint16_t reg_id = detail->regs_write[i]; const char* reg_name = cs_reg_name(handle, reg_id); printf("\twriting to reg: %s\n", reg_name); } } static void print_insn_detail(cs_insn *ins) { cs_m68k* m68k; cs_detail* detail; int i; // detail can be NULL on "data" instruction if SKIPDATA option is turned ON if (ins->detail == NULL) return; detail = ins->detail; m68k = &detail->m68k; if (m68k->op_count) printf("\top_count: %u\n", m68k->op_count); print_read_write_regs(detail); printf("\tgroups_count: %u\n", detail->groups_count); for (i = 0; i < m68k->op_count; i++) { cs_m68k_op* op = &(m68k->operands[i]); switch((int)op->type) { default: break; case M68K_OP_REG: printf("\t\toperands[%u].type: REG = %s\n", i, cs_reg_name(handle, op->reg)); break; case M68K_OP_IMM: printf("\t\toperands[%u].type: IMM = 0x%x\n", i, (int)op->imm); break; case M68K_OP_MEM: printf("\t\toperands[%u].type: MEM\n", i); if (op->mem.base_reg != M68K_REG_INVALID) printf("\t\t\toperands[%u].mem.base: REG = %s\n", i, cs_reg_name(handle, op->mem.base_reg)); if (op->mem.index_reg != M68K_REG_INVALID) { printf("\t\t\toperands[%u].mem.index: REG = %s\n", i, cs_reg_name(handle, op->mem.index_reg)); printf("\t\t\toperands[%u].mem.index: size = %c\n", i, op->mem.index_size ? 'l' : 'w'); } if (op->mem.disp != 0) printf("\t\t\toperands[%u].mem.disp: 0x%x\n", i, op->mem.disp); if (op->mem.scale != 0) printf("\t\t\toperands[%u].mem.scale: %d\n", i, op->mem.scale); printf("\t\taddress mode: %s\n", s_addressing_modes[op->address_mode]); break; case M68K_OP_FP_SINGLE: printf("\t\toperands[%u].type: FP_SINGLE\n", i); printf("\t\t\toperands[%u].simm: %f\n", i, op->simm); break; case M68K_OP_FP_DOUBLE: printf("\t\toperands[%u].type: FP_DOUBLE\n", i); printf("\t\t\toperands[%u].dimm: %lf\n", i, op->dimm); break; case M68K_OP_REG_BITS: printf("\t\toperands[%u].type: REG_BITS = $%x\n", i, op->register_bits); } } printf("\n"); } static void test() { #define M68K_CODE "\xf0\x10\xf0\x00\x48\xaf\xff\xff\x7f\xff\x11\xb0\x01\x37\x7f\xff\xff\xff\x12\x34\x56\x78\x01\x33\x10\x10\x10\x10\x32\x32\x32\x32\x4C\x00\x54\x04\x48\xe7\xe0\x30\x4C\xDF\x0C\x07\xd4\x40\x87\x5a\x4e\x71\x02\xb4\xc0\xde\xc0\xde\x5c\x00\x1d\x80\x71\x12\x01\x23\xf2\x3c\x44\x22\x40\x49\x0e\x56\x54\xc5\xf2\x3c\x44\x00\x44\x7a\x00\x00\xf2\x00\x0a\x28\x4E\xB9\x00\x00\x00\x12\x4E\x75" struct platform platforms[] = { { CS_ARCH_M68K, (cs_mode)(CS_MODE_BIG_ENDIAN | CS_MODE_M68K_040), (unsigned char*)M68K_CODE, sizeof(M68K_CODE) - 1, "M68K", }, }; uint64_t address = 0x01000; cs_insn *insn; int i; size_t count; for (i = 0; i < sizeof(platforms)/sizeof(platforms[0]); i++) { cs_err err = cs_open(platforms[i].arch, platforms[i].mode, &handle); if (err) { printf("Failed on cs_open() with error returned: %u\n", err); abort(); } cs_option(handle, CS_OPT_DETAIL, CS_OPT_ON); count = cs_disasm(handle, platforms[i].code, platforms[i].size, address, 0, &insn); if (count) { size_t j; printf("****************\n"); printf("Platform: %s\n", platforms[i].comment); print_string_hex("Code: ", platforms[i].code, platforms[i].size); printf("Disasm:\n"); for (j = 0; j < count; j++) { assert(address == insn[j].address && "this means the size of the previous instruction was incorrect"); address += insn[j].size; printf("0x%" PRIx64 ":\t%s\t%s\n", insn[j].address, insn[j].mnemonic, insn[j].op_str); print_insn_detail(&insn[j]); } printf("0x%" PRIx64 ":\n", insn[j-1].address + insn[j-1].size); // free memory allocated by cs_disasm() cs_free(insn, count); } else { printf("****************\n"); printf("Platform: %s\n", platforms[i].comment); print_string_hex("Code:", platforms[i].code, platforms[i].size); printf("ERROR: Failed to disasm given code!\n"); abort(); } printf("\n"); cs_close(&handle); } } int main() { test(); return 0; }