#!/usr/bin/env python # Capstone Python bindings, by Nguyen Anh Quynnh from __future__ import print_function from capstone import * from capstone.x86 import * from xprint import to_hex, to_x, to_x_32 X86_CODE64 = b"\x55\x48\x8b\x05\xb8\x13\x00\x00\xe9\xea\xbe\xad\xde\xff\x25\x23\x01\x00\x00\xe8\xdf\xbe\xad\xde\x74\xff" X86_CODE16 = b"\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6\x66\xe9\xb8\x00\x00\x00\x67\xff\xa0\x23\x01\x00\x00\x66\xe8\xcb\x00\x00\x00\x74\xfc" X86_CODE32 = b"\x8d\x4c\x32\x08\x01\xd8\x81\xc6\x34\x12\x00\x00\x05\x23\x01\x00\x00\x36\x8b\x84\x91\x23\x01\x00\x00\x41\x8d\x84\x39\x89\x67\x00\x00\x8d\x87\x89\x67\x00\x00\xb4\xc6\xe9\xea\xbe\xad\xde\xff\xa0\x23\x01\x00\x00\xe8\xdf\xbe\xad\xde\x74\xff" all_tests = ( (CS_ARCH_X86, CS_MODE_16, X86_CODE16, "X86 16bit (Intel syntax)", None), (CS_ARCH_X86, CS_MODE_32, X86_CODE32, "X86 32 (AT&T syntax)", CS_OPT_SYNTAX_ATT), (CS_ARCH_X86, CS_MODE_32, X86_CODE32, "X86 32 (Intel syntax)", None), (CS_ARCH_X86, CS_MODE_64, X86_CODE64, "X86 64 (Intel syntax)", None), ) def get_eflag_name(eflag): if eflag == X86_EFLAGS_UNDEFINED_OF: return "UNDEF_OF" elif eflag == X86_EFLAGS_UNDEFINED_SF: return "UNDEF_SF" elif eflag == X86_EFLAGS_UNDEFINED_ZF: return "UNDEF_ZF" elif eflag == X86_EFLAGS_MODIFY_AF: return "MOD_AF" elif eflag == X86_EFLAGS_UNDEFINED_PF: return "UNDEF_PF" elif eflag == X86_EFLAGS_MODIFY_CF: return "MOD_CF" elif eflag == X86_EFLAGS_MODIFY_SF: return "MOD_SF" elif eflag == X86_EFLAGS_MODIFY_ZF: return "MOD_ZF" elif eflag == X86_EFLAGS_UNDEFINED_AF: return "UNDEF_AF" elif eflag == X86_EFLAGS_MODIFY_PF: return "MOD_PF" elif eflag == X86_EFLAGS_UNDEFINED_CF: return "UNDEF_CF" elif eflag == X86_EFLAGS_MODIFY_OF: return "MOD_OF" elif eflag == X86_EFLAGS_RESET_OF: return "RESET_OF" elif eflag == X86_EFLAGS_RESET_CF: return "RESET_CF" elif eflag == X86_EFLAGS_RESET_DF: return "RESET_DF" elif eflag == X86_EFLAGS_RESET_IF: return "RESET_IF" elif eflag == X86_EFLAGS_TEST_OF: return "TEST_OF" elif eflag == X86_EFLAGS_TEST_SF: return "TEST_SF" elif eflag == X86_EFLAGS_TEST_ZF: return "TEST_ZF" elif eflag == X86_EFLAGS_TEST_PF: return "TEST_PF" elif eflag == X86_EFLAGS_TEST_CF: return "TEST_CF" elif eflag == X86_EFLAGS_RESET_SF: return "RESET_SF" elif eflag == X86_EFLAGS_RESET_AF: return "RESET_AF" elif eflag == X86_EFLAGS_RESET_TF: return "RESET_TF" elif eflag == X86_EFLAGS_RESET_NT: return "RESET_NT" elif eflag == X86_EFLAGS_PRIOR_OF: return "PRIOR_OF" elif eflag == X86_EFLAGS_PRIOR_SF: return "PRIOR_SF" elif eflag == X86_EFLAGS_PRIOR_ZF: return "PRIOR_ZF" elif eflag == X86_EFLAGS_PRIOR_AF: return "PRIOR_AF" elif eflag == X86_EFLAGS_PRIOR_PF: return "PRIOR_PF" elif eflag == X86_EFLAGS_PRIOR_CF: return "PRIOR_CF" elif eflag == X86_EFLAGS_PRIOR_TF: return "PRIOR_TF" elif eflag == X86_EFLAGS_PRIOR_IF: return "PRIOR_IF" elif eflag == X86_EFLAGS_PRIOR_DF: return "PRIOR_DF" elif eflag == X86_EFLAGS_TEST_NT: return "TEST_NT" elif eflag == X86_EFLAGS_TEST_DF: return "TEST_DF" elif eflag == X86_EFLAGS_RESET_PF: return "RESET_PF" elif eflag == X86_EFLAGS_PRIOR_NT: return "PRIOR_NT" elif eflag == X86_EFLAGS_MODIFY_TF: return "MOD_TF" elif eflag == X86_EFLAGS_MODIFY_IF: return "MOD_IF" elif eflag == X86_EFLAGS_MODIFY_DF: return "MOD_DF" elif eflag == X86_EFLAGS_MODIFY_NT: return "MOD_NT" elif eflag == X86_EFLAGS_MODIFY_RF: return "MOD_RF" elif eflag == X86_EFLAGS_SET_CF: return "SET_CF" elif eflag == X86_EFLAGS_SET_DF: return "SET_DF" elif eflag == X86_EFLAGS_SET_IF: return "SET_IF" else: return None def print_insn_detail(mode, insn): def print_string_hex(comment, str): print(comment, end=' '), for c in str: print("0x%02x " % c, end=''), print() # print address, mnemonic and operands print("0x%x:\t%s\t%s" % (insn.address, insn.mnemonic, insn.op_str)) # "data" instruction generated by SKIPDATA option has no detail if insn.id == 0: return # print instruction prefix print_string_hex("\tPrefix:", insn.prefix) # print instruction's opcode print_string_hex("\tOpcode:", insn.opcode) # print operand's REX prefix (non-zero value is relavant for x86_64 instructions) print("\trex: 0x%x" % (insn.rex)) # print operand's address size print("\taddr_size: %u" % (insn.addr_size)) # print modRM byte print("\tmodrm: 0x%x" % (insn.modrm)) # print modRM offset if insn.modrm_offset != 0: print("\tmodrm_offset: 0x%x" % (insn.modrm_offset)) # print displacement value print("\tdisp: 0x%s" % to_x_32(insn.disp)) # print displacement offset (offset into instruction bytes) if insn.disp_offset != 0: print("\tdisp_offset: 0x%x" % (insn.disp_offset)) # print displacement size if insn.disp_size != 0: print("\tdisp_size: 0x%x" % (insn.disp_size)) # SIB is not available in 16-bit mode if (mode & CS_MODE_16 == 0): # print SIB byte print("\tsib: 0x%x" % (insn.sib)) if (insn.sib): if insn.sib_base != 0: print("\t\tsib_base: %s" % (insn.reg_name(insn.sib_base))) if insn.sib_index != 0: print("\t\tsib_index: %s" % (insn.reg_name(insn.sib_index))) if insn.sib_scale != 0: print("\t\tsib_scale: %d" % (insn.sib_scale)) # XOP CC type if insn.xop_cc != X86_XOP_CC_INVALID: print("\txop_cc: %u" % (insn.xop_cc)) # SSE CC type if insn.sse_cc != X86_SSE_CC_INVALID: print("\tsse_cc: %u" % (insn.sse_cc)) # AVX CC type if insn.avx_cc != X86_AVX_CC_INVALID: print("\tavx_cc: %u" % (insn.avx_cc)) # AVX Suppress All Exception if insn.avx_sae: print("\tavx_sae: TRUE") # AVX Rounding Mode type if insn.avx_rm != X86_AVX_RM_INVALID: print("\tavx_rm: %u" % (insn.avx_rm)) count = insn.op_count(X86_OP_IMM) if count > 0: print("\timm_count: %u" % count) for i in range(count): op = insn.op_find(X86_OP_IMM, i + 1) print("\t\timms[%u]: 0x%s" % (i + 1, to_x(op.imm))) if insn.imm_offset != 0: print("\timm_offset: 0x%x" % (insn.imm_offset)) if insn.imm_size != 0: print("\timm_size: 0x%x" % (insn.imm_size)) if len(insn.operands) > 0: print("\top_count: %u" % len(insn.operands)) c = -1 for i in insn.operands: c += 1 if i.type == X86_OP_REG: print("\t\toperands[%u].type: REG = %s" % (c, insn.reg_name(i.reg))) if i.type == X86_OP_IMM: print("\t\toperands[%u].type: IMM = 0x%s" % (c, to_x(i.imm))) if i.type == X86_OP_MEM: print("\t\toperands[%u].type: MEM" % c) if i.mem.segment != 0: print("\t\t\toperands[%u].mem.segment: REG = %s" % (c, insn.reg_name(i.mem.segment))) if i.mem.base != 0: print("\t\t\toperands[%u].mem.base: REG = %s" % (c, insn.reg_name(i.mem.base))) if i.mem.index != 0: print("\t\t\toperands[%u].mem.index: REG = %s" % (c, insn.reg_name(i.mem.index))) if i.mem.scale != 1: print("\t\t\toperands[%u].mem.scale: %u" % (c, i.mem.scale)) if i.mem.disp != 0: print("\t\t\toperands[%u].mem.disp: 0x%s" % (c, to_x(i.mem.disp))) # AVX broadcast type if i.avx_bcast != X86_AVX_BCAST_INVALID: print("\t\toperands[%u].avx_bcast: %u" % (c, i.avx_bcast)) # AVX zero opmask {z} if i.avx_zero_opmask: print("\t\toperands[%u].avx_zero_opmask: TRUE" % (c)) print("\t\toperands[%u].size: %u" % (c, i.size)) if i.access == CS_AC_READ: print("\t\toperands[%u].access: READ\n" % (c)) elif i.access == CS_AC_WRITE: print("\t\toperands[%u].access: WRITE\n" % (c)) elif i.access == CS_AC_READ | CS_AC_WRITE: print("\t\toperands[%u].access: READ | WRITE\n" % (c)) (regs_read, regs_write) = insn.regs_access() if len(regs_read) > 0: print("\tRegisters read:", end="") for r in regs_read: print(" %s" %(insn.reg_name(r)), end="") print("") if len(regs_write) > 0: print("\tRegisters modified:", end="") for r in regs_write: print(" %s" %(insn.reg_name(r)), end="") print("") if insn.eflags: updated_flags = [] for i in range(0,46): if insn.eflags & (1 << i): updated_flags.append(get_eflag_name(1 << i)) print("\tEFLAGS: %s" % (','.join(p for p in updated_flags))) # ## Test class Cs def test_class(): for (arch, mode, code, comment, syntax) in all_tests: print("*" * 16) print("Platform: %s" % comment) print("Code: %s" % to_hex(code)) print("Disasm:") try: md = Cs(arch, mode) md.detail = True if syntax is not None: md.syntax = syntax for insn in md.disasm(code, 0x1000): print_insn_detail(mode, insn) print () print ("0x%x:\n" % (insn.address + insn.size)) except CsError as e: print("ERROR: %s" % e) if __name__ == '__main__': test_class()