/* Capstone Disassembler Engine */ /* By Nguyen Anh Quynh , 2013 */ #include #include #include #include static csh handle; struct platform { cs_arch arch; cs_mode mode; unsigned char *code; size_t size; const char *comment; int syntax; }; 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"); } static void print_insn_detail(csh cs_handle, cs_insn *ins) { cs_arm *arm; int i; cs_regs regs_read, regs_write; uint8_t regs_read_count, regs_write_count; // detail can be NULL on "data" instruction if SKIPDATA option is turned ON if (ins->detail == NULL) return; arm = &(ins->detail->arm); if (arm->op_count) printf("\top_count: %u\n", arm->op_count); for (i = 0; i < arm->op_count; i++) { cs_arm_op *op = &(arm->operands[i]); switch((int)op->type) { default: break; case ARM_OP_REG: printf("\t\toperands[%u].type: REG = %s\n", i, cs_reg_name(cs_handle, op->reg)); break; case ARM_OP_IMM: printf("\t\toperands[%u].type: IMM = 0x%x\n", i, op->imm); break; case ARM_OP_FP: #if defined(_KERNEL_MODE) // Issue #681: Windows kernel does not support formatting float point printf("\t\toperands[%u].type: FP = \n", i); #else printf("\t\toperands[%u].type: FP = %f\n", i, op->fp); #endif break; case ARM_OP_MEM: printf("\t\toperands[%u].type: MEM\n", i); if (op->mem.base != ARM_REG_INVALID) printf("\t\t\toperands[%u].mem.base: REG = %s\n", i, cs_reg_name(cs_handle, op->mem.base)); if (op->mem.index != ARM_REG_INVALID) printf("\t\t\toperands[%u].mem.index: REG = %s\n", i, cs_reg_name(cs_handle, op->mem.index)); if (op->mem.scale != 1) printf("\t\t\toperands[%u].mem.scale: %u\n", i, op->mem.scale); if (op->mem.disp != 0) printf("\t\t\toperands[%u].mem.disp: 0x%x\n", i, op->mem.disp); if (op->mem.lshift != 0) printf("\t\t\toperands[%u].mem.lshift: 0x%x\n", i, op->mem.lshift); break; case ARM_OP_PIMM: printf("\t\toperands[%u].type: P-IMM = %u\n", i, op->imm); break; case ARM_OP_CIMM: printf("\t\toperands[%u].type: C-IMM = %u\n", i, op->imm); break; case ARM_OP_SETEND: printf("\t\toperands[%u].type: SETEND = %s\n", i, op->setend == ARM_SETEND_BE? "be" : "le"); break; case ARM_OP_SYSREG: printf("\t\toperands[%u].type: SYSREG = %u\n", i, op->reg); break; } if (op->neon_lane != -1) { printf("\t\toperands[%u].neon_lane = %u\n", i, op->neon_lane); } switch(op->access) { default: break; case CS_AC_READ: printf("\t\toperands[%u].access: READ\n", i); break; case CS_AC_WRITE: printf("\t\toperands[%u].access: WRITE\n", i); break; case CS_AC_READ | CS_AC_WRITE: printf("\t\toperands[%u].access: READ | WRITE\n", i); break; } if (op->shift.type != ARM_SFT_INVALID && op->shift.value) { if (op->shift.type < ARM_SFT_ASR_REG) // shift with constant value printf("\t\t\tShift: %u = %u\n", op->shift.type, op->shift.value); else // shift with register printf("\t\t\tShift: %u = %s\n", op->shift.type, cs_reg_name(cs_handle, op->shift.value)); } if (op->vector_index != -1) { printf("\t\toperands[%u].vector_index = %u\n", i, op->vector_index); } if (op->subtracted) printf("\t\tSubtracted: True\n"); } if (arm->cc != ARM_CC_AL && arm->cc != ARM_CC_INVALID) printf("\tCode condition: %u\n", arm->cc); if (arm->update_flags) printf("\tUpdate-flags: True\n"); if (arm->writeback) printf("\tWrite-back: True\n"); if (arm->cps_mode) printf("\tCPSI-mode: %u\n", arm->cps_mode); if (arm->cps_flag) printf("\tCPSI-flag: %u\n", arm->cps_flag); if (arm->vector_data) printf("\tVector-data: %u\n", arm->vector_data); if (arm->vector_size) printf("\tVector-size: %u\n", arm->vector_size); if (arm->usermode) printf("\tUser-mode: True\n"); if (arm->mem_barrier) printf("\tMemory-barrier: %u\n", arm->mem_barrier); // Print out all registers accessed by this instruction (either implicit or explicit) if (!cs_regs_access(cs_handle, ins, regs_read, ®s_read_count, regs_write, ®s_write_count)) { if (regs_read_count) { printf("\tRegisters read:"); for(i = 0; i < regs_read_count; i++) { printf(" %s", cs_reg_name(cs_handle, regs_read[i])); } printf("\n"); } if (regs_write_count) { printf("\tRegisters modified:"); for(i = 0; i < regs_write_count; i++) { printf(" %s", cs_reg_name(cs_handle, regs_write[i])); } printf("\n"); } } printf("\n"); } static void test() { //#define ARM_CODE "\x04\xe0\x2d\xe5" // str lr, [sp, #-0x4]! //#define ARM_CODE "\xe0\x83\x22\xe5" // str r8, [r2, #-0x3e0]! //#define ARM_CODE "\xf1\x02\x03\x0e" // mcreq p0x2, #0x0, r0, c0x3, c0x1, #0x7 //#define ARM_CODE "\x00\x00\xa0\xe3" // mov r0, #0x0 //#define ARM_CODE "\x02\x30\xc1\xe7" // strb r3, [r1, r2] //#define ARM_CODE "\x00\x00\x53\xe3" // cmp r3, #0x0 //#define ARM_CODE "\x02\x00\xa1\xe2" // adc r0, r1, r2 //#define ARM_CODE "\x21\x01\xa0\xe0" // adc r0, r0, r1, lsr #2 //#define ARM_CODE "\x21\x01\xb0\xe0" // adcs r0, r0, r1, lsr #2 //#define ARM_CODE "\x32\x03\xa1\xe0" // adc r0, r1, r2, lsr r3 //#define ARM_CODE "\x22\x01\xa1\xe0" // adc r0, r1, r2, lsr #2 //#define ARM_CODE "\x65\x61\x4f\x50" // subpl r6, pc, r5, ror #2 //#define ARM_CODE "\x30\x30\x53\xe5" // ldrb r3, [r3, #-0x30] //#define ARM_CODE "\xb6\x10\xdf\xe1" // ldrh r1, [pc, #0x6] //#define ARM_CODE "\x02\x00\x9f\xef" // svc #0x9f0002 //#define ARM_CODE "\x00\xc0\x27\xea" // b 0x9F0002: FIXME: disasm as "b #0x9f0000" //#define ARM_CODE "\x12\x13\xa0\xe1" // lsl r1, r2, r3 //#define ARM_CODE "\x82\x11\xa0\xe1" // lsl r1, r2, #0x3 //#define ARM_CODE "\x00\xc0\xa0\xe1" // mov ip, r0 //#define ARM_CODE "\x02\x00\x12\xe3" // tst r2, #2 //#define ARM_CODE "\x51\x12\xa0\xe1" // asr r1, r2 //#define ARM_CODE "\x72\x10\xef\xe6" // uxtb r1, r2 //#define ARM_CODE "\xe0\x0a\xb7\xee" // vcvt.f64.f32 d0, s1 //#define ARM_CODE "\x9f\x0f\x91\xe1" // ldrex r0, [r1] //#define ARM_CODE "\x0f\x06\x20\xf4" // vld1.8 {d0, d1, d2}, [r0] //#define ARM_CODE "\x72\x00\xa1\xe6" // sxtab r0, r1, r2 //#define ARM_CODE "\x50\x06\x84\xf2" // vmov.i32 q0, #0x40000000 //#define ARM_CODE "\x73\xe0\xb8\xee" // mrc p0, #5, lr, c8, c3, #3 //#define ARM_CODE "\x12\x02\x81\xe6" // pkhbt r0, r1, r2, lsl #0x4 //#define ARM_CODE "\x12\x00\xa0\xe6" // ssat r0, #0x1, r2 //#define ARM_CODE "\x03\x60\x2d\xe9" // push {r0, r1, sp, lr} //#define ARM_CODE "\x8f\x40\x60\xf4" // vld4.32 {d20, d21, d22, d23}, [r0] //#define ARM_CODE "\xd0\x00\xc2\xe1" // ldrd r0, r1, [r2] //#define ARM_CODE "\x08\xf0\xd0\xf5" // pld [r0, #0x8] //#define ARM_CODE "\x10\x8b\xbc\xec" // ldc p11, c8, [r12], #64 //#define ARM_CODE "\xd4\x30\xd2\xe1" // ldrsb r3, [r2, #0x4] //#define ARM_CODE "\x11\x0f\xbe\xf2" // vcvt.s32.f32 d0, d1, #2 //#define ARM_CODE "\x01\x01\x70\xe1" // cmn r0, r1, lsl #2 //#define ARM_CODE "\x06\x00\x91\xe2" // adds r0, r1, #6 //#define ARM_CODE "\x5b\xf0\x7f\xf5" // dmb ish //#define ARM_CODE "\xf7\xff\xff\xfe" //#define ARM_CODE "\x00\x20\xbd\xe8" // ldm sp!, {sp} //#define ARM_CODE "\x00\xa0\xbd\xe8" // pop {sp, pc} //#define ARM_CODE "\x90\x04\x0E\x00" // muleq lr, r0, r4 //#define ARM_CODE "\x90\x24\x0E\x00" // muleq lr, r0, r4 //#define ARM_CODE "\xb6\x10\x5f\xe1" // ldrh r1, [pc, #-6] #define ARM_CODE "\x86\x48\x60\xf4\x4d\x0f\xe2\xf4\xED\xFF\xFF\xEB\x04\xe0\x2d\xe5\x00\x00\x00\x00\xe0\x83\x22\xe5\xf1\x02\x03\x0e\x00\x00\xa0\xe3\x02\x30\xc1\xe7\x00\x00\x53\xe3\x00\x02\x01\xf1\x05\x40\xd0\xe8\xf4\x80\x00\x00" //#define ARM_CODE "\x86\x48\x60\xf4" //#define ARM_CODE2 "\xf0\x24" //#define ARM_CODE2 "\x83\xb0" #define ARM_CODE2 "\xd1\xe8\x00\xf0\xf0\x24\x04\x07\x1f\x3c\xf2\xc0\x00\x00\x4f\xf0\x00\x01\x46\x6c" //#define THUMB_CODE "\x70\x47" // bl 0x26 //#define THUMB_CODE "\x07\xdd" // ble 0x1c //#define THUMB_CODE "\x00\x47" // bx r0 //#define THUMB_CODE "\x01\x47" // bx r0 //#define THUMB_CODE "\x02\x47" // bx r0 //#define THUMB_CODE "\x0a\xbf" // itet eq #define THUMB_CODE "\x60\xf9\x1f\x04\xe0\xf9\x4f\x07\x70\x47\x00\xf0\x10\xe8\xeb\x46\x83\xb0\xc9\x68\x1f\xb1\x30\xbf\xaf\xf3\x20\x84\x52\xf8\x23\xf0" //#define THUMB_CODE "\xe0\xf9\x4f\x07" #define THUMB_CODE2 "\x4f\xf0\x00\x01\xbd\xe8\x00\x88\xd1\xe8\x00\xf0\x18\xbf\xad\xbf\xf3\xff\x0b\x0c\x86\xf3\x00\x89\x80\xf3\x00\x8c\x4f\xfa\x99\xf6\xd0\xff\xa2\x01" #define THUMB_MCLASS "\xef\xf3\x02\x80" #define ARMV8 "\xe0\x3b\xb2\xee\x42\x00\x01\xe1\x51\xf0\x7f\xf5" struct platform platforms[] = { { CS_ARCH_ARM, CS_MODE_ARM, (unsigned char *)ARM_CODE, sizeof(ARM_CODE) - 1, "ARM" }, { CS_ARCH_ARM, CS_MODE_THUMB, (unsigned char *)THUMB_CODE, sizeof(THUMB_CODE) - 1, "Thumb" }, { CS_ARCH_ARM, CS_MODE_THUMB, (unsigned char *)ARM_CODE2, sizeof(ARM_CODE2) - 1, "Thumb-mixed" }, { CS_ARCH_ARM, CS_MODE_THUMB, (unsigned char *)THUMB_CODE2, sizeof(THUMB_CODE2) - 1, "Thumb-2 & register named with numbers", CS_OPT_SYNTAX_NOREGNAME }, { CS_ARCH_ARM, (cs_mode)(CS_MODE_THUMB + CS_MODE_MCLASS), (unsigned char*)THUMB_MCLASS, sizeof(THUMB_MCLASS) - 1, "Thumb-MClass" }, { CS_ARCH_ARM, (cs_mode)(CS_MODE_ARM + CS_MODE_V8), (unsigned char*)ARMV8, sizeof(ARMV8) - 1, "Arm-V8" }, }; uint64_t address = 0x80001000; 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); if (platforms[i].syntax) cs_option(handle, CS_OPT_SYNTAX, platforms[i].syntax); 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++) { printf("0x%" PRIx64 ":\t%s\t%s\n", insn[j].address, insn[j].mnemonic, insn[j].op_str); print_insn_detail(handle, &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; }