/* Capstone Disassembler Engine */
/* By Sebastian Macke <sebastian@macke.de>, 2018 */
#include <stdio.h>
#include <stdlib.h>
#include <capstone/platform.h>
#include <capstone/capstone.h>
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");
}
static const char *get_am_name(mos65xx_address_mode mode)
{
switch(mode) {
default:
case MOS65XX_AM_NONE:
return "No address mode";
case MOS65XX_AM_IMP:
return "implied addressing (no addressing mode)";
case MOS65XX_AM_ACC:
return "accumulator addressing";
case MOS65XX_AM_ABS:
return "absolute addressing";
case MOS65XX_AM_ZP:
return "zeropage addressing";
case MOS65XX_AM_IMM:
return "8 Bit immediate value";
case MOS65XX_AM_ABSX:
return "indexed absolute addressing by the X index register";
case MOS65XX_AM_ABSY:
return "indexed absolute addressing by the Y index register";
case MOS65XX_AM_INDX:
return "indexed indirect addressing by the X index register";
case MOS65XX_AM_INDY:
return "indirect indexed addressing by the Y index register";
case MOS65XX_AM_ZPX:
return "indexed zeropage addressing by the X index register";
case MOS65XX_AM_ZPY:
return "indexed zeropage addressing by the Y index register";
case MOS65XX_AM_REL:
return "relative addressing used by branches";
case MOS65XX_AM_IND:
return "absolute indirect addressing";
}
}
static void print_insn_detail(cs_insn *ins)
{
cs_mos65xx *mos65xx;
int i;
// detail can be NULL on "data" instruction if SKIPDATA option is turned ON
if (ins->detail == NULL)
return;
mos65xx = &(ins->detail->mos65xx);
// printf("insn_detail\n");
printf("\taddress mode: %s\n", get_am_name(mos65xx->am));
printf("\tmodifies flags: %s\n", mos65xx->modifies_flags ? "true": "false");
if (mos65xx->op_count)
printf("\top_count: %u\n", mos65xx->op_count);
for (i = 0; i < mos65xx->op_count; i++) {
cs_mos65xx_op *op = &(mos65xx->operands[i]);
switch((int)op->type) {
default:
break;
case MOS65XX_OP_REG:
printf("\t\toperands[%u].type: REG = %s\n", i, cs_reg_name(handle, op->reg));
break;
case MOS65XX_OP_IMM:
printf("\t\toperands[%u].type: IMM = 0x%x\n", i, op->imm);
break;
case MOS65XX_OP_MEM:
printf("\t\toperands[%u].type: MEM = 0x%x\n", i, op->mem);
break;
}
}
}
static void test()
{
#define MOS65XX_CODE "\x0d\x34\x12\x00\x81\x87\x6c\x01\x00\x85\xFF\x10\x00\x19\x42\x42\x00\x49\x42"
struct platform platforms[] = {
{
CS_ARCH_MOS65XX,
0,
(unsigned char *)MOS65XX_CODE,
sizeof(MOS65XX_CODE) - 1,
"MOS65XX"
},
};
uint64_t address = 0x1000;
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++) {
printf("0x%" PRIx64 ":\t%s\t%s\n", insn[j].address, insn[j].mnemonic, insn[j].op_str);
print_insn_detail(&insn[j]);
puts("");
}
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;
}