Пример #1
0
/* 
 * decode_moffset
 *    Decode offset-only memory operand
 */
static void
decode_moffset(struct ud *u, unsigned int size, struct ud_operand *opr)
{
  opr->type = UD_OP_MEM;
  opr->size = resolve_operand_size(u, size);
  decode_mem_disp(u, u->adr_mode, opr);
}
Пример #2
0
static void
decode_reg(struct ud *u, 
           struct ud_operand *opr,
           int type,
           int num,
           int size)
{
  int reg;
  size = resolve_operand_size(u, size);
  switch (type) {
    case REGCLASS_GPR : reg = decode_gpr(u, size, num); break;
    case REGCLASS_MMX : reg = UD_R_MM0  + (num & 7); break;
    case REGCLASS_XMM : reg = UD_R_XMM0 + num; break;
    case REGCLASS_CR : reg = UD_R_CR0  + num; break;
    case REGCLASS_DB : reg = UD_R_DR0  + num; break;
    case REGCLASS_SEG : {
      /*
       * Only 6 segment registers, anything else is an error.
       */
      if ((num & 7) > 5) {
        UDERR(u, "invalid segment register value\n");
        return;
      } else {
        reg = UD_R_ES + (num & 7);
      }
      break;
    }
    default:
      UD_ASSERT(!"invalid register type");
      return;
  }
  opr->type = UD_OP_REG;
  opr->base = reg;
  opr->size = size;
}
Пример #3
0
/* -----------------------------------------------------------------------------
 * decode_imm() - Decodes Immediate values.
 * -----------------------------------------------------------------------------
 */
static void 
decode_imm(struct ud* u, unsigned int s, struct ud_operand *op)
{
  op->size = (uint8_t) resolve_operand_size(u, s);
  op->type = UD_OP_IMM;

  switch (op->size) {
    case  8: op->lval.sbyte = inp_uint8(u);   break;
    case 16: op->lval.uword = inp_uint16(u);  break;
    case 32: op->lval.udword = inp_uint32(u); break;
    default: return;
  }
}
Пример #4
0
/*
 * decode_modrm_reg
 *
 *    Decodes reg field of mod/rm byte
 * 
 */
static void
decode_modrm_reg(struct ud         *u, 
                 struct ud_operand *operand,
                 unsigned int       type,
                 unsigned int       size)
{
  uint8_t reg = (REX_R(u->pfx_rex) << 3) | MODRM_REG(modrm(u));
  operand->type = UD_OP_REG;
  operand->size = resolve_operand_size(u, size);

  if (type == T_GPR) {
    operand->base = decode_gpr(u, operand->size, reg);
  } else {
    operand->base = resolve_reg(u, type, reg);
  }
}
Пример #5
0
/* -----------------------------------------------------------------------------
 * decode_o() - Decodes offset
 * -----------------------------------------------------------------------------
 */
static void 
decode_o(struct ud* u, unsigned int s, struct ud_operand *op)
{
  switch (u->adr_mode) {
    case 32:
        op->offset = 32; 
        op->lval.udword = inp_uint32(u); 
        break;
    case 16:
        op->offset = 16; 
        op->lval.uword  = inp_uint16(u); 
        break;
    default:
        return;
  }
  op->type = UD_OP_MEM;
  op->size = (uint8_t)resolve_operand_size(u, s);
}
Пример #6
0
/* -----------------------------------------------------------------------------
 * decode_gpr() - Returns decoded General Purpose Register 
 * -----------------------------------------------------------------------------
 */
static enum ud_type 
decode_gpr(register struct ud* u, unsigned int s, unsigned char rm)
{
  s = resolve_operand_size(u, s);
        
  switch (s) {
    case SZ_DP:
    case 32:
        return UD_R_EAX + rm;
    case SZ_WP:
    case 16:
        return UD_R_AX  + rm;
    case  8:
        if (u->dis_mode == 64 && u->pfx_rex) {
            if (rm >= 4)
                return UD_R_SPL + (rm-4);
            return UD_R_AL + rm;
        } else return UD_R_AL + rm;
    default:
        return 0;
  }
}
Пример #7
0
/*
 * decode_modrm_rm
 *
 *    Decodes rm field of mod/rm byte
 * 
 */
static void 
decode_modrm_rm(struct ud         *u, 
                struct ud_operand *op,
                unsigned char      type,
                unsigned int       size)

{
  unsigned char mod, rm, reg;

  /* get mod, r/m and reg fields */
  mod = MODRM_MOD(modrm(u));
  rm  = (REX_B(u->pfx_rex) << 3) | MODRM_RM(modrm(u));
  reg = (REX_R(u->pfx_rex) << 3) | MODRM_REG(modrm(u));

  op->size = resolve_operand_size(u, size);

  /* 
   * If mod is 11b, then the modrm.rm specifies a register.
   *
   */
  if (mod == 3) {
    op->type = UD_OP_REG;
    if (type ==  T_GPR) {
      op->base = decode_gpr(u, op->size, rm);
    } else {
      op->base = resolve_reg(u, type, (REX_B(u->pfx_rex) << 3) | (rm & 7));
    }
    return;
  } 


  /* 
   * !11 => Memory Address
   */  
  op->type = UD_OP_MEM;

  if (u->adr_mode == 64) {
    op->base = UD_R_RAX + rm;
    if (mod == 1) {
      op->offset = 8;
    } else if (mod == 2) {
      op->offset = 32;
    } else if (mod == 0 && (rm & 7) == 5) {           
      op->base = UD_R_RIP;
      op->offset = 32;
    } else {
      op->offset = 0;
    }
    /* 
     * Scale-Index-Base (SIB) 
     */
    if ((rm & 7) == 4) {
      inp_next(u);
      
      op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
      op->index = UD_R_RAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
      op->base  = UD_R_RAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

      /* special conditions for base reference */
      if (op->index == UD_R_RSP) {
        op->index = UD_NONE;
        op->scale = UD_NONE;
      }

      if (op->base == UD_R_RBP || op->base == UD_R_R13) {
        if (mod == 0) {
          op->base = UD_NONE;
        } 
        if (mod == 1) {
          op->offset = 8;
        } else {
          op->offset = 32;
        }
      }
    }
  } else if (u->adr_mode == 32) {
    op->base = UD_R_EAX + rm;
    if (mod == 1) {
      op->offset = 8;
    } else if (mod == 2) {
      op->offset = 32;
    } else if (mod == 0 && rm == 5) {
      op->base = UD_NONE;
      op->offset = 32;
    } else {
      op->offset = 0;
    }

    /* Scale-Index-Base (SIB) */
    if ((rm & 7) == 4) {
      inp_next(u);

      op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
      op->index = UD_R_EAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
      op->base  = UD_R_EAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

      if (op->index == UD_R_ESP) {
        op->index = UD_NONE;
        op->scale = UD_NONE;
      }

      /* special condition for base reference */
      if (op->base == UD_R_EBP) {
        if (mod == 0) {
          op->base = UD_NONE;
        } 
        if (mod == 1) {
          op->offset = 8;
        } else {
          op->offset = 32;
        }
      }
    }
  } else {
    const unsigned int bases[]   = { UD_R_BX, UD_R_BX, UD_R_BP, UD_R_BP,
                                     UD_R_SI, UD_R_DI, UD_R_BP, UD_R_BX };
    const unsigned int indices[] = { UD_R_SI, UD_R_DI, UD_R_SI, UD_R_DI,
                                     UD_NONE, UD_NONE, UD_NONE, UD_NONE };
    op->base  = bases[rm & 7];
    op->index = indices[rm & 7];
    if (mod == 0 && rm == 6) {
      op->offset= 16;
      op->base = UD_NONE;
    } else if (mod == 1) {
      op->offset = 8;
    } else if (mod == 2) { 
      op->offset = 16;
    }
  }

  /* 
   * extract offset, if any 
   */
  switch (op->offset) {
    case 8 : op->lval.ubyte  = inp_uint8(u);  break;
    case 16: op->lval.uword  = inp_uint16(u); break;
    case 32: op->lval.udword = inp_uint32(u); break;
    case 64: op->lval.uqword = inp_uint64(u); break;
    default: break;
  }
}
Пример #8
0
/*
 * decode_modrm_rm
 *
 *    Decodes rm field of mod/rm byte
 * 
 */
static void 
decode_modrm_rm(struct ud         *u, 
                struct ud_operand *op,
                unsigned char      type,    /* register type */
                unsigned int       size)    /* operand size */

{
  size_t offset = 0;
  unsigned char mod, rm;

  /* get mod, r/m and reg fields */
  mod = MODRM_MOD(modrm(u));
  rm  = (REX_B(u->pfx_rex) << 3) | MODRM_RM(modrm(u));

  /* 
   * If mod is 11b, then the modrm.rm specifies a register.
   *
   */
  if (mod == 3) {
    decode_reg(u, op, type, rm, size);
    return;
  }

  /* 
   * !11b => Memory Address
   */  
  op->type = UD_OP_MEM;
  op->size = resolve_operand_size(u, size);

  if (u->adr_mode == 64) {
    op->base = UD_R_RAX + rm;
    if (mod == 1) {
      offset = 8;
    } else if (mod == 2) {
      offset = 32;
    } else if (mod == 0 && (rm & 7) == 5) {           
      op->base = UD_R_RIP;
      offset = 32;
    } else {
      offset = 0;
    }
    /* 
     * Scale-Index-Base (SIB) 
     */
    if ((rm & 7) == 4) {
      inp_next(u);
      
      op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
      op->index = UD_R_RAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
      op->base  = UD_R_RAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

      /* special conditions for base reference */
      if (op->index == UD_R_RSP) {
        op->index = UD_NONE;
        op->scale = UD_NONE;
      }

      if (op->base == UD_R_RBP || op->base == UD_R_R13) {
        if (mod == 0) {
          op->base = UD_NONE;
        } 
        if (mod == 1) {
          offset = 8;
        } else {
          offset = 32;
        }
      }
    }
  } else if (u->adr_mode == 32) {
    op->base = UD_R_EAX + rm;
    if (mod == 1) {
      offset = 8;
    } else if (mod == 2) {
      offset = 32;
    } else if (mod == 0 && rm == 5) {
      op->base = UD_NONE;
      offset = 32;
    } else {
      offset = 0;
    }

    /* Scale-Index-Base (SIB) */
    if ((rm & 7) == 4) {
      inp_next(u);

      op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
      op->index = UD_R_EAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
      op->base  = UD_R_EAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

      if (op->index == UD_R_ESP) {
        op->index = UD_NONE;
        op->scale = UD_NONE;
      }

      /* special condition for base reference */
      if (op->base == UD_R_EBP) {
        if (mod == 0) {
          op->base = UD_NONE;
        } 
        if (mod == 1) {
          offset = 8;
        } else {
          offset = 32;
        }
      }
    }
  } else {
    const unsigned int bases[]   = { UD_R_BX, UD_R_BX, UD_R_BP, UD_R_BP,
                                     UD_R_SI, UD_R_DI, UD_R_BP, UD_R_BX };
    const unsigned int indices[] = { UD_R_SI, UD_R_DI, UD_R_SI, UD_R_DI,
                                     UD_NONE, UD_NONE, UD_NONE, UD_NONE };
    op->base  = bases[rm & 7];
    op->index = indices[rm & 7];
    if (mod == 0 && rm == 6) {
      offset = 16;
      op->base = UD_NONE;
    } else if (mod == 1) {
      offset = 8;
    } else if (mod == 2) { 
      offset = 16;
    }
  }

  if (offset) {
    decode_mem_disp(u, offset, op);
  }
}
Пример #9
0
/* -----------------------------------------------------------------------------
 * disasm_operands() - Disassembles Operands.
 * -----------------------------------------------------------------------------
 */
static int disasm_operands(register struct ud* u)
{


  /* mopXt = map entry, operand X, type; */
  enum ud_operand_code mop1t = u->itab_entry->operand1.type;
  enum ud_operand_code mop2t = u->itab_entry->operand2.type;
  enum ud_operand_code mop3t = u->itab_entry->operand3.type;

  /* mopXs = map entry, operand X, size */
  unsigned int mop1s = u->itab_entry->operand1.size;
  unsigned int mop2s = u->itab_entry->operand2.size;
  unsigned int mop3s = u->itab_entry->operand3.size;

  /* iop = instruction operand */
  register struct ud_operand* iop = u->operand;
    
  switch(mop1t) {
    
    case OP_A :
        decode_a(u, &(iop[0]));
        break;
    
    /* M[b] ... */
    case OP_M :
        if (MODRM_MOD(inp_peek(u)) == 3)
            u->error= 1;
    /* E, G/P/V/I/CL/1/S */
    case OP_E :
        if (mop2t == OP_G) {
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_GPR);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
            else if (mop3t == OP_CL) {
                iop[2].type = UD_OP_REG;
                iop[2].base = UD_R_CL;
                iop[2].size = 8;
            }
        }
        else if (mop2t == OP_P)
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_MMX);
        else if (mop2t == OP_V)
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_XMM);
        else if (mop2t == OP_S)
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_SEG);
        else {
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, NULL, 0, T_NONE);
            if (mop2t == OP_CL) {
                iop[1].type = UD_OP_REG;
                iop[1].base = UD_R_CL;
                iop[1].size = 8;
            } else if (mop2t == OP_I1) {
                iop[1].type = UD_OP_CONST;
                u->operand[1].lval.udword = 1;
            } else if (mop2t == OP_I) {
                decode_imm(u, mop2s, &(iop[1]));
            }
        }
        break;

    /* G, E/PR[,I]/VR */
    case OP_G :
        if (mop2t == OP_M) {
            if (MODRM_MOD(inp_peek(u)) == 3)
                u->error= 1;
            decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_GPR);
        } else if (mop2t == OP_E) {
            decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_GPR);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
        } else if (mop2t == OP_PR) {
            decode_modrm(u, &(iop[1]), mop2s, T_MMX, &(iop[0]), mop1s, T_GPR);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
        } else if (mop2t == OP_VR) {
            if (MODRM_MOD(inp_peek(u)) != 3)
                u->error = 1;
            decode_modrm(u, &(iop[1]), mop2s, T_XMM, &(iop[0]), mop1s, T_GPR);
        } else if (mop2t == OP_W)
            decode_modrm(u, &(iop[1]), mop2s, T_XMM, &(iop[0]), mop1s, T_GPR);
        break;

    /* AL..BH, I/O/DX */
    case OP_AL : case OP_CL : case OP_DL : case OP_BL :
    case OP_AH : case OP_CH : case OP_DH : case OP_BH :

        iop[0].type = UD_OP_REG;
        iop[0].base = UD_R_AL + (mop1t - OP_AL);
        iop[0].size = 8;

        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        else if (mop2t == OP_DX) {
            iop[1].type = UD_OP_REG;
            iop[1].base = UD_R_DX;
            iop[1].size = 16;
        }
        else if (mop2t == OP_O)
            decode_o(u, mop2s, &(iop[1]));
        break;

    /* rAX[r8]..rDI[r15], I/rAX..rDI/O */
    case OP_rAXr8 : case OP_rCXr9 : case OP_rDXr10 : case OP_rBXr11 :
    case OP_rSPr12: case OP_rBPr13: case OP_rSIr14 : case OP_rDIr15 :
    case OP_rAX : case OP_rCX : case OP_rDX : case OP_rBX :
    case OP_rSP : case OP_rBP : case OP_rSI : case OP_rDI :

        iop[0].type = UD_OP_REG;
        iop[0].base = resolve_gpr64(u, mop1t);

        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        else if (mop2t >= OP_rAX && mop2t <= OP_rDI) {
            iop[1].type = UD_OP_REG;
            iop[1].base = resolve_gpr64(u, mop2t);
        }
        else if (mop2t == OP_O) {
            decode_o(u, mop2s, &(iop[1]));  
            iop[0].size = (uint8_t)resolve_operand_size(u, mop2s);
        }
        break;

    /* AL[r8b]..BH[r15b], I */
    case OP_ALr8b : case OP_CLr9b : case OP_DLr10b : case OP_BLr11b :
    case OP_AHr12b: case OP_CHr13b: case OP_DHr14b : case OP_BHr15b :
    {
        ud_type_t gpr = (mop1t - OP_ALr8b) + UD_R_AL + 
                        (REX_B(u->pfx_rex) << 3);
        if (UD_R_AH <= gpr && u->pfx_rex)
            gpr = gpr + 4;
        iop[0].type = UD_OP_REG;
        iop[0].base = gpr;
        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        break;
    }

    /* eAX..eDX, DX/I */
    case OP_eAX : case OP_eCX : case OP_eDX : case OP_eBX :
    case OP_eSP : case OP_eBP : case OP_eSI : case OP_eDI :
        iop[0].type = UD_OP_REG;
        iop[0].base = resolve_gpr32(u, mop1t);
        if (mop2t == OP_DX) {
            iop[1].type = UD_OP_REG;
            iop[1].base = UD_R_DX;
            iop[1].size = 16;
        } else if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        break;

    /* ES..GS */
    case OP_ES : case OP_CS : case OP_DS :
    case OP_SS : case OP_FS : case OP_GS :

        /* in 64bits mode, only fs and gs are allowed */
        if (u->dis_mode == 64)
            if (mop1t != OP_FS && mop1t != OP_GS)
                u->error= 1;
        iop[0].type = UD_OP_REG;
        iop[0].base = (mop1t - OP_ES) + UD_R_ES;
        iop[0].size = 16;

        break;

    /* J */
    case OP_J :
        decode_imm(u, mop1s, &(iop[0]));        
        iop[0].type = UD_OP_JIMM;
        break ;

    /* PR, I */
    case OP_PR:
        if (MODRM_MOD(inp_peek(u)) != 3)
            u->error = 1;
        decode_modrm(u, &(iop[0]), mop1s, T_MMX, NULL, 0, T_NONE);
        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        break; 

    /* VR, I */
    case OP_VR:
        if (MODRM_MOD(inp_peek(u)) != 3)
            u->error = 1;
        decode_modrm(u, &(iop[0]), mop1s, T_XMM, NULL, 0, T_NONE);
        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        break; 

    /* P, Q[,I]/W/E[,I],VR */
    case OP_P :
        if (mop2t == OP_Q) {
            decode_modrm(u, &(iop[1]), mop2s, T_MMX, &(iop[0]), mop1s, T_MMX);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
        } else if (mop2t == OP_W) {
            decode_modrm(u, &(iop[1]), mop2s, T_XMM, &(iop[0]), mop1s, T_MMX);
        } else if (mop2t == OP_VR) {
            if (MODRM_MOD(inp_peek(u)) != 3)
                u->error = 1;
            decode_modrm(u, &(iop[1]), mop2s, T_XMM, &(iop[0]), mop1s, T_MMX);
        } else if (mop2t == OP_E) {
            decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_MMX);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
        }
        break;

    /* R, C/D */
    case OP_R :
        if (mop2t == OP_C)
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_CRG);
        else if (mop2t == OP_D)
            decode_modrm(u, &(iop[0]), mop1s, T_GPR, &(iop[1]), mop2s, T_DBG);
        break;

    /* C, R */
    case OP_C :
        decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_CRG);
        break;

    /* D, R */
    case OP_D :
        decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_DBG);
        break;

    /* Q, P */
    case OP_Q :
        decode_modrm(u, &(iop[0]), mop1s, T_MMX, &(iop[1]), mop2s, T_MMX);
        break;

    /* S, E */
    case OP_S :
        decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_SEG);
        break;

    /* W, V */
    case OP_W :
        decode_modrm(u, &(iop[0]), mop1s, T_XMM, &(iop[1]), mop2s, T_XMM);
        break;

    /* V, W[,I]/Q/M/E */
    case OP_V :
        if (mop2t == OP_W) {
            /* special cases for movlps and movhps */
            if (MODRM_MOD(inp_peek(u)) == 3) {
                if (u->mnemonic == UD_Imovlps)
                    u->mnemonic = UD_Imovhlps;
                else
                if (u->mnemonic == UD_Imovhps)
                    u->mnemonic = UD_Imovlhps;
            }
            decode_modrm(u, &(iop[1]), mop2s, T_XMM, &(iop[0]), mop1s, T_XMM);
            if (mop3t == OP_I)
                decode_imm(u, mop3s, &(iop[2]));
        } else if (mop2t == OP_Q)
            decode_modrm(u, &(iop[1]), mop2s, T_MMX, &(iop[0]), mop1s, T_XMM);
        else if (mop2t == OP_M) {
            if (MODRM_MOD(inp_peek(u)) == 3)
                u->error= 1;
            decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_XMM);
        } else if (mop2t == OP_E) {
            decode_modrm(u, &(iop[1]), mop2s, T_GPR, &(iop[0]), mop1s, T_XMM);
        } else if (mop2t == OP_PR) {
            decode_modrm(u, &(iop[1]), mop2s, T_MMX, &(iop[0]), mop1s, T_XMM);
        }
        break;

    /* DX, eAX/AL */
    case OP_DX :
        iop[0].type = UD_OP_REG;
        iop[0].base = UD_R_DX;
        iop[0].size = 16;

        if (mop2t == OP_eAX) {
            iop[1].type = UD_OP_REG;    
            iop[1].base = resolve_gpr32(u, mop2t);
        } else if (mop2t == OP_AL) {
            iop[1].type = UD_OP_REG;
            iop[1].base = UD_R_AL;
            iop[1].size = 8;
        }

        break;

    /* I, I/AL/eAX */
    case OP_I :
        decode_imm(u, mop1s, &(iop[0]));
        if (mop2t == OP_I)
            decode_imm(u, mop2s, &(iop[1]));
        else if (mop2t == OP_AL) {
            iop[1].type = UD_OP_REG;
            iop[1].base = UD_R_AL;
            iop[1].size = 16;
        } else if (mop2t == OP_eAX) {
            iop[1].type = UD_OP_REG;    
            iop[1].base = resolve_gpr32(u, mop2t);
        }
        break;

    /* O, AL/eAX */
    case OP_O :
        decode_o(u, mop1s, &(iop[0]));
        iop[1].type = UD_OP_REG;
        iop[1].size = (uint8_t)resolve_operand_size(u, mop1s);
        if (mop2t == OP_AL)
            iop[1].base = UD_R_AL;
        else if (mop2t == OP_eAX)
            iop[1].base = resolve_gpr32(u, mop2t);
        else if (mop2t == OP_rAX)
            iop[1].base = resolve_gpr64(u, mop2t);      
        break;

    /* 3 */
    case OP_I3 :
        iop[0].type = UD_OP_CONST;
        iop[0].lval.sbyte = 3;
        break;

    /* ST(n), ST(n) */
    case OP_ST0 : case OP_ST1 : case OP_ST2 : case OP_ST3 :
    case OP_ST4 : case OP_ST5 : case OP_ST6 : case OP_ST7 :

        iop[0].type = UD_OP_REG;
        iop[0].base = (mop1t-OP_ST0) + UD_R_ST0;
        iop[0].size = 0;

        if (mop2t >= OP_ST0 && mop2t <= OP_ST7) {
            iop[1].type = UD_OP_REG;
            iop[1].base = (mop2t-OP_ST0) + UD_R_ST0;
            iop[1].size = 0;
        }
        break;

    /* AX */
    case OP_AX:
        iop[0].type = UD_OP_REG;
        iop[0].base = UD_R_AX;
        iop[0].size = 16;
        break;

    /* none */
    default :
        iop[0].type = iop[1].type = iop[2].type = UD_NONE;
  }

  return 0;
}
Пример #10
0
/* -----------------------------------------------------------------------------
 * decode_modrm() - Decodes ModRM Byte
 * -----------------------------------------------------------------------------
 */
static void 
decode_modrm(struct ud* u, struct ud_operand *op, unsigned int s, 
         unsigned char rm_type, struct ud_operand *opreg, 
			 unsigned int reg_size, unsigned char reg_type)
{
  unsigned char mod, rm, reg;

  inp_next(u);

  /* get mod, r/m and reg fields */
  mod = MODRM_MOD(inp_curr(u));
  rm  = (REX_B(u->pfx_rex) << 3) | MODRM_RM(inp_curr(u));
  reg = (REX_R(u->pfx_rex) << 3) | MODRM_REG(inp_curr(u));

  op->size = (uint8_t) resolve_operand_size(u, s);

  /* if mod is 11b, then the UD_R_m specifies a gpr/mmx/sse/control/debug */
  if (mod == 3) {
    op->type = UD_OP_REG;
    if (rm_type ==  T_GPR)
        op->base = decode_gpr(u, op->size, rm);
    else    op->base = resolve_reg(u, rm_type, (REX_B(u->pfx_rex) << 3) | (rm&7));
  } 
  /* else its memory addressing */  
  else {
    op->type = UD_OP_MEM;

    /* 64bit addressing */
    if (u->adr_mode == 64) {

        op->base = UD_R_RAX + rm;

        /* get offset type */
        if (mod == 1)
            op->offset = 8;
        else if (mod == 2)
            op->offset = 32;
        else if (mod == 0 && (rm & 7) == 5) {           
            op->base = UD_R_RIP;
            op->offset = 32;
        } else  op->offset = 0;

        /* Scale-Index-Base (SIB) */
        if ((rm & 7) == 4) {
            inp_next(u);
            
            op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
            op->index = UD_R_RAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
            op->base  = UD_R_RAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

            /* special conditions for base reference */
            if (op->index == UD_R_RSP) {
                op->index = UD_NONE;
                op->scale = UD_NONE;
            }

            if (op->base == UD_R_RBP || op->base == UD_R_R13) {
                if (mod == 0) 
                    op->base = UD_NONE;
                if (mod == 1)
                    op->offset = 8;
                else op->offset = 32;
            }
        }
    } 

    /* 32-Bit addressing mode */
    else if (u->adr_mode == 32) {

        /* get base */
        op->base = UD_R_EAX + rm;

        /* get offset type */
        if (mod == 1)
            op->offset = 8;
        else if (mod == 2)
            op->offset = 32;
        else if (mod == 0 && rm == 5) {
            op->base = UD_NONE;
            op->offset = 32;
        } else  op->offset = 0;

        /* Scale-Index-Base (SIB) */
        if ((rm & 7) == 4) {
            inp_next(u);

            op->scale = (1 << SIB_S(inp_curr(u))) & ~1;
            op->index = UD_R_EAX + (SIB_I(inp_curr(u)) | (REX_X(u->pfx_rex) << 3));
            op->base  = UD_R_EAX + (SIB_B(inp_curr(u)) | (REX_B(u->pfx_rex) << 3));

            if (op->index == UD_R_ESP) {
                op->index = UD_NONE;
                op->scale = UD_NONE;
            }

            /* special condition for base reference */
            if (op->base == UD_R_EBP) {
                if (mod == 0)
                    op->base = UD_NONE;
                if (mod == 1)
                    op->offset = 8;
                else op->offset = 32;
            }
        }
    } 

    /* 16bit addressing mode */
    else  {
        switch (rm) {
            case 0: op->base = UD_R_BX; op->index = UD_R_SI; break;
            case 1: op->base = UD_R_BX; op->index = UD_R_DI; break;
            case 2: op->base = UD_R_BP; op->index = UD_R_SI; break;
            case 3: op->base = UD_R_BP; op->index = UD_R_DI; break;
            case 4: op->base = UD_R_SI; break;
            case 5: op->base = UD_R_DI; break;
            case 6: op->base = UD_R_BP; break;
            case 7: op->base = UD_R_BX; break;
        }

        if (mod == 0 && rm == 6) {
            op->offset= 16;
            op->base = UD_NONE;
        }
        else if (mod == 1)
            op->offset = 8;
        else if (mod == 2) 
            op->offset = 16;
    }
  }  

  /* extract offset, if any */
  switch(op->offset) {
    case 8 : op->lval.ubyte  = inp_uint8(u);  break;
    case 16: op->lval.uword  = inp_uint16(u);  break;
    case 32: op->lval.udword = inp_uint32(u); break;
    default: break;
  }

  /* resolve register encoded in reg field */
  if (opreg) {
    opreg->type = UD_OP_REG;
    opreg->size = (uint8_t)resolve_operand_size(u, reg_size);
    if (reg_type == T_GPR) 
        opreg->base = decode_gpr(u, opreg->size, reg);
    else opreg->base = resolve_reg(u, reg_type, reg);
  }
}