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/* Chrysalide - Outil d'analyse de fichiers binaires
* operand.c - gestion des operandes de l'architecture x86
*
* Copyright (C) 2008-2012 Cyrille Bagard
*
* This file is part of Chrysalide.
*
* Chrysalide is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* Chrysalide is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Foobar. If not, see <http://www.gnu.org/licenses/>.
*/
#include "operand.h"
/******************************************************************************
* *
* Paramètres : instr = instruction dont la définition est à compléter. [OUT]*
* data = flux de données à analyser. *
* pos = position courante dans ce flux. [OUT] *
* len = taille totale des données à analyser. *
* count = quantité d'opérandes à lire. *
* ... = éventuelle(s) information(s) complémentaire(s). *
* *
* Description : Procède à la lecture de trois opérandes donnés. *
* *
* Retour : Bilan de l'opération : true en cas de succès, false sinon. *
* *
* Remarques : - *
* *
******************************************************************************/
bool _x86_read_operands(GArchInstruction *instr, const bin_t *data, off_t *pos, off_t len, unsigned int count, ...)
{
bool result; /* Bilan à retourner */
va_list ap; /* Liste des compléments */
X86OperandType types[MAX_OPERANDS]; /* Type des opérandes */
unsigned int i; /* Boucle de parcours */
bool op1_first; /* Position de l'opérande #1 */
bool op2_first; /* Position de l'opérande #2 */
MemoryDataSize oprsize; /* Taille des opérandes */
off_t op_pos[MAX_OPERANDS]; /* Position après lecture */
vmpa_t offset; /* Adresse courante */
bin_t base; /* Indice du premier registre */
GArchOperand *op; /* Opérande unique décodé */
if (count > MAX_OPERANDS) return false;
result = true;
va_start(ap, count);
/* Types à charger */
for (i = 0; i < count; i++)
types[i] = va_arg(ap, MemoryDataSize);
for ( ; i < MAX_OPERANDS; i++)
types[i] = X86_OTP_NONE;
/* Initialisations */
if (types[0] & X86_OTP_RM_TYPE)
{
op1_first = true;
op2_first = false;
}
else if (types[1] & X86_OTP_RM_TYPE)
{
op1_first = false;
op2_first = true;
}
else
{
op1_first = true;
op2_first = false;
}
oprsize = MDS_UNDEFINED;
/* Lecture des opérandes */
for (i = 0; i < count && result; i++)
{
/* Tête de lecture */
switch (i)
{
case 0:
op_pos[0] = *pos;
break;
case 1:
if ((types[0] & X86_OTP_REG_TYPE || types[0] & X86_OTP_RM_TYPE) && (types[1] & X86_OTP_IMM_TYPE))
op_pos[1] = op_pos[0];
else op_pos[1] = *pos;
*pos = op_pos[0];
break;
case 2 ... MAX_OPERANDS:
*pos = MAX(*pos, op_pos[i - 1]);
op_pos[i] = *pos;
}
/* Lecture */
switch (types[i])
{
case X86_OTP_IMM8:
assert(0);
//op = g_imm_operand_new_from_data_old(MDS_8_BITS, data, &op_pos[i], len, SRE_LITTLE /* FIXME */);
break;
case X86_OTP_IMM16:
assert(0);
//op = g_imm_operand_new_from_data_old(MDS_16_BITS, data, &op_pos[i], len, SRE_LITTLE /* FIXME */);
break;
case X86_OTP_IMM1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
assert(0);
//op = g_imm_operand_new_from_data_old(oprsize == MDS_32_BITS ? MDS_32_BITS : MDS_16_BITS, data, &op_pos[i], len, SRE_LITTLE /* FIXME */);
break;
case X86_OTP_MOFFS8:
op = g_x86_moffs_operand_new(data, &op_pos[i], len, MDS_8_BITS);
break;
case X86_OTP_MOFFS1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_moffs_operand_new(data, &op_pos[i], len, oprsize);
break;
case X86_OTP_REL8:
offset = va_arg(ap, vmpa_t);
op = g_x86_relative_operand_new(data, &op_pos[i], len, MDS_8_BITS, offset + 1);
break;
case X86_OTP_REL1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
offset = va_arg(ap, vmpa_t);
op = g_x86_relative_operand_new(data, &op_pos[i], len, oprsize, offset + 1);
break;
case X86_OTP_R8:
op = g_x86_register_operand_new_from_mod_rm(data, &op_pos[i], len, MDS_8_BITS, i == 0 ? op1_first : op2_first);
break;
case X86_OTP_R1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_register_operand_new_from_mod_rm(data, &op_pos[i], len, oprsize, i == 0 ? op1_first : op2_first);
break;
case X86_OTP_OP_R8:
base = (bin_t)va_arg(ap, int);
op = g_x86_register_operand_new_from_opcode(data, &op_pos[i], len, MDS_8_BITS, base);
break;
case X86_OTP_OP_R1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
base = (bin_t)va_arg(ap, int);
op = g_x86_register_operand_new_from_opcode(data, &op_pos[i], len, oprsize, base);
break;
case X86_OTP_RM8:
op = g_x86_mod_rm_operand_new(data, &op_pos[i], len, MDS_8_BITS);
break;
case X86_OTP_RM16:
op = g_x86_mod_rm_operand_new(data, &op_pos[i], len, MDS_16_BITS);
break;
case X86_OTP_RM1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_mod_rm_operand_new(data, &op_pos[i], len, oprsize);
break;
case X86_OTP_DST_8:
op = g_x86_data_operand_new(MDS_8_BITS, true);
break;
case X86_OTP_DST_1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_data_operand_new(oprsize == MDS_32_BITS ? MDS_32_BITS : MDS_16_BITS, true);
break;
case X86_OTP_SRC_8:
op = g_x86_data_operand_new(MDS_8_BITS, false);
break;
case X86_OTP_SRC_1632:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_data_operand_new(oprsize == MDS_32_BITS ? MDS_32_BITS : MDS_16_BITS, false);
break;
case X86_OTP_ONE:
op = g_imm_operand_new_from_value(MDS_8_BITS, 1);
break;
case X86_OTP_CL:
op = g_x86_register_operand_new_from_index(0x01, MDS_8_BITS);
break;
case X86_OTP_AL:
op = g_x86_register_operand_new_from_index(0x00, MDS_8_BITS);
break;
case X86_OTP_E_AX:
if (oprsize == MDS_UNDEFINED) oprsize = va_arg(ap, MemoryDataSize);
op = g_x86_register_operand_new_from_index(0x00, oprsize);
break;
}
if (op == NULL) result = false;
else g_arch_instruction_attach_extra_operand(instr, op);
}
*pos = MAX(*pos, op_pos[i - 1]);
return result;
}
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