/* Chrysalide - Outil d'analyse de fichiers binaires
* arithmetic.c - gestion des opérations arithmétiques
*
* Copyright (C) 2023 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 .
*/
#include "arithmetic.h"
#include
#include "arithmetic-int.h"
#include "literal.h"
/* --------------------- INTRODUCTION D'UNE NOUVELLE EXPRESSION --------------------- */
/* Initialise la classe des opérations arithmétiques. */
static void g_scan_arithmetic_operation_class_init(GScanArithmeticOperationClass *);
/* Initialise une instance d'opération arithmétique. */
static void g_scan_arithmetic_operation_init(GScanArithmeticOperation *);
/* Supprime toutes les références externes. */
static void g_scan_arithmetic_operation_dispose(GScanArithmeticOperation *);
/* Procède à la libération totale de la mémoire. */
static void g_scan_arithmetic_operation_finalize(GScanArithmeticOperation *);
/* --------------------- IMPLEMENTATION DES FONCTIONS DE CLASSE --------------------- */
/* Réalise une comparaison entre objets selon un critère précis. */
static bool g_scan_arithmetic_operation_compare_rich(const GScanArithmeticOperation *, const GScanArithmeticOperation *, RichCmpOperation, bool *);
/* Réduit une expression à une forme plus simple. */
static ScanReductionState g_scan_arithmetic_operation_reduce(const GScanArithmeticOperation *, GScanContext *, GScanScope *, GScanExpression **);
/* ---------------------------------------------------------------------------------- */
/* INTRODUCTION D'UNE NOUVELLE EXPRESSION */
/* ---------------------------------------------------------------------------------- */
/* Indique le type défini pour une opération de relation entre expressions. */
G_DEFINE_TYPE(GScanArithmeticOperation, g_scan_arithmetic_operation, G_TYPE_SCAN_EXPRESSION);
/******************************************************************************
* *
* Paramètres : klass = classe à initialiser. *
* *
* Description : Initialise la classe des opérations arithmétiques. *
* *
* Retour : - *
* *
* Remarques : - *
* *
******************************************************************************/
static void g_scan_arithmetic_operation_class_init(GScanArithmeticOperationClass *klass)
{
GObjectClass *object; /* Autre version de la classe */
GScanExpressionClass *expr; /* Version de classe parente */
object = G_OBJECT_CLASS(klass);
object->dispose = (GObjectFinalizeFunc/* ! */)g_scan_arithmetic_operation_dispose;
object->finalize = (GObjectFinalizeFunc)g_scan_arithmetic_operation_finalize;
expr = G_SCAN_EXPRESSION_CLASS(klass);
expr->cmp_rich = (compare_expr_rich_fc)g_scan_arithmetic_operation_compare_rich;
expr->reduce = (reduce_expr_fc)g_scan_arithmetic_operation_reduce;
}
/******************************************************************************
* *
* Paramètres : op = instance à initialiser. *
* *
* Description : Initialise une instance d'opération arithmétique. *
* *
* Retour : - *
* *
* Remarques : - *
* *
******************************************************************************/
static void g_scan_arithmetic_operation_init(GScanArithmeticOperation *op)
{
op->left = NULL;
op->right = NULL;
}
/******************************************************************************
* *
* Paramètres : op = instance d'objet GLib à traiter. *
* *
* Description : Supprime toutes les références externes. *
* *
* Retour : - *
* *
* Remarques : - *
* *
******************************************************************************/
static void g_scan_arithmetic_operation_dispose(GScanArithmeticOperation *op)
{
g_clear_object(&op->left);
g_clear_object(&op->right);
G_OBJECT_CLASS(g_scan_arithmetic_operation_parent_class)->dispose(G_OBJECT(op));
}
/******************************************************************************
* *
* Paramètres : op = instance d'objet GLib à traiter. *
* *
* Description : Procède à la libération totale de la mémoire. *
* *
* Retour : - *
* *
* Remarques : - *
* *
******************************************************************************/
static void g_scan_arithmetic_operation_finalize(GScanArithmeticOperation *op)
{
G_OBJECT_CLASS(g_scan_arithmetic_operation_parent_class)->finalize(G_OBJECT(op));
}
/******************************************************************************
* *
* Paramètres : operator = type d'opération arithmétique à représenter. *
* left = premier opérande concerné. *
* right = éventuel second opérande impliqué ou NULL. *
* *
* Description : Organise une opération arithmétique entre expressions. *
* *
* Retour : Fonction mise en place. *
* *
* Remarques : - *
* *
******************************************************************************/
GScanExpression *g_scan_arithmetic_operation_new(ArithmeticExpressionOperator operator, GScanExpression *left, GScanExpression *right)
{
GScanExpression *result; /* Structure à retourner */
result = g_object_new(G_TYPE_SCAN_ARITHMETIC_OPERATION, NULL);
if (!g_scan_arithmetic_operation_create(G_SCAN_ARITHMETIC_OPERATION(result), operator, left, right))
g_clear_object(&result);
return result;
}
/******************************************************************************
* *
* Paramètres : op = instance à initialiser pleinement. *
* operator = type d'opération booléenne à représenter. *
* left = premier opérande concerné. *
* right = éventuel second opérande impliqué ou NULL. *
* *
* Description : Met en place une opération arithmétique entre expressions. *
* *
* Retour : Bilan de l'opération. *
* *
* Remarques : - *
* *
******************************************************************************/
bool g_scan_arithmetic_operation_create(GScanArithmeticOperation *op, ArithmeticExpressionOperator operator, GScanExpression *left, GScanExpression *right)
{
bool result; /* Bilan à retourner */
result = g_scan_expression_create(G_SCAN_EXPRESSION(op), SRS_PENDING);
if (!result) goto exit;
op->operator = operator;
op->left = left;
g_object_ref(G_OBJECT(op->left));
op->right = right;
g_object_ref(G_OBJECT(op->right));
exit:
return result;
}
/* ---------------------------------------------------------------------------------- */
/* IMPLEMENTATION DES FONCTIONS DE CLASSE */
/* ---------------------------------------------------------------------------------- */
/******************************************************************************
* *
* Paramètres : item = premier objet à consulter pour une comparaison. *
* other = second objet à consulter pour une comparaison. *
* op = opération de comparaison à réaliser. *
* status = bilan des opérations de comparaison. [OUT] *
* *
* Description : Réalise une comparaison entre objets selon un critère précis.*
* *
* Retour : true si la comparaison a pu être effectuée, false sinon. *
* *
* Remarques : - *
* *
******************************************************************************/
static bool g_scan_arithmetic_operation_compare_rich(const GScanArithmeticOperation *item, const GScanArithmeticOperation *other, RichCmpOperation op, bool *status)
{
bool result; /* Etat à retourner */
result = g_type_is_a(G_TYPE_FROM_INSTANCE(other), G_TYPE_SCAN_ARITHMETIC_OPERATION);
if (!result) goto done;
if (item->operator != other->operator)
{
result = compare_rich_integer_values_unsigned(item->operator, other->operator, op);
goto done;
}
result = g_comparable_item_compare_rich(G_COMPARABLE_ITEM(item), G_COMPARABLE_ITEM(other), RCO_EQ, status);
if (!result || STATUS_NOT_EQUAL(*status, op)) goto done;
result = g_comparable_item_compare_rich(G_COMPARABLE_ITEM(item->left),
G_COMPARABLE_ITEM(other->left),
op, status);
if (!result || STATUS_NOT_EQUAL(*status, op)) goto done;
result = g_comparable_item_compare_rich(G_COMPARABLE_ITEM(item->right),
G_COMPARABLE_ITEM(other->right),
op, status);
done:
return result;
}
/******************************************************************************
* *
* Paramètres : expr = expression à consulter. *
* ctx = contexte de suivi de l'analyse courante. *
* scope = portée courante des variables locales. *
* out = zone d'enregistrement de la réduction opérée. [OUT] *
* *
* Description : Réduit une expression à une forme plus simple. *
* *
* Retour : Bilan de l'opération : false en cas d'erreur irrécupérable. *
* *
* Remarques : - *
* *
******************************************************************************/
static ScanReductionState g_scan_arithmetic_operation_reduce(const GScanArithmeticOperation *expr, GScanContext *ctx, GScanScope *scope, GScanExpression **out)
{
ScanReductionState result; /* Etat synthétisé à retourner */
GScanExpression *new_left; /* Expression réduite (gauche) */
GScanExpression *new_right; /* Expression réduite (droite) */
ScanReductionState state_left; /* Etat synthétisé #1 */
ScanReductionState state_right; /* Etat synthétisé #2 */
GScanLiteralExpression *op_left; /* Opérande gauche final */
GScanLiteralExpression *op_right; /* Opérande droite final */
LiteralValueType vtype_left; /* Type de valeur portée #1 */
LiteralValueType vtype_right; /* Type de valeur portée #2 */
long long val_1_s; /* Première valeur à traiter */
unsigned long long val_1_u; /* Première valeur à traiter */
long long val_2_s; /* Seconde valeur à traiter */
unsigned long long val_2_u; /* Seconde valeur à traiter */
LiteralValueType state_final; /* Nature de la valeur finale */
long long reduced_s; /* Valeur réduite finale */
unsigned long long reduced_u; /* Valeur réduite finale */
/* Réduction des éléments considérés */
new_left = NULL;
new_right = NULL;
state_left = g_scan_expression_reduce(expr->left, ctx, scope, &new_left);
if (state_left == SRS_UNRESOLVABLE)
{
result = SRS_UNRESOLVABLE;
goto exit;
}
state_right = g_scan_expression_reduce(expr->right, ctx, scope, &new_right);
if (state_right == SRS_UNRESOLVABLE)
{
result = SRS_UNRESOLVABLE;
goto exit;
}
/* Construction d'une réduction locale ? */
if (G_IS_SCAN_LITERAL_EXPRESSION(new_left) && G_IS_SCAN_LITERAL_EXPRESSION(new_right))
{
/* Récupération de l'opérande de gauche */
op_left = G_SCAN_LITERAL_EXPRESSION(new_left);
vtype_left = g_scan_literal_expression_get_value_type(op_left);
if (vtype_left == LVT_SIGNED_INTEGER)
{
if (!g_scan_literal_expression_get_signed_integer_value(op_left, &val_1_s))
{
result = SRS_UNRESOLVABLE;
goto exit;
}
}
else if (vtype_left == LVT_UNSIGNED_INTEGER)
{
if (!g_scan_literal_expression_get_unsigned_integer_value(op_left, &val_1_u))
{
result = SRS_UNRESOLVABLE;
goto exit;
}
}
else
{
result = SRS_UNRESOLVABLE;
goto exit;
}
/* Récupération de l'opérande de droite */
op_right = G_SCAN_LITERAL_EXPRESSION(new_right);
vtype_right = g_scan_literal_expression_get_value_type(op_right);
if (vtype_right == LVT_SIGNED_INTEGER)
{
if (!g_scan_literal_expression_get_signed_integer_value(op_right, &val_2_s))
{
result = SRS_UNRESOLVABLE;
goto exit;
}
}
else if (vtype_right == LVT_UNSIGNED_INTEGER)
{
if (!g_scan_literal_expression_get_unsigned_integer_value(op_right, &val_2_u))
{
result = SRS_UNRESOLVABLE;
goto exit;
}
}
else
{
result = SRS_UNRESOLVABLE;
goto exit;
}
/* Partie des calculs */
result = SRS_REDUCED;
switch (expr->operator)
{
case AEO_PLUS:
if (vtype_left == LVT_SIGNED_INTEGER)
{
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s + val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
if ((long long)val_2_u > val_1_s)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_s + (long long)val_2_u;
}
else
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s + (long long)val_2_u;
}
}
}
else
{
assert(vtype_left == LVT_UNSIGNED_INTEGER);
if (vtype_right == LVT_SIGNED_INTEGER)
{
if ((long long)val_1_u > val_2_s)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = (long long)val_1_u + val_2_s;
}
else
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = (long long)val_1_u + val_2_s;
}
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_u + val_2_u;
}
}
break;
case AEO_MINUS:
if (vtype_left == LVT_SIGNED_INTEGER)
{
if (vtype_right == LVT_SIGNED_INTEGER)
{
if (val_2_s < val_1_s)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_s - val_2_s;
}
else
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s - val_2_s;
}
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s - (long long)val_2_u;
}
}
else
{
assert(vtype_left == LVT_UNSIGNED_INTEGER);
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = (long long)val_1_u - val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
if (val_1_u > val_2_u)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_u - val_2_u;
}
else
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_u - val_2_u;
}
}
}
break;
case AEO_MUL:
if (vtype_left == LVT_SIGNED_INTEGER)
{
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_s * val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s * (long long)val_2_u;
}
}
else
{
assert(vtype_left == LVT_UNSIGNED_INTEGER);
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = (long long)val_1_u * val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_u * val_2_u;
}
}
break;
case AEO_DIV:
if ((vtype_right == LVT_SIGNED_INTEGER && val_2_s == 0)
|| (vtype_right == LVT_UNSIGNED_INTEGER && val_2_u == 0))
{
result = SRS_UNRESOLVABLE;
break;
}
if (vtype_left == LVT_SIGNED_INTEGER)
{
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_s / val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_SIGNED_INTEGER;
reduced_s = val_1_s / (long long)val_2_u;
}
}
else
{
assert(vtype_left == LVT_UNSIGNED_INTEGER);
if (vtype_right == LVT_SIGNED_INTEGER)
{
state_final = LVT_SIGNED_INTEGER;
reduced_s = (long long)val_1_u / val_2_s;
}
else
{
assert(vtype_right == LVT_UNSIGNED_INTEGER);
state_final = LVT_UNSIGNED_INTEGER;
reduced_u = val_1_u / val_2_u;
}
}
break;
case AEO_MOD:
result = SRS_UNRESOLVABLE;
/* FIXME
result = (val_2 != 0);
if (result)
reduced = val_1 % val_2;
*/
break;
}
if (result == SRS_REDUCED)
{
if (state_final == LVT_SIGNED_INTEGER)
*out = g_scan_literal_expression_new(LVT_SIGNED_INTEGER, &reduced_s);
else
{
assert(state_final == LVT_UNSIGNED_INTEGER);
*out = g_scan_literal_expression_new(LVT_UNSIGNED_INTEGER, &reduced_u);
}
}
}
/* Mise à jour de la progression ? */
else if (state_left == SRS_WAIT_FOR_SCAN || state_right == SRS_WAIT_FOR_SCAN)
{
if (new_left != expr->left || new_right != expr->right)
*out = g_scan_arithmetic_operation_new(expr->operator, new_left, new_right);
result = SRS_WAIT_FOR_SCAN;
}
/* Cas des situations où les expressions ne sont pas exploitables (!) */
else
{
assert(state_left == SRS_REDUCED && state_right == SRS_REDUCED);
result = SRS_UNRESOLVABLE;
}
/* Sortie propre */
exit:
g_clear_object(&new_left);
g_clear_object(&new_right);
return result;
}