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kernel.return_fixes: add mipi_dsi_device_transfer(), timer_delete() and get_device()
[smatch.git] / smatch_equiv.c
blob8b36fd6e73309c14d575ec223407feb426ed4fee
1 /*
2 * Copyright (C) 2010 Dan Carpenter.
3 *
4 * This program is free software; you can redistribute it and/or
5 * modify it under the terms of the GNU General Public License
6 * as published by the Free Software Foundation; either version 2
7 * of the License, or (at your option) any later version.
8 *
9 * This program is distributed in the hope that it will be useful,
10 * but WITHOUT ANY WARRANTY; without even the implied warranty of
11 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
12 * GNU General Public License for more details.
13 *
14 * You should have received a copy of the GNU General Public License
15 * along with this program; if not, see http://www.gnu.org/copyleft/gpl.txt
16 */
17
18 /*
19 * smatch_equiv.c is for tracking how variables are the same
20 *
21 * if (a == b) {
22 * Or
23 * x = y;
24 *
25 * When a variable gets modified all the old relationships are
26 * deleted. remove_equiv(expr);
27 *
28 */
29
30 #include "smatch.h"
31 #include "smatch_slist.h"
32 #include "smatch_extra.h"
33
34 ALLOCATOR(relation, "related variables");
35
36 static struct relation *alloc_relation(const char *name, struct symbol *sym)
37 {
38 struct relation *tmp;
39
40 tmp = __alloc_relation(0);
41 tmp->name = alloc_string(name);
42 tmp->sym = sym;
43 return tmp;
44 }
45
46 struct related_list *clone_related_list(struct related_list *related)
47 {
48 struct relation *rel;
49 struct related_list *to_list = NULL;
50
51 FOR_EACH_PTR(related, rel) {
52 add_ptr_list(&to_list, rel);
53 } END_FOR_EACH_PTR(rel);
54
55 return to_list;
56 }
57
58 static int cmp_relation(struct relation *a, struct relation *b)
59 {
60 int ret;
61
62 if (a == b)
63 return 0;
64
65 if (a->sym > b->sym)
66 return -1;
67 if (a->sym < b->sym)
68 return 1;
69
70 ret = strcmp(a->name, b->name);
71 if (ret)
72 return ret;
73
74 return 0;
75 }
76
77 struct related_list *get_shared_relations(struct related_list *one,
78 struct related_list *two)
79 {
80 struct related_list *ret = NULL;
81 struct relation *one_rel;
82 struct relation *two_rel;
83
84 PREPARE_PTR_LIST(one, one_rel);
85 PREPARE_PTR_LIST(two, two_rel);
86 for (;;) {
87 if (!one_rel || !two_rel)
88 break;
89 if (cmp_relation(one_rel, two_rel) < 0) {
90 NEXT_PTR_LIST(one_rel);
91 } else if (cmp_relation(one_rel, two_rel) == 0) {
92 add_ptr_list(&ret, one_rel);
93 NEXT_PTR_LIST(one_rel);
94 NEXT_PTR_LIST(two_rel);
95 } else {
96 NEXT_PTR_LIST(two_rel);
97 }
98 }
99 FINISH_PTR_LIST(two_rel);
100 FINISH_PTR_LIST(one_rel);
101
102 return ret;
103 }
104
105 static void add_related(struct related_list **rlist, const char *name, struct symbol *sym)
106 {
107 struct relation *rel;
108 struct relation *new;
109 struct relation tmp = {
110 .name = (char *)name,
111 .sym = sym
112 };
113
114 FOR_EACH_PTR(*rlist, rel) {
115 if (cmp_relation(rel, &tmp) < 0)
116 continue;
117 if (cmp_relation(rel, &tmp) == 0)
118 return;
119 new = alloc_relation(name, sym);
120 INSERT_CURRENT(new, rel);
121 return;
122 } END_FOR_EACH_PTR(rel);
123 new = alloc_relation(name, sym);
124 add_ptr_list(rlist, new);
125 }
126
127 static struct related_list *del_related(struct smatch_state *state, const char *name, struct symbol *sym)
128 {
129 struct relation *tmp;
130 struct relation remove = {
131 .name = (char *)name,
132 .sym = sym,
133 };
134 struct related_list *ret = NULL;
135
136 FOR_EACH_PTR(estate_related(state), tmp) {
137 if (cmp_relation(tmp, &remove) != 0)
138 add_ptr_list(&ret, tmp);
139 } END_FOR_EACH_PTR(tmp);
140
141 return ret;
142 }
143
144 void remove_from_equiv(const char *name, struct symbol *sym)
145 {
146 struct sm_state *orig_sm;
147 struct relation *rel;
148 struct smatch_state *state;
149 struct related_list *to_update;
150
151 // FIXME: is this the right permanent solution. Perhaps it is, I guess.
152 if (in_fake_env)
153 return;
154 orig_sm = get_sm_state(SMATCH_EXTRA, name, sym);
155 if (!orig_sm || !get_dinfo(orig_sm->state)->related)
156 return;
157
158 state = clone_estate(orig_sm->state);
159 to_update = del_related(state, name, sym);
160
161 FOR_EACH_PTR(to_update, rel) {
162 struct sm_state *old_sm, *new_sm;
163
164 old_sm = get_sm_state(SMATCH_EXTRA, rel->name, rel->sym);
165 if (!old_sm)
166 continue;
167
168 new_sm = clone_sm(old_sm);
169 get_dinfo(new_sm->state)->related = to_update;
170 __set_sm(new_sm);
171 } END_FOR_EACH_PTR(rel);
172 }
173
174 void set_related(struct smatch_state *estate, struct related_list *rlist)
175 {
176 if (!estate_related(estate) && !rlist)
177 return;
178 get_dinfo(estate)->related = rlist;
179 }
180
181 /*
182 * set_equiv() is only used for assignments where we set one variable
183 * equal to the other. a = b;. It's not used for if conditions where
184 * a == b.
185 */
186 void set_equiv(struct expression *left, struct expression *right)
187 {
188 struct sm_state *right_sm, *left_sm, *other_sm;
189 struct relation *rel;
190 char *left_name;
191 struct symbol *left_sym;
192 struct related_list *rlist;
193 char *other_name;
194 struct symbol *other_sym;
195
196 if (in_fake_env)
197 return;
198 left_name = expr_to_var_sym(left, &left_sym);
199 if (!left_name || !left_sym)
200 goto free;
201
202 other_name = get_other_name_sym(left_name, left_sym, &other_sym);
203
204 right_sm = get_sm_state_expr(SMATCH_EXTRA, right);
205 if (!right_sm) {
206 struct range_list *rl;
207
208 if (!get_implied_rl(right, &rl))
209 rl = alloc_whole_rl(get_type(right));
210 right_sm = set_state_expr(SMATCH_EXTRA, right, alloc_estate_rl(rl));
211 }
212 if (!right_sm)
213 goto free;
214
215 /* This block is because we want to preserve the implications. */
216 left_sm = clone_sm(right_sm);
217 left_sm->name = alloc_string(left_name);
218 left_sm->sym = left_sym;
219 left_sm->state = clone_estate_cast(get_type(left), right_sm->state);
220 /* FIXME: The expression we're passing is wrong */
221 set_extra_mod_helper(left_name, left_sym, left, left_sm->state);
222 __set_sm(left_sm);
223
224 if (other_name && other_sym) {
225 other_sm = clone_sm(right_sm);
226 other_sm->name = alloc_string(other_name);
227 other_sm->sym = other_sym;
228 other_sm->state = clone_estate_cast(get_type(left), left_sm->state);
229 set_extra_mod_helper(other_name, other_sym, NULL, other_sm->state);
230 __set_sm(other_sm);
231 }
232
233 rlist = clone_related_list(estate_related(right_sm->state));
234 add_related(&rlist, right_sm->name, right_sm->sym);
235 add_related(&rlist, left_name, left_sym);
236 if (other_name && other_sym)
237 add_related(&rlist, other_name, other_sym);
238
239 FOR_EACH_PTR(rlist, rel) {
240 struct sm_state *old_sm, *new_sm;
241
242 old_sm = get_sm_state(SMATCH_EXTRA, rel->name, rel->sym);
243 if (!old_sm) /* shouldn't happen */
244 continue;
245 new_sm = clone_sm(old_sm);
246 new_sm->state = clone_estate(old_sm->state);
247 get_dinfo(new_sm->state)->related = rlist;
248 __set_sm(new_sm);
249 } END_FOR_EACH_PTR(rel);
250 free:
251 free_string(left_name);
252 }
253
254 void set_equiv_state_expr(int id, struct expression *expr, struct smatch_state *state)
255 {
256 struct relation *rel;
257 struct smatch_state *estate;
258
259 estate = get_state_expr(SMATCH_EXTRA, expr);
260
261 if (!estate)
262 return;
263
264 FOR_EACH_PTR(get_dinfo(estate)->related, rel) {
265 set_state(id, rel->name, rel->sym, state);
266 } END_FOR_EACH_PTR(rel);
267 }
Static analysis for C