| blob | e1fab61bedabedc078d5fcf034e2c1aaffdcc651 |
1 /* Detect paths through the CFG which can never be executed in a conforming
2 program and isolate them.
4 Copyright (C) 2013-2018 Free Software Foundation, Inc.
6 This file is part of GCC.
8 GCC is free software; you can redistribute it and/or modify
9 it under the terms of the GNU General Public License as published by
10 the Free Software Foundation; either version 3, or (at your option)
11 any later version.
13 GCC is distributed in the hope that it will be useful,
14 but WITHOUT ANY WARRANTY; without even the implied warranty of
15 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
16 GNU General Public License for more details.
18 You should have received a copy of the GNU General Public License
19 along with GCC; see the file COPYING3. If not see
20 <http://www.gnu.org/licenses/>. */
44 /* Callback for walk_stmt_load_store_ops.
46 Return TRUE if OP will dereference the tree stored in DATA, FALSE
47 otherwise.
49 This routine only makes a superficial check for a dereference. Thus,
50 it must only be used if it is safe to return a false negative. */
51 static bool
53 {
56 {
61 }
63 }
65 /* Insert a trap after SI and split the block after the trap. */
67 static void
69 {
70 /* We want the NULL pointer dereference to actually occur so that
71 code that wishes to catch the signal can do so.
73 If the dereference is a load, then there's nothing to do as the
74 LHS will be a throw-away SSA_NAME and the RHS is the NULL dereference.
76 If the dereference is a store and we can easily transform the RHS,
77 then simplify the RHS to enable more DCE. Note that we require the
78 statement to be a GIMPLE_ASSIGN which filters out calls on the RHS. */
83 {
84 /* We just need to turn the RHS into zero converted to the proper
85 type. */
90 }
92 gcall *new_stmt
97 /* If we had a NULL pointer dereference, then we want to insert the
98 __builtin_trap after the statement, for the other cases we want
99 to insert before the statement. */
101 check_loadstore,
102 check_loadstore))
103 {
106 {
109 }
110 }
111 else
116 }
118 /* BB when reached via incoming edge E will exhibit undefined behavior
119 at STMT. Isolate and optimize the path which exhibits undefined
120 behavior.
122 Isolation is simple. Duplicate BB and redirect E to BB'.
124 Optimization is simple as well. Replace STMT in BB' with an
125 unconditional trap and remove all outgoing edges from BB'.
127 If RET_ZERO, do not trap, only return NULL.
129 DUPLICATE is a pre-existing duplicate, use it as BB' if it exists.
131 Return BB'. */
133 basic_block
136 {
138 edge_iterator ei;
139 edge e2;
145 {
148 }
151 /* First duplicate BB if we have not done so already and remove all
152 the duplicate's outgoing edges as duplicate is going to unconditionally
153 trap. Removing the outgoing edges is both an optimization and ensures
154 we don't need to do any PHI node updates. */
156 {
162 }
165 /* Complete the isolation step by redirecting E to reach DUPLICATE. */
168 {
171 /* Update profile only when redirection is really processed. */
173 }
175 /* There may be more than one statement in DUPLICATE which exhibits
176 undefined behavior. Ultimately we want the first such statement in
177 DUPLCIATE so that we're able to delete as much code as possible.
179 So each time we discover undefined behavior in DUPLICATE, search for
180 the statement which triggers undefined behavior. If found, then
181 transform the statement into a trap and delete everything after the
182 statement. If not found, then this particular instance was subsumed by
183 an earlier instance of undefined behavior and there's nothing to do.
185 This is made more complicated by the fact that we have STMT, which is in
186 BB rather than in DUPLICATE. So we set up two iterators, one for each
187 block and walk forward looking for STMT in BB, advancing each iterator at
188 each step.
190 When we find STMT the second iterator should point to STMT's equivalent in
191 duplicate. If DUPLICATE ends before STMT is found in BB, then there's
192 nothing to do.
194 Ignore labels and debug statements. */
198 {
201 }
203 /* This would be an indicator that we never found STMT in BB, which should
204 never happen. */
207 /* If we did not run to the end of DUPLICATE, then SI points to STMT and
208 SI2 points to the duplicate of STMT in DUPLICATE. Insert a trap
209 before SI2 and remove SI2 and all trailing statements. */
211 {
213 {
218 }
219 else
221 }
224 }
226 /* Return TRUE if STMT is a div/mod operation using DIVISOR as the divisor.
227 FALSE otherwise. */
229 static bool
231 {
232 /* Only assignments matter. */
236 /* Check for every DIV/MOD expression. */
247 {
248 /* Pointer equality is fine when DIVISOR is an SSA_NAME, but
249 not sufficient for constants which may have different types. */
252 }
254 }
256 /* NAME is an SSA_NAME that we have already determined has the value 0 or NULL.
258 Return TRUE if USE_STMT uses NAME in a way where a 0 or NULL value results
259 in undefined behavior, FALSE otherwise
261 LOC is used for issuing diagnostics. This case represents potential
262 undefined behavior exposed by path splitting and that's reflected in
263 the diagnostic. */
265 bool
267 {
268 /* If we are working with a non pointer type, then see
269 if this use is a DIV/MOD operation using NAME as the
270 divisor. */
272 {
276 }
278 /* NAME is a pointer, so see if it's used in a context where it must
279 be non-NULL. */
280 bool by_dereference
285 {
288 {
293 }
294 else
295 {
298 }
300 }
302 }
304 /* Return TRUE if USE_STMT uses 0 or NULL in a context which results in
305 undefined behavior, FALSE otherwise.
307 These cases are explicit in the IL. */
309 bool
311 {
316 /* By passing null_pointer_node, we can use the
317 infer_nonnull_range functions to detect explicit NULL
318 pointer dereferences and other uses where a non-NULL
319 value is required. */
321 bool by_dereference
325 {
327 {
333 }
334 else
335 {
338 }
340 }
342 }
344 /* Look for PHI nodes which feed statements in the same block where
345 the value of the PHI node implies the statement is erroneous.
347 For example, a NULL PHI arg value which then feeds a pointer
348 dereference.
350 When found isolate and optimize the path associated with the PHI
351 argument feeding the erroneous statement. */
352 static void
354 {
355 basic_block bb;
358 {
359 gphi_iterator si;
361 /* Out of an abundance of caution, do not isolate paths to a
362 block where the block has any abnormal outgoing edges.
364 We might be able to relax this in the future. We have to detect
365 when we have to split the block with the NULL dereference and
366 the trap we insert. We have to preserve abnormal edges out
367 of the isolated block which in turn means updating PHIs at
368 the targets of those abnormal outgoing edges. */
373 /* If BB has an edge to itself, then duplication of BB below
374 could result in reallocation of BB's PHI nodes. If that happens
375 then the loop below over the PHIs would use the old PHI and
376 thus invalid information. We don't have a good way to know
377 if a PHI has been reallocated, so just avoid isolation in
378 this case. */
382 /* First look for a PHI which sets a pointer to NULL and which
383 is then dereferenced within BB. This is somewhat overly
384 conservative, but probably catches most of the interesting
385 cases. */
387 {
391 /* PHI produces a pointer result. See if any of the PHI's
392 arguments are NULL.
394 When we remove an edge, we want to reprocess the current
395 index, hence the ugly way we update I for each iteration. */
400 {
403 imm_use_iterator iter;
409 {
413 {
415 {
416 greturn *return_stmt
424 {
425 auto_diagnostic_group d;
427 OPT_Wreturn_local_addr,
428 "function may return address "
432 }
435 {
439 /* When we remove an incoming edge, we need to
440 reprocess the Ith element. */
443 }
444 }
445 }
446 }
453 /* We've got a NULL PHI argument. Now see if the
454 PHI's result is dereferenced within BB. */
456 {
457 /* We only care about uses in BB. Catching cases in
458 in other blocks would require more complex path
459 isolation code. */
468 {
472 /* When we remove an incoming edge, we need to
473 reprocess the Ith element. */
476 }
477 }
478 }
479 }
480 }
481 }
483 /* Look for statements which exhibit erroneous behavior. For example
484 a NULL pointer dereference.
486 When found, optimize the block containing the erroneous behavior. */
487 static void
489 {
490 basic_block bb;
493 {
494 gimple_stmt_iterator si;
496 /* Out of an abundance of caution, do not isolate paths to a
497 block where the block has any abnormal outgoing edges.
499 We might be able to relax this in the future. We have to detect
500 when we have to split the block with the NULL dereference and
501 the trap we insert. We have to preserve abnormal edges out
502 of the isolated block which in turn means updating PHIs at
503 the targets of those abnormal outgoing edges. */
507 /* Now look at the statements in the block and see if any of
508 them explicitly dereference a NULL pointer. This happens
509 because of jump threading and constant propagation. */
511 {
515 {
519 /* Ignore any more operands on this statement and
520 continue the statement iterator (which should
521 terminate its loop immediately. */
524 }
526 /* Detect returning the address of a local variable. This only
527 becomes undefined behavior if the result is used, so we do not
528 insert a trap and only return NULL instead. */
530 {
533 {
537 {
538 /* We only need it for this particular case. */
546 else
549 {
550 auto_diagnostic_group d;
555 }
559 }
560 }
561 }
562 }
563 }
564 }
566 /* Search the function for statements which, if executed, would cause
567 the program to fault such as a dereference of a NULL pointer.
569 Such a program can't be valid if such a statement was to execute
570 according to ISO standards.
572 We detect explicit NULL pointer dereferences as well as those implied
573 by a PHI argument having a NULL value which unconditionally flows into
574 a dereference in the same block as the PHI.
576 In the former case we replace the offending statement with an
577 unconditional trap and eliminate the outgoing edges from the statement's
578 basic block. This may expose secondary optimization opportunities.
580 In the latter case, we isolate the path(s) with the NULL PHI
581 feeding the dereference. We can then replace the offending statement
582 and eliminate the outgoing edges in the duplicate. Again, this may
583 expose secondary optimization opportunities.
585 A warning for both cases may be advisable as well.
587 Other statically detectable violations of the ISO standard could be
588 handled in a similar way, such as out-of-bounds array indexing. */
590 static unsigned int
592 {
595 /* Search all the blocks for edges which, if traversed, will
596 result in undefined behavior. */
599 /* First handle cases where traversal of a particular edge
600 triggers undefined behavior. These cases require creating
601 duplicate blocks and thus new SSA_NAMEs.
603 We want that process complete prior to the phase where we start
604 removing edges from the CFG. Edge removal may ultimately result in
605 removal of PHI nodes and thus releasing SSA_NAMEs back to the
606 name manager.
608 If the two processes run in parallel we could release an SSA_NAME
609 back to the manager but we could still have dangling references
610 to the released SSA_NAME in unreachable blocks.
611 that any released names not have dangling references in the IL. */
617 /* We scramble the CFG and loop structures a bit, clean up
618 appropriately. We really should incrementally update the
619 loop structures, in theory it shouldn't be that hard. */
622 {
626 }
628 }
632 {
642 };
645 {
649 {}
651 /* opt_pass methods: */
654 {
655 /* If we do not have a suitable builtin function for the trap statement,
656 then do not perform the optimization. */
660 }
663 {
665 }
668 }
670 gimple_opt_pass *
672 {
674 }