1 /*
2   This file is part of Valgrind, a dynamic binary instrumentation
3   framework.
4 
5   Copyright (C) 2008-2008 Google Inc
6      opensource@google.com
7 
8   This program is free software; you can redistribute it and/or
9   modify it under the terms of the GNU General Public License as
10   published by the Free Software Foundation; either version 2 of the
11   License, or (at your option) any later version.
12 
13   This program is distributed in the hope that it will be useful, but
14   WITHOUT ANY WARRANTY; without even the implied warranty of
15   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
16   General Public License for more details.
17 
18   You should have received a copy of the GNU General Public License
19   along with this program; if not, write to the Free Software
20   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA
21   02111-1307, USA.
22 
23   The GNU General Public License is contained in the file COPYING.
24 */
25 
26 // Author: Konstantin Serebryany <opensource@google.com>
27 //
28 // This file contains a set of unit tests for a data race detection tool.
29 //
30 //
31 //
32 // This test can be compiled with pthreads (default) or
33 // with any other library that supports threads, locks, cond vars, etc.
34 //
35 // To compile with pthreads:
36 //   g++  racecheck_unittest.cc dynamic_annotations.cc
37 //        -lpthread -g -DDYNAMIC_ANNOTATIONS=1
38 //
39 // To compile with different library:
40 //   1. cp thread_wrappers_pthread.h thread_wrappers_yourlib.h
41 //   2. edit thread_wrappers_yourlib.h
42 //   3. add '-DTHREAD_WRAPPERS="thread_wrappers_yourlib.h"' to your compilation.
43 //
44 //
45 
46 // This test must not include any other file specific to threading library,
47 // everything should be inside THREAD_WRAPPERS.
48 #ifndef THREAD_WRAPPERS
49 # define THREAD_WRAPPERS "thread_wrappers_pthread.h"
50 #endif
51 #include THREAD_WRAPPERS
52 
53 #ifndef NEEDS_SEPERATE_RW_LOCK
54 #define RWLock Mutex // Mutex does work as an rw-lock.
55 #define WriterLockScoped MutexLock
56 #define ReaderLockScoped ReaderMutexLock
57 #endif // !NEEDS_SEPERATE_RW_LOCK
58 
59 
60 // Helgrind memory usage testing stuff
61 // If not present in dynamic_annotations.h/.cc - ignore
62 #ifndef ANNOTATE_RESET_STATS
63 #define ANNOTATE_RESET_STATS() do { } while(0)
64 #endif
65 #ifndef ANNOTATE_PRINT_STATS
66 #define ANNOTATE_PRINT_STATS() do { } while(0)
67 #endif
68 #ifndef ANNOTATE_PRINT_MEMORY_USAGE
69 #define ANNOTATE_PRINT_MEMORY_USAGE(a) do { } while(0)
70 #endif
71 //
72 
73 // A function that allows to suppress gcc's warnings about
74 // unused return values in a portable way.
75 template <typename T>
IGNORE_RETURN_VALUE(T v)76 static inline void IGNORE_RETURN_VALUE(T v)
77 { }
78 
79 #include <vector>
80 #include <string>
81 #include <map>
82 #include <queue>
83 #include <algorithm>
84 #include <cstring>      // strlen(), index(), rindex()
85 #include <ctime>
86 #include <sys/time.h>
87 #include <sys/types.h>
88 #include <sys/stat.h>
89 #include <fcntl.h>
90 #include <sys/mman.h>  // mmap
91 #include <errno.h>
92 #include <stdint.h>    // uintptr_t
93 #include <stdlib.h>
94 #include <dirent.h>
95 
96 #ifndef VGO_darwin
97 #include <malloc.h>
98 #endif
99 
100 #ifdef VGO_solaris
101 #include <strings.h> // index(), rindex()
102 #endif
103 
104 // The tests are
105 // - Stability tests (marked STAB)
106 // - Performance tests (marked PERF)
107 // - Feature tests
108 //   - TN (true negative) : no race exists and the tool is silent.
109 //   - TP (true positive) : a race exists and reported.
110 //   - FN (false negative): a race exists but not reported.
111 //   - FP (false positive): no race exists but the tool reports it.
112 //
113 // The feature tests are marked according to the behavior of helgrind 3.3.0.
114 //
115 // TP and FP tests are annotated with ANNOTATE_EXPECT_RACE,
116 // so, no error reports should be seen when running under helgrind.
117 //
118 // When some of the FP cases are fixed in helgrind we'll need
119 // to update this test.
120 //
121 // Each test resides in its own namespace.
122 // Namespaces are named test01, test02, ...
123 // Please, *DO NOT* change the logic of existing tests nor rename them.
124 // Create a new test instead.
125 //
126 // Some tests use sleep()/usleep().
127 // This is not a synchronization, but a simple way to trigger
128 // some specific behaviour of the race detector's scheduler.
129 
130 // Globals and utilities used by several tests. {{{1
131 CondVar CV;
132 int     COND = 0;
133 
134 
135 typedef void (*void_func_void_t)(void);
136 enum TEST_FLAG {
137   FEATURE           = 1 << 0,
138   STABILITY         = 1 << 1,
139   PERFORMANCE       = 1 << 2,
140   EXCLUDE_FROM_ALL  = 1 << 3,
141   NEEDS_ANNOTATIONS = 1 << 4,
142   RACE_DEMO         = 1 << 5,
143   MEMORY_USAGE      = 1 << 6,
144   PRINT_STATS       = 1 << 7
145 };
146 
147 // Put everything into stderr.
148 Mutex printf_mu;
149 #define printf(args...) \
150     do{ \
151       printf_mu.Lock();\
152       fprintf(stderr, args);\
153       printf_mu.Unlock(); \
154     }while(0)
155 
GetTimeInMs()156 long GetTimeInMs() {
157    struct timeval tv;
158    gettimeofday(&tv, NULL);
159    return (tv.tv_sec * 1000L) + (tv.tv_usec / 1000L);
160 }
161 
162 struct Test{
163   void_func_void_t f_;
164   int flags_;
TestTest165   Test(void_func_void_t f, int flags)
166     : f_(f)
167     , flags_(flags)
168   {}
TestTest169   Test() : f_(0), flags_(0) {}
RunTest170   void Run() {
171      ANNOTATE_RESET_STATS();
172      if (flags_ & PERFORMANCE) {
173         long start = GetTimeInMs();
174         f_();
175         long end = GetTimeInMs();
176         printf ("Time: %4ldms\n", end-start);
177      } else
178         f_();
179      if (flags_ & PRINT_STATS)
180         ANNOTATE_PRINT_STATS();
181      if (flags_ & MEMORY_USAGE)
182         ANNOTATE_PRINT_MEMORY_USAGE(0);
183   }
184 };
185 std::map<int, Test> TheMapOfTests;
186 
187 #define NOINLINE __attribute__ ((noinline))
AnnotateSetVerbosity(const char *,int,int)188 extern "C" void NOINLINE AnnotateSetVerbosity(const char *, int, int) {};
189 
190 
191 struct TestAdder {
TestAdderTestAdder192   TestAdder(void_func_void_t f, int id, int flags = FEATURE) {
193     // AnnotateSetVerbosity(__FILE__, __LINE__, 0);
194     CHECK(TheMapOfTests.count(id) == 0);
195     TheMapOfTests[id] = Test(f, flags);
196   }
197 };
198 
199 #define REGISTER_TEST(f, id)         TestAdder add_test_##id (f, id);
200 #define REGISTER_TEST2(f, id, flags) TestAdder add_test_##id (f, id, flags);
201 
ArgIsOne(int * arg)202 static bool ArgIsOne(int *arg) { return *arg == 1; };
ArgIsZero(int * arg)203 static bool ArgIsZero(int *arg) { return *arg == 0; };
ArgIsTrue(bool * arg)204 static bool ArgIsTrue(bool *arg) { return *arg == true; };
205 
206 // Call ANNOTATE_EXPECT_RACE only if 'machine' env variable is defined.
207 // Useful to test against several different machines.
208 // Supported machines so far:
209 //   MSM_HYBRID1             -- aka MSMProp1
210 //   MSM_HYBRID1_INIT_STATE  -- aka MSMProp1 with --initialization-state=yes
211 //   MSM_THREAD_SANITIZER    -- ThreadSanitizer's state machine
212 #define ANNOTATE_EXPECT_RACE_FOR_MACHINE(mem, descr, machine) \
213     while(getenv(machine)) {\
214       ANNOTATE_EXPECT_RACE(mem, descr); \
215       break;\
216     }\
217 
218 #define ANNOTATE_EXPECT_RACE_FOR_TSAN(mem, descr) \
219     ANNOTATE_EXPECT_RACE_FOR_MACHINE(mem, descr, "MSM_THREAD_SANITIZER")
220 
Tsan_PureHappensBefore()221 inline bool Tsan_PureHappensBefore() {
222   return true;
223 }
224 
Tsan_FastMode()225 inline bool Tsan_FastMode()           {
226   return getenv("TSAN_FAST_MODE") != NULL;
227 }
228 
229 // Initialize *(mem) to 0 if Tsan_FastMode.
230 #define FAST_MODE_INIT(mem) do { if (Tsan_FastMode()) { *(mem) = 0; } } while(0)
231 
232 #ifndef MAIN_INIT_ACTION
233 #define MAIN_INIT_ACTION
234 #endif
235 
236 
237 
main(int argc,char ** argv)238 int main(int argc, char** argv) { // {{{1
239   MAIN_INIT_ACTION;
240   printf("FLAGS [phb=%i, fm=%i]\n", Tsan_PureHappensBefore(), Tsan_FastMode());
241   if (argc == 2 && !strcmp(argv[1], "benchmark")) {
242      for (std::map<int,Test>::iterator it = TheMapOfTests.begin();
243          it != TheMapOfTests.end(); ++it) {
244        if(!(it->second.flags_ & PERFORMANCE)) continue;
245        it->second.Run();
246      }
247   } else if (argc == 2 && !strcmp(argv[1], "demo")) {
248      for (std::map<int,Test>::iterator it = TheMapOfTests.begin();
249          it != TheMapOfTests.end();  ++it) {
250        if(!(it->second.flags_ & RACE_DEMO)) continue;
251        it->second.Run();
252      }
253   } else if (argc > 1) {
254     // the tests are listed in command line flags
255     for (int i = 1; i < argc; i++) {
256       int f_num = atoi(argv[i]);
257       CHECK(TheMapOfTests.count(f_num));
258       TheMapOfTests[f_num].Run();
259     }
260   } else {
261     bool run_tests_with_annotations = false;
262     if (getenv("DRT_ALLOW_ANNOTATIONS")) {
263       run_tests_with_annotations = true;
264     }
265     for (std::map<int,Test>::iterator it = TheMapOfTests.begin();
266         it != TheMapOfTests.end();
267         ++it) {
268       if(it->second.flags_ & EXCLUDE_FROM_ALL) continue;
269       if(it->second.flags_ & RACE_DEMO) continue;
270       if((it->second.flags_ & NEEDS_ANNOTATIONS)
271          && run_tests_with_annotations == false) continue;
272       it->second.Run();
273     }
274   }
275 }
276 
277 #ifdef THREAD_WRAPPERS_PTHREAD_H
278 #endif
279 
280 
281 // An array of threads. Create/start/join all elements at once. {{{1
282 class MyThreadArray {
283  public:
284   static const int kSize = 5;
285   typedef void (*F) (void);
MyThreadArray(F f1,F f2=NULL,F f3=NULL,F f4=NULL,F f5=NULL)286   MyThreadArray(F f1, F f2 = NULL, F f3 = NULL, F f4 = NULL, F f5 = NULL) {
287     ar_[0] = new MyThread(f1);
288     ar_[1] = f2 ? new MyThread(f2) : NULL;
289     ar_[2] = f3 ? new MyThread(f3) : NULL;
290     ar_[3] = f4 ? new MyThread(f4) : NULL;
291     ar_[4] = f5 ? new MyThread(f5) : NULL;
292   }
Start()293   void Start() {
294     for(int i = 0; i < kSize; i++) {
295       if(ar_[i]) {
296         ar_[i]->Start();
297         usleep(10);
298       }
299     }
300   }
301 
Join()302   void Join() {
303     for(int i = 0; i < kSize; i++) {
304       if(ar_[i]) {
305         ar_[i]->Join();
306       }
307     }
308   }
309 
~MyThreadArray()310   ~MyThreadArray() {
311     for(int i = 0; i < kSize; i++) {
312       delete ar_[i];
313     }
314   }
315  private:
316   MyThread *ar_[kSize];
317 };
318 
319 
320 
321 // test00: {{{1
322 namespace test00 {
323 int     GLOB = 0;
Run()324 void Run() {
325   printf("test00: negative\n");
326   printf("\tGLOB=%d\n", GLOB);
327 }
328 REGISTER_TEST(Run, 00)
329 }  // namespace test00
330 
331 
332 // test01: TP. Simple race (write vs write). {{{1
333 namespace test01 {
334 int     GLOB = 0;
Worker()335 void Worker() {
336   GLOB = 1;
337 }
338 
Parent()339 void Parent() {
340   MyThread t(Worker);
341   t.Start();
342   const timespec delay = { 0, 100 * 1000 * 1000 };
343   nanosleep(&delay, 0);
344   GLOB = 2;
345   t.Join();
346 }
Run()347 void Run() {
348   FAST_MODE_INIT(&GLOB);
349   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test01. TP.");
350   ANNOTATE_TRACE_MEMORY(&GLOB);
351   printf("test01: positive\n");
352   Parent();
353   const int tmp = GLOB;
354   printf("\tGLOB=%d\n", tmp);
355 }
356 REGISTER_TEST(Run, 1);
357 }  // namespace test01
358 
359 
360 // test02: TN. Synchronization via CondVar. {{{1
361 namespace test02 {
362 int     GLOB = 0;
363 // Two write accesses to GLOB are synchronized because
364 // the pair of CV.Signal() and CV.Wait() establish happens-before relation.
365 //
366 // Waiter:                      Waker:
367 // 1. COND = 0
368 // 2. Start(Waker)
369 // 3. MU.Lock()                 a. write(GLOB)
370 //                              b. MU.Lock()
371 //                              c. COND = 1
372 //                         /--- d. CV.Signal()
373 //  4. while(COND)        /     e. MU.Unlock()
374 //       CV.Wait(MU) <---/
375 //  5. MU.Unlock()
376 //  6. write(GLOB)
377 Mutex   MU;
378 
Waker()379 void Waker() {
380   usleep(100000);  // Make sure the waiter blocks.
381   GLOB = 1;
382 
383   MU.Lock();
384   COND = 1;
385   CV.Signal();
386   MU.Unlock();
387 }
388 
Waiter()389 void Waiter() {
390   ThreadPool pool(1);
391   pool.StartWorkers();
392   COND = 0;
393   pool.Add(NewCallback(Waker));
394   MU.Lock();
395   while(COND != 1)
396     CV.Wait(&MU);
397   MU.Unlock();
398   GLOB = 2;
399 }
Run()400 void Run() {
401   printf("test02: negative\n");
402   Waiter();
403   printf("\tGLOB=%d\n", GLOB);
404 }
405 REGISTER_TEST(Run, 2);
406 }  // namespace test02
407 
408 
409 // test03: TN. Synchronization via LockWhen, signaller gets there first. {{{1
410 namespace test03 {
411 int     GLOB = 0;
412 // Two write accesses to GLOB are synchronized via conditional critical section.
413 // Note that LockWhen() happens first (we use sleep(1) to make sure)!
414 //
415 // Waiter:                           Waker:
416 // 1. COND = 0
417 // 2. Start(Waker)
418 //                                   a. write(GLOB)
419 //                                   b. MU.Lock()
420 //                                   c. COND = 1
421 //                              /--- d. MU.Unlock()
422 // 3. MU.LockWhen(COND==1) <---/
423 // 4. MU.Unlock()
424 // 5. write(GLOB)
425 Mutex   MU;
426 
Waker()427 void Waker() {
428   usleep(100000);  // Make sure the waiter blocks.
429   GLOB = 1;
430 
431   MU.Lock();
432   COND = 1; // We are done! Tell the Waiter.
433   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
434 }
Waiter()435 void Waiter() {
436   ThreadPool pool(1);
437   pool.StartWorkers();
438   COND = 0;
439   pool.Add(NewCallback(Waker));
440   MU.LockWhen(Condition(&ArgIsOne, &COND));  // calls ANNOTATE_CONDVAR_WAIT
441   MU.Unlock();  // Waker is done!
442 
443   GLOB = 2;
444 }
Run()445 void Run() {
446   printf("test03: negative\n");
447   Waiter();
448   printf("\tGLOB=%d\n", GLOB);
449 }
450 REGISTER_TEST2(Run, 3, FEATURE|NEEDS_ANNOTATIONS);
451 }  // namespace test03
452 
453 // test04: TN. Synchronization via PCQ. {{{1
454 namespace test04 {
455 int     GLOB = 0;
456 ProducerConsumerQueue Q(INT_MAX);
457 // Two write accesses to GLOB are separated by PCQ Put/Get.
458 //
459 // Putter:                        Getter:
460 // 1. write(GLOB)
461 // 2. Q.Put() ---------\          .
462 //                      \-------> a. Q.Get()
463 //                                b. write(GLOB)
464 
465 
Putter()466 void Putter() {
467   GLOB = 1;
468   Q.Put(NULL);
469 }
470 
Getter()471 void Getter() {
472   Q.Get();
473   GLOB = 2;
474 }
475 
Run()476 void Run() {
477   printf("test04: negative\n");
478   MyThreadArray t(Putter, Getter);
479   t.Start();
480   t.Join();
481   printf("\tGLOB=%d\n", GLOB);
482 }
483 REGISTER_TEST(Run, 4);
484 }  // namespace test04
485 
486 
487 // test05: FP. Synchronization via CondVar, but waiter does not block. {{{1
488 // Since CondVar::Wait() is not called, we get a false positive.
489 namespace test05 {
490 int     GLOB = 0;
491 // Two write accesses to GLOB are synchronized via CondVar.
492 // But race detector can not see it.
493 // See this for details:
494 // http://www.valgrind.org/docs/manual/hg-manual.html#hg-manual.effective-use.
495 //
496 // Waiter:                                  Waker:
497 // 1. COND = 0
498 // 2. Start(Waker)
499 // 3. MU.Lock()                             a. write(GLOB)
500 //                                          b. MU.Lock()
501 //                                          c. COND = 1
502 //                                          d. CV.Signal()
503 //  4. while(COND)                          e. MU.Unlock()
504 //       CV.Wait(MU) <<< not called
505 //  5. MU.Unlock()
506 //  6. write(GLOB)
507 Mutex   MU;
508 
Waker()509 void Waker() {
510   GLOB = 1;
511   MU.Lock();
512   COND = 1;
513   CV.Signal();
514   MU.Unlock();
515 }
516 
Waiter()517 void Waiter() {
518   ThreadPool pool(1);
519   pool.StartWorkers();
520   COND = 0;
521   pool.Add(NewCallback(Waker));
522   usleep(100000);  // Make sure the signaller gets first.
523   MU.Lock();
524   while(COND != 1)
525     CV.Wait(&MU);
526   MU.Unlock();
527   GLOB = 2;
528 }
Run()529 void Run() {
530   FAST_MODE_INIT(&GLOB);
531   if (!Tsan_PureHappensBefore())
532     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test05. FP. Unavoidable in hybrid scheme.");
533   printf("test05: unavoidable false positive\n");
534   Waiter();
535   printf("\tGLOB=%d\n", GLOB);
536 }
537 REGISTER_TEST(Run, 5);
538 }  // namespace test05
539 
540 
541 // test06: TN. Synchronization via CondVar, but Waker gets there first.  {{{1
542 namespace test06 {
543 int     GLOB = 0;
544 // Same as test05 but we annotated the Wait() loop.
545 //
546 // Waiter:                                            Waker:
547 // 1. COND = 0
548 // 2. Start(Waker)
549 // 3. MU.Lock()                                       a. write(GLOB)
550 //                                                    b. MU.Lock()
551 //                                                    c. COND = 1
552 //                                           /------- d. CV.Signal()
553 //  4. while(COND)                          /         e. MU.Unlock()
554 //       CV.Wait(MU) <<< not called        /
555 //  6. ANNOTATE_CONDVAR_WAIT(CV, MU) <----/
556 //  5. MU.Unlock()
557 //  6. write(GLOB)
558 
559 Mutex   MU;
560 
Waker()561 void Waker() {
562   GLOB = 1;
563   MU.Lock();
564   COND = 1;
565   CV.Signal();
566   MU.Unlock();
567 }
568 
Waiter()569 void Waiter() {
570   ThreadPool pool(1);
571   pool.StartWorkers();
572   COND = 0;
573   pool.Add(NewCallback(Waker));
574   usleep(100000);  // Make sure the signaller gets first.
575   MU.Lock();
576   while(COND != 1)
577     CV.Wait(&MU);
578   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
579 
580   MU.Unlock();
581   GLOB = 2;
582 }
Run()583 void Run() {
584   printf("test06: negative\n");
585   Waiter();
586   printf("\tGLOB=%d\n", GLOB);
587 }
588 REGISTER_TEST2(Run, 6, FEATURE|NEEDS_ANNOTATIONS);
589 }  // namespace test06
590 
591 
592 // test07: TN. Synchronization via LockWhen(), Signaller is observed first. {{{1
593 namespace test07 {
594 int     GLOB = 0;
595 bool    COND = 0;
596 // Two write accesses to GLOB are synchronized via conditional critical section.
597 // LockWhen() is observed after COND has been set (due to sleep).
598 // Unlock() calls ANNOTATE_CONDVAR_SIGNAL().
599 //
600 // Waiter:                           Signaller:
601 // 1. COND = 0
602 // 2. Start(Signaller)
603 //                                   a. write(GLOB)
604 //                                   b. MU.Lock()
605 //                                   c. COND = 1
606 //                              /--- d. MU.Unlock calls ANNOTATE_CONDVAR_SIGNAL
607 // 3. MU.LockWhen(COND==1) <---/
608 // 4. MU.Unlock()
609 // 5. write(GLOB)
610 
611 Mutex   MU;
Signaller()612 void Signaller() {
613   GLOB = 1;
614   MU.Lock();
615   COND = true; // We are done! Tell the Waiter.
616   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
617 }
Waiter()618 void Waiter() {
619   COND = false;
620   MyThread t(Signaller);
621   t.Start();
622   usleep(100000);  // Make sure the signaller gets there first.
623 
624   MU.LockWhen(Condition(&ArgIsTrue, &COND));  // calls ANNOTATE_CONDVAR_WAIT
625   MU.Unlock();  // Signaller is done!
626 
627   GLOB = 2; // If LockWhen didn't catch the signal, a race may be reported here.
628   t.Join();
629 }
Run()630 void Run() {
631   printf("test07: negative\n");
632   Waiter();
633   printf("\tGLOB=%d\n", GLOB);
634 }
635 REGISTER_TEST2(Run, 7, FEATURE|NEEDS_ANNOTATIONS);
636 }  // namespace test07
637 
638 // test08: TN. Synchronization via thread start/join. {{{1
639 namespace test08 {
640 int     GLOB = 0;
641 // Three accesses to GLOB are separated by thread start/join.
642 //
643 // Parent:                        Worker:
644 // 1. write(GLOB)
645 // 2. Start(Worker) ------------>
646 //                                a. write(GLOB)
647 // 3. Join(Worker) <------------
648 // 4. write(GLOB)
Worker()649 void Worker() {
650   GLOB = 2;
651 }
652 
Parent()653 void Parent() {
654   MyThread t(Worker);
655   GLOB = 1;
656   t.Start();
657   t.Join();
658   GLOB = 3;
659 }
Run()660 void Run() {
661   printf("test08: negative\n");
662   Parent();
663   printf("\tGLOB=%d\n", GLOB);
664 }
665 REGISTER_TEST(Run, 8);
666 }  // namespace test08
667 
668 
669 // test09: TP. Simple race (read vs write). {{{1
670 namespace test09 {
671 int     GLOB = 0;
672 // A simple data race between writer and reader.
673 // Write happens after read (enforced by sleep).
674 // Usually, easily detectable by a race detector.
Writer()675 void Writer() {
676   usleep(100000);
677   GLOB = 3;
678 }
Reader()679 void Reader() {
680   CHECK(GLOB != -777);
681 }
682 
Run()683 void Run() {
684   ANNOTATE_TRACE_MEMORY(&GLOB);
685   FAST_MODE_INIT(&GLOB);
686   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test09. TP.");
687   printf("test09: positive\n");
688   MyThreadArray t(Writer, Reader);
689   t.Start();
690   t.Join();
691   printf("\tGLOB=%d\n", GLOB);
692 }
693 REGISTER_TEST(Run, 9);
694 }  // namespace test09
695 
696 
697 // test10: FN. Simple race (write vs read). {{{1
698 namespace test10 {
699 int     GLOB = 0;
700 // A simple data race between writer and reader.
701 // Write happens before Read (enforced by sleep),
702 // otherwise this test is the same as test09.
703 //
704 // Writer:                    Reader:
705 // 1. write(GLOB)             a. sleep(long enough so that GLOB
706 //                                is most likely initialized by Writer)
707 //                            b. read(GLOB)
708 //
709 //
710 // Eraser algorithm does not detect the race here,
711 // see Section 2.2 of http://citeseer.ist.psu.edu/savage97eraser.html.
712 //
Writer()713 void Writer() {
714   GLOB = 3;
715 }
Reader()716 void Reader() {
717   usleep(100000);
718   CHECK(GLOB != -777);
719 }
720 
Run()721 void Run() {
722   FAST_MODE_INIT(&GLOB);
723   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test10. TP. FN in MSMHelgrind.");
724   printf("test10: positive\n");
725   MyThreadArray t(Writer, Reader);
726   t.Start();
727   t.Join();
728   printf("\tGLOB=%d\n", GLOB);
729 }
730 REGISTER_TEST(Run, 10);
731 }  // namespace test10
732 
733 
734 // test11: FP. Synchronization via CondVar, 2 workers. {{{1
735 // This test is properly synchronized, but currently (Dec 2007)
736 // helgrind reports a false positive.
737 //
738 // Parent:                              Worker1, Worker2:
739 // 1. Start(workers)                    a. read(GLOB)
740 // 2. MU.Lock()                         b. MU.Lock()
741 // 3. while(COND != 2)        /-------- c. CV.Signal()
742 //      CV.Wait(&MU) <-------/          d. MU.Unlock()
743 // 4. MU.Unlock()
744 // 5. write(GLOB)
745 //
746 namespace test11 {
747 int     GLOB = 0;
748 Mutex   MU;
Worker()749 void Worker() {
750   usleep(200000);
751   CHECK(GLOB != 777);
752 
753   MU.Lock();
754   COND++;
755   CV.Signal();
756   MU.Unlock();
757 }
758 
Parent()759 void Parent() {
760   COND = 0;
761 
762   MyThreadArray t(Worker, Worker);
763   t.Start();
764 
765   MU.Lock();
766   while(COND != 2) {
767     CV.Wait(&MU);
768   }
769   MU.Unlock();
770 
771   GLOB = 2;
772 
773   t.Join();
774 }
775 
Run()776 void Run() {
777 //  ANNOTATE_EXPECT_RACE(&GLOB, "test11. FP. Fixed by MSMProp1.");
778   printf("test11: negative\n");
779   Parent();
780   printf("\tGLOB=%d\n", GLOB);
781 }
782 REGISTER_TEST(Run, 11);
783 }  // namespace test11
784 
785 
786 // test12: FP. Synchronization via Mutex, then via PCQ. {{{1
787 namespace test12 {
788 int     GLOB = 0;
789 // This test is properly synchronized, but currently (Dec 2007)
790 // helgrind reports a false positive.
791 //
792 // First, we write to GLOB under MU, then we synchronize via PCQ,
793 // which is essentially a semaphore.
794 //
795 // Putter:                       Getter:
796 // 1. MU.Lock()                  a. MU.Lock()
797 // 2. write(GLOB) <---- MU ----> b. write(GLOB)
798 // 3. MU.Unlock()                c. MU.Unlock()
799 // 4. Q.Put()   ---------------> d. Q.Get()
800 //                               e. write(GLOB)
801 
802 ProducerConsumerQueue Q(INT_MAX);
803 Mutex   MU;
804 
Putter()805 void Putter() {
806   MU.Lock();
807   GLOB++;
808   MU.Unlock();
809 
810   Q.Put(NULL);
811 }
812 
Getter()813 void Getter() {
814   MU.Lock();
815   GLOB++;
816   MU.Unlock();
817 
818   Q.Get();
819   GLOB++;
820 }
821 
Run()822 void Run() {
823 //  ANNOTATE_EXPECT_RACE(&GLOB, "test12. FP. Fixed by MSMProp1.");
824   printf("test12: negative\n");
825   MyThreadArray t(Putter, Getter);
826   t.Start();
827   t.Join();
828   printf("\tGLOB=%d\n", GLOB);
829 }
830 REGISTER_TEST(Run, 12);
831 }  // namespace test12
832 
833 
834 // test13: FP. Synchronization via Mutex, then via LockWhen. {{{1
835 namespace test13 {
836 int     GLOB = 0;
837 // This test is essentially the same as test12, but uses LockWhen
838 // instead of PCQ.
839 //
840 // Waker:                                     Waiter:
841 // 1. MU.Lock()                               a. MU.Lock()
842 // 2. write(GLOB) <---------- MU ---------->  b. write(GLOB)
843 // 3. MU.Unlock()                             c. MU.Unlock()
844 // 4. MU.Lock()                               .
845 // 5. COND = 1                                .
846 // 6. ANNOTATE_CONDVAR_SIGNAL -------\        .
847 // 7. MU.Unlock()                     \       .
848 //                                     \----> d. MU.LockWhen(COND == 1)
849 //                                            e. MU.Unlock()
850 //                                            f. write(GLOB)
851 Mutex   MU;
852 
Waker()853 void Waker() {
854   MU.Lock();
855   GLOB++;
856   MU.Unlock();
857 
858   MU.Lock();
859   COND = 1;
860   ANNOTATE_CONDVAR_SIGNAL(&MU);
861   MU.Unlock();
862 }
863 
Waiter()864 void Waiter() {
865   MU.Lock();
866   GLOB++;
867   MU.Unlock();
868 
869   MU.LockWhen(Condition(&ArgIsOne, &COND));
870   MU.Unlock();
871   GLOB++;
872 }
873 
Run()874 void Run() {
875 //  ANNOTATE_EXPECT_RACE(&GLOB, "test13. FP. Fixed by MSMProp1.");
876   printf("test13: negative\n");
877   COND = 0;
878 
879   MyThreadArray t(Waker, Waiter);
880   t.Start();
881   t.Join();
882 
883   printf("\tGLOB=%d\n", GLOB);
884 }
885 REGISTER_TEST2(Run, 13, FEATURE|NEEDS_ANNOTATIONS);
886 }  // namespace test13
887 
888 
889 // test14: FP. Synchronization via PCQ, reads, 2 workers. {{{1
890 namespace test14 {
891 int     GLOB = 0;
892 // This test is properly synchronized, but currently (Dec 2007)
893 // helgrind reports a false positive.
894 //
895 // This test is similar to test11, but uses PCQ (semaphore).
896 //
897 // Putter2:                  Putter1:                     Getter:
898 // 1. read(GLOB)             a. read(GLOB)
899 // 2. Q2.Put() ----\         b. Q1.Put() -----\           .
900 //                  \                          \--------> A. Q1.Get()
901 //                   \----------------------------------> B. Q2.Get()
902 //                                                        C. write(GLOB)
903 ProducerConsumerQueue Q1(INT_MAX), Q2(INT_MAX);
904 
Putter1()905 void Putter1() {
906   CHECK(GLOB != 777);
907   Q1.Put(NULL);
908 }
Putter2()909 void Putter2() {
910   CHECK(GLOB != 777);
911   Q2.Put(NULL);
912 }
Getter()913 void Getter() {
914   Q1.Get();
915   Q2.Get();
916   GLOB++;
917 }
Run()918 void Run() {
919 //  ANNOTATE_EXPECT_RACE(&GLOB, "test14. FP. Fixed by MSMProp1.");
920   printf("test14: negative\n");
921   MyThreadArray t(Getter, Putter1, Putter2);
922   t.Start();
923   t.Join();
924   printf("\tGLOB=%d\n", GLOB);
925 }
926 REGISTER_TEST(Run, 14);
927 }  // namespace test14
928 
929 
930 // test15: TN. Synchronization via LockWhen. One waker and 2 waiters. {{{1
931 namespace test15 {
932 // Waker:                                   Waiter1, Waiter2:
933 // 1. write(GLOB)
934 // 2. MU.Lock()
935 // 3. COND = 1
936 // 4. ANNOTATE_CONDVAR_SIGNAL ------------> a. MU.LockWhen(COND == 1)
937 // 5. MU.Unlock()                           b. MU.Unlock()
938 //                                          c. read(GLOB)
939 
940 int     GLOB = 0;
941 Mutex   MU;
942 
Waker()943 void Waker() {
944   GLOB = 2;
945 
946   MU.Lock();
947   COND = 1;
948   ANNOTATE_CONDVAR_SIGNAL(&MU);
949   MU.Unlock();
950 };
951 
Waiter()952 void Waiter() {
953   MU.LockWhen(Condition(&ArgIsOne, &COND));
954   MU.Unlock();
955   CHECK(GLOB != 777);
956 }
957 
958 
Run()959 void Run() {
960   COND = 0;
961   printf("test15: negative\n");
962   MyThreadArray t(Waker, Waiter, Waiter);
963   t.Start();
964   t.Join();
965   printf("\tGLOB=%d\n", GLOB);
966 }
967 REGISTER_TEST(Run, 15);
968 }  // namespace test15
969 
970 
971 // test16: FP. Barrier (emulated by CV), 2 threads. {{{1
972 namespace test16 {
973 // Worker1:                                     Worker2:
974 // 1. MU.Lock()                                 a. MU.Lock()
975 // 2. write(GLOB) <------------ MU ---------->  b. write(GLOB)
976 // 3. MU.Unlock()                               c. MU.Unlock()
977 // 4. MU2.Lock()                                d. MU2.Lock()
978 // 5. COND--                                    e. COND--
979 // 6. ANNOTATE_CONDVAR_SIGNAL(MU2) ---->V       .
980 // 7. MU2.Await(COND == 0) <------------+------ f. ANNOTATE_CONDVAR_SIGNAL(MU2)
981 // 8. MU2.Unlock()                      V-----> g. MU2.Await(COND == 0)
982 // 9. read(GLOB)                                h. MU2.Unlock()
983 //                                              i. read(GLOB)
984 //
985 //
986 // TODO: This way we may create too many edges in happens-before graph.
987 // Arndt Mühlenfeld in his PhD (TODO: link) suggests creating special nodes in
988 // happens-before graph to reduce the total number of edges.
989 // See figure 3.14.
990 //
991 //
992 int     GLOB = 0;
993 Mutex   MU;
994 Mutex MU2;
995 
Worker()996 void Worker() {
997   MU.Lock();
998   GLOB++;
999   MU.Unlock();
1000 
1001   MU2.Lock();
1002   COND--;
1003   ANNOTATE_CONDVAR_SIGNAL(&MU2);
1004   MU2.Await(Condition(&ArgIsZero, &COND));
1005   MU2.Unlock();
1006 
1007   CHECK(GLOB == 2);
1008 }
1009 
Run()1010 void Run() {
1011 //  ANNOTATE_EXPECT_RACE(&GLOB, "test16. FP. Fixed by MSMProp1 + Barrier support.");
1012   COND = 2;
1013   printf("test16: negative\n");
1014   MyThreadArray t(Worker, Worker);
1015   t.Start();
1016   t.Join();
1017   printf("\tGLOB=%d\n", GLOB);
1018 }
1019 REGISTER_TEST2(Run, 16, FEATURE|NEEDS_ANNOTATIONS);
1020 }  // namespace test16
1021 
1022 
1023 // test17: FP. Barrier (emulated by CV), 3 threads. {{{1
1024 namespace test17 {
1025 // Same as test16, but with 3 threads.
1026 int     GLOB = 0;
1027 Mutex   MU;
1028 Mutex MU2;
1029 
Worker()1030 void Worker() {
1031   MU.Lock();
1032   GLOB++;
1033   MU.Unlock();
1034 
1035   MU2.Lock();
1036   COND--;
1037   ANNOTATE_CONDVAR_SIGNAL(&MU2);
1038   MU2.Await(Condition(&ArgIsZero, &COND));
1039   MU2.Unlock();
1040 
1041   CHECK(GLOB == 3);
1042 }
1043 
Run()1044 void Run() {
1045 //  ANNOTATE_EXPECT_RACE(&GLOB, "test17. FP. Fixed by MSMProp1 + Barrier support.");
1046   COND = 3;
1047   printf("test17: negative\n");
1048   MyThreadArray t(Worker, Worker, Worker);
1049   t.Start();
1050   t.Join();
1051   printf("\tGLOB=%d\n", GLOB);
1052 }
1053 REGISTER_TEST2(Run, 17, FEATURE|NEEDS_ANNOTATIONS);
1054 }  // namespace test17
1055 
1056 
1057 // test18: TN. Synchronization via Await(), signaller gets there first. {{{1
1058 namespace test18 {
1059 int     GLOB = 0;
1060 Mutex   MU;
1061 // Same as test03, but uses Mutex::Await() instead of Mutex::LockWhen().
1062 
Waker()1063 void Waker() {
1064   usleep(100000);  // Make sure the waiter blocks.
1065   GLOB = 1;
1066 
1067   MU.Lock();
1068   COND = 1; // We are done! Tell the Waiter.
1069   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
1070 }
Waiter()1071 void Waiter() {
1072   ThreadPool pool(1);
1073   pool.StartWorkers();
1074   COND = 0;
1075   pool.Add(NewCallback(Waker));
1076 
1077   MU.Lock();
1078   MU.Await(Condition(&ArgIsOne, &COND));  // calls ANNOTATE_CONDVAR_WAIT
1079   MU.Unlock();  // Waker is done!
1080 
1081   GLOB = 2;
1082 }
Run()1083 void Run() {
1084   printf("test18: negative\n");
1085   Waiter();
1086   printf("\tGLOB=%d\n", GLOB);
1087 }
1088 REGISTER_TEST2(Run, 18, FEATURE|NEEDS_ANNOTATIONS);
1089 }  // namespace test18
1090 
1091 // test19: TN. Synchronization via AwaitWithTimeout(). {{{1
1092 namespace test19 {
1093 int     GLOB = 0;
1094 // Same as test18, but with AwaitWithTimeout. Do not timeout.
1095 Mutex   MU;
Waker()1096 void Waker() {
1097   usleep(100000);  // Make sure the waiter blocks.
1098   GLOB = 1;
1099 
1100   MU.Lock();
1101   COND = 1; // We are done! Tell the Waiter.
1102   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
1103 }
Waiter()1104 void Waiter() {
1105   ThreadPool pool(1);
1106   pool.StartWorkers();
1107   COND = 0;
1108   pool.Add(NewCallback(Waker));
1109 
1110   MU.Lock();
1111   CHECK(MU.AwaitWithTimeout(Condition(&ArgIsOne, &COND), INT_MAX));
1112   MU.Unlock();
1113 
1114   GLOB = 2;
1115 }
Run()1116 void Run() {
1117   printf("test19: negative\n");
1118   Waiter();
1119   printf("\tGLOB=%d\n", GLOB);
1120 }
1121 REGISTER_TEST2(Run, 19, FEATURE|NEEDS_ANNOTATIONS);
1122 }  // namespace test19
1123 
1124 // test20: TP. Incorrect synchronization via AwaitWhen(), timeout. {{{1
1125 namespace test20 {
1126 int     GLOB = 0;
1127 Mutex   MU;
1128 // True race. We timeout in AwaitWhen.
Waker()1129 void Waker() {
1130   GLOB = 1;
1131   usleep(100 * 1000);
1132 }
Waiter()1133 void Waiter() {
1134   ThreadPool pool(1);
1135   pool.StartWorkers();
1136   COND = 0;
1137   pool.Add(NewCallback(Waker));
1138 
1139   MU.Lock();
1140   CHECK(!MU.AwaitWithTimeout(Condition(&ArgIsOne, &COND), 100));
1141   MU.Unlock();
1142 
1143   GLOB = 2;
1144 }
Run()1145 void Run() {
1146   FAST_MODE_INIT(&GLOB);
1147   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test20. TP.");
1148   printf("test20: positive\n");
1149   Waiter();
1150   printf("\tGLOB=%d\n", GLOB);
1151 }
1152 REGISTER_TEST2(Run, 20, FEATURE|NEEDS_ANNOTATIONS);
1153 }  // namespace test20
1154 
1155 // test21: TP. Incorrect synchronization via LockWhenWithTimeout(). {{{1
1156 namespace test21 {
1157 int     GLOB = 0;
1158 // True race. We timeout in LockWhenWithTimeout().
1159 Mutex   MU;
Waker()1160 void Waker() {
1161   GLOB = 1;
1162   usleep(100 * 1000);
1163 }
Waiter()1164 void Waiter() {
1165   ThreadPool pool(1);
1166   pool.StartWorkers();
1167   COND = 0;
1168   pool.Add(NewCallback(Waker));
1169 
1170   CHECK(!MU.LockWhenWithTimeout(Condition(&ArgIsOne, &COND), 100));
1171   MU.Unlock();
1172 
1173   GLOB = 2;
1174 }
Run()1175 void Run() {
1176   FAST_MODE_INIT(&GLOB);
1177   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test21. TP.");
1178   printf("test21: positive\n");
1179   Waiter();
1180   printf("\tGLOB=%d\n", GLOB);
1181 }
1182 REGISTER_TEST2(Run, 21, FEATURE|NEEDS_ANNOTATIONS);
1183 }  // namespace test21
1184 
1185 // test22: TP. Incorrect synchronization via CondVar::WaitWithTimeout(). {{{1
1186 namespace test22 {
1187 int     GLOB = 0;
1188 Mutex   MU;
1189 // True race. We timeout in CondVar::WaitWithTimeout().
Waker()1190 void Waker() {
1191   GLOB = 1;
1192   usleep(100 * 1000);
1193 }
Waiter()1194 void Waiter() {
1195   ThreadPool pool(1);
1196   pool.StartWorkers();
1197   COND = 0;
1198   pool.Add(NewCallback(Waker));
1199 
1200   int64_t ms_left_to_wait = 100;
1201   int64_t deadline_ms = GetCurrentTimeMillis() + ms_left_to_wait;
1202   MU.Lock();
1203   while(COND != 1 && ms_left_to_wait > 0) {
1204     CV.WaitWithTimeout(&MU, ms_left_to_wait);
1205     ms_left_to_wait = deadline_ms - GetCurrentTimeMillis();
1206   }
1207   MU.Unlock();
1208 
1209   GLOB = 2;
1210 }
Run()1211 void Run() {
1212   FAST_MODE_INIT(&GLOB);
1213   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test22. TP.");
1214   printf("test22: positive\n");
1215   Waiter();
1216   printf("\tGLOB=%d\n", GLOB);
1217 }
1218 REGISTER_TEST(Run, 22);
1219 }  // namespace test22
1220 
1221 // test23: TN. TryLock, ReaderLock, ReaderTryLock. {{{1
1222 namespace test23 {
1223 // Correct synchronization with TryLock, Lock, ReaderTryLock, ReaderLock.
1224 int     GLOB = 0;
1225 Mutex   MU;
Worker_TryLock()1226 void Worker_TryLock() {
1227   for (int i = 0; i < 20; i++) {
1228     while (true) {
1229       if (MU.TryLock()) {
1230         GLOB++;
1231         MU.Unlock();
1232         break;
1233       }
1234       usleep(1000);
1235     }
1236   }
1237 }
1238 
Worker_ReaderTryLock()1239 void Worker_ReaderTryLock() {
1240   for (int i = 0; i < 20; i++) {
1241     while (true) {
1242       if (MU.ReaderTryLock()) {
1243         CHECK(GLOB != 777);
1244         MU.ReaderUnlock();
1245         break;
1246       }
1247       usleep(1000);
1248     }
1249   }
1250 }
1251 
Worker_ReaderLock()1252 void Worker_ReaderLock() {
1253   for (int i = 0; i < 20; i++) {
1254     MU.ReaderLock();
1255     CHECK(GLOB != 777);
1256     MU.ReaderUnlock();
1257     usleep(1000);
1258   }
1259 }
1260 
Worker_Lock()1261 void Worker_Lock() {
1262   for (int i = 0; i < 20; i++) {
1263     MU.Lock();
1264     GLOB++;
1265     MU.Unlock();
1266     usleep(1000);
1267   }
1268 }
1269 
Run()1270 void Run() {
1271   printf("test23: negative\n");
1272   MyThreadArray t(Worker_TryLock,
1273                   Worker_ReaderTryLock,
1274                   Worker_ReaderLock,
1275                   Worker_Lock
1276                   );
1277   t.Start();
1278   t.Join();
1279   printf("\tGLOB=%d\n", GLOB);
1280 }
1281 REGISTER_TEST(Run, 23);
1282 }  // namespace test23
1283 
1284 // test24: TN. Synchronization via ReaderLockWhen(). {{{1
1285 namespace test24 {
1286 int     GLOB = 0;
1287 Mutex   MU;
1288 // Same as test03, but uses ReaderLockWhen().
1289 
Waker()1290 void Waker() {
1291   usleep(100000);  // Make sure the waiter blocks.
1292   GLOB = 1;
1293 
1294   MU.Lock();
1295   COND = 1; // We are done! Tell the Waiter.
1296   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
1297 }
Waiter()1298 void Waiter() {
1299   ThreadPool pool(1);
1300   pool.StartWorkers();
1301   COND = 0;
1302   pool.Add(NewCallback(Waker));
1303   MU.ReaderLockWhen(Condition(&ArgIsOne, &COND));
1304   MU.ReaderUnlock();
1305 
1306   GLOB = 2;
1307 }
Run()1308 void Run() {
1309   printf("test24: negative\n");
1310   Waiter();
1311   printf("\tGLOB=%d\n", GLOB);
1312 }
1313 REGISTER_TEST2(Run, 24, FEATURE|NEEDS_ANNOTATIONS);
1314 }  // namespace test24
1315 
1316 // test25: TN. Synchronization via ReaderLockWhenWithTimeout(). {{{1
1317 namespace test25 {
1318 int     GLOB = 0;
1319 Mutex   MU;
1320 // Same as test24, but uses ReaderLockWhenWithTimeout().
1321 // We do not timeout.
1322 
Waker()1323 void Waker() {
1324   usleep(100000);  // Make sure the waiter blocks.
1325   GLOB = 1;
1326 
1327   MU.Lock();
1328   COND = 1; // We are done! Tell the Waiter.
1329   MU.Unlock(); // calls ANNOTATE_CONDVAR_SIGNAL;
1330 }
Waiter()1331 void Waiter() {
1332   ThreadPool pool(1);
1333   pool.StartWorkers();
1334   COND = 0;
1335   pool.Add(NewCallback(Waker));
1336   CHECK(MU.ReaderLockWhenWithTimeout(Condition(&ArgIsOne, &COND), INT_MAX));
1337   MU.ReaderUnlock();
1338 
1339   GLOB = 2;
1340 }
Run()1341 void Run() {
1342   printf("test25: negative\n");
1343   Waiter();
1344   printf("\tGLOB=%d\n", GLOB);
1345 }
1346 REGISTER_TEST2(Run, 25, FEATURE|NEEDS_ANNOTATIONS);
1347 }  // namespace test25
1348 
1349 // test26: TP. Incorrect synchronization via ReaderLockWhenWithTimeout(). {{{1
1350 namespace test26 {
1351 int     GLOB = 0;
1352 Mutex   MU;
1353 // Same as test25, but we timeout and incorrectly assume happens-before.
1354 
Waker()1355 void Waker() {
1356   GLOB = 1;
1357   usleep(10000);
1358 }
Waiter()1359 void Waiter() {
1360   ThreadPool pool(1);
1361   pool.StartWorkers();
1362   COND = 0;
1363   pool.Add(NewCallback(Waker));
1364   CHECK(!MU.ReaderLockWhenWithTimeout(Condition(&ArgIsOne, &COND), 100));
1365   MU.ReaderUnlock();
1366 
1367   GLOB = 2;
1368 }
Run()1369 void Run() {
1370   FAST_MODE_INIT(&GLOB);
1371   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test26. TP");
1372   printf("test26: positive\n");
1373   Waiter();
1374   printf("\tGLOB=%d\n", GLOB);
1375 }
1376 REGISTER_TEST2(Run, 26, FEATURE|NEEDS_ANNOTATIONS);
1377 }  // namespace test26
1378 
1379 
1380 // test27: TN. Simple synchronization via SpinLock. {{{1
1381 namespace test27 {
1382 #ifndef NO_SPINLOCK
1383 int     GLOB = 0;
1384 SpinLock MU;
Worker()1385 void Worker() {
1386   MU.Lock();
1387   GLOB++;
1388   MU.Unlock();
1389   usleep(10000);
1390 }
1391 
Run()1392 void Run() {
1393   printf("test27: negative\n");
1394   MyThreadArray t(Worker, Worker, Worker, Worker);
1395   t.Start();
1396   t.Join();
1397   printf("\tGLOB=%d\n", GLOB);
1398 }
1399 REGISTER_TEST2(Run, 27, FEATURE|NEEDS_ANNOTATIONS);
1400 #endif // NO_SPINLOCK
1401 }  // namespace test27
1402 
1403 
1404 // test28: TN. Synchronization via Mutex, then PCQ. 3 threads {{{1
1405 namespace test28 {
1406 // Putter1:                       Getter:                         Putter2:
1407 // 1. MU.Lock()                                                   A. MU.Lock()
1408 // 2. write(GLOB)                                                 B. write(GLOB)
1409 // 3. MU.Unlock()                                                 C. MU.Unlock()
1410 // 4. Q.Put() ---------\                                 /------- D. Q.Put()
1411 // 5. MU.Lock()         \-------> a. Q.Get()            /         E. MU.Lock()
1412 // 6. read(GLOB)                  b. Q.Get() <---------/          F. read(GLOB)
1413 // 7. MU.Unlock()                   (sleep)                       G. MU.Unlock()
1414 //                                c. read(GLOB)
1415 ProducerConsumerQueue Q(INT_MAX);
1416 int     GLOB = 0;
1417 Mutex   MU;
1418 
Putter()1419 void Putter() {
1420   MU.Lock();
1421   GLOB++;
1422   MU.Unlock();
1423 
1424   Q.Put(NULL);
1425 
1426   MU.Lock();
1427   CHECK(GLOB != 777);
1428   MU.Unlock();
1429 }
1430 
Getter()1431 void Getter() {
1432   Q.Get();
1433   Q.Get();
1434   usleep(100000);
1435   CHECK(GLOB == 2);
1436 }
1437 
Run()1438 void Run() {
1439   printf("test28: negative\n");
1440   MyThreadArray t(Getter, Putter, Putter);
1441   t.Start();
1442   t.Join();
1443   printf("\tGLOB=%d\n", GLOB);
1444 }
1445 REGISTER_TEST(Run, 28);
1446 }  // namespace test28
1447 
1448 
1449 // test29: TN. Synchronization via Mutex, then PCQ. 4 threads. {{{1
1450 namespace test29 {
1451 // Similar to test28, but has two Getters and two PCQs.
1452 ProducerConsumerQueue *Q1, *Q2;
1453 Mutex   MU;
1454 int     GLOB = 0;
1455 
Putter(ProducerConsumerQueue * q)1456 void Putter(ProducerConsumerQueue *q) {
1457   MU.Lock();
1458   GLOB++;
1459   MU.Unlock();
1460 
1461   q->Put(NULL);
1462   q->Put(NULL);
1463 
1464   MU.Lock();
1465   CHECK(GLOB != 777);
1466   MU.Unlock();
1467 
1468 }
1469 
Putter1()1470 void Putter1() { Putter(Q1); }
Putter2()1471 void Putter2() { Putter(Q2); }
1472 
Getter()1473 void Getter() {
1474   Q1->Get();
1475   Q2->Get();
1476   usleep(100000);
1477   CHECK(GLOB == 2);
1478   usleep(48000); //  TODO: remove this when FP in test32 is fixed.
1479 }
1480 
Run()1481 void Run() {
1482   printf("test29: negative\n");
1483   Q1 = new ProducerConsumerQueue(INT_MAX);
1484   Q2 = new ProducerConsumerQueue(INT_MAX);
1485   MyThreadArray t(Getter, Getter, Putter1, Putter2);
1486   t.Start();
1487   t.Join();
1488   printf("\tGLOB=%d\n", GLOB);
1489   delete Q1;
1490   delete Q2;
1491 }
1492 REGISTER_TEST(Run, 29);
1493 }  // namespace test29
1494 
1495 
1496 // test30: TN. Synchronization via 'safe' race. Writer vs multiple Readers. {{{1
1497 namespace test30 {
1498 // This test shows a very risky kind of synchronization which is very easy
1499 // to get wrong. Actually, I am not sure I've got it right.
1500 //
1501 // Writer:                                 Reader1, Reader2, ..., ReaderN:
1502 // 1. write(GLOB[i]: i >= BOUNDARY)        a. n = BOUNDARY
1503 // 2. HAPPENS_BEFORE(BOUNDARY+1)  -------> b. HAPPENS_AFTER(n)
1504 // 3. BOUNDARY++;                          c. read(GLOB[i]: i < n)
1505 //
1506 // Here we have a 'safe' race on accesses to BOUNDARY and
1507 // no actual races on accesses to GLOB[]:
1508 // Writer writes to GLOB[i] where i>=BOUNDARY and then increments BOUNDARY.
1509 // Readers read BOUNDARY and read GLOB[i] where i<BOUNDARY.
1510 //
1511 // I am not completely sure that this scheme guaranties no race between
1512 // accesses to GLOB since compilers and CPUs
1513 // are free to rearrange memory operations.
1514 // I am actually sure that this scheme is wrong unless we use
1515 // some smart memory fencing...
1516 
1517 
1518 const int N = 48;
1519 static int GLOB[N];
1520 volatile int BOUNDARY = 0;
1521 
Writer()1522 void Writer() {
1523   for (int i = 0; i < N; i++) {
1524     CHECK(BOUNDARY == i);
1525     for (int j = i; j < N; j++) {
1526       GLOB[j] = j;
1527     }
1528     ANNOTATE_HAPPENS_BEFORE(reinterpret_cast<void*>(BOUNDARY+1));
1529     BOUNDARY++;
1530     usleep(1000);
1531   }
1532 }
1533 
Reader()1534 void Reader() {
1535   int n;
1536   do {
1537     n = BOUNDARY;
1538     if (n == 0) continue;
1539     ANNOTATE_HAPPENS_AFTER(reinterpret_cast<void*>(n));
1540     for (int i = 0; i < n; i++) {
1541       CHECK(GLOB[i] == i);
1542     }
1543     usleep(100);
1544   } while(n < N);
1545 }
1546 
Run()1547 void Run() {
1548   FAST_MODE_INIT(&BOUNDARY);
1549   ANNOTATE_EXPECT_RACE((void*)(&BOUNDARY), "test30. Sync via 'safe' race.");
1550   printf("test30: negative\n");
1551   MyThreadArray t(Writer, Reader, Reader, Reader);
1552   t.Start();
1553   t.Join();
1554   printf("\tGLOB=%d\n", GLOB[N-1]);
1555 }
1556 REGISTER_TEST2(Run, 30, FEATURE|NEEDS_ANNOTATIONS);
1557 }  // namespace test30
1558 
1559 
1560 // test31: TN. Synchronization via 'safe' race. Writer vs Writer. {{{1
1561 namespace test31 {
1562 // This test is similar to test30, but
1563 // it has one Writer instead of mulitple Readers.
1564 //
1565 // Writer1:                                Writer2
1566 // 1. write(GLOB[i]: i >= BOUNDARY)        a. n = BOUNDARY
1567 // 2. HAPPENS_BEFORE(BOUNDARY+1)  -------> b. HAPPENS_AFTER(n)
1568 // 3. BOUNDARY++;                          c. write(GLOB[i]: i < n)
1569 //
1570 
1571 const int N = 48;
1572 static int GLOB[N];
1573 volatile int BOUNDARY = 0;
1574 
Writer1()1575 void Writer1() {
1576   for (int i = 0; i < N; i++) {
1577     CHECK(BOUNDARY == i);
1578     for (int j = i; j < N; j++) {
1579       GLOB[j] = j;
1580     }
1581     ANNOTATE_HAPPENS_BEFORE(reinterpret_cast<void*>(BOUNDARY+1));
1582     BOUNDARY++;
1583     usleep(1000);
1584   }
1585 }
1586 
Writer2()1587 void Writer2() {
1588   int n;
1589   do {
1590     n = BOUNDARY;
1591     if (n == 0) continue;
1592     ANNOTATE_HAPPENS_AFTER(reinterpret_cast<void*>(n));
1593     for (int i = 0; i < n; i++) {
1594       if(GLOB[i] == i) {
1595         GLOB[i]++;
1596       }
1597     }
1598     usleep(100);
1599   } while(n < N);
1600 }
1601 
Run()1602 void Run() {
1603   FAST_MODE_INIT(&BOUNDARY);
1604   ANNOTATE_EXPECT_RACE((void*)(&BOUNDARY), "test31. Sync via 'safe' race.");
1605   printf("test31: negative\n");
1606   MyThreadArray t(Writer1, Writer2);
1607   t.Start();
1608   t.Join();
1609   printf("\tGLOB=%d\n", GLOB[N-1]);
1610 }
1611 REGISTER_TEST2(Run, 31, FEATURE|NEEDS_ANNOTATIONS);
1612 }  // namespace test31
1613 
1614 
1615 // test32: FP. Synchronization via thread create/join. W/R. {{{1
1616 namespace test32 {
1617 // This test is well synchronized but helgrind 3.3.0 reports a race.
1618 //
1619 // Parent:                   Writer:               Reader:
1620 // 1. Start(Reader) -----------------------\       .
1621 //                                          \      .
1622 // 2. Start(Writer) ---\                     \     .
1623 //                      \---> a. MU.Lock()    \--> A. sleep(long enough)
1624 //                            b. write(GLOB)
1625 //                      /---- c. MU.Unlock()
1626 // 3. Join(Writer) <---/
1627 //                                                 B. MU.Lock()
1628 //                                                 C. read(GLOB)
1629 //                                   /------------ D. MU.Unlock()
1630 // 4. Join(Reader) <----------------/
1631 // 5. write(GLOB)
1632 //
1633 //
1634 // The call to sleep() in Reader is not part of synchronization,
1635 // it is required to trigger the false positive in helgrind 3.3.0.
1636 //
1637 int     GLOB = 0;
1638 Mutex   MU;
1639 
Writer()1640 void Writer() {
1641   MU.Lock();
1642   GLOB = 1;
1643   MU.Unlock();
1644 }
1645 
Reader()1646 void Reader() {
1647   usleep(480000);
1648   MU.Lock();
1649   CHECK(GLOB != 777);
1650   MU.Unlock();
1651 }
1652 
Parent()1653 void Parent() {
1654   MyThread r(Reader);
1655   MyThread w(Writer);
1656   r.Start();
1657   w.Start();
1658 
1659   w.Join();  // 'w' joins first.
1660   r.Join();
1661 
1662   GLOB = 2;
1663 }
1664 
Run()1665 void Run() {
1666 //  ANNOTATE_EXPECT_RACE(&GLOB, "test32. FP. Fixed by MSMProp1.");
1667   printf("test32: negative\n");
1668   Parent();
1669   printf("\tGLOB=%d\n", GLOB);
1670 }
1671 
1672 REGISTER_TEST(Run, 32);
1673 }  // namespace test32
1674 
1675 
1676 // test33: STAB. Stress test for the number of thread sets (TSETs). {{{1
1677 namespace test33 {
1678 int     GLOB = 0;
1679 // Here we access N memory locations from within log(N) threads.
1680 // We do it in such a way that helgrind creates nearly all possible TSETs.
1681 // Then we join all threads and start again (N_iter times).
1682 const int N_iter = 48;
1683 const int Nlog  = 15;
1684 const int N     = 1 << Nlog;
1685 static int ARR[N];
1686 Mutex   MU;
1687 
Worker()1688 void Worker() {
1689   MU.Lock();
1690   int n = ++GLOB;
1691   MU.Unlock();
1692 
1693   n %= Nlog;
1694   for (int i = 0; i < N; i++) {
1695     // ARR[i] is accessed by threads from i-th subset
1696     if (i & (1 << n)) {
1697         CHECK(ARR[i] == 0);
1698     }
1699   }
1700 }
1701 
Run()1702 void Run() {
1703   printf("test33:\n");
1704 
1705   std::vector<MyThread*> vec(Nlog);
1706 
1707   for (int j = 0; j < N_iter; j++) {
1708     // Create and start Nlog threads
1709     for (int i = 0; i < Nlog; i++) {
1710       vec[i] = new MyThread(Worker);
1711     }
1712     for (int i = 0; i < Nlog; i++) {
1713       vec[i]->Start();
1714     }
1715     // Join all threads.
1716     for (int i = 0; i < Nlog; i++) {
1717       vec[i]->Join();
1718       delete vec[i];
1719     }
1720     printf("------------------\n");
1721   }
1722 
1723   printf("\tGLOB=%d; ARR[1]=%d; ARR[7]=%d; ARR[N-1]=%d\n",
1724          GLOB, ARR[1], ARR[7], ARR[N-1]);
1725 }
1726 REGISTER_TEST2(Run, 33, STABILITY|EXCLUDE_FROM_ALL);
1727 }  // namespace test33
1728 
1729 
1730 // test34: STAB. Stress test for the number of locks sets (LSETs). {{{1
1731 namespace test34 {
1732 // Similar to test33, but for lock sets.
1733 int     GLOB = 0;
1734 const int N_iter = 48;
1735 const int Nlog = 10;
1736 const int N    = 1 << Nlog;
1737 static int ARR[N];
1738 static Mutex *MUs[Nlog];
1739 
Worker()1740 void Worker() {
1741     for (int i = 0; i < N; i++) {
1742       // ARR[i] is protected by MUs from i-th subset of all MUs
1743       for (int j = 0; j < Nlog; j++)  if (i & (1 << j)) MUs[j]->Lock();
1744       CHECK(ARR[i] == 0);
1745       for (int j = 0; j < Nlog; j++)  if (i & (1 << j)) MUs[j]->Unlock();
1746     }
1747 }
1748 
Run()1749 void Run() {
1750   printf("test34:\n");
1751   for (int iter = 0; iter < N_iter; iter++) {
1752     for (int i = 0; i < Nlog; i++) {
1753       MUs[i] = new Mutex;
1754     }
1755     MyThreadArray t(Worker, Worker);
1756     t.Start();
1757     t.Join();
1758     for (int i = 0; i < Nlog; i++) {
1759       delete MUs[i];
1760     }
1761     printf("------------------\n");
1762   }
1763   printf("\tGLOB=%d\n", GLOB);
1764 }
1765 REGISTER_TEST2(Run, 34, STABILITY|EXCLUDE_FROM_ALL);
1766 }  // namespace test34
1767 
1768 
1769 // test35: PERF. Lots of mutexes and lots of call to free().  {{{1
1770 namespace test35 {
1771 // Helgrind 3.3.0 has very slow in shadow_mem_make_NoAccess(). Fixed locally.
1772 // With the fix helgrind runs this test about a minute.
1773 // Without the fix -- about 5 minutes. (on c2d 2.4GHz).
1774 //
1775 // TODO: need to figure out the best way for performance testing.
1776 int **ARR;
1777 const int N_mu   = 25000;
1778 const int N_free = 48000;
1779 
Worker()1780 void Worker() {
1781   for (int i = 0; i < N_free; i++)
1782     CHECK(777 == *ARR[i]);
1783 }
1784 
Run()1785 void Run() {
1786   printf("test35:\n");
1787   std::vector<Mutex*> mus;
1788 
1789   ARR = new int *[N_free];
1790   for (int i = 0; i < N_free; i++) {
1791     const int c = N_free / N_mu;
1792     if ((i % c) == 0) {
1793       mus.push_back(new Mutex);
1794       mus.back()->Lock();
1795       mus.back()->Unlock();
1796     }
1797     ARR[i] = new int(777);
1798   }
1799 
1800   // Need to put all ARR[i] into shared state in order
1801   // to trigger the performance bug.
1802   MyThreadArray t(Worker, Worker);
1803   t.Start();
1804   t.Join();
1805 
1806   for (int i = 0; i < N_free; i++) delete ARR[i];
1807   delete [] ARR;
1808 
1809   for (size_t i = 0; i < mus.size(); i++) {
1810     delete mus[i];
1811   }
1812 }
1813 REGISTER_TEST2(Run, 35, PERFORMANCE|EXCLUDE_FROM_ALL);
1814 }  // namespace test35
1815 
1816 
1817 // test36: TN. Synchronization via Mutex, then PCQ. 3 threads. W/W {{{1
1818 namespace test36 {
1819 // variation of test28 (W/W instead of W/R)
1820 
1821 // Putter1:                       Getter:                         Putter2:
1822 // 1. MU.Lock();                                                  A. MU.Lock()
1823 // 2. write(GLOB)                                                 B. write(GLOB)
1824 // 3. MU.Unlock()                                                 C. MU.Unlock()
1825 // 4. Q.Put() ---------\                                 /------- D. Q.Put()
1826 // 5. MU1.Lock()        \-------> a. Q.Get()            /         E. MU1.Lock()
1827 // 6. MU.Lock()                   b. Q.Get() <---------/          F. MU.Lock()
1828 // 7. write(GLOB)                                                 G. write(GLOB)
1829 // 8. MU.Unlock()                                                 H. MU.Unlock()
1830 // 9. MU1.Unlock()                  (sleep)                       I. MU1.Unlock()
1831 //                                c. MU1.Lock()
1832 //                                d. write(GLOB)
1833 //                                e. MU1.Unlock()
1834 ProducerConsumerQueue Q(INT_MAX);
1835 int     GLOB = 0;
1836 Mutex   MU, MU1;
1837 
Putter()1838 void Putter() {
1839   MU.Lock();
1840   GLOB++;
1841   MU.Unlock();
1842 
1843   Q.Put(NULL);
1844 
1845   MU1.Lock();
1846   MU.Lock();
1847   GLOB++;
1848   MU.Unlock();
1849   MU1.Unlock();
1850 }
1851 
Getter()1852 void Getter() {
1853   Q.Get();
1854   Q.Get();
1855   usleep(100000);
1856   MU1.Lock();
1857   GLOB++;
1858   MU1.Unlock();
1859 }
1860 
Run()1861 void Run() {
1862   printf("test36: negative \n");
1863   MyThreadArray t(Getter, Putter, Putter);
1864   t.Start();
1865   t.Join();
1866   printf("\tGLOB=%d\n", GLOB);
1867 }
1868 REGISTER_TEST(Run, 36);
1869 }  // namespace test36
1870 
1871 
1872 // test37: TN. Simple synchronization (write vs read). {{{1
1873 namespace test37 {
1874 int     GLOB = 0;
1875 Mutex   MU;
1876 // Similar to test10, but properly locked.
1877 // Writer:             Reader:
1878 // 1. MU.Lock()
1879 // 2. write
1880 // 3. MU.Unlock()
1881 //                    a. MU.Lock()
1882 //                    b. read
1883 //                    c. MU.Unlock();
1884 
Writer()1885 void Writer() {
1886   MU.Lock();
1887   GLOB = 3;
1888   MU.Unlock();
1889 }
Reader()1890 void Reader() {
1891   usleep(100000);
1892   MU.Lock();
1893   CHECK(GLOB != -777);
1894   MU.Unlock();
1895 }
1896 
Run()1897 void Run() {
1898   printf("test37: negative\n");
1899   MyThreadArray t(Writer, Reader);
1900   t.Start();
1901   t.Join();
1902   printf("\tGLOB=%d\n", GLOB);
1903 }
1904 REGISTER_TEST(Run, 37);
1905 }  // namespace test37
1906 
1907 
1908 // test38: TN. Synchronization via Mutexes and PCQ. 4 threads. W/W {{{1
1909 namespace test38 {
1910 // Fusion of test29 and test36.
1911 
1912 // Putter1:            Putter2:           Getter1:       Getter2:
1913 //    MU1.Lock()          MU1.Lock()
1914 //    write(GLOB)         write(GLOB)
1915 //    MU1.Unlock()        MU1.Unlock()
1916 //    Q1.Put()            Q2.Put()
1917 //    Q1.Put()            Q2.Put()
1918 //    MU1.Lock()          MU1.Lock()
1919 //    MU2.Lock()          MU2.Lock()
1920 //    write(GLOB)         write(GLOB)
1921 //    MU2.Unlock()        MU2.Unlock()
1922 //    MU1.Unlock()        MU1.Unlock()     sleep          sleep
1923 //                                         Q1.Get()       Q1.Get()
1924 //                                         Q2.Get()       Q2.Get()
1925 //                                         MU2.Lock()     MU2.Lock()
1926 //                                         write(GLOB)    write(GLOB)
1927 //                                         MU2.Unlock()   MU2.Unlock()
1928 //
1929 
1930 
1931 ProducerConsumerQueue *Q1, *Q2;
1932 int     GLOB = 0;
1933 Mutex   MU, MU1, MU2;
1934 
Putter(ProducerConsumerQueue * q)1935 void Putter(ProducerConsumerQueue *q) {
1936   MU1.Lock();
1937   GLOB++;
1938   MU1.Unlock();
1939 
1940   q->Put(NULL);
1941   q->Put(NULL);
1942 
1943   MU1.Lock();
1944   MU2.Lock();
1945   GLOB++;
1946   MU2.Unlock();
1947   MU1.Unlock();
1948 
1949 }
1950 
Putter1()1951 void Putter1() { Putter(Q1); }
Putter2()1952 void Putter2() { Putter(Q2); }
1953 
Getter()1954 void Getter() {
1955   usleep(100000);
1956   Q1->Get();
1957   Q2->Get();
1958 
1959   MU2.Lock();
1960   GLOB++;
1961   MU2.Unlock();
1962 
1963   usleep(48000); //  TODO: remove this when FP in test32 is fixed.
1964 }
1965 
Run()1966 void Run() {
1967   printf("test38: negative\n");
1968   Q1 = new ProducerConsumerQueue(INT_MAX);
1969   Q2 = new ProducerConsumerQueue(INT_MAX);
1970   MyThreadArray t(Getter, Getter, Putter1, Putter2);
1971   t.Start();
1972   t.Join();
1973   printf("\tGLOB=%d\n", GLOB);
1974   delete Q1;
1975   delete Q2;
1976 }
1977 REGISTER_TEST(Run, 38);
1978 }  // namespace test38
1979 
1980 // test39: FP. Barrier. {{{1
1981 namespace test39 {
1982 #ifndef NO_BARRIER
1983 // Same as test17 but uses Barrier class (pthread_barrier_t).
1984 int     GLOB = 0;
1985 const int N_threads = 3;
1986 Barrier barrier(N_threads);
1987 Mutex   MU;
1988 
Worker()1989 void Worker() {
1990   MU.Lock();
1991   GLOB++;
1992   MU.Unlock();
1993   barrier.Block();
1994   CHECK(GLOB == N_threads);
1995 }
Run()1996 void Run() {
1997   ANNOTATE_TRACE_MEMORY(&GLOB);
1998 //  ANNOTATE_EXPECT_RACE(&GLOB, "test39. FP. Fixed by MSMProp1. Barrier.");
1999   printf("test39: negative\n");
2000   {
2001     ThreadPool pool(N_threads);
2002     pool.StartWorkers();
2003     for (int i = 0; i < N_threads; i++) {
2004       pool.Add(NewCallback(Worker));
2005     }
2006   } // all folks are joined here.
2007   printf("\tGLOB=%d\n", GLOB);
2008 }
2009 REGISTER_TEST(Run, 39);
2010 #endif // NO_BARRIER
2011 }  // namespace test39
2012 
2013 
2014 // test40: FP. Synchronization via Mutexes and PCQ. 4 threads. W/W {{{1
2015 namespace test40 {
2016 // Similar to test38 but with different order of events (due to sleep).
2017 
2018 // Putter1:            Putter2:           Getter1:       Getter2:
2019 //    MU1.Lock()          MU1.Lock()
2020 //    write(GLOB)         write(GLOB)
2021 //    MU1.Unlock()        MU1.Unlock()
2022 //    Q1.Put()            Q2.Put()
2023 //    Q1.Put()            Q2.Put()
2024 //                                        Q1.Get()       Q1.Get()
2025 //                                        Q2.Get()       Q2.Get()
2026 //                                        MU2.Lock()     MU2.Lock()
2027 //                                        write(GLOB)    write(GLOB)
2028 //                                        MU2.Unlock()   MU2.Unlock()
2029 //
2030 //    MU1.Lock()          MU1.Lock()
2031 //    MU2.Lock()          MU2.Lock()
2032 //    write(GLOB)         write(GLOB)
2033 //    MU2.Unlock()        MU2.Unlock()
2034 //    MU1.Unlock()        MU1.Unlock()
2035 
2036 
2037 ProducerConsumerQueue *Q1, *Q2;
2038 int     GLOB = 0;
2039 Mutex   MU, MU1, MU2;
2040 
Putter(ProducerConsumerQueue * q)2041 void Putter(ProducerConsumerQueue *q) {
2042   MU1.Lock();
2043   GLOB++;
2044   MU1.Unlock();
2045 
2046   q->Put(NULL);
2047   q->Put(NULL);
2048   usleep(100000);
2049 
2050   MU1.Lock();
2051   MU2.Lock();
2052   GLOB++;
2053   MU2.Unlock();
2054   MU1.Unlock();
2055 
2056 }
2057 
Putter1()2058 void Putter1() { Putter(Q1); }
Putter2()2059 void Putter2() { Putter(Q2); }
2060 
Getter()2061 void Getter() {
2062   Q1->Get();
2063   Q2->Get();
2064 
2065   MU2.Lock();
2066   GLOB++;
2067   MU2.Unlock();
2068 
2069   usleep(48000); //  TODO: remove this when FP in test32 is fixed.
2070 }
2071 
Run()2072 void Run() {
2073 //  ANNOTATE_EXPECT_RACE(&GLOB, "test40. FP. Fixed by MSMProp1. Complex Stuff.");
2074   printf("test40: negative\n");
2075   Q1 = new ProducerConsumerQueue(INT_MAX);
2076   Q2 = new ProducerConsumerQueue(INT_MAX);
2077   MyThreadArray t(Getter, Getter, Putter1, Putter2);
2078   t.Start();
2079   t.Join();
2080   printf("\tGLOB=%d\n", GLOB);
2081   delete Q1;
2082   delete Q2;
2083 }
2084 REGISTER_TEST(Run, 40);
2085 }  // namespace test40
2086 
2087 // test41: TN. Test for race that appears when loading a dynamic symbol. {{{1
2088 namespace test41 {
Worker()2089 void Worker() {
2090   ANNOTATE_NO_OP(NULL); // An empty function, loaded from dll.
2091 }
Run()2092 void Run() {
2093   printf("test41: negative\n");
2094   MyThreadArray t(Worker, Worker, Worker);
2095   t.Start();
2096   t.Join();
2097 }
2098 REGISTER_TEST2(Run, 41, FEATURE|NEEDS_ANNOTATIONS);
2099 }  // namespace test41
2100 
2101 
2102 // test42: TN. Using the same cond var several times. {{{1
2103 namespace test42 {
2104 int GLOB = 0;
2105 int COND = 0;
2106 int N_threads = 3;
2107 Mutex   MU;
2108 
Worker1()2109 void Worker1() {
2110   GLOB=1;
2111 
2112   MU.Lock();
2113   COND = 1;
2114   CV.Signal();
2115   MU.Unlock();
2116 
2117   MU.Lock();
2118   while (COND != 0)
2119     CV.Wait(&MU);
2120   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
2121   MU.Unlock();
2122 
2123   GLOB=3;
2124 
2125 }
2126 
Worker2()2127 void Worker2() {
2128 
2129   MU.Lock();
2130   while (COND != 1)
2131     CV.Wait(&MU);
2132   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
2133   MU.Unlock();
2134 
2135   GLOB=2;
2136 
2137   MU.Lock();
2138   COND = 0;
2139   CV.Signal();
2140   MU.Unlock();
2141 
2142 }
2143 
Run()2144 void Run() {
2145 //  ANNOTATE_EXPECT_RACE(&GLOB, "test42. TN. debugging.");
2146   printf("test42: negative\n");
2147   MyThreadArray t(Worker1, Worker2);
2148   t.Start();
2149   t.Join();
2150   printf("\tGLOB=%d\n", GLOB);
2151 }
2152 REGISTER_TEST2(Run, 42, FEATURE|NEEDS_ANNOTATIONS);
2153 }  // namespace test42
2154 
2155 
2156 
2157 // test43: TN. {{{1
2158 namespace test43 {
2159 //
2160 // Putter:            Getter:
2161 // 1. write
2162 // 2. Q.Put() --\     .
2163 // 3. read       \--> a. Q.Get()
2164 //                    b. read
2165 int     GLOB = 0;
2166 ProducerConsumerQueue Q(INT_MAX);
Putter()2167 void Putter() {
2168   GLOB = 1;
2169   Q.Put(NULL);
2170   CHECK(GLOB == 1);
2171 }
Getter()2172 void Getter() {
2173   Q.Get();
2174   usleep(100000);
2175   CHECK(GLOB == 1);
2176 }
Run()2177 void Run() {
2178   printf("test43: negative\n");
2179   MyThreadArray t(Putter, Getter);
2180   t.Start();
2181   t.Join();
2182   printf("\tGLOB=%d\n", GLOB);
2183 }
2184 REGISTER_TEST(Run, 43)
2185 }  // namespace test43
2186 
2187 
2188 // test44: FP. {{{1
2189 namespace test44 {
2190 //
2191 // Putter:            Getter:
2192 // 1. read
2193 // 2. Q.Put() --\     .
2194 // 3. MU.Lock()  \--> a. Q.Get()
2195 // 4. write
2196 // 5. MU.Unlock()
2197 //                    b. MU.Lock()
2198 //                    c. write
2199 //                    d. MU.Unlock();
2200 int     GLOB = 0;
2201 Mutex   MU;
2202 ProducerConsumerQueue Q(INT_MAX);
Putter()2203 void Putter() {
2204   CHECK(GLOB == 0);
2205   Q.Put(NULL);
2206   MU.Lock();
2207   GLOB = 1;
2208   MU.Unlock();
2209 }
Getter()2210 void Getter() {
2211   Q.Get();
2212   usleep(100000);
2213   MU.Lock();
2214   GLOB = 1;
2215   MU.Unlock();
2216 }
Run()2217 void Run() {
2218 //  ANNOTATE_EXPECT_RACE(&GLOB, "test44. FP. Fixed by MSMProp1.");
2219   printf("test44: negative\n");
2220   MyThreadArray t(Putter, Getter);
2221   t.Start();
2222   t.Join();
2223   printf("\tGLOB=%d\n", GLOB);
2224 }
2225 REGISTER_TEST(Run, 44)
2226 }  // namespace test44
2227 
2228 
2229 // test45: TN. {{{1
2230 namespace test45 {
2231 //
2232 // Putter:            Getter:
2233 // 1. read
2234 // 2. Q.Put() --\     .
2235 // 3. MU.Lock()  \--> a. Q.Get()
2236 // 4. write
2237 // 5. MU.Unlock()
2238 //                    b. MU.Lock()
2239 //                    c. read
2240 //                    d. MU.Unlock();
2241 int     GLOB = 0;
2242 Mutex   MU;
2243 ProducerConsumerQueue Q(INT_MAX);
Putter()2244 void Putter() {
2245   CHECK(GLOB == 0);
2246   Q.Put(NULL);
2247   MU.Lock();
2248   GLOB++;
2249   MU.Unlock();
2250 }
Getter()2251 void Getter() {
2252   Q.Get();
2253   usleep(100000);
2254   MU.Lock();
2255   CHECK(GLOB <= 1);
2256   MU.Unlock();
2257 }
Run()2258 void Run() {
2259   printf("test45: negative\n");
2260   MyThreadArray t(Putter, Getter);
2261   t.Start();
2262   t.Join();
2263   printf("\tGLOB=%d\n", GLOB);
2264 }
2265 REGISTER_TEST(Run, 45)
2266 }  // namespace test45
2267 
2268 
2269 // test46: FN. {{{1
2270 namespace test46 {
2271 //
2272 // First:                             Second:
2273 // 1. write
2274 // 2. MU.Lock()
2275 // 3. write
2276 // 4. MU.Unlock()                      (sleep)
2277 //                                    a. MU.Lock()
2278 //                                    b. write
2279 //                                    c. MU.Unlock();
2280 int     GLOB = 0;
2281 Mutex   MU;
First()2282 void First() {
2283   GLOB++;
2284   MU.Lock();
2285   GLOB++;
2286   MU.Unlock();
2287 }
Second()2288 void Second() {
2289   usleep(480000);
2290   MU.Lock();
2291   GLOB++;
2292   MU.Unlock();
2293 
2294   // just a print.
2295   // If we move it to Run()  we will get report in MSMHelgrind
2296   // due to its false positive (test32).
2297   MU.Lock();
2298   printf("\tGLOB=%d\n", GLOB);
2299   MU.Unlock();
2300 }
Run()2301 void Run() {
2302   ANNOTATE_TRACE_MEMORY(&GLOB);
2303   MyThreadArray t(First, Second);
2304   t.Start();
2305   t.Join();
2306 }
2307 REGISTER_TEST(Run, 46)
2308 }  // namespace test46
2309 
2310 
2311 // test47: TP. Not detected by pure happens-before detectors. {{{1
2312 namespace test47 {
2313 // A true race that can not be detected by a pure happens-before
2314 // race detector.
2315 //
2316 // First:                             Second:
2317 // 1. write
2318 // 2. MU.Lock()
2319 // 3. MU.Unlock()                      (sleep)
2320 //                                    a. MU.Lock()
2321 //                                    b. MU.Unlock();
2322 //                                    c. write
2323 int     GLOB = 0;
2324 Mutex   MU;
First()2325 void First() {
2326   GLOB=1;
2327   MU.Lock();
2328   MU.Unlock();
2329 }
Second()2330 void Second() {
2331   usleep(480000);
2332   MU.Lock();
2333   MU.Unlock();
2334   GLOB++;
2335 }
Run()2336 void Run() {
2337   FAST_MODE_INIT(&GLOB);
2338   if (!Tsan_PureHappensBefore())
2339     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test47. TP. Not detected by pure HB.");
2340   printf("test47: positive\n");
2341   MyThreadArray t(First, Second);
2342   t.Start();
2343   t.Join();
2344   printf("\tGLOB=%d\n", GLOB);
2345 }
2346 REGISTER_TEST(Run, 47)
2347 }  // namespace test47
2348 
2349 
2350 // test48: FN. Simple race (single write vs multiple reads). {{{1
2351 namespace test48 {
2352 int     GLOB = 0;
2353 // same as test10 but with single writer and  multiple readers
2354 // A simple data race between single writer and  multiple readers.
2355 // Write happens before Reads (enforced by sleep(1)),
2356 
2357 //
2358 // Writer:                    Readers:
2359 // 1. write(GLOB)             a. sleep(long enough so that GLOB
2360 //                                is most likely initialized by Writer)
2361 //                            b. read(GLOB)
2362 //
2363 //
2364 // Eraser algorithm does not detect the race here,
2365 // see Section 2.2 of http://citeseer.ist.psu.edu/savage97eraser.html.
2366 //
Writer()2367 void Writer() {
2368   GLOB = 3;
2369 }
Reader()2370 void Reader() {
2371   usleep(100000);
2372   CHECK(GLOB != -777);
2373 }
2374 
Run()2375 void Run() {
2376   FAST_MODE_INIT(&GLOB);
2377   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test48. TP. FN in MSMHelgrind.");
2378   printf("test48: positive\n");
2379   MyThreadArray t(Writer, Reader,Reader,Reader);
2380   t.Start();
2381   t.Join();
2382   printf("\tGLOB=%d\n", GLOB);
2383 }
2384 REGISTER_TEST(Run, 48)
2385 }  // namespace test48
2386 
2387 
2388 // test49: FN. Simple race (single write vs multiple reads). {{{1
2389 namespace test49 {
2390 int     GLOB = 0;
2391 // same as test10 but with multiple read operations done by a single reader
2392 // A simple data race between writer and readers.
2393 // Write happens before Read (enforced by sleep(1)),
2394 //
2395 // Writer:                    Reader:
2396 // 1. write(GLOB)             a. sleep(long enough so that GLOB
2397 //                                is most likely initialized by Writer)
2398 //                            b. read(GLOB)
2399 //                            c. read(GLOB)
2400 //                            d. read(GLOB)
2401 //                            e. read(GLOB)
2402 //
2403 //
2404 // Eraser algorithm does not detect the race here,
2405 // see Section 2.2 of http://citeseer.ist.psu.edu/savage97eraser.html.
2406 //
Writer()2407 void Writer() {
2408   GLOB = 3;
2409 }
Reader()2410 void Reader() {
2411   usleep(100000);
2412   CHECK(GLOB != -777);
2413   CHECK(GLOB != -777);
2414   CHECK(GLOB != -777);
2415   CHECK(GLOB != -777);
2416 }
2417 
Run()2418 void Run() {
2419   FAST_MODE_INIT(&GLOB);
2420   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test49. TP. FN in MSMHelgrind.");
2421   printf("test49: positive\n");
2422   MyThreadArray t(Writer, Reader);
2423   t.Start();
2424   t.Join();
2425   printf("\tGLOB=%d\n", GLOB);
2426 }
2427 REGISTER_TEST(Run, 49);
2428 }  // namespace test49
2429 
2430 
2431 // test50: TP. Synchronization via CondVar. {{{1
2432 namespace test50 {
2433 int     GLOB = 0;
2434 Mutex   MU;
2435 // Two last write accesses to GLOB are not synchronized
2436 //
2437 // Waiter:                      Waker:
2438 // 1. COND = 0
2439 // 2. Start(Waker)
2440 // 3. MU.Lock()                 a. write(GLOB)
2441 //                              b. MU.Lock()
2442 //                              c. COND = 1
2443 //                         /--- d. CV.Signal()
2444 //  4. while(COND != 1)   /     e. MU.Unlock()
2445 //       CV.Wait(MU) <---/
2446 //  5. MU.Unlock()
2447 //  6. write(GLOB)              f. MU.Lock()
2448 //                              g. write(GLOB)
2449 //                              h. MU.Unlock()
2450 
2451 
Waker()2452 void Waker() {
2453   usleep(100000);  // Make sure the waiter blocks.
2454 
2455   GLOB = 1;
2456 
2457   MU.Lock();
2458   COND = 1;
2459   CV.Signal();
2460   MU.Unlock();
2461 
2462   usleep(100000);
2463   MU.Lock();
2464   GLOB = 3;
2465   MU.Unlock();
2466 }
2467 
Waiter()2468 void Waiter() {
2469   ThreadPool pool(1);
2470   pool.StartWorkers();
2471   COND = 0;
2472   pool.Add(NewCallback(Waker));
2473 
2474   MU.Lock();
2475   while(COND != 1)
2476     CV.Wait(&MU);
2477   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
2478   MU.Unlock();
2479 
2480   GLOB = 2;
2481 }
Run()2482 void Run() {
2483   FAST_MODE_INIT(&GLOB);
2484   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test50. TP.");
2485   printf("test50: positive\n");
2486   Waiter();
2487   printf("\tGLOB=%d\n", GLOB);
2488 }
2489 REGISTER_TEST2(Run, 50, FEATURE|NEEDS_ANNOTATIONS);
2490 }  // namespace test50
2491 
2492 
2493 // test51: TP. Synchronization via CondVar: problem with several signals. {{{1
2494 namespace test51 {
2495 int     GLOB = 0;
2496 int     COND = 0;
2497 Mutex   MU;
2498 
2499 
2500 // scheduler dependent results because of several signals
2501 // second signal will be lost
2502 //
2503 // Waiter:                      Waker:
2504 // 1. Start(Waker)
2505 // 2. MU.Lock()
2506 // 3. while(COND)
2507 //       CV.Wait(MU)<-\         .
2508 // 4. MU.Unlock()      \        .
2509 // 5. write(GLOB)       \       a. write(GLOB)
2510 //                       \      b. MU.Lock()
2511 //                        \     c. COND = 1
2512 //                         \--- d. CV.Signal()
2513 //                              e. MU.Unlock()
2514 //
2515 //                              f. write(GLOB)
2516 //
2517 //                              g. MU.Lock()
2518 //                              h. COND = 1
2519 //                    LOST<---- i. CV.Signal()
2520 //                              j. MU.Unlock()
2521 
Waker()2522 void Waker() {
2523 
2524   usleep(10000);  // Make sure the waiter blocks.
2525 
2526   GLOB = 1;
2527 
2528   MU.Lock();
2529   COND = 1;
2530   CV.Signal();
2531   MU.Unlock();
2532 
2533   usleep(10000);  // Make sure the waiter is signalled.
2534 
2535   GLOB = 2;
2536 
2537   MU.Lock();
2538   COND = 1;
2539   CV.Signal();   //Lost Signal
2540   MU.Unlock();
2541 }
2542 
Waiter()2543 void Waiter() {
2544 
2545   ThreadPool pool(1);
2546   pool.StartWorkers();
2547   pool.Add(NewCallback(Waker));
2548 
2549   MU.Lock();
2550   while(COND != 1)
2551     CV.Wait(&MU);
2552   MU.Unlock();
2553 
2554 
2555   GLOB = 3;
2556 }
Run()2557 void Run() {
2558   FAST_MODE_INIT(&GLOB);
2559   ANNOTATE_EXPECT_RACE(&GLOB, "test51. TP.");
2560   printf("test51: positive\n");
2561   Waiter();
2562   printf("\tGLOB=%d\n", GLOB);
2563 }
2564 REGISTER_TEST(Run, 51);
2565 }  // namespace test51
2566 
2567 
2568 // test52: TP. Synchronization via CondVar: problem with several signals. {{{1
2569 namespace test52 {
2570 int     GLOB = 0;
2571 int     COND = 0;
2572 Mutex   MU;
2573 
2574 // same as test51 but the first signal will be lost
2575 // scheduler dependent results because of several signals
2576 //
2577 // Waiter:                      Waker:
2578 // 1. Start(Waker)
2579 //                              a. write(GLOB)
2580 //                              b. MU.Lock()
2581 //                              c. COND = 1
2582 //                    LOST<---- d. CV.Signal()
2583 //                              e. MU.Unlock()
2584 //
2585 // 2. MU.Lock()
2586 // 3. while(COND)
2587 //       CV.Wait(MU)<-\         .
2588 // 4. MU.Unlock()      \        f. write(GLOB)
2589 // 5. write(GLOB)       \       .
2590 //                       \      g. MU.Lock()
2591 //                        \     h. COND = 1
2592 //                         \--- i. CV.Signal()
2593 //                              j. MU.Unlock()
2594 
Waker()2595 void Waker() {
2596 
2597   GLOB = 1;
2598 
2599   MU.Lock();
2600   COND = 1;
2601   CV.Signal();    //lost signal
2602   MU.Unlock();
2603 
2604   usleep(20000);  // Make sure the waiter blocks
2605 
2606   GLOB = 2;
2607 
2608   MU.Lock();
2609   COND = 1;
2610   CV.Signal();
2611   MU.Unlock();
2612 }
2613 
Waiter()2614 void Waiter() {
2615   ThreadPool pool(1);
2616   pool.StartWorkers();
2617   pool.Add(NewCallback(Waker));
2618 
2619   usleep(10000);  // Make sure the first signal will be lost
2620 
2621   MU.Lock();
2622   while(COND != 1)
2623     CV.Wait(&MU);
2624   MU.Unlock();
2625 
2626   GLOB = 3;
2627 }
Run()2628 void Run() {
2629   FAST_MODE_INIT(&GLOB);
2630   ANNOTATE_EXPECT_RACE(&GLOB, "test52. TP.");
2631   printf("test52: positive\n");
2632   Waiter();
2633   printf("\tGLOB=%d\n", GLOB);
2634 }
2635 REGISTER_TEST(Run, 52);
2636 }  // namespace test52
2637 
2638 
2639 // test53: FP. Synchronization via implicit semaphore. {{{1
2640 namespace test53 {
2641 // Correctly synchronized test, but the common lockset is empty.
2642 // The variable FLAG works as an implicit semaphore.
2643 // MSMHelgrind still does not complain since it does not maintain the lockset
2644 // at the exclusive state. But MSMProp1 does complain.
2645 // See also test54.
2646 //
2647 //
2648 // Initializer:                  Users
2649 // 1. MU1.Lock()
2650 // 2. write(GLOB)
2651 // 3. FLAG = true
2652 // 4. MU1.Unlock()
2653 //                               a. MU1.Lock()
2654 //                               b. f = FLAG;
2655 //                               c. MU1.Unlock()
2656 //                               d. if (!f) goto a.
2657 //                               e. MU2.Lock()
2658 //                               f. write(GLOB)
2659 //                               g. MU2.Unlock()
2660 //
2661 
2662 int     GLOB = 0;
2663 bool    FLAG = false;
2664 Mutex   MU1, MU2;
2665 
Initializer()2666 void Initializer() {
2667   MU1.Lock();
2668   GLOB = 1000;
2669   FLAG = true;
2670   MU1.Unlock();
2671   usleep(100000); // just in case
2672 }
2673 
User()2674 void User() {
2675   bool f = false;
2676   while(!f) {
2677     MU1.Lock();
2678     f = FLAG;
2679     MU1.Unlock();
2680     usleep(10000);
2681   }
2682   // at this point Initializer will not access GLOB again
2683   MU2.Lock();
2684   CHECK(GLOB >= 1000);
2685   GLOB++;
2686   MU2.Unlock();
2687 }
2688 
Run()2689 void Run() {
2690   FAST_MODE_INIT(&GLOB);
2691   if (!Tsan_PureHappensBefore())
2692     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test53. FP. Implicit semaphore");
2693   printf("test53: FP. false positive, Implicit semaphore\n");
2694   MyThreadArray t(Initializer, User, User);
2695   t.Start();
2696   t.Join();
2697   printf("\tGLOB=%d\n", GLOB);
2698 }
2699 REGISTER_TEST(Run, 53)
2700 }  // namespace test53
2701 
2702 
2703 // test54: TN. Synchronization via implicit semaphore. Annotated {{{1
2704 namespace test54 {
2705 // Same as test53, but annotated.
2706 int     GLOB = 0;
2707 bool    FLAG = false;
2708 Mutex   MU1, MU2;
2709 
Initializer()2710 void Initializer() {
2711   MU1.Lock();
2712   GLOB = 1000;
2713   FLAG = true;
2714   ANNOTATE_CONDVAR_SIGNAL(&GLOB);
2715   MU1.Unlock();
2716   usleep(100000); // just in case
2717 }
2718 
User()2719 void User() {
2720   bool f = false;
2721   while(!f) {
2722     MU1.Lock();
2723     f = FLAG;
2724     MU1.Unlock();
2725     usleep(10000);
2726   }
2727   // at this point Initializer will not access GLOB again
2728   ANNOTATE_CONDVAR_WAIT(&GLOB);
2729   MU2.Lock();
2730   CHECK(GLOB >= 1000);
2731   GLOB++;
2732   MU2.Unlock();
2733 }
2734 
Run()2735 void Run() {
2736   printf("test54: negative\n");
2737   MyThreadArray t(Initializer, User, User);
2738   t.Start();
2739   t.Join();
2740   printf("\tGLOB=%d\n", GLOB);
2741 }
2742 REGISTER_TEST2(Run, 54, FEATURE|NEEDS_ANNOTATIONS)
2743 }  // namespace test54
2744 
2745 
2746 // test55: FP. Synchronization with TryLock. Not easy for race detectors {{{1
2747 namespace test55 {
2748 // "Correct" synchronization with TryLock and Lock.
2749 //
2750 // This scheme is actually very risky.
2751 // It is covered in detail in this video:
2752 // http://youtube.com/watch?v=mrvAqvtWYb4 (slide 36, near 50-th minute).
2753 int     GLOB = 0;
2754 Mutex   MU;
2755 
Worker_Lock()2756 void Worker_Lock() {
2757   GLOB = 1;
2758   MU.Lock();
2759 }
2760 
Worker_TryLock()2761 void Worker_TryLock() {
2762   while (true) {
2763     if (!MU.TryLock()) {
2764       MU.Unlock();
2765       break;
2766     }
2767     else
2768       MU.Unlock();
2769     usleep(100);
2770   }
2771   GLOB = 2;
2772 }
2773 
Run()2774 void Run() {
2775   printf("test55:\n");
2776   MyThreadArray t(Worker_Lock, Worker_TryLock);
2777   t.Start();
2778   t.Join();
2779   printf("\tGLOB=%d\n", GLOB);
2780 }
2781 REGISTER_TEST2(Run, 55, FEATURE|EXCLUDE_FROM_ALL);
2782 }  // namespace test55
2783 
2784 
2785 
2786 // test56: TP. Use of ANNOTATE_BENIGN_RACE. {{{1
2787 namespace test56 {
2788 // For whatever reason the user wants to treat
2789 // a race on GLOB as a benign race.
2790 int     GLOB = 0;
2791 int     GLOB2 = 0;
2792 
Worker()2793 void Worker() {
2794   GLOB++;
2795 }
2796 
Run()2797 void Run() {
2798   ANNOTATE_BENIGN_RACE(&GLOB, "test56. Use of ANNOTATE_BENIGN_RACE.");
2799   ANNOTATE_BENIGN_RACE(&GLOB2, "No race. The tool should be silent");
2800   printf("test56: positive\n");
2801   MyThreadArray t(Worker, Worker, Worker, Worker);
2802   t.Start();
2803   t.Join();
2804   printf("\tGLOB=%d\n", GLOB);
2805 }
2806 REGISTER_TEST2(Run, 56, FEATURE|NEEDS_ANNOTATIONS)
2807 }  // namespace test56
2808 
2809 
2810 // test57: TN: Correct use of atomics. {{{1
2811 namespace test57 {
2812 int     GLOB = 0;
Writer()2813 void Writer() {
2814   for (int i = 0; i < 10; i++) {
2815     AtomicIncrement(&GLOB, 1);
2816     usleep(1000);
2817   }
2818 }
Reader()2819 void Reader() {
2820   while (GLOB < 20) usleep(1000);
2821 }
Run()2822 void Run() {
2823   printf("test57: negative\n");
2824   MyThreadArray t(Writer, Writer, Reader, Reader);
2825   t.Start();
2826   t.Join();
2827   CHECK(GLOB == 20);
2828   printf("\tGLOB=%d\n", GLOB);
2829 }
2830 REGISTER_TEST(Run, 57)
2831 }  // namespace test57
2832 
2833 
2834 // test58: TN. User defined synchronization. {{{1
2835 namespace test58 {
2836 int     GLOB1 = 1;
2837 int     GLOB2 = 2;
2838 int     FLAG1 = 0;
2839 int     FLAG2 = 0;
2840 
2841 // Correctly synchronized test, but the common lockset is empty.
2842 // The variables FLAG1 and FLAG2 used for synchronization and as
2843 // temporary variables for swapping two global values.
2844 // Such kind of synchronization is rarely used (Excluded from all tests??).
2845 
Worker2()2846 void Worker2() {
2847   FLAG1=GLOB2;
2848 
2849   while(!FLAG2)
2850     ;
2851   GLOB2=FLAG2;
2852 }
2853 
Worker1()2854 void Worker1() {
2855   FLAG2=GLOB1;
2856 
2857   while(!FLAG1)
2858     ;
2859   GLOB1=FLAG1;
2860 }
2861 
Run()2862 void Run() {
2863   printf("test58:\n");
2864   MyThreadArray t(Worker1, Worker2);
2865   t.Start();
2866   t.Join();
2867   printf("\tGLOB1=%d\n", GLOB1);
2868   printf("\tGLOB2=%d\n", GLOB2);
2869 }
2870 REGISTER_TEST2(Run, 58, FEATURE|EXCLUDE_FROM_ALL)
2871 }  // namespace test58
2872 
2873 
2874 
2875 // test59: TN. User defined synchronization. Annotated {{{1
2876 namespace test59 {
2877 int     COND1 = 0;
2878 int     COND2 = 0;
2879 int     GLOB1 = 1;
2880 int     GLOB2 = 2;
2881 int     FLAG1 = 0;
2882 int     FLAG2 = 0;
2883 // same as test 58 but annotated
2884 
Worker2()2885 void Worker2() {
2886   FLAG1=GLOB2;
2887   ANNOTATE_CONDVAR_SIGNAL(&COND2);
2888   while(!FLAG2) usleep(1);
2889   ANNOTATE_CONDVAR_WAIT(&COND1);
2890   GLOB2=FLAG2;
2891 }
2892 
Worker1()2893 void Worker1() {
2894   FLAG2=GLOB1;
2895   ANNOTATE_CONDVAR_SIGNAL(&COND1);
2896   while(!FLAG1) usleep(1);
2897   ANNOTATE_CONDVAR_WAIT(&COND2);
2898   GLOB1=FLAG1;
2899 }
2900 
Run()2901 void Run() {
2902   printf("test59: negative\n");
2903   ANNOTATE_BENIGN_RACE(&FLAG1, "synchronization via 'safe' race");
2904   ANNOTATE_BENIGN_RACE(&FLAG2, "synchronization via 'safe' race");
2905   MyThreadArray t(Worker1, Worker2);
2906   t.Start();
2907   t.Join();
2908   printf("\tGLOB1=%d\n", GLOB1);
2909   printf("\tGLOB2=%d\n", GLOB2);
2910 }
2911 REGISTER_TEST2(Run, 59, FEATURE|NEEDS_ANNOTATIONS)
2912 }  // namespace test59
2913 
2914 
2915 // test60: TN. Correct synchronization using signal-wait {{{1
2916 namespace test60 {
2917 int     COND1 = 0;
2918 int     COND2 = 0;
2919 int     GLOB1 = 1;
2920 int     GLOB2 = 2;
2921 int     FLAG2 = 0;
2922 int     FLAG1 = 0;
2923 Mutex   MU;
2924 // same as test 59 but synchronized with signal-wait.
2925 
Worker2()2926 void Worker2() {
2927   FLAG1=GLOB2;
2928 
2929   MU.Lock();
2930   COND1 = 1;
2931   CV.Signal();
2932   MU.Unlock();
2933 
2934   MU.Lock();
2935   while(COND2 != 1)
2936     CV.Wait(&MU);
2937   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
2938   MU.Unlock();
2939 
2940   GLOB2=FLAG2;
2941 }
2942 
Worker1()2943 void Worker1() {
2944   FLAG2=GLOB1;
2945 
2946   MU.Lock();
2947   COND2 = 1;
2948   CV.Signal();
2949   MU.Unlock();
2950 
2951   MU.Lock();
2952   while(COND1 != 1)
2953     CV.Wait(&MU);
2954   ANNOTATE_CONDVAR_LOCK_WAIT(&CV, &MU);
2955   MU.Unlock();
2956 
2957   GLOB1=FLAG1;
2958 }
2959 
Run()2960 void Run() {
2961   printf("test60: negative\n");
2962   MyThreadArray t(Worker1, Worker2);
2963   t.Start();
2964   t.Join();
2965   printf("\tGLOB1=%d\n", GLOB1);
2966   printf("\tGLOB2=%d\n", GLOB2);
2967 }
2968 REGISTER_TEST2(Run, 60, FEATURE|NEEDS_ANNOTATIONS)
2969 }  // namespace test60
2970 
2971 
2972 // test61: TN. Synchronization via Mutex as in happens-before, annotated. {{{1
2973 namespace test61 {
2974 Mutex MU;
2975 int     GLOB = 0;
2976 int     *P1 = NULL, *P2 = NULL;
2977 
2978 // In this test Mutex lock/unlock operations introduce happens-before relation.
2979 // We annotate the code so that MU is treated as in pure happens-before detector.
2980 
2981 
Putter()2982 void Putter() {
2983   ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&MU);
2984   MU.Lock();
2985   if (P1 == NULL) {
2986     P1 = &GLOB;
2987     *P1 = 1;
2988   }
2989   MU.Unlock();
2990 }
2991 
Getter()2992 void Getter() {
2993   bool done  = false;
2994   while (!done) {
2995     MU.Lock();
2996     if (P1) {
2997       done = true;
2998       P2 = P1;
2999       P1 = NULL;
3000     }
3001     MU.Unlock();
3002   }
3003   *P2 = 2;
3004 }
3005 
3006 
Run()3007 void Run() {
3008   printf("test61: negative\n");
3009   MyThreadArray t(Putter, Getter);
3010   t.Start();
3011   t.Join();
3012   printf("\tGLOB=%d\n", GLOB);
3013 }
3014 REGISTER_TEST2(Run, 61, FEATURE|NEEDS_ANNOTATIONS)
3015 }  // namespace test61
3016 
3017 
3018 // test62: STAB. Create as many segments as possible. {{{1
3019 namespace test62 {
3020 // Helgrind 3.3.0 will fail as it has a hard limit of < 2^24 segments.
3021 // A better scheme is to implement garbage collection for segments.
3022 ProducerConsumerQueue Q(INT_MAX);
3023 const int N = 1 << 22;
3024 
Putter()3025 void Putter() {
3026   for (int i = 0; i < N; i++){
3027     if ((i % (N / 8)) == 0) {
3028       printf("i=%d\n", i);
3029     }
3030     Q.Put(NULL);
3031   }
3032 }
3033 
Getter()3034 void Getter() {
3035   for (int i = 0; i < N; i++)
3036     Q.Get();
3037 }
3038 
Run()3039 void Run() {
3040   printf("test62:\n");
3041   MyThreadArray t(Putter, Getter);
3042   t.Start();
3043   t.Join();
3044 }
3045 REGISTER_TEST2(Run, 62, STABILITY|EXCLUDE_FROM_ALL)
3046 }  // namespace test62
3047 
3048 
3049 // test63: STAB. Create as many segments as possible and do it fast. {{{1
3050 namespace test63 {
3051 // Helgrind 3.3.0 will fail as it has a hard limit of < 2^24 segments.
3052 // A better scheme is to implement garbage collection for segments.
3053 const int N = 1 << 24;
3054 int C = 0;
3055 
Putter()3056 void Putter() {
3057   for (int i = 0; i < N; i++){
3058     if ((i % (N / 8)) == 0) {
3059       printf("i=%d\n", i);
3060     }
3061     ANNOTATE_CONDVAR_SIGNAL(&C);
3062   }
3063 }
3064 
Getter()3065 void Getter() {
3066 }
3067 
Run()3068 void Run() {
3069   printf("test63:\n");
3070   MyThreadArray t(Putter, Getter);
3071   t.Start();
3072   t.Join();
3073 }
3074 REGISTER_TEST2(Run, 63, STABILITY|EXCLUDE_FROM_ALL)
3075 }  // namespace test63
3076 
3077 
3078 // test64: TP. T2 happens-before T3, but T1 is independent. Reads in T1/T2. {{{1
3079 namespace test64 {
3080 // True race between T1 and T3:
3081 //
3082 // T1:                   T2:                   T3:
3083 // 1. read(GLOB)         (sleep)
3084 //                       a. read(GLOB)
3085 //                       b. Q.Put() ----->    A. Q.Get()
3086 //                                            B. write(GLOB)
3087 //
3088 //
3089 
3090 int     GLOB = 0;
3091 ProducerConsumerQueue Q(INT_MAX);
3092 
T1()3093 void T1() {
3094   CHECK(GLOB == 0);
3095 }
3096 
T2()3097 void T2() {
3098   usleep(100000);
3099   CHECK(GLOB == 0);
3100   Q.Put(NULL);
3101 }
3102 
T3()3103 void T3() {
3104   Q.Get();
3105   GLOB = 1;
3106 }
3107 
3108 
Run()3109 void Run() {
3110   FAST_MODE_INIT(&GLOB);
3111   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test64: TP.");
3112   printf("test64: positive\n");
3113   MyThreadArray t(T1, T2, T3);
3114   t.Start();
3115   t.Join();
3116   printf("\tGLOB=%d\n", GLOB);
3117 }
3118 REGISTER_TEST(Run, 64)
3119 }  // namespace test64
3120 
3121 
3122 // test65: TP. T2 happens-before T3, but T1 is independent. Writes in T1/T2. {{{1
3123 namespace test65 {
3124 // Similar to test64.
3125 // True race between T1 and T3:
3126 //
3127 // T1:                   T2:                   T3:
3128 // 1. MU.Lock()
3129 // 2. write(GLOB)
3130 // 3. MU.Unlock()         (sleep)
3131 //                       a. MU.Lock()
3132 //                       b. write(GLOB)
3133 //                       c. MU.Unlock()
3134 //                       d. Q.Put() ----->    A. Q.Get()
3135 //                                            B. write(GLOB)
3136 //
3137 //
3138 
3139 int     GLOB = 0;
3140 Mutex   MU;
3141 ProducerConsumerQueue Q(INT_MAX);
3142 
T1()3143 void T1() {
3144   MU.Lock();
3145   GLOB++;
3146   MU.Unlock();
3147 }
3148 
T2()3149 void T2() {
3150   usleep(100000);
3151   MU.Lock();
3152   GLOB++;
3153   MU.Unlock();
3154   Q.Put(NULL);
3155 }
3156 
T3()3157 void T3() {
3158   Q.Get();
3159   GLOB = 1;
3160 }
3161 
3162 
Run()3163 void Run() {
3164   FAST_MODE_INIT(&GLOB);
3165   if (!Tsan_PureHappensBefore())
3166     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test65. TP.");
3167   printf("test65: positive\n");
3168   MyThreadArray t(T1, T2, T3);
3169   t.Start();
3170   t.Join();
3171   printf("\tGLOB=%d\n", GLOB);
3172 }
3173 REGISTER_TEST(Run, 65)
3174 }  // namespace test65
3175 
3176 
3177 // test66: TN. Two separate pairs of signaller/waiter using the same CV. {{{1
3178 namespace test66 {
3179 int     GLOB1 = 0;
3180 int     GLOB2 = 0;
3181 int     C1 = 0;
3182 int     C2 = 0;
3183 Mutex   MU;
3184 
Signaller1()3185 void Signaller1() {
3186   GLOB1 = 1;
3187   MU.Lock();
3188   C1 = 1;
3189   CV.Signal();
3190   MU.Unlock();
3191 }
3192 
Signaller2()3193 void Signaller2() {
3194   GLOB2 = 1;
3195   usleep(100000);
3196   MU.Lock();
3197   C2 = 1;
3198   CV.Signal();
3199   MU.Unlock();
3200 }
3201 
Waiter1()3202 void Waiter1() {
3203   MU.Lock();
3204   while (C1 != 1) CV.Wait(&MU);
3205   ANNOTATE_CONDVAR_WAIT(&CV);
3206   MU.Unlock();
3207   GLOB1 = 2;
3208 }
3209 
Waiter2()3210 void Waiter2() {
3211   MU.Lock();
3212   while (C2 != 1) CV.Wait(&MU);
3213   ANNOTATE_CONDVAR_WAIT(&CV);
3214   MU.Unlock();
3215   GLOB2 = 2;
3216 }
3217 
Run()3218 void Run() {
3219   printf("test66: negative\n");
3220   MyThreadArray t(Signaller1, Signaller2, Waiter1, Waiter2);
3221   t.Start();
3222   t.Join();
3223   printf("\tGLOB=%d/%d\n", GLOB1, GLOB2);
3224 }
3225 REGISTER_TEST2(Run, 66, FEATURE|NEEDS_ANNOTATIONS)
3226 }  // namespace test66
3227 
3228 
3229 // test67: FN. Race between Signaller1 and Waiter2 {{{1
3230 namespace test67 {
3231 // Similar to test66, but there is a real race here.
3232 //
3233 // Here we create a happens-before arc between Signaller1 and Waiter2
3234 // even though there should be no such arc.
3235 // However, it's probably improssible (or just very hard) to avoid it.
3236 int     GLOB = 0;
3237 int     C1 = 0;
3238 int     C2 = 0;
3239 Mutex   MU;
3240 
Signaller1()3241 void Signaller1() {
3242   GLOB = 1;
3243   MU.Lock();
3244   C1 = 1;
3245   CV.Signal();
3246   MU.Unlock();
3247 }
3248 
Signaller2()3249 void Signaller2() {
3250   usleep(100000);
3251   MU.Lock();
3252   C2 = 1;
3253   CV.Signal();
3254   MU.Unlock();
3255 }
3256 
Waiter1()3257 void Waiter1() {
3258   MU.Lock();
3259   while (C1 != 1) CV.Wait(&MU);
3260   ANNOTATE_CONDVAR_WAIT(&CV);
3261   MU.Unlock();
3262 }
3263 
Waiter2()3264 void Waiter2() {
3265   MU.Lock();
3266   while (C2 != 1) CV.Wait(&MU);
3267   ANNOTATE_CONDVAR_WAIT(&CV);
3268   MU.Unlock();
3269   GLOB = 2;
3270 }
3271 
Run()3272 void Run() {
3273   FAST_MODE_INIT(&GLOB);
3274   ANNOTATE_EXPECT_RACE(&GLOB, "test67. FN. Race between Signaller1 and Waiter2");
3275   printf("test67: positive\n");
3276   MyThreadArray t(Signaller1, Signaller2, Waiter1, Waiter2);
3277   t.Start();
3278   t.Join();
3279   printf("\tGLOB=%d\n", GLOB);
3280 }
3281 REGISTER_TEST2(Run, 67, FEATURE|NEEDS_ANNOTATIONS|EXCLUDE_FROM_ALL)
3282 }  // namespace test67
3283 
3284 
3285 // test68: TP. Writes are protected by MU, reads are not. {{{1
3286 namespace test68 {
3287 // In this test, all writes to GLOB are protected by a mutex
3288 // but some reads go unprotected.
3289 // This is certainly a race, but in some cases such code could occur in
3290 // a correct program. For example, the unprotected reads may be used
3291 // for showing statistics and are not required to be precise.
3292 int     GLOB = 0;
3293 int     COND = 0;
3294 const int N_writers = 3;
3295 Mutex MU, MU1;
3296 
Writer()3297 void Writer() {
3298   for (int i = 0; i < 100; i++) {
3299     MU.Lock();
3300     GLOB++;
3301     MU.Unlock();
3302   }
3303 
3304   // we are done
3305   MU1.Lock();
3306   COND++;
3307   MU1.Unlock();
3308 }
3309 
Reader()3310 void Reader() {
3311   bool cont = true;
3312   while (cont) {
3313     CHECK(GLOB >= 0);
3314 
3315     // are we done?
3316     MU1.Lock();
3317     if (COND == N_writers)
3318       cont = false;
3319     MU1.Unlock();
3320     usleep(100);
3321   }
3322 }
3323 
Run()3324 void Run() {
3325   FAST_MODE_INIT(&GLOB);
3326   ANNOTATE_EXPECT_RACE(&GLOB, "TP. Writes are protected, reads are not.");
3327   printf("test68: positive\n");
3328   MyThreadArray t(Reader, Writer, Writer, Writer);
3329   t.Start();
3330   t.Join();
3331   printf("\tGLOB=%d\n", GLOB);
3332 }
3333 REGISTER_TEST(Run, 68)
3334 }  // namespace test68
3335 
3336 
3337 // test69:  {{{1
3338 namespace test69 {
3339 // This is the same as test68, but annotated.
3340 // We do not want to annotate GLOB as a benign race
3341 // because we want to allow racy reads only in certain places.
3342 //
3343 // TODO:
3344 int     GLOB = 0;
3345 int     COND = 0;
3346 const int N_writers = 3;
3347 int     FAKE_MU = 0;
3348 Mutex MU, MU1;
3349 
Writer()3350 void Writer() {
3351   for (int i = 0; i < 10; i++) {
3352     MU.Lock();
3353     GLOB++;
3354     MU.Unlock();
3355   }
3356 
3357   // we are done
3358   MU1.Lock();
3359   COND++;
3360   MU1.Unlock();
3361 }
3362 
Reader()3363 void Reader() {
3364   bool cont = true;
3365   while (cont) {
3366     ANNOTATE_IGNORE_READS_BEGIN();
3367     CHECK(GLOB >= 0);
3368     ANNOTATE_IGNORE_READS_END();
3369 
3370     // are we done?
3371     MU1.Lock();
3372     if (COND == N_writers)
3373       cont = false;
3374     MU1.Unlock();
3375     usleep(100);
3376   }
3377 }
3378 
Run()3379 void Run() {
3380   printf("test69: negative\n");
3381   MyThreadArray t(Reader, Writer, Writer, Writer);
3382   t.Start();
3383   t.Join();
3384   printf("\tGLOB=%d\n", GLOB);
3385 }
3386 REGISTER_TEST(Run, 69)
3387 }  // namespace test69
3388 
3389 // test70: STAB. Check that TRACE_MEMORY works. {{{1
3390 namespace test70 {
3391 int     GLOB = 0;
Run()3392 void Run() {
3393   printf("test70: negative\n");
3394   ANNOTATE_TRACE_MEMORY(&GLOB);
3395   GLOB = 1;
3396   printf("\tGLOB=%d\n", GLOB);
3397 }
3398 REGISTER_TEST(Run, 70)
3399 }  // namespace test70
3400 
3401 
3402 
3403 // test71: TN. strlen, index. {{{1
3404 namespace test71 {
3405 // This test is a reproducer for a benign race in strlen (as well as index, etc).
3406 // Some implementations of strlen may read up to 7 bytes past the end of the string
3407 // thus touching memory which may not belong to this string.
3408 // Such race is benign because the data read past the end of the string is not used.
3409 //
3410 // Here, we allocate a 8-byte aligned string str and initialize first 5 bytes.
3411 // Then one thread calls strlen(str) (as well as index & rindex)
3412 // and another thread initializes str[5]..str[7].
3413 //
3414 // This can be fixed in Helgrind by intercepting strlen and replacing it
3415 // with a simpler implementation.
3416 
3417 char    *str;
WorkerX()3418 void WorkerX() {
3419   usleep(100000);
3420   CHECK(strlen(str) == 4);
3421   CHECK(index(str, 'X') == str);
3422   CHECK(index(str, 'x') == str+1);
3423   CHECK(index(str, 'Y') == NULL);
3424   CHECK(rindex(str, 'X') == str+2);
3425   CHECK(rindex(str, 'x') == str+3);
3426   CHECK(rindex(str, 'Y') == NULL);
3427 }
WorkerY()3428 void WorkerY() {
3429   str[5] = 'Y';
3430   str[6] = 'Y';
3431   str[7] = '\0';
3432 }
3433 
Run()3434 void Run() {
3435   str = new char[8];
3436   str[0] = 'X';
3437   str[1] = 'x';
3438   str[2] = 'X';
3439   str[3] = 'x';
3440   str[4] = '\0';
3441 
3442   printf("test71: negative (strlen & index)\n");
3443   MyThread t1(WorkerY);
3444   MyThread t2(WorkerX);
3445   t1.Start();
3446   t2.Start();
3447   t1.Join();
3448   t2.Join();
3449   printf("\tstrX=%s; strY=%s\n", str, str+5);
3450 }
3451 REGISTER_TEST(Run, 71)
3452 }  // namespace test71
3453 
3454 
3455 // test72: STAB. Stress test for the number of segment sets (SSETs). {{{1
3456 namespace test72 {
3457 #ifndef NO_BARRIER
3458 // Variation of test33.
3459 // Instead of creating Nlog*N_iter threads,
3460 // we create Nlog threads and do N_iter barriers.
3461 int     GLOB = 0;
3462 const int N_iter = 30;
3463 const int Nlog  = 16;
3464 const int N     = 1 << Nlog;
3465 static int64_t ARR1[N];
3466 static int64_t ARR2[N];
3467 Barrier *barriers[N_iter];
3468 Mutex   MU;
3469 
Worker()3470 void Worker() {
3471   MU.Lock();
3472   int n = ++GLOB;
3473   MU.Unlock();
3474 
3475   n %= Nlog;
3476 
3477   long t0 = clock();
3478   long t __attribute__((unused)) = t0;
3479 
3480   for (int it = 0; it < N_iter; it++) {
3481     if(n == 0) {
3482       //printf("Iter: %d; %ld %ld\n", it, clock() - t, clock() - t0);
3483       t = clock();
3484     }
3485     // Iterate N_iter times, block on barrier after each iteration.
3486     // This way Helgrind will create new segments after each barrier.
3487 
3488     for (int x = 0; x < 2; x++) {
3489       // run the inner loop twice.
3490       // When a memory location is accessed second time it is likely
3491       // that the state (SVal) will be unchanged.
3492       // The memory machine may optimize this case.
3493       for (int i = 0; i < N; i++) {
3494         // ARR1[i] and ARR2[N-1-i] are accessed by threads from i-th subset
3495         if (i & (1 << n)) {
3496           CHECK(ARR1[i] == 0);
3497           CHECK(ARR2[N-1-i] == 0);
3498         }
3499       }
3500     }
3501     barriers[it]->Block();
3502   }
3503 }
3504 
3505 
Run()3506 void Run() {
3507   printf("test72:\n");
3508 
3509   std::vector<MyThread*> vec(Nlog);
3510 
3511   for (int i = 0; i < N_iter; i++)
3512     barriers[i] = new Barrier(Nlog);
3513 
3514   // Create and start Nlog threads
3515   for (int i = 0; i < Nlog; i++) {
3516     vec[i] = new MyThread(Worker);
3517     vec[i]->Start();
3518   }
3519 
3520   // Join all threads.
3521   for (int i = 0; i < Nlog; i++) {
3522     vec[i]->Join();
3523     delete vec[i];
3524   }
3525   for (int i = 0; i < N_iter; i++)
3526     delete barriers[i];
3527 
3528   /*printf("\tGLOB=%d; ARR[1]=%d; ARR[7]=%d; ARR[N-1]=%d\n",
3529          GLOB, (int)ARR1[1], (int)ARR1[7], (int)ARR1[N-1]);*/
3530 }
3531 REGISTER_TEST2(Run, 72, STABILITY|PERFORMANCE|EXCLUDE_FROM_ALL);
3532 #endif // NO_BARRIER
3533 }  // namespace test72
3534 
3535 
3536 // test73: STAB. Stress test for the number of (SSETs), different access sizes. {{{1
3537 namespace test73 {
3538 #ifndef NO_BARRIER
3539 // Variation of test72.
3540 // We perform accesses of different sizes to the same location.
3541 int     GLOB = 0;
3542 const int N_iter = 2;
3543 const int Nlog  = 16;
3544 const int N     = 1 << Nlog;
3545 union uint64_union {
3546   uint64_t u64[1];
3547   uint32_t u32[2];
3548   uint16_t u16[4];
3549   uint8_t  u8 [8];
3550 };
3551 static uint64_union ARR1[N];
3552 union uint32_union {
3553   uint32_t u32[1];
3554   uint16_t u16[2];
3555   uint8_t  u8 [4];
3556 };
3557 static uint32_union ARR2[N];
3558 Barrier *barriers[N_iter];
3559 Mutex   MU;
3560 
Worker()3561 void Worker() {
3562   MU.Lock();
3563   int n = ++GLOB;
3564   MU.Unlock();
3565 
3566   n %= Nlog;
3567 
3568   for (int it = 0; it < N_iter; it++) {
3569     // Iterate N_iter times, block on barrier after each iteration.
3570     // This way Helgrind will create new segments after each barrier.
3571 
3572     for (int x = 0; x < 4; x++) {
3573       for (int i = 0; i < N; i++) {
3574         // ARR1[i] are accessed by threads from i-th subset
3575         if (i & (1 << n)) {
3576           for (int off = 0; off < (1 << x); off++) {
3577             switch(x) {
3578               case 0: CHECK(ARR1[i].u64[off] == 0); break;
3579               case 1: CHECK(ARR1[i].u32[off] == 0); break;
3580               case 2: CHECK(ARR1[i].u16[off] == 0); break;
3581               case 3: CHECK(ARR1[i].u8 [off] == 0); break;
3582             }
3583             switch(x) {
3584               case 1: CHECK(ARR2[i].u32[off] == 0); break;
3585               case 2: CHECK(ARR2[i].u16[off] == 0); break;
3586               case 3: CHECK(ARR2[i].u8 [off] == 0); break;
3587             }
3588           }
3589         }
3590       }
3591     }
3592     barriers[it]->Block();
3593   }
3594 }
3595 
3596 
3597 
Run()3598 void Run() {
3599   printf("test73:\n");
3600 
3601   std::vector<MyThread*> vec(Nlog);
3602 
3603   for (int i = 0; i < N_iter; i++)
3604     barriers[i] = new Barrier(Nlog);
3605 
3606   // Create and start Nlog threads
3607   for (int i = 0; i < Nlog; i++) {
3608     vec[i] = new MyThread(Worker);
3609     vec[i]->Start();
3610   }
3611 
3612   // Join all threads.
3613   for (int i = 0; i < Nlog; i++) {
3614     vec[i]->Join();
3615     delete vec[i];
3616   }
3617   for (int i = 0; i < N_iter; i++)
3618     delete barriers[i];
3619 
3620   /*printf("\tGLOB=%d; ARR[1]=%d; ARR[7]=%d; ARR[N-1]=%d\n",
3621          GLOB, (int)ARR1[1], (int)ARR1[7], (int)ARR1[N-1]);*/
3622 }
3623 REGISTER_TEST2(Run, 73, STABILITY|PERFORMANCE|EXCLUDE_FROM_ALL);
3624 #endif // NO_BARRIER
3625 }  // namespace test73
3626 
3627 
3628 // test74: PERF. A lot of lock/unlock calls. {{{1
3629 namespace    test74 {
3630 const int N = 100000;
3631 Mutex   MU;
Run()3632 void Run() {
3633   printf("test74: perf\n");
3634   for (int i = 0; i < N; i++ ) {
3635     MU.Lock();
3636     MU.Unlock();
3637   }
3638 }
3639 REGISTER_TEST(Run, 74)
3640 }  // namespace test74
3641 
3642 
3643 // test75: TN. Test for sem_post, sem_wait, sem_trywait. {{{1
3644 namespace test75 {
3645 int     GLOB = 0;
3646 sem_t   sem[2];
3647 
Poster()3648 void Poster() {
3649   GLOB = 1;
3650   sem_post(&sem[0]);
3651   sem_post(&sem[1]);
3652 }
3653 
Waiter()3654 void Waiter() {
3655   sem_wait(&sem[0]);
3656   CHECK(GLOB==1);
3657 }
TryWaiter()3658 void TryWaiter() {
3659   usleep(500000);
3660   sem_trywait(&sem[1]);
3661   CHECK(GLOB==1);
3662 }
3663 
Run()3664 void Run() {
3665 #ifndef DRT_NO_SEM
3666   sem_init(&sem[0], 0, 0);
3667   sem_init(&sem[1], 0, 0);
3668 
3669   printf("test75: negative\n");
3670   {
3671     MyThreadArray t(Poster, Waiter);
3672     t.Start();
3673     t.Join();
3674   }
3675   GLOB = 2;
3676   {
3677     MyThreadArray t(Poster, TryWaiter);
3678     t.Start();
3679     t.Join();
3680   }
3681   printf("\tGLOB=%d\n", GLOB);
3682 
3683   sem_destroy(&sem[0]);
3684   sem_destroy(&sem[1]);
3685 #endif
3686 }
3687 REGISTER_TEST(Run, 75)
3688 }  // namespace test75
3689 
3690 // RefCountedClass {{{1
3691 struct RefCountedClass {
3692  public:
RefCountedClassRefCountedClass3693   RefCountedClass() {
3694     annotate_unref_ = false;
3695     ref_ = 0;
3696     data_ = 0;
3697   }
3698 
~RefCountedClassRefCountedClass3699   ~RefCountedClass() {
3700     CHECK(ref_ == 0);     // race may be reported here
3701     int data_val = data_; // and here
3702                           // if MU is not annotated
3703     data_ = 0;
3704     ref_ = -1;
3705     printf("\tRefCountedClass::data_ = %d\n", data_val);
3706   }
3707 
AccessDataRefCountedClass3708   void AccessData() {
3709     this->mu_.Lock();
3710     this->data_++;
3711     this->mu_.Unlock();
3712   }
3713 
RefRefCountedClass3714   void Ref() {
3715     MU.Lock();
3716     CHECK(ref_ >= 0);
3717     ref_++;
3718     MU.Unlock();
3719   }
3720 
UnrefRefCountedClass3721   void Unref() {
3722     MU.Lock();
3723     CHECK(ref_ > 0);
3724     ref_--;
3725     bool do_delete = ref_ == 0;
3726     if (annotate_unref_) {
3727       ANNOTATE_CONDVAR_SIGNAL(this);
3728     }
3729     MU.Unlock();
3730     if (do_delete) {
3731       if (annotate_unref_) {
3732         ANNOTATE_CONDVAR_WAIT(this);
3733       }
3734       delete this;
3735     }
3736   }
3737 
Annotate_MURefCountedClass3738   static void Annotate_MU() {
3739     ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&MU);
3740   }
AnnotateUnrefRefCountedClass3741   void AnnotateUnref() {
3742     annotate_unref_ = true;
3743   }
Annotate_RaceRefCountedClass3744   void Annotate_Race() {
3745     ANNOTATE_BENIGN_RACE(&this->data_, "needs annotation");
3746     ANNOTATE_BENIGN_RACE(&this->ref_, "needs annotation");
3747   }
3748  private:
3749   bool annotate_unref_;
3750 
3751   int data_;
3752   Mutex mu_; // protects data_
3753 
3754   int ref_;
3755   static Mutex MU; // protects ref_
3756 };
3757 
3758 Mutex RefCountedClass::MU;
3759 
3760 // test76: FP. Ref counting, no annotations. {{{1
3761 namespace test76 {
3762 #ifndef NO_BARRIER
3763 int     GLOB = 0;
3764 Barrier barrier(4);
3765 RefCountedClass *object = NULL;
Worker()3766 void Worker() {
3767   object->Ref();
3768   barrier.Block();
3769   object->AccessData();
3770   object->Unref();
3771 }
Run()3772 void Run() {
3773   printf("test76: false positive (ref counting)\n");
3774   object = new RefCountedClass;
3775   object->Annotate_Race();
3776   MyThreadArray t(Worker, Worker, Worker, Worker);
3777   t.Start();
3778   t.Join();
3779 }
3780 REGISTER_TEST2(Run, 76, FEATURE)
3781 #endif // NO_BARRIER
3782 }  // namespace test76
3783 
3784 
3785 
3786 // test77: TN. Ref counting, MU is annotated. {{{1
3787 namespace test77 {
3788 #ifndef NO_BARRIER
3789 // same as test76, but RefCountedClass::MU is annotated.
3790 int     GLOB = 0;
3791 Barrier barrier(4);
3792 RefCountedClass *object = NULL;
Worker()3793 void Worker() {
3794   object->Ref();
3795   barrier.Block();
3796   object->AccessData();
3797   object->Unref();
3798 }
Run()3799 void Run() {
3800   printf("test77: true negative (ref counting), mutex is annotated\n");
3801   RefCountedClass::Annotate_MU();
3802   object = new RefCountedClass;
3803   MyThreadArray t(Worker, Worker, Worker, Worker);
3804   t.Start();
3805   t.Join();
3806 }
3807 REGISTER_TEST(Run, 77)
3808 #endif // NO_BARRIER
3809 }  // namespace test77
3810 
3811 
3812 
3813 // test78: TN. Ref counting, Unref is annotated. {{{1
3814 namespace test78 {
3815 #ifndef NO_BARRIER
3816 // same as test76, but RefCountedClass::Unref is annotated.
3817 int     GLOB = 0;
3818 Barrier barrier(4);
3819 RefCountedClass *object = NULL;
Worker()3820 void Worker() {
3821   object->Ref();
3822   barrier.Block();
3823   object->AccessData();
3824   object->Unref();
3825 }
Run()3826 void Run() {
3827   printf("test78: true negative (ref counting), Unref is annotated\n");
3828   RefCountedClass::Annotate_MU();
3829   object = new RefCountedClass;
3830   MyThreadArray t(Worker, Worker, Worker, Worker);
3831   t.Start();
3832   t.Join();
3833 }
3834 REGISTER_TEST(Run, 78)
3835 #endif // NO_BARRIER
3836 }  // namespace test78
3837 
3838 
3839 
3840 // test79 TN. Swap. {{{1
3841 namespace test79 {
3842 #if 0
3843 typedef __gnu_cxx::hash_map<int, int> map_t;
3844 #else
3845 typedef std::map<int, int> map_t;
3846 #endif
3847 map_t   MAP;
3848 Mutex   MU;
3849 
3850 // Here we use swap to pass MAP between threads.
3851 // The synchronization is correct, but w/o ANNOTATE_MUTEX_IS_USED_AS_CONDVAR
3852 // Helgrind will complain.
3853 
Worker1()3854 void Worker1() {
3855   map_t tmp;
3856   MU.Lock();
3857   // We swap the new empty map 'tmp' with 'MAP'.
3858   MAP.swap(tmp);
3859   MU.Unlock();
3860   // tmp (which is the old version of MAP) is destroyed here.
3861 }
3862 
Worker2()3863 void Worker2() {
3864   MU.Lock();
3865   MAP[1]++;  // Just update MAP under MU.
3866   MU.Unlock();
3867 }
3868 
Worker3()3869 void Worker3() { Worker1(); }
Worker4()3870 void Worker4() { Worker2(); }
3871 
Run()3872 void Run() {
3873   ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&MU);
3874   printf("test79: negative\n");
3875   MyThreadArray t(Worker1, Worker2, Worker3, Worker4);
3876   t.Start();
3877   t.Join();
3878 }
3879 REGISTER_TEST(Run, 79)
3880 }  // namespace test79
3881 
3882 
3883 // AtomicRefCountedClass. {{{1
3884 // Same as RefCountedClass, but using atomic ops instead of mutex.
3885 struct AtomicRefCountedClass {
3886  public:
AtomicRefCountedClassAtomicRefCountedClass3887   AtomicRefCountedClass() {
3888     annotate_unref_ = false;
3889     ref_ = 0;
3890     data_ = 0;
3891   }
3892 
~AtomicRefCountedClassAtomicRefCountedClass3893   ~AtomicRefCountedClass() {
3894     CHECK(ref_ == 0);     // race may be reported here
3895     int data_val = data_; // and here
3896     data_ = 0;
3897     ref_ = -1;
3898     printf("\tRefCountedClass::data_ = %d\n", data_val);
3899   }
3900 
AccessDataAtomicRefCountedClass3901   void AccessData() {
3902     this->mu_.Lock();
3903     this->data_++;
3904     this->mu_.Unlock();
3905   }
3906 
RefAtomicRefCountedClass3907   void Ref() {
3908     AtomicIncrement(&ref_, 1);
3909   }
3910 
UnrefAtomicRefCountedClass3911   void Unref() {
3912     // DISCLAIMER: I am not sure I've implemented this correctly
3913     // (might require some memory barrier, etc).
3914     // But this implementation of reference counting is enough for
3915     // the purpose of Helgrind demonstration.
3916     AtomicIncrement(&ref_, -1);
3917     if (annotate_unref_) { ANNOTATE_CONDVAR_SIGNAL(this); }
3918     if (ref_ == 0) {
3919       if (annotate_unref_) { ANNOTATE_CONDVAR_WAIT(this); }
3920       delete this;
3921     }
3922   }
3923 
AnnotateUnrefAtomicRefCountedClass3924   void AnnotateUnref() {
3925     annotate_unref_ = true;
3926   }
Annotate_RaceAtomicRefCountedClass3927   void Annotate_Race() {
3928     ANNOTATE_BENIGN_RACE(&this->data_, "needs annotation");
3929   }
3930  private:
3931   bool annotate_unref_;
3932 
3933   Mutex mu_;
3934   int data_; // under mu_
3935 
3936   int ref_;  // used in atomic ops.
3937 };
3938 
3939 // test80: FP. Ref counting with atomics, no annotations. {{{1
3940 namespace test80 {
3941 #ifndef NO_BARRIER
3942 int     GLOB = 0;
3943 Barrier barrier(4);
3944 AtomicRefCountedClass *object = NULL;
Worker()3945 void Worker() {
3946   object->Ref();
3947   barrier.Block();
3948   object->AccessData();
3949   object->Unref(); // All the tricky stuff is here.
3950 }
Run()3951 void Run() {
3952   printf("test80: false positive (ref counting)\n");
3953   object = new AtomicRefCountedClass;
3954   object->Annotate_Race();
3955   MyThreadArray t(Worker, Worker, Worker, Worker);
3956   t.Start();
3957   t.Join();
3958 }
3959 REGISTER_TEST2(Run, 80, FEATURE|EXCLUDE_FROM_ALL)
3960 #endif // NO_BARRIER
3961 }  // namespace test80
3962 
3963 
3964 // test81: TN. Ref counting with atomics, Unref is annotated. {{{1
3965 namespace test81 {
3966 #ifndef NO_BARRIER
3967 // same as test80, but Unref is annotated.
3968 int     GLOB = 0;
3969 Barrier barrier(4);
3970 AtomicRefCountedClass *object = NULL;
Worker()3971 void Worker() {
3972   object->Ref();
3973   barrier.Block();
3974   object->AccessData();
3975   object->Unref(); // All the tricky stuff is here.
3976 }
Run()3977 void Run() {
3978   printf("test81: negative (annotated ref counting)\n");
3979   object = new AtomicRefCountedClass;
3980   object->AnnotateUnref();
3981   MyThreadArray t(Worker, Worker, Worker, Worker);
3982   t.Start();
3983   t.Join();
3984 }
3985 REGISTER_TEST2(Run, 81, FEATURE|EXCLUDE_FROM_ALL)
3986 #endif // NO_BARRIER
3987 }  // namespace test81
3988 
3989 
3990 // test82: Object published w/o synchronization. {{{1
3991 namespace test82 {
3992 
3993 // Writer creates a new object and makes the pointer visible to the Reader.
3994 // Reader waits until the object pointer is non-null and reads the object.
3995 //
3996 // On Core 2 Duo this test will sometimes (quite rarely) fail in
3997 // the CHECK below, at least if compiled with -O2.
3998 //
3999 // The sequence of events::
4000 // Thread1:                  Thread2:
4001 //   a. arr_[...] = ...
4002 //   b. foo[i]    = ...
4003 //                           A. ... = foo[i]; // non NULL
4004 //                           B. ... = arr_[...];
4005 //
4006 //  Since there is no proper synchronization, during the even (B)
4007 //  Thread2 may not see the result of the event (a).
4008 //  On x86 and x86_64 this happens due to compiler reordering instructions.
4009 //  On other arcitectures it may also happen due to cashe inconsistency.
4010 
4011 class FOO {
4012  public:
FOO()4013   FOO() {
4014     idx_ = rand() % 1024;
4015     arr_[idx_] = 77777;
4016   //   __asm__ __volatile__("" : : : "memory"); // this fixes!
4017   }
check(volatile FOO * foo)4018   static void check(volatile FOO *foo) {
4019     CHECK(foo->arr_[foo->idx_] == 77777);
4020   }
4021  private:
4022   int idx_;
4023   int arr_[1024];
4024 };
4025 
4026 const int N = 100000;
4027 static volatile FOO *foo[N];
4028 Mutex   MU;
4029 
Writer()4030 void Writer() {
4031   for (int i = 0; i < N; i++) {
4032     foo[i] = new FOO;
4033     usleep(100);
4034   }
4035 }
4036 
Reader()4037 void Reader() {
4038   for (int i = 0; i < N; i++) {
4039     while (!foo[i]) {
4040       MU.Lock();   // this is NOT a synchronization,
4041       MU.Unlock(); // it just helps foo[i] to become visible in Reader.
4042     }
4043     if ((i % 100) == 0) {
4044       printf("rd %d\n", i);
4045     }
4046     // At this point Reader() sees the new value of foo[i]
4047     // but in very rare cases will not see the new value of foo[i]->arr_.
4048     // Thus this CHECK will sometimes fail.
4049     FOO::check(foo[i]);
4050   }
4051 }
4052 
Run()4053 void Run() {
4054   printf("test82: positive\n");
4055   MyThreadArray t(Writer, Reader);
4056   t.Start();
4057   t.Join();
4058 }
4059 REGISTER_TEST2(Run, 82, FEATURE|EXCLUDE_FROM_ALL)
4060 }  // namespace test82
4061 
4062 
4063 // test83: Object published w/o synchronization (simple version){{{1
4064 namespace test83 {
4065 // A simplified version of test83 (example of a wrong code).
4066 // This test, though incorrect, will almost never fail.
4067 volatile static int *ptr = NULL;
4068 Mutex   MU;
4069 
Writer()4070 void Writer() {
4071   usleep(100);
4072   ptr = new int(777);
4073 }
4074 
Reader()4075 void Reader() {
4076   while(!ptr) {
4077     MU.Lock(); // Not a synchronization!
4078     MU.Unlock();
4079   }
4080   CHECK(*ptr == 777);
4081 }
4082 
Run()4083 void Run() {
4084 //  printf("test83: positive\n");
4085   MyThreadArray t(Writer, Reader);
4086   t.Start();
4087   t.Join();
4088 }
4089 REGISTER_TEST2(Run, 83, FEATURE|EXCLUDE_FROM_ALL)
4090 }  // namespace test83
4091 
4092 
4093 // test84: TP. True race (regression test for a bug related to atomics){{{1
4094 namespace test84 {
4095 // Helgrind should not create HB arcs for the bus lock even when
4096 // --pure-happens-before=yes is used.
4097 // Bug found in by Bart Van Assche, the test is taken from
4098 // valgrind file drd/tests/atomic_var.c.
4099 static int s_x = 0;
4100 /* s_dummy[] ensures that s_x and s_y are not in the same cache line. */
4101 static char s_dummy[512] = {0};
4102 static int s_y;
4103 
thread_func_1()4104 void thread_func_1()
4105 {
4106   s_y = 1;
4107   AtomicIncrement(&s_x, 1);
4108 }
4109 
thread_func_2()4110 void thread_func_2()
4111 {
4112   while (AtomicIncrement(&s_x, 0) == 0)
4113     ;
4114   printf("y = %d\n", s_y);
4115 }
4116 
4117 
Run()4118 void Run() {
4119   CHECK(s_dummy[0] == 0);  // Avoid compiler warning about 's_dummy unused'.
4120   printf("test84: positive\n");
4121   FAST_MODE_INIT(&s_y);
4122   ANNOTATE_EXPECT_RACE_FOR_TSAN(&s_y, "test84: TP. true race.");
4123   MyThreadArray t(thread_func_1, thread_func_2);
4124   t.Start();
4125   t.Join();
4126 }
4127 REGISTER_TEST(Run, 84)
4128 }  // namespace test84
4129 
4130 
4131 // test85: Test for RunningOnValgrind(). {{{1
4132 namespace  test85 {
4133 int     GLOB = 0;
Run()4134 void Run() {
4135   printf("test85: RunningOnValgrind() = %d\n", RunningOnValgrind());
4136 }
4137 REGISTER_TEST(Run, 85)
4138 }  // namespace test85
4139 
4140 
4141 // test86: Test for race inside DTOR: racey write to vptr. Benign. {{{1
4142 namespace test86 {
4143 // This test shows a racey access to vptr (the pointer to vtbl).
4144 // We have class A and class B derived from A.
4145 // Both classes have a virtual function f() and a virtual DTOR.
4146 // We create an object 'A *a = new B'
4147 // and pass this object from Thread1 to Thread2.
4148 // Thread2 calls a->f(). This call reads a->vtpr.
4149 // Thread1 deletes the object. B::~B waits untill the object can be destroyed
4150 // (flag_stopped == true) but at the very beginning of B::~B
4151 // a->vptr is written to.
4152 // So, we have a race on a->vptr.
4153 // On this particular test this race is benign, but test87 shows
4154 // how such race could harm.
4155 //
4156 //
4157 //
4158 // Threa1:                                            Thread2:
4159 // 1. A a* = new B;
4160 // 2. Q.Put(a); ------------\                         .
4161 //                           \-------------------->   a. a = Q.Get();
4162 //                                                    b. a->f();
4163 //                                       /---------   c. flag_stopped = true;
4164 // 3. delete a;                         /
4165 //    waits untill flag_stopped <------/
4166 //    inside the dtor
4167 //
4168 
4169 bool flag_stopped = false;
4170 Mutex mu;
4171 
4172 ProducerConsumerQueue Q(INT_MAX);  // Used to pass A* between threads.
4173 
4174 struct A {
Atest86::A4175   A()  { printf("A::A()\n"); }
~Atest86::A4176   virtual ~A() { printf("A::~A()\n"); }
ftest86::A4177   virtual void f() { }
4178 
4179   uintptr_t padding[15];
4180 } __attribute__ ((aligned (64)));
4181 
4182 struct B: A {
Btest86::B4183   B()  { printf("B::B()\n"); }
~Btest86::B4184   virtual ~B() {
4185     // The race is here.    <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
4186     printf("B::~B()\n");
4187     // wait until flag_stopped is true.
4188     mu.LockWhen(Condition(&ArgIsTrue, &flag_stopped));
4189     mu.Unlock();
4190     printf("B::~B() done\n");
4191   }
ftest86::B4192   virtual void f() { }
4193 };
4194 
Waiter()4195 void Waiter() {
4196   A *a = new B;
4197   if (!Tsan_FastMode())
4198     ANNOTATE_EXPECT_RACE(a, "test86: expected race on a->vptr");
4199   printf("Waiter: B created\n");
4200   Q.Put(a);
4201   usleep(100000); // so that Worker calls a->f() first.
4202   printf("Waiter: deleting B\n");
4203   delete a;
4204   printf("Waiter: B deleted\n");
4205   usleep(100000);
4206   printf("Waiter: done\n");
4207 }
4208 
Worker()4209 void Worker() {
4210   A *a = reinterpret_cast<A*>(Q.Get());
4211   printf("Worker: got A\n");
4212   a->f();
4213 
4214   mu.Lock();
4215   flag_stopped = true;
4216   mu.Unlock();
4217   usleep(200000);
4218   printf("Worker: done\n");
4219 }
4220 
Run()4221 void Run() {
4222   printf("test86: positive, race inside DTOR\n");
4223   MyThreadArray t(Waiter, Worker);
4224   t.Start();
4225   t.Join();
4226 }
4227 REGISTER_TEST(Run, 86)
4228 }  // namespace test86
4229 
4230 
4231 // test87: Test for race inside DTOR: racey write to vptr. Harmful.{{{1
4232 namespace test87 {
4233 // A variation of test86 where the race is harmful.
4234 // Here we have class C derived from B.
4235 // We create an object 'A *a = new C' in Thread1 and pass it to Thread2.
4236 // Thread2 calls a->f().
4237 // Thread1 calls 'delete a'.
4238 // It first calls C::~C, then B::~B where it rewrites the vptr to point
4239 // to B::vtbl. This is a problem because Thread2 might not have called a->f()
4240 // and now it will call B::f instead of C::f.
4241 //
4242 bool flag_stopped = false;
4243 Mutex mu;
4244 
4245 ProducerConsumerQueue Q(INT_MAX);  // Used to pass A* between threads.
4246 
4247 struct A {
Atest87::A4248   A()  { printf("A::A()\n"); }
~Atest87::A4249   virtual ~A() { printf("A::~A()\n"); }
4250   virtual void f() = 0; // pure virtual.
4251 };
4252 
4253 struct B: A {
Btest87::B4254   B()  { printf("B::B()\n"); }
~Btest87::B4255   virtual ~B() {
4256     // The race is here.    <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
4257     printf("B::~B()\n");
4258     // wait until flag_stopped is true.
4259     mu.LockWhen(Condition(&ArgIsTrue, &flag_stopped));
4260     mu.Unlock();
4261     printf("B::~B() done\n");
4262   }
4263   virtual void f() = 0; // pure virtual.
4264 };
4265 
4266 struct C: B {
Ctest87::C4267   C()  { printf("C::C()\n"); }
~Ctest87::C4268   virtual ~C() { printf("C::~C()\n"); }
ftest87::C4269   virtual void f() { }
4270 };
4271 
Waiter()4272 void Waiter() {
4273   A *a = new C;
4274   Q.Put(a);
4275   delete a;
4276 }
4277 
Worker()4278 void Worker() {
4279   A *a = reinterpret_cast<A*>(Q.Get());
4280   a->f();
4281 
4282   mu.Lock();
4283   flag_stopped = true;
4284   ANNOTATE_CONDVAR_SIGNAL(&mu);
4285   mu.Unlock();
4286 }
4287 
Run()4288 void Run() {
4289   printf("test87: positive, race inside DTOR\n");
4290   MyThreadArray t(Waiter, Worker);
4291   t.Start();
4292   t.Join();
4293 }
4294 REGISTER_TEST2(Run, 87, FEATURE|EXCLUDE_FROM_ALL)
4295 }  // namespace test87
4296 
4297 
4298 // test88: Test for ANNOTATE_IGNORE_WRITES_*{{{1
4299 namespace test88 {
4300 // a recey write annotated with ANNOTATE_IGNORE_WRITES_BEGIN/END.
4301 int     GLOB = 0;
Worker()4302 void Worker() {
4303   ANNOTATE_IGNORE_WRITES_BEGIN();
4304   GLOB = 1;
4305   ANNOTATE_IGNORE_WRITES_END();
4306 }
Run()4307 void Run() {
4308   printf("test88: negative, test for ANNOTATE_IGNORE_WRITES_*\n");
4309   MyThread t(Worker);
4310   t.Start();
4311   GLOB = 1;
4312   t.Join();
4313   printf("\tGLOB=%d\n", GLOB);
4314 }
4315 REGISTER_TEST(Run, 88)
4316 }  // namespace test88
4317 
4318 
4319 // test89: Test for debug info. {{{1
4320 namespace test89 {
4321 // Simlpe races with different objects (stack, heap globals; scalars, structs).
4322 // Also, if run with --trace-level=2 this test will show a sequence of
4323 // CTOR and DTOR calls.
4324 struct STRUCT {
4325   int a, b, c;
4326 };
4327 
4328 struct A {
4329   int a;
Atest89::A4330   A() {
4331     ANNOTATE_TRACE_MEMORY(&a);
4332     a = 1;
4333   }
~Atest89::A4334   virtual ~A() {
4335     a = 4;
4336   }
4337 };
4338 
4339 struct B : A {
Btest89::B4340   B()  { CHECK(a == 1); }
~Btest89::B4341   virtual ~B() { CHECK(a == 3); }
4342 };
4343 struct C : B {
Ctest89::C4344   C()  { a = 2; }
~Ctest89::C4345   virtual ~C() { a = 3; }
4346 };
4347 
4348 int            GLOBAL = 0;
4349 int           *STACK  = 0;
4350 STRUCT         GLOB_STRUCT;
4351 STRUCT        *STACK_STRUCT;
4352 STRUCT        *HEAP_STRUCT;
4353 
Worker()4354 void Worker() {
4355   GLOBAL = 1;
4356   *STACK = 1;
4357   GLOB_STRUCT.b   = 1;
4358   STACK_STRUCT->b = 1;
4359   HEAP_STRUCT->b  = 1;
4360 }
4361 
Run()4362 void Run() {
4363   int stack_var = 0;
4364   STACK = &stack_var;
4365 
4366   STRUCT stack_struct;
4367   STACK_STRUCT = &stack_struct;
4368 
4369   HEAP_STRUCT = new STRUCT;
4370 
4371   printf("test89: negative\n");
4372   MyThreadArray t(Worker, Worker);
4373   t.Start();
4374   t.Join();
4375 
4376   delete HEAP_STRUCT;
4377 
4378   A *a = new C;
4379   printf("Using 'a->a':  %d\n", a->a);
4380   delete a;
4381 }
4382 REGISTER_TEST2(Run, 89, FEATURE|EXCLUDE_FROM_ALL)
4383 }  // namespace test89
4384 
4385 
4386 // test90: FP. Test for a safely-published pointer (read-only). {{{1
4387 namespace test90 {
4388 // The Publisher creates an object and safely publishes it under a mutex.
4389 // Readers access the object read-only.
4390 // See also test91.
4391 //
4392 // Without annotations Helgrind will issue a false positive in Reader().
4393 //
4394 // Choices for annotations:
4395 //   -- ANNOTATE_CONDVAR_SIGNAL/ANNOTATE_CONDVAR_WAIT
4396 //   -- ANNOTATE_MUTEX_IS_USED_AS_CONDVAR
4397 //   -- ANNOTATE_PUBLISH_MEMORY_RANGE.
4398 
4399 int     *GLOB = 0;
4400 Mutex   MU;
4401 
Publisher()4402 void Publisher() {
4403   MU.Lock();
4404   GLOB = (int*)memalign(64, sizeof(int));
4405   *GLOB = 777;
4406   if (!Tsan_PureHappensBefore() && !Tsan_FastMode())
4407     ANNOTATE_EXPECT_RACE_FOR_TSAN(GLOB, "test90. FP. This is a false positve");
4408   MU.Unlock();
4409   usleep(200000);
4410 }
4411 
Reader()4412 void Reader() {
4413   usleep(10000);
4414   while (true) {
4415     MU.Lock();
4416     int *p = GLOB;
4417     MU.Unlock();
4418     if (p) {
4419       CHECK(*p == 777);  // Race is reported here.
4420       break;
4421     }
4422   }
4423 }
4424 
Run()4425 void Run() {
4426   printf("test90: false positive (safely published pointer).\n");
4427   MyThreadArray t(Publisher, Reader, Reader, Reader);
4428   t.Start();
4429   t.Join();
4430   printf("\t*GLOB=%d\n", *GLOB);
4431   free(GLOB);
4432 }
4433 REGISTER_TEST(Run, 90)
4434 }  // namespace test90
4435 
4436 
4437 // test91: FP. Test for a safely-published pointer (read-write). {{{1
4438 namespace test91 {
4439 // Similar to test90.
4440 // The Publisher creates an object and safely publishes it under a mutex MU1.
4441 // Accessors get the object under MU1 and access it (read/write) under MU2.
4442 //
4443 // Without annotations Helgrind will issue a false positive in Accessor().
4444 //
4445 
4446 int     *GLOB = 0;
4447 Mutex   MU, MU1, MU2;
4448 
Publisher()4449 void Publisher() {
4450   MU1.Lock();
4451   GLOB = (int*)memalign(64, sizeof(int));
4452   *GLOB = 777;
4453   if (!Tsan_PureHappensBefore() && !Tsan_FastMode())
4454     ANNOTATE_EXPECT_RACE_FOR_TSAN(GLOB, "test91. FP. This is a false positve");
4455   MU1.Unlock();
4456 }
4457 
Accessor()4458 void Accessor() {
4459   usleep(10000);
4460   while (true) {
4461     MU1.Lock();
4462     int *p = GLOB;
4463     MU1.Unlock();
4464     if (p) {
4465       MU2.Lock();
4466       (*p)++;  // Race is reported here.
4467       CHECK(*p >  777);
4468       MU2.Unlock();
4469       break;
4470     }
4471   }
4472 }
4473 
Run()4474 void Run() {
4475   printf("test91: false positive (safely published pointer, read/write).\n");
4476   MyThreadArray t(Publisher, Accessor, Accessor, Accessor);
4477   t.Start();
4478   t.Join();
4479   printf("\t*GLOB=%d\n", *GLOB);
4480   free(GLOB);
4481 }
4482 REGISTER_TEST(Run, 91)
4483 }  // namespace test91
4484 
4485 
4486 // test92: TN. Test for a safely-published pointer (read-write), annotated. {{{1
4487 namespace test92 {
4488 // Similar to test91, but annotated with ANNOTATE_PUBLISH_MEMORY_RANGE.
4489 //
4490 //
4491 // Publisher:                                       Accessors:
4492 //
4493 // 1. MU1.Lock()
4494 // 2. Create GLOB.
4495 // 3. ANNOTATE_PUBLISH_...(GLOB) -------\            .
4496 // 4. MU1.Unlock()                       \           .
4497 //                                        \          a. MU1.Lock()
4498 //                                         \         b. Get GLOB
4499 //                                          \        c. MU1.Unlock()
4500 //                                           \-->    d. Access GLOB
4501 //
4502 //  A happens-before arc is created between ANNOTATE_PUBLISH_MEMORY_RANGE and
4503 //  accesses to GLOB.
4504 
4505 struct ObjType {
4506   int arr[10];
4507 };
4508 
4509 ObjType *GLOB = 0;
4510 Mutex   MU, MU1, MU2;
4511 
Publisher()4512 void Publisher() {
4513   MU1.Lock();
4514   GLOB = new ObjType;
4515   for (int i = 0; i < 10; i++) {
4516     GLOB->arr[i] = 777;
4517   }
4518   // This annotation should go right before the object is published.
4519   ANNOTATE_PUBLISH_MEMORY_RANGE(GLOB, sizeof(*GLOB));
4520   MU1.Unlock();
4521 }
4522 
Accessor(int index)4523 void Accessor(int index) {
4524   while (true) {
4525     MU1.Lock();
4526     ObjType *p = GLOB;
4527     MU1.Unlock();
4528     if (p) {
4529       MU2.Lock();
4530       p->arr[index]++;  // W/o the annotations the race will be reported here.
4531       CHECK(p->arr[index] ==  778);
4532       MU2.Unlock();
4533       break;
4534     }
4535   }
4536 }
4537 
Accessor0()4538 void Accessor0() { Accessor(0); }
Accessor5()4539 void Accessor5() { Accessor(5); }
Accessor9()4540 void Accessor9() { Accessor(9); }
4541 
Run()4542 void Run() {
4543   printf("test92: safely published pointer, read/write, annotated.\n");
4544   MyThreadArray t(Publisher, Accessor0, Accessor5, Accessor9);
4545   t.Start();
4546   t.Join();
4547   printf("\t*GLOB=%d\n", GLOB->arr[0]);
4548 }
4549 REGISTER_TEST(Run, 92)
4550 }  // namespace test92
4551 
4552 
4553 // test93: TP. Test for incorrect usage of ANNOTATE_PUBLISH_MEMORY_RANGE. {{{1
4554 namespace test93 {
4555 int     GLOB = 0;
4556 
Reader()4557 void Reader() {
4558   CHECK(GLOB == 0);
4559 }
4560 
Publisher()4561 void Publisher() {
4562   usleep(10000);
4563   // Incorrect, used after the memory has been accessed in another thread.
4564   ANNOTATE_PUBLISH_MEMORY_RANGE(&GLOB, sizeof(GLOB));
4565 }
4566 
Run()4567 void Run() {
4568   printf("test93: positive, misuse of ANNOTATE_PUBLISH_MEMORY_RANGE\n");
4569   MyThreadArray t(Reader, Publisher);
4570   t.Start();
4571   t.Join();
4572   printf("\tGLOB=%d\n", GLOB);
4573 }
4574 REGISTER_TEST2(Run, 93, FEATURE|EXCLUDE_FROM_ALL)
4575 }  // namespace test93
4576 
4577 
4578 // test94: TP. Check do_cv_signal/fake segment logic {{{1
4579 namespace test94 {
4580 int     GLOB;
4581 
4582 int COND  = 0;
4583 int COND2 = 0;
4584 Mutex MU, MU2;
4585 CondVar CV, CV2;
4586 
Thr1()4587 void Thr1() {
4588   usleep(10000);  // Make sure the waiter blocks.
4589 
4590   GLOB = 1; // WRITE
4591 
4592   MU.Lock();
4593   COND = 1;
4594   CV.Signal();
4595   MU.Unlock();
4596 }
Thr2()4597 void Thr2() {
4598   usleep(1000*1000); // Make sure CV2.Signal() "happens after" CV.Signal()
4599   usleep(10000);  // Make sure the waiter blocks.
4600 
4601   MU2.Lock();
4602   COND2 = 1;
4603   CV2.Signal();
4604   MU2.Unlock();
4605 }
Thr3()4606 void Thr3() {
4607   MU.Lock();
4608   while(COND != 1)
4609     CV.Wait(&MU);
4610   MU.Unlock();
4611 }
Thr4()4612 void Thr4() {
4613   MU2.Lock();
4614   while(COND2 != 1)
4615     CV2.Wait(&MU2);
4616   MU2.Unlock();
4617   GLOB = 2; // READ: no HB-relation between CV.Signal and CV2.Wait !
4618 }
Run()4619 void Run() {
4620   FAST_MODE_INIT(&GLOB);
4621   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test94: TP.");
4622   printf("test94: TP. Check do_cv_signal/fake segment logic\n");
4623   MyThreadArray mta(Thr1, Thr2, Thr3, Thr4);
4624   mta.Start();
4625   mta.Join();
4626   printf("\tGLOB=%d\n", GLOB);
4627 }
4628 REGISTER_TEST(Run, 94);
4629 }  // namespace test94
4630 
4631 // test95: TP. Check do_cv_signal/fake segment logic {{{1
4632 namespace test95 {
4633 int     GLOB = 0;
4634 
4635 int COND  = 0;
4636 int COND2 = 0;
4637 Mutex MU, MU2;
4638 CondVar CV, CV2;
4639 
Thr1()4640 void Thr1() {
4641   usleep(1000*1000); // Make sure CV2.Signal() "happens before" CV.Signal()
4642   usleep(10000);  // Make sure the waiter blocks.
4643 
4644   GLOB = 1; // WRITE
4645 
4646   MU.Lock();
4647   COND = 1;
4648   CV.Signal();
4649   MU.Unlock();
4650 }
Thr2()4651 void Thr2() {
4652   usleep(10000);  // Make sure the waiter blocks.
4653 
4654   MU2.Lock();
4655   COND2 = 1;
4656   CV2.Signal();
4657   MU2.Unlock();
4658 }
Thr3()4659 void Thr3() {
4660   MU.Lock();
4661   while(COND != 1)
4662     CV.Wait(&MU);
4663   MU.Unlock();
4664 }
Thr4()4665 void Thr4() {
4666   MU2.Lock();
4667   while(COND2 != 1)
4668     CV2.Wait(&MU2);
4669   MU2.Unlock();
4670   GLOB = 2; // READ: no HB-relation between CV.Signal and CV2.Wait !
4671 }
Run()4672 void Run() {
4673   FAST_MODE_INIT(&GLOB);
4674   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test95: TP.");
4675   printf("test95: TP. Check do_cv_signal/fake segment logic\n");
4676   MyThreadArray mta(Thr1, Thr2, Thr3, Thr4);
4677   mta.Start();
4678   mta.Join();
4679   printf("\tGLOB=%d\n", GLOB);
4680 }
4681 REGISTER_TEST(Run, 95);
4682 }  // namespace test95
4683 
4684 // test96: TN. tricky LockSet behaviour {{{1
4685 // 3 threads access the same memory with three different
4686 // locksets: {A, B}, {B, C}, {C, A}.
4687 // These locksets have empty intersection
4688 namespace test96 {
4689 int     GLOB = 0;
4690 
4691 Mutex A, B, C;
4692 
Thread1()4693 void Thread1() {
4694   MutexLock a(&A);
4695   MutexLock b(&B);
4696   GLOB++;
4697 }
4698 
Thread2()4699 void Thread2() {
4700   MutexLock b(&B);
4701   MutexLock c(&C);
4702   GLOB++;
4703 }
4704 
Thread3()4705 void Thread3() {
4706   MutexLock a(&A);
4707   MutexLock c(&C);
4708   GLOB++;
4709 }
4710 
Run()4711 void Run() {
4712   printf("test96: FP. tricky LockSet behaviour\n");
4713   ANNOTATE_TRACE_MEMORY(&GLOB);
4714   MyThreadArray mta(Thread1, Thread2, Thread3);
4715   mta.Start();
4716   mta.Join();
4717   CHECK(GLOB == 3);
4718   printf("\tGLOB=%d\n", GLOB);
4719 }
4720 REGISTER_TEST(Run, 96);
4721 }  // namespace test96
4722 
4723 // test97: This test shows false negative with --fast-mode=yes {{{1
4724 namespace test97 {
4725 const int HG_CACHELINE_SIZE = 64;
4726 
4727 Mutex MU;
4728 
4729 const int ARRAY_SIZE = HG_CACHELINE_SIZE * 4 / sizeof(int);
4730 int array[ARRAY_SIZE];
4731 int * GLOB = &array[ARRAY_SIZE/2];
4732 /*
4733   We use sizeof(array) == 4 * HG_CACHELINE_SIZE to be sure that GLOB points
4734   to a memory inside a CacheLineZ which is inside array's memory range
4735  */
4736 
Reader()4737 void Reader() {
4738   usleep(500000);
4739   CHECK(777 == *GLOB);
4740 }
4741 
Run()4742 void Run() {
4743   MyThreadArray t(Reader);
4744   if (!Tsan_FastMode())
4745     ANNOTATE_EXPECT_RACE_FOR_TSAN(GLOB, "test97: TP. FN with --fast-mode=yes");
4746   printf("test97: This test shows false negative with --fast-mode=yes\n");
4747 
4748   t.Start();
4749   *GLOB = 777;
4750   t.Join();
4751 }
4752 
4753 REGISTER_TEST2(Run, 97, FEATURE)
4754 }  // namespace test97
4755 
4756 // test98: Synchronization via read/write (or send/recv). {{{1
4757 namespace test98 {
4758 // The synchronization here is done by a pair of read/write calls
4759 // that create a happens-before arc. Same may be done with send/recv.
4760 // Such synchronization is quite unusual in real programs
4761 // (why would one synchronizae via a file or socket?), but
4762 // quite possible in unittests where one threads runs for producer
4763 // and one for consumer.
4764 //
4765 // A race detector has to create a happens-before arcs for
4766 // {read,send}->{write,recv} even if the file descriptors are different.
4767 //
4768 int     GLOB = 0;
4769 int fd_out = -1;
4770 int fd_in  = -1;
4771 
Writer()4772 void Writer() {
4773   usleep(1000);
4774   GLOB = 1;
4775   const char *str = "Hey there!\n";
4776   IGNORE_RETURN_VALUE(write(fd_out, str, strlen(str) + 1));
4777 }
4778 
Reader()4779 void Reader() {
4780   char buff[100];
4781   while (read(fd_in, buff, 100) == 0)
4782     sleep(1);
4783   printf("read: %s\n", buff);
4784   GLOB = 2;
4785 }
4786 
Run()4787 void Run() {
4788   printf("test98: negative, synchronization via I/O\n");
4789   char in_name[100];
4790   char out_name[100];
4791   // we open two files, on for reading and one for writing,
4792   // but the files are actually the same (symlinked).
4793   sprintf(out_name, "/tmp/racecheck_unittest_out.%ld", (long) getpid());
4794   fd_out = creat(out_name, O_WRONLY | S_IRWXU);
4795 #ifdef VGO_darwin
4796   // symlink() is not supported on Darwin. Copy the output file name.
4797   strcpy(in_name, out_name);
4798 #else
4799   sprintf(in_name,  "/tmp/racecheck_unittest_in.%ld", (long) getpid());
4800   IGNORE_RETURN_VALUE(symlink(out_name, in_name));
4801 #endif
4802   fd_in  = open(in_name, 0, O_RDONLY);
4803   CHECK(fd_out >= 0);
4804   CHECK(fd_in  >= 0);
4805   MyThreadArray t(Writer, Reader);
4806   t.Start();
4807   t.Join();
4808   printf("\tGLOB=%d\n", GLOB);
4809   // cleanup
4810   close(fd_in);
4811   close(fd_out);
4812   unlink(in_name);
4813   unlink(out_name);
4814 }
4815 REGISTER_TEST(Run, 98)
4816 }  // namespace test98
4817 
4818 
4819 // test99: TP. Unit test for a bug in LockWhen*. {{{1
4820 namespace test99 {
4821 
4822 
4823 bool GLOB = false;
4824 Mutex mu;
4825 
Thread1()4826 static void Thread1() {
4827   for (int i = 0; i < 100; i++) {
4828     mu.LockWhenWithTimeout(Condition(&ArgIsTrue, &GLOB), 5);
4829     GLOB = false;
4830     mu.Unlock();
4831     usleep(10000);
4832   }
4833 }
4834 
Thread2()4835 static void Thread2() {
4836   for (int i = 0; i < 100; i++) {
4837     mu.Lock();
4838     mu.Unlock();
4839     usleep(10000);
4840   }
4841 }
4842 
Run()4843 void Run() {
4844   printf("test99: regression test for LockWhen*\n");
4845   MyThreadArray t(Thread1, Thread2);
4846   t.Start();
4847   t.Join();
4848 }
4849 REGISTER_TEST(Run, 99);
4850 }  // namespace test99
4851 
4852 
4853 // test100: Test for initialization bit. {{{1
4854 namespace test100 {
4855 int     G1 = 0;
4856 int     G2 = 0;
4857 int     G3 = 0;
4858 int     G4 = 0;
4859 
Creator()4860 void Creator() {
4861   G1 = 1; CHECK(G1);
4862   G2 = 1;
4863   G3 = 1; CHECK(G3);
4864   G4 = 1;
4865 }
4866 
Worker1()4867 void Worker1() {
4868   usleep(100000);
4869   CHECK(G1);
4870   CHECK(G2);
4871   G3 = 3;
4872   G4 = 3;
4873 }
4874 
Worker2()4875 void Worker2() {
4876 
4877 }
4878 
4879 
Run()4880 void Run() {
4881   printf("test100: test for initialization bit. \n");
4882   MyThreadArray t(Creator, Worker1, Worker2);
4883   ANNOTATE_TRACE_MEMORY(&G1);
4884   ANNOTATE_TRACE_MEMORY(&G2);
4885   ANNOTATE_TRACE_MEMORY(&G3);
4886   ANNOTATE_TRACE_MEMORY(&G4);
4887   t.Start();
4888   t.Join();
4889 }
4890 REGISTER_TEST2(Run, 100, FEATURE|EXCLUDE_FROM_ALL)
4891 }  // namespace test100
4892 
4893 
4894 // test101: TN. Two signals and two waits. {{{1
4895 namespace test101 {
4896 Mutex MU;
4897 CondVar CV;
4898 int     GLOB = 0;
4899 
4900 int C1 = 0, C2 = 0;
4901 
Signaller()4902 void Signaller() {
4903   usleep(100000);
4904   MU.Lock();
4905   C1 = 1;
4906   CV.Signal();
4907   printf("signal\n");
4908   MU.Unlock();
4909 
4910   GLOB = 1;
4911 
4912   usleep(500000);
4913   MU.Lock();
4914   C2 = 1;
4915   CV.Signal();
4916   printf("signal\n");
4917   MU.Unlock();
4918 }
4919 
Waiter()4920 void Waiter() {
4921   MU.Lock();
4922   while(!C1)
4923     CV.Wait(&MU);
4924   printf("wait\n");
4925   MU.Unlock();
4926 
4927   MU.Lock();
4928   while(!C2)
4929     CV.Wait(&MU);
4930   printf("wait\n");
4931   MU.Unlock();
4932 
4933   GLOB = 2;
4934 
4935 }
4936 
Run()4937 void Run() {
4938   printf("test101: negative\n");
4939   MyThreadArray t(Waiter, Signaller);
4940   t.Start();
4941   t.Join();
4942   printf("\tGLOB=%d\n", GLOB);
4943 }
4944 REGISTER_TEST(Run, 101)
4945 }  // namespace test101
4946 
4947 // test102: --fast-mode=yes vs. --initialization-bit=yes {{{1
4948 namespace test102 {
4949 const int HG_CACHELINE_SIZE = 64;
4950 
4951 Mutex MU;
4952 
4953 const int ARRAY_SIZE = HG_CACHELINE_SIZE * 4 / sizeof(int);
4954 int array[ARRAY_SIZE + 1];
4955 int * GLOB = &array[ARRAY_SIZE/2];
4956 /*
4957   We use sizeof(array) == 4 * HG_CACHELINE_SIZE to be sure that GLOB points
4958   to a memory inside a CacheLineZ which is inside array's memory range
4959 */
4960 
Reader()4961 void Reader() {
4962   usleep(200000);
4963   CHECK(777 == GLOB[0]);
4964   usleep(400000);
4965   CHECK(777 == GLOB[1]);
4966 }
4967 
Run()4968 void Run() {
4969   MyThreadArray t(Reader);
4970   if (!Tsan_FastMode())
4971     ANNOTATE_EXPECT_RACE_FOR_TSAN(GLOB+0, "test102: TP. FN with --fast-mode=yes");
4972   ANNOTATE_EXPECT_RACE_FOR_TSAN(GLOB+1, "test102: TP");
4973   printf("test102: --fast-mode=yes vs. --initialization-bit=yes\n");
4974 
4975   t.Start();
4976   GLOB[0] = 777;
4977   usleep(400000);
4978   GLOB[1] = 777;
4979   t.Join();
4980 }
4981 
4982 REGISTER_TEST2(Run, 102, FEATURE)
4983 }  // namespace test102
4984 
4985 // test103: Access different memory locations with different LockSets {{{1
4986 namespace test103 {
4987 const int N_MUTEXES = 6;
4988 const int LOCKSET_INTERSECTION_SIZE = 3;
4989 
4990 int data[1 << LOCKSET_INTERSECTION_SIZE] = {0};
4991 Mutex MU[N_MUTEXES];
4992 
LS_to_idx(int ls)4993 inline int LS_to_idx (int ls) {
4994   return (ls >> (N_MUTEXES - LOCKSET_INTERSECTION_SIZE))
4995       & ((1 << LOCKSET_INTERSECTION_SIZE) - 1);
4996 }
4997 
Worker()4998 void Worker() {
4999   for (int ls = 0; ls < (1 << N_MUTEXES); ls++) {
5000     if (LS_to_idx(ls) == 0)
5001       continue;
5002     for (int m = 0; m < N_MUTEXES; m++)
5003       if (ls & (1 << m))
5004         MU[m].Lock();
5005 
5006     data[LS_to_idx(ls)]++;
5007 
5008     for (int m = N_MUTEXES - 1; m >= 0; m--)
5009       if (ls & (1 << m))
5010         MU[m].Unlock();
5011   }
5012 }
5013 
Run()5014 void Run() {
5015   printf("test103: Access different memory locations with different LockSets\n");
5016   MyThreadArray t(Worker, Worker, Worker, Worker);
5017   t.Start();
5018   t.Join();
5019 }
5020 REGISTER_TEST2(Run, 103, FEATURE)
5021 }  // namespace test103
5022 
5023 // test104: TP. Simple race (write vs write). Heap mem. {{{1
5024 namespace test104 {
5025 int     *GLOB = NULL;
Worker()5026 void Worker() {
5027   *GLOB = 1;
5028 }
5029 
Parent()5030 void Parent() {
5031   MyThread t(Worker);
5032   t.Start();
5033   usleep(100000);
5034   *GLOB = 2;
5035   t.Join();
5036 }
Run()5037 void Run() {
5038   GLOB = (int*)memalign(64, sizeof(int));
5039   *GLOB = 0;
5040   ANNOTATE_EXPECT_RACE(GLOB, "test104. TP.");
5041   ANNOTATE_TRACE_MEMORY(GLOB);
5042   printf("test104: positive\n");
5043   Parent();
5044   printf("\tGLOB=%d\n", *GLOB);
5045   free(GLOB);
5046 }
5047 REGISTER_TEST(Run, 104);
5048 }  // namespace test104
5049 
5050 
5051 // test105: Checks how stack grows. {{{1
5052 namespace test105 {
5053 int     GLOB = 0;
5054 
F1()5055 void F1() {
5056   int ar[32] __attribute__((unused));
5057 //  ANNOTATE_TRACE_MEMORY(&ar[0]);
5058 //  ANNOTATE_TRACE_MEMORY(&ar[31]);
5059   ar[0] = 1;
5060   ar[31] = 1;
5061 }
5062 
Worker()5063 void Worker() {
5064   int ar[32] __attribute__((unused));
5065 //  ANNOTATE_TRACE_MEMORY(&ar[0]);
5066 //  ANNOTATE_TRACE_MEMORY(&ar[31]);
5067   ar[0] = 1;
5068   ar[31] = 1;
5069   F1();
5070 }
5071 
Run()5072 void Run() {
5073   printf("test105: negative\n");
5074   Worker();
5075   MyThread t(Worker);
5076   t.Start();
5077   t.Join();
5078   printf("\tGLOB=%d\n", GLOB);
5079 }
5080 REGISTER_TEST(Run, 105)
5081 }  // namespace test105
5082 
5083 
5084 // test106: TN. pthread_once. {{{1
5085 namespace test106 {
5086 int     *GLOB = NULL;
5087 static pthread_once_t once = PTHREAD_ONCE_INIT;
Init()5088 void Init() {
5089   GLOB = new int;
5090   ANNOTATE_TRACE_MEMORY(GLOB);
5091   *GLOB = 777;
5092 }
5093 
Worker0()5094 void Worker0() {
5095   pthread_once(&once, Init);
5096 }
Worker1()5097 void Worker1() {
5098   usleep(100000);
5099   pthread_once(&once, Init);
5100   CHECK(*GLOB == 777);
5101 }
5102 
5103 
Run()5104 void Run() {
5105   printf("test106: negative\n");
5106   MyThreadArray t(Worker0, Worker1, Worker1, Worker1);
5107   t.Start();
5108   t.Join();
5109   printf("\tGLOB=%d\n", *GLOB);
5110 }
5111 REGISTER_TEST2(Run, 106, FEATURE)
5112 }  // namespace test106
5113 
5114 
5115 // test107: Test for ANNOTATE_EXPECT_RACE {{{1
5116 namespace test107 {
5117 int     GLOB = 0;
Run()5118 void Run() {
5119   printf("test107: negative\n");
5120   ANNOTATE_EXPECT_RACE(&GLOB, "No race in fact. Just checking the tool.");
5121   printf("\tGLOB=%d\n", GLOB);
5122 }
5123 REGISTER_TEST2(Run, 107, FEATURE|EXCLUDE_FROM_ALL)
5124 }  // namespace test107
5125 
5126 
5127 // test108: TN. initialization of static object. {{{1
5128 namespace test108 {
5129 // Here we have a function-level static object.
5130 // Starting from gcc 4 this is therad safe,
5131 // but is is not thread safe with many other compilers.
5132 //
5133 // Helgrind supports this kind of initialization by
5134 // intercepting __cxa_guard_acquire/__cxa_guard_release
5135 // and ignoring all accesses between them.
5136 // Helgrind also intercepts pthread_once in the same manner.
5137 class Foo {
5138  public:
Foo()5139   Foo() {
5140     ANNOTATE_TRACE_MEMORY(&a_);
5141     a_ = 42;
5142   }
Check() const5143   void Check() const { CHECK(a_ == 42); }
5144  private:
5145   int a_;
5146 };
5147 
GetFoo()5148 const Foo *GetFoo() {
5149   static const Foo *foo = new Foo();
5150   return foo;
5151 }
Worker0()5152 void Worker0() {
5153   GetFoo();
5154 }
5155 
Worker()5156 void Worker() {
5157   usleep(200000);
5158   const Foo *foo = GetFoo();
5159   foo->Check();
5160 }
5161 
5162 
Run()5163 void Run() {
5164   printf("test108: negative, initialization of static object\n");
5165   MyThreadArray t(Worker0, Worker, Worker);
5166   t.Start();
5167   t.Join();
5168 }
5169 REGISTER_TEST2(Run, 108, FEATURE)
5170 }  // namespace test108
5171 
5172 
5173 // test109: TN. Checking happens before between parent and child threads. {{{1
5174 namespace test109 {
5175 // Check that the detector correctly connects
5176 //   pthread_create with the new thread
5177 // and
5178 //   thread exit with pthread_join
5179 const int N = 32;
5180 static int GLOB[N];
5181 
Worker(void * a)5182 void Worker(void *a) {
5183   usleep(10000);
5184 //  printf("--Worker : %ld %p\n", (int*)a - GLOB, (void*)pthread_self());
5185   int *arg = (int*)a;
5186   (*arg)++;
5187 }
5188 
Run()5189 void Run() {
5190   printf("test109: negative\n");
5191   MyThread *t[N];
5192   for (int i  = 0; i < N; i++) {
5193     t[i] = new MyThread(Worker, &GLOB[i]);
5194   }
5195   for (int i  = 0; i < N; i++) {
5196     ANNOTATE_TRACE_MEMORY(&GLOB[i]);
5197     GLOB[i] = 1;
5198     t[i]->Start();
5199 //    printf("--Started: %p\n", (void*)t[i]->tid());
5200   }
5201   for (int i  = 0; i < N; i++) {
5202 //    printf("--Joining: %p\n", (void*)t[i]->tid());
5203     t[i]->Join();
5204 //    printf("--Joined : %p\n", (void*)t[i]->tid());
5205     GLOB[i]++;
5206   }
5207   for (int i  = 0; i < N; i++) delete t[i];
5208 
5209   printf("\tGLOB=%d\n", GLOB[13]);
5210 }
5211 REGISTER_TEST(Run, 109)
5212 }  // namespace test109
5213 
5214 
5215 // test110: TP. Simple races with stack, global and heap objects. {{{1
5216 namespace test110 {
5217 int        GLOB = 0;
5218 static int STATIC;
5219 
5220 int       *STACK = 0;
5221 
5222 int       *MALLOC;
5223 int       *CALLOC;
5224 int       *REALLOC;
5225 int       *VALLOC;
5226 int       *PVALLOC;
5227 int       *MEMALIGN;
5228 union pi_pv_union { int* pi; void* pv; } POSIX_MEMALIGN;
5229 int       *MMAP;
5230 
5231 int       *NEW;
5232 int       *NEW_ARR;
5233 
Worker()5234 void Worker() {
5235   GLOB++;
5236   STATIC++;
5237 
5238   (*STACK)++;
5239 
5240   (*MALLOC)++;
5241   (*CALLOC)++;
5242   (*REALLOC)++;
5243   (*VALLOC)++;
5244   (*PVALLOC)++;
5245   (*MEMALIGN)++;
5246   (*(POSIX_MEMALIGN.pi))++;
5247   (*MMAP)++;
5248 
5249   (*NEW)++;
5250   (*NEW_ARR)++;
5251 }
Run()5252 void Run() {
5253   int x = 0;
5254   STACK = &x;
5255 
5256   MALLOC = (int*)malloc(sizeof(int));
5257   CALLOC = (int*)calloc(1, sizeof(int));
5258   REALLOC = (int*)realloc(NULL, sizeof(int));
5259   VALLOC = (int*)valloc(sizeof(int));
5260   PVALLOC = (int*)valloc(sizeof(int));  // TODO: pvalloc breaks helgrind.
5261   MEMALIGN = (int*)memalign(64, sizeof(int));
5262   CHECK(0 == posix_memalign(&POSIX_MEMALIGN.pv, 64, sizeof(int)));
5263   MMAP = (int*)mmap(NULL, sizeof(int), PROT_READ | PROT_WRITE,
5264                     MAP_PRIVATE | MAP_ANON, -1, 0);
5265 
5266   NEW     = new int;
5267   NEW_ARR = new int[10];
5268 
5269 
5270   FAST_MODE_INIT(STACK);
5271   ANNOTATE_EXPECT_RACE(STACK, "real race on stack object");
5272   FAST_MODE_INIT(&GLOB);
5273   ANNOTATE_EXPECT_RACE(&GLOB, "real race on global object");
5274   FAST_MODE_INIT(&STATIC);
5275   ANNOTATE_EXPECT_RACE(&STATIC, "real race on a static global object");
5276   FAST_MODE_INIT(MALLOC);
5277   ANNOTATE_EXPECT_RACE(MALLOC, "real race on a malloc-ed object");
5278   FAST_MODE_INIT(CALLOC);
5279   ANNOTATE_EXPECT_RACE(CALLOC, "real race on a calloc-ed object");
5280   FAST_MODE_INIT(REALLOC);
5281   ANNOTATE_EXPECT_RACE(REALLOC, "real race on a realloc-ed object");
5282   FAST_MODE_INIT(VALLOC);
5283   ANNOTATE_EXPECT_RACE(VALLOC, "real race on a valloc-ed object");
5284   FAST_MODE_INIT(PVALLOC);
5285   ANNOTATE_EXPECT_RACE(PVALLOC, "real race on a pvalloc-ed object");
5286   FAST_MODE_INIT(MEMALIGN);
5287   ANNOTATE_EXPECT_RACE(MEMALIGN, "real race on a memalign-ed object");
5288   FAST_MODE_INIT(POSIX_MEMALIGN.pi);
5289   ANNOTATE_EXPECT_RACE(POSIX_MEMALIGN.pi, "real race on a posix_memalign-ed object");
5290   FAST_MODE_INIT(MMAP);
5291   ANNOTATE_EXPECT_RACE(MMAP, "real race on a mmap-ed object");
5292 
5293   FAST_MODE_INIT(NEW);
5294   ANNOTATE_EXPECT_RACE(NEW, "real race on a new-ed object");
5295   FAST_MODE_INIT(NEW_ARR);
5296   ANNOTATE_EXPECT_RACE(NEW_ARR, "real race on a new[]-ed object");
5297 
5298   MyThreadArray t(Worker, Worker, Worker);
5299   t.Start();
5300   t.Join();
5301   printf("test110: positive (race on a stack object)\n");
5302   printf("\tSTACK=%d\n", *STACK);
5303   CHECK(GLOB <= 3);
5304   CHECK(STATIC <= 3);
5305 
5306   free(MALLOC);
5307   free(CALLOC);
5308   free(REALLOC);
5309   free(VALLOC);
5310   free(PVALLOC);
5311   free(MEMALIGN);
5312   free(POSIX_MEMALIGN.pv);
5313   munmap(MMAP, sizeof(int));
5314   delete NEW;
5315   delete [] NEW_ARR;
5316 }
5317 REGISTER_TEST(Run, 110)
5318 }  // namespace test110
5319 
5320 
5321 // test111: TN. Unit test for a bug related to stack handling. {{{1
5322 namespace test111 {
5323 char     *GLOB = 0;
5324 bool COND = false;
5325 Mutex mu;
5326 const int N = 3000;
5327 
write_to_p(char * p,int val)5328 void write_to_p(char *p, int val) {
5329   for (int i = 0; i < N; i++)
5330     p[i] = val;
5331 }
5332 
ArgIsTrue(bool * arg)5333 static bool ArgIsTrue(bool *arg) {
5334 //  printf("ArgIsTrue: %d tid=%d\n", *arg, (int)pthread_self());
5335   return *arg == true;
5336 }
5337 
f1()5338 void f1() {
5339   char some_stack[N];
5340   write_to_p(some_stack, 1);
5341   mu.LockWhen(Condition(&ArgIsTrue, &COND));
5342   mu.Unlock();
5343 }
5344 
f2()5345 void f2() {
5346   char some_stack[N];
5347   char some_more_stack[N];
5348   write_to_p(some_stack, 2);
5349   write_to_p(some_more_stack, 2);
5350 }
5351 
f0()5352 void f0() { f2(); }
5353 
Worker1()5354 void Worker1() {
5355   f0();
5356   f1();
5357   f2();
5358 }
5359 
Worker2()5360 void Worker2() {
5361   usleep(100000);
5362   mu.Lock();
5363   COND = true;
5364   mu.Unlock();
5365 }
5366 
Run()5367 void Run() {
5368   printf("test111: regression test\n");
5369   MyThreadArray t(Worker1, Worker1, Worker2);
5370 //  AnnotateSetVerbosity(__FILE__, __LINE__, 3);
5371   t.Start();
5372   t.Join();
5373 //  AnnotateSetVerbosity(__FILE__, __LINE__, 1);
5374 }
5375 REGISTER_TEST2(Run, 111, FEATURE)
5376 }  // namespace test111
5377 
5378 // test112: STAB. Test for ANNOTATE_PUBLISH_MEMORY_RANGE{{{1
5379 namespace test112 {
5380 char     *GLOB = 0;
5381 const int N = 64 * 5;
5382 Mutex mu;
5383 bool ready = false; // under mu
5384 int beg, end; // under mu
5385 
5386 Mutex mu1;
5387 
Worker()5388 void Worker() {
5389 
5390   bool is_ready = false;
5391   int b, e;
5392   while (!is_ready) {
5393     mu.Lock();
5394     is_ready = ready;
5395     b = beg;
5396     e = end;
5397     mu.Unlock();
5398     usleep(1000);
5399   }
5400 
5401   mu1.Lock();
5402   for (int i = b; i < e; i++) {
5403     GLOB[i]++;
5404   }
5405   mu1.Unlock();
5406 }
5407 
PublishRange(int b,int e)5408 void PublishRange(int b, int e) {
5409   MyThreadArray t(Worker, Worker);
5410   ready = false; // runs before other threads
5411   t.Start();
5412 
5413   ANNOTATE_NEW_MEMORY(GLOB + b, e - b);
5414   ANNOTATE_TRACE_MEMORY(GLOB + b);
5415   for (int j = b; j < e; j++) {
5416     GLOB[j] = 0;
5417   }
5418   ANNOTATE_PUBLISH_MEMORY_RANGE(GLOB + b, e - b);
5419 
5420   // hand off
5421   mu.Lock();
5422   ready = true;
5423   beg = b;
5424   end = e;
5425   mu.Unlock();
5426 
5427   t.Join();
5428 }
5429 
Run()5430 void Run() {
5431   printf("test112: stability (ANNOTATE_PUBLISH_MEMORY_RANGE)\n");
5432   GLOB = new char [N];
5433 
5434   PublishRange(0, 10);
5435   PublishRange(3, 5);
5436 
5437   PublishRange(12, 13);
5438   PublishRange(10, 14);
5439 
5440   PublishRange(15, 17);
5441   PublishRange(16, 18);
5442 
5443   // do few more random publishes.
5444   for (int i = 0; i < 20; i++) {
5445     const int begin = rand() % N;
5446     const int size = (rand() % (N - begin)) + 1;
5447     CHECK(size > 0);
5448     CHECK(begin + size <= N);
5449     PublishRange(begin, begin + size);
5450   }
5451 
5452   printf("GLOB = %d\n", (int)GLOB[0]);
5453 }
5454 REGISTER_TEST2(Run, 112, STABILITY)
5455 }  // namespace test112
5456 
5457 
5458 // test113: PERF. A lot of lock/unlock calls. Many locks {{{1
5459 namespace    test113 {
5460 const int kNumIter = 100000;
5461 const int kNumLocks = 7;
5462 Mutex   MU[kNumLocks];
Run()5463 void Run() {
5464   printf("test113: perf\n");
5465   for (int i = 0; i < kNumIter; i++ ) {
5466     for (int j = 0; j < kNumLocks; j++) {
5467       if (i & (1 << j)) MU[j].Lock();
5468     }
5469     for (int j = kNumLocks - 1; j >= 0; j--) {
5470       if (i & (1 << j)) MU[j].Unlock();
5471     }
5472   }
5473 }
5474 REGISTER_TEST(Run, 113)
5475 }  // namespace test113
5476 
5477 
5478 // test114: STAB. Recursive lock. {{{1
5479 namespace    test114 {
Bar()5480 int Bar() {
5481   static int bar = 1;
5482   return bar;
5483 }
Foo()5484 int Foo() {
5485   static int foo = Bar();
5486   return foo;
5487 }
Worker()5488 void Worker() {
5489   static int x = Foo();
5490   CHECK(x == 1);
5491 }
Run()5492 void Run() {
5493   printf("test114: stab\n");
5494   MyThreadArray t(Worker, Worker);
5495   t.Start();
5496   t.Join();
5497 }
5498 REGISTER_TEST(Run, 114)
5499 }  // namespace test114
5500 
5501 
5502 // test115: TN. sem_open. {{{1
5503 namespace    test115 {
5504 int tid = 0;
5505 Mutex mu;
5506 const char *kSemName = "drt-test-sem";
5507 
5508 int GLOB = 0;
5509 
DoSemOpen()5510 sem_t *DoSemOpen() {
5511   // TODO: there is some race report inside sem_open
5512   // for which suppressions do not work... (???)
5513   ANNOTATE_IGNORE_WRITES_BEGIN();
5514   sem_t *sem = sem_open(kSemName, O_CREAT, 0600, 3);
5515   ANNOTATE_IGNORE_WRITES_END();
5516   return sem;
5517 }
5518 
Worker()5519 void Worker() {
5520   mu.Lock();
5521   int my_tid = tid++;
5522   mu.Unlock();
5523 
5524   if (my_tid == 0) {
5525     GLOB = 1;
5526   }
5527 
5528   // if the detector observes a happens-before arc between
5529   // sem_open and sem_wait, it will be silent.
5530   sem_t *sem = DoSemOpen();
5531   usleep(100000);
5532   CHECK(sem != SEM_FAILED);
5533   CHECK(sem_wait(sem) == 0);
5534 
5535   if (my_tid > 0) {
5536     CHECK(GLOB == 1);
5537   }
5538 }
5539 
Run()5540 void Run() {
5541   printf("test115: stab (sem_open())\n");
5542 
5543   // just check that sem_open is not completely broken
5544   sem_unlink(kSemName);
5545   sem_t* sem = DoSemOpen();
5546   CHECK(sem != SEM_FAILED);
5547   CHECK(sem_wait(sem) == 0);
5548   sem_unlink(kSemName);
5549 
5550   // check that sem_open and sem_wait create a happens-before arc.
5551   MyThreadArray t(Worker, Worker, Worker);
5552   t.Start();
5553   t.Join();
5554   // clean up
5555   sem_unlink(kSemName);
5556 }
5557 REGISTER_TEST(Run, 115)
5558 }  // namespace test115
5559 
5560 
5561 // test116: TN. some operations with string<> objects. {{{1
5562 namespace test116 {
5563 
Worker()5564 void Worker() {
5565   string A[10], B[10], C[10];
5566   for (int i = 0; i < 1000; i++) {
5567     for (int j = 0; j < 10; j++) {
5568       string &a = A[j];
5569       string &b = B[j];
5570       string &c = C[j];
5571       a = "sdl;fkjhasdflksj df";
5572       b = "sdf sdf;ljsd ";
5573       c = "'sfdf df";
5574       c = b;
5575       a = c;
5576       b = a;
5577       swap(a,b);
5578       swap(b,c);
5579     }
5580     for (int j = 0; j < 10; j++) {
5581       string &a = A[j];
5582       string &b = B[j];
5583       string &c = C[j];
5584       a.clear();
5585       b.clear();
5586       c.clear();
5587     }
5588   }
5589 }
5590 
Run()5591 void Run() {
5592   printf("test116: negative (strings)\n");
5593   MyThreadArray t(Worker, Worker, Worker);
5594   t.Start();
5595   t.Join();
5596 }
5597 REGISTER_TEST2(Run, 116, FEATURE|EXCLUDE_FROM_ALL)
5598 }  // namespace test116
5599 
5600 // test117: TN. Many calls to function-scope static init. {{{1
5601 namespace test117 {
5602 const int N = 50;
5603 
Foo()5604 int Foo() {
5605   usleep(20000);
5606   return 1;
5607 }
5608 
Worker(void * a)5609 void Worker(void *a) {
5610   static int foo = Foo();
5611   CHECK(foo == 1);
5612 }
5613 
Run()5614 void Run() {
5615   printf("test117: negative\n");
5616   MyThread *t[N];
5617   for (int i  = 0; i < N; i++) {
5618     t[i] = new MyThread(Worker);
5619   }
5620   for (int i  = 0; i < N; i++) {
5621     t[i]->Start();
5622   }
5623   for (int i  = 0; i < N; i++) {
5624     t[i]->Join();
5625   }
5626   for (int i  = 0; i < N; i++) delete t[i];
5627 }
5628 REGISTER_TEST(Run, 117)
5629 }  // namespace test117
5630 
5631 
5632 
5633 // test118 PERF: One signal, multiple waits. {{{1
5634 namespace   test118 {
5635 int     GLOB = 0;
5636 const int kNumIter = 2000000;
Signaller()5637 void Signaller() {
5638   usleep(50000);
5639   ANNOTATE_CONDVAR_SIGNAL(&GLOB);
5640 }
Waiter()5641 void Waiter() {
5642   for (int i = 0; i < kNumIter; i++) {
5643     ANNOTATE_CONDVAR_WAIT(&GLOB);
5644     if (i == kNumIter / 2)
5645       usleep(100000);
5646   }
5647 }
Run()5648 void Run() {
5649   printf("test118: perf\n");
5650   MyThreadArray t(Signaller, Waiter, Signaller, Waiter);
5651   t.Start();
5652   t.Join();
5653   printf("\tGLOB=%d\n", GLOB);
5654 }
5655 REGISTER_TEST(Run, 118)
5656 }  // namespace test118
5657 
5658 
5659 // test119: TP. Testing that malloc does not introduce any HB arc. {{{1
5660 namespace test119 {
5661 int     GLOB = 0;
Worker1()5662 void Worker1() {
5663   GLOB = 1;
5664   free(malloc(123));
5665 }
Worker2()5666 void Worker2() {
5667   usleep(100000);
5668   free(malloc(345));
5669   GLOB = 2;
5670 }
Run()5671 void Run() {
5672   printf("test119: positive (checking if malloc creates HB arcs)\n");
5673   FAST_MODE_INIT(&GLOB);
5674   if (!(Tsan_PureHappensBefore() && kMallocUsesMutex))
5675     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "true race");
5676   MyThreadArray t(Worker1, Worker2);
5677   t.Start();
5678   t.Join();
5679   printf("\tGLOB=%d\n", GLOB);
5680 }
5681 REGISTER_TEST(Run, 119)
5682 }  // namespace test119
5683 
5684 
5685 // test120: TP. Thread1: write then read. Thread2: read. {{{1
5686 namespace test120 {
5687 int     GLOB = 0;
5688 
Thread1()5689 void Thread1() {
5690   GLOB = 1;           // write
5691   CHECK(GLOB);        // read
5692 }
5693 
Thread2()5694 void Thread2() {
5695   usleep(100000);
5696   CHECK(GLOB >= 0);   // read
5697 }
5698 
Run()5699 void Run() {
5700   FAST_MODE_INIT(&GLOB);
5701   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "TP (T1: write then read, T2: read)");
5702   printf("test120: positive\n");
5703   MyThreadArray t(Thread1, Thread2);
5704   GLOB = 1;
5705   t.Start();
5706   t.Join();
5707   printf("\tGLOB=%d\n", GLOB);
5708 }
5709 REGISTER_TEST(Run, 120)
5710 }  // namespace test120
5711 
5712 
5713 // test121: TP. Example of double-checked-locking  {{{1
5714 namespace test121 {
5715 struct Foo {
5716   uintptr_t a, b[15];
5717 } __attribute__ ((aligned (64)));
5718 
5719 static Mutex mu;
5720 static Foo  *foo;
5721 
InitMe()5722 void InitMe() {
5723   if (!foo) {
5724     MutexLock lock(&mu);
5725     if (!foo) {
5726       ANNOTATE_EXPECT_RACE_FOR_TSAN(&foo, "test121. Double-checked locking (ptr)");
5727       foo = new Foo;
5728       if (!Tsan_FastMode())
5729         ANNOTATE_EXPECT_RACE_FOR_TSAN(&foo->a, "test121. Double-checked locking (obj)");
5730       foo->a = 42;
5731     }
5732   }
5733 }
5734 
UseMe()5735 void UseMe() {
5736   InitMe();
5737   CHECK(foo && foo->a == 42);
5738 }
5739 
Worker1()5740 void Worker1() { UseMe(); }
Worker2()5741 void Worker2() { UseMe(); }
Worker3()5742 void Worker3() { UseMe(); }
5743 
5744 
Run()5745 void Run() {
5746   FAST_MODE_INIT(&foo);
5747   printf("test121: TP. Example of double-checked-locking\n");
5748   MyThreadArray t1(Worker1, Worker2, Worker3);
5749   t1.Start();
5750   t1.Join();
5751   delete foo;
5752 }
5753 REGISTER_TEST(Run, 121)
5754 }  // namespace test121
5755 
5756 // test122 TP: Simple test with RWLock {{{1
5757 namespace  test122 {
5758 int     VAR1 = 0;
5759 int     VAR2 = 0;
5760 RWLock mu;
5761 
WriteWhileHoldingReaderLock(int * p)5762 void WriteWhileHoldingReaderLock(int *p) {
5763   usleep(100000);
5764   ReaderLockScoped lock(&mu);  // Reader lock for writing. -- bug.
5765   (*p)++;
5766 }
5767 
CorrectWrite(int * p)5768 void CorrectWrite(int *p) {
5769   WriterLockScoped lock(&mu);
5770   (*p)++;
5771 }
5772 
Thread1()5773 void Thread1() { WriteWhileHoldingReaderLock(&VAR1); }
Thread2()5774 void Thread2() { CorrectWrite(&VAR1); }
Thread3()5775 void Thread3() { CorrectWrite(&VAR2); }
Thread4()5776 void Thread4() { WriteWhileHoldingReaderLock(&VAR2); }
5777 
5778 
Run()5779 void Run() {
5780   printf("test122: positive (rw-lock)\n");
5781   VAR1 = 0;
5782   VAR2 = 0;
5783   ANNOTATE_TRACE_MEMORY(&VAR1);
5784   ANNOTATE_TRACE_MEMORY(&VAR2);
5785   if (!Tsan_PureHappensBefore()) {
5786     ANNOTATE_EXPECT_RACE_FOR_TSAN(&VAR1, "test122. TP. ReaderLock-ed while writing");
5787     ANNOTATE_EXPECT_RACE_FOR_TSAN(&VAR2, "test122. TP. ReaderLock-ed while writing");
5788   }
5789   MyThreadArray t(Thread1, Thread2, Thread3, Thread4);
5790   t.Start();
5791   t.Join();
5792 }
5793 REGISTER_TEST(Run, 122)
5794 }  // namespace test122
5795 
5796 
5797 // test123 TP: accesses of different sizes. {{{1
5798 namespace test123 {
5799 
5800 union uint_union {
5801   uint64_t u64[1];
5802   uint32_t u32[2];
5803   uint16_t u16[4];
5804   uint8_t  u8[8];
5805 };
5806 
5807 uint_union MEM[8];
5808 
5809 // Q. Hey dude, why so many functions?
5810 // A. I need different stack traces for different accesses.
5811 
Wr64_0()5812 void Wr64_0() { MEM[0].u64[0] = 1; }
Wr64_1()5813 void Wr64_1() { MEM[1].u64[0] = 1; }
Wr64_2()5814 void Wr64_2() { MEM[2].u64[0] = 1; }
Wr64_3()5815 void Wr64_3() { MEM[3].u64[0] = 1; }
Wr64_4()5816 void Wr64_4() { MEM[4].u64[0] = 1; }
Wr64_5()5817 void Wr64_5() { MEM[5].u64[0] = 1; }
Wr64_6()5818 void Wr64_6() { MEM[6].u64[0] = 1; }
Wr64_7()5819 void Wr64_7() { MEM[7].u64[0] = 1; }
5820 
Wr32_0()5821 void Wr32_0() { MEM[0].u32[0] = 1; }
Wr32_1()5822 void Wr32_1() { MEM[1].u32[1] = 1; }
Wr32_2()5823 void Wr32_2() { MEM[2].u32[0] = 1; }
Wr32_3()5824 void Wr32_3() { MEM[3].u32[1] = 1; }
Wr32_4()5825 void Wr32_4() { MEM[4].u32[0] = 1; }
Wr32_5()5826 void Wr32_5() { MEM[5].u32[1] = 1; }
Wr32_6()5827 void Wr32_6() { MEM[6].u32[0] = 1; }
Wr32_7()5828 void Wr32_7() { MEM[7].u32[1] = 1; }
5829 
Wr16_0()5830 void Wr16_0() { MEM[0].u16[0] = 1; }
Wr16_1()5831 void Wr16_1() { MEM[1].u16[1] = 1; }
Wr16_2()5832 void Wr16_2() { MEM[2].u16[2] = 1; }
Wr16_3()5833 void Wr16_3() { MEM[3].u16[3] = 1; }
Wr16_4()5834 void Wr16_4() { MEM[4].u16[0] = 1; }
Wr16_5()5835 void Wr16_5() { MEM[5].u16[1] = 1; }
Wr16_6()5836 void Wr16_6() { MEM[6].u16[2] = 1; }
Wr16_7()5837 void Wr16_7() { MEM[7].u16[3] = 1; }
5838 
Wr8_0()5839 void Wr8_0() { MEM[0].u8[0] = 1; }
Wr8_1()5840 void Wr8_1() { MEM[1].u8[1] = 1; }
Wr8_2()5841 void Wr8_2() { MEM[2].u8[2] = 1; }
Wr8_3()5842 void Wr8_3() { MEM[3].u8[3] = 1; }
Wr8_4()5843 void Wr8_4() { MEM[4].u8[4] = 1; }
Wr8_5()5844 void Wr8_5() { MEM[5].u8[5] = 1; }
Wr8_6()5845 void Wr8_6() { MEM[6].u8[6] = 1; }
Wr8_7()5846 void Wr8_7() { MEM[7].u8[7] = 1; }
5847 
WriteAll64()5848 void WriteAll64() {
5849   Wr64_0();
5850   Wr64_1();
5851   Wr64_2();
5852   Wr64_3();
5853   Wr64_4();
5854   Wr64_5();
5855   Wr64_6();
5856   Wr64_7();
5857 }
5858 
WriteAll32()5859 void WriteAll32() {
5860   Wr32_0();
5861   Wr32_1();
5862   Wr32_2();
5863   Wr32_3();
5864   Wr32_4();
5865   Wr32_5();
5866   Wr32_6();
5867   Wr32_7();
5868 }
5869 
WriteAll16()5870 void WriteAll16() {
5871   Wr16_0();
5872   Wr16_1();
5873   Wr16_2();
5874   Wr16_3();
5875   Wr16_4();
5876   Wr16_5();
5877   Wr16_6();
5878   Wr16_7();
5879 }
5880 
WriteAll8()5881 void WriteAll8() {
5882   Wr8_0();
5883   Wr8_1();
5884   Wr8_2();
5885   Wr8_3();
5886   Wr8_4();
5887   Wr8_5();
5888   Wr8_6();
5889   Wr8_7();
5890 }
5891 
W00()5892 void W00() { WriteAll64(); }
W01()5893 void W01() { WriteAll64(); }
W02()5894 void W02() { WriteAll64(); }
5895 
W10()5896 void W10() { WriteAll32(); }
W11()5897 void W11() { WriteAll32(); }
W12()5898 void W12() { WriteAll32(); }
5899 
W20()5900 void W20() { WriteAll16(); }
W21()5901 void W21() { WriteAll16(); }
W22()5902 void W22() { WriteAll16(); }
5903 
W30()5904 void W30() { WriteAll8(); }
W31()5905 void W31() { WriteAll8(); }
W32()5906 void W32() { WriteAll8(); }
5907 
5908 typedef void (*F)(void);
5909 
TestTwoSizes(F f1,F f2)5910 void TestTwoSizes(F f1, F f2) {
5911   // first f1, then f2
5912   ANNOTATE_NEW_MEMORY(&MEM, sizeof(MEM));
5913   memset(&MEM, 0, sizeof(MEM));
5914   MyThreadArray t1(f1, f2);
5915   t1.Start();
5916   t1.Join();
5917   // reverse order
5918   ANNOTATE_NEW_MEMORY(&MEM, sizeof(MEM));
5919   memset(&MEM, 0, sizeof(MEM));
5920   MyThreadArray t2(f2, f1);
5921   t2.Start();
5922   t2.Join();
5923 }
5924 
Run()5925 void Run() {
5926   printf("test123: positive (different sizes)\n");
5927   TestTwoSizes(W00, W10);
5928 //  TestTwoSizes(W01, W20);
5929 //  TestTwoSizes(W02, W30);
5930 //  TestTwoSizes(W11, W21);
5931 //  TestTwoSizes(W12, W31);
5932 //  TestTwoSizes(W22, W32);
5933 
5934 }
5935 REGISTER_TEST2(Run, 123, FEATURE|EXCLUDE_FROM_ALL)
5936 }  // namespace test123
5937 
5938 
5939 // test124: What happens if we delete an unlocked lock? {{{1
5940 namespace test124 {
5941 // This test does not worg with pthreads (you can't call
5942 // pthread_mutex_destroy on a locked lock).
5943 int     GLOB = 0;
5944 const int N = 1000;
Worker()5945 void Worker() {
5946   Mutex *a_large_local_array_of_mutexes;
5947   a_large_local_array_of_mutexes = new Mutex[N];
5948   for (int i = 0; i < N; i++) {
5949     a_large_local_array_of_mutexes[i].Lock();
5950   }
5951   delete []a_large_local_array_of_mutexes;
5952   GLOB = 1;
5953 }
5954 
Run()5955 void Run() {
5956   printf("test124: negative\n");
5957   MyThreadArray t(Worker, Worker, Worker);
5958   t.Start();
5959   t.Join();
5960   printf("\tGLOB=%d\n", GLOB);
5961 }
5962 REGISTER_TEST2(Run, 124, FEATURE|EXCLUDE_FROM_ALL)
5963 }  // namespace test124
5964 
5965 
5966 // test125 TN: Backwards lock (annotated). {{{1
5967 namespace test125 {
5968 // This test uses "Backwards mutex" locking protocol.
5969 // We take a *reader* lock when writing to a per-thread data
5970 // (GLOB[thread_num])  and we take a *writer* lock when we
5971 // are reading from the entire array at once.
5972 //
5973 // Such locking protocol is not understood by ThreadSanitizer's
5974 // hybrid state machine. So, you either have to use a pure-happens-before
5975 // detector ("tsan --pure-happens-before") or apply pure happens-before mode
5976 // to this particular lock by using ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&mu).
5977 
5978 const int n_threads = 3;
5979 RWLock   mu;
5980 int     GLOB[n_threads];
5981 
5982 int adder_num; // updated atomically.
5983 
Adder()5984 void Adder() {
5985   int my_num = AtomicIncrement(&adder_num, 1);
5986 
5987   ReaderLockScoped lock(&mu);
5988   GLOB[my_num]++;
5989 }
5990 
Aggregator()5991 void Aggregator() {
5992   int sum = 0;
5993   {
5994     WriterLockScoped lock(&mu);
5995     for (int i = 0; i < n_threads; i++) {
5996       sum += GLOB[i];
5997     }
5998   }
5999   printf("sum=%d\n", sum);
6000 }
6001 
Run()6002 void Run() {
6003   printf("test125: negative\n");
6004 
6005   ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&mu);
6006 
6007   // run Adders, then Aggregator
6008   {
6009     MyThreadArray t(Adder, Adder, Adder, Aggregator);
6010     t.Start();
6011     t.Join();
6012   }
6013 
6014   // Run Aggregator first.
6015   adder_num = 0;
6016   {
6017     MyThreadArray t(Aggregator, Adder, Adder, Adder);
6018     t.Start();
6019     t.Join();
6020   }
6021 
6022 }
6023 REGISTER_TEST(Run, 125)
6024 }  // namespace test125
6025 
6026 // test126 TN: test for BlockingCounter {{{1
6027 namespace  test126 {
6028 BlockingCounter *blocking_counter;
6029 int     GLOB = 0;
Worker()6030 void Worker() {
6031   CHECK(blocking_counter);
6032   CHECK(GLOB == 0);
6033   blocking_counter->DecrementCount();
6034 }
Run()6035 void Run() {
6036   printf("test126: negative\n");
6037   MyThreadArray t(Worker, Worker, Worker);
6038   blocking_counter = new BlockingCounter(3);
6039   t.Start();
6040   blocking_counter->Wait();
6041   GLOB = 1;
6042   t.Join();
6043   printf("\tGLOB=%d\n", GLOB);
6044 }
6045 REGISTER_TEST(Run, 126)
6046 }  // namespace test126
6047 
6048 
6049 // test127. Bad code: unlocking a mutex locked by another thread. {{{1
6050 namespace test127 {
6051 Mutex mu;
Thread1()6052 void Thread1() {
6053   mu.Lock();
6054 }
Thread2()6055 void Thread2() {
6056   usleep(100000);
6057   mu.Unlock();
6058 }
Run()6059 void Run() {
6060   printf("test127: unlocking a mutex locked by another thread.\n");
6061   MyThreadArray t(Thread1, Thread2);
6062   t.Start();
6063   t.Join();
6064 }
6065 REGISTER_TEST(Run, 127)
6066 }  // namespace test127
6067 
6068 // test128. Suppressed code in concurrent accesses {{{1
6069 // Please use --suppressions=unittest.supp flag when running this test.
6070 namespace test128 {
6071 Mutex mu;
6072 int GLOB = 0;
Worker()6073 void Worker() {
6074   usleep(100000);
6075   mu.Lock();
6076   GLOB++;
6077   mu.Unlock();
6078 }
ThisFunctionShouldBeSuppressed()6079 void ThisFunctionShouldBeSuppressed() {
6080   GLOB++;
6081 }
Run()6082 void Run() {
6083   printf("test128: Suppressed code in concurrent accesses.\n");
6084   MyThreadArray t(Worker, ThisFunctionShouldBeSuppressed);
6085   t.Start();
6086   t.Join();
6087 }
6088 REGISTER_TEST2(Run, 128, FEATURE | EXCLUDE_FROM_ALL)
6089 }  // namespace test128
6090 
6091 // test129: TN. Synchronization via ReaderLockWhen(). {{{1
6092 namespace test129 {
6093 int     GLOB = 0;
6094 Mutex   MU;
WeirdCondition(int * param)6095 bool WeirdCondition(int* param) {
6096   *param = GLOB;  // a write into Waiter's memory
6097   return GLOB > 0;
6098 }
Waiter()6099 void Waiter() {
6100   int param = 0;
6101   MU.ReaderLockWhen(Condition(WeirdCondition, &param));
6102   MU.ReaderUnlock();
6103   CHECK(GLOB > 0);
6104   CHECK(param > 0);
6105 }
Waker()6106 void Waker() {
6107   usleep(100000);  // Make sure the waiter blocks.
6108   MU.Lock();
6109   GLOB++;
6110   MU.Unlock();     // calls ANNOTATE_CONDVAR_SIGNAL;
6111 }
Run()6112 void Run() {
6113   printf("test129: Synchronization via ReaderLockWhen()\n");
6114   MyThread mt(Waiter, NULL, "Waiter Thread");
6115   mt.Start();
6116   Waker();
6117   mt.Join();
6118   printf("\tGLOB=%d\n", GLOB);
6119 }
6120 REGISTER_TEST2(Run, 129, FEATURE);
6121 }  // namespace test129
6122 
6123 // test130: TN. Per-thread. {{{1
6124 namespace test130 {
6125 #ifndef NO_TLS
6126 // This test verifies that the race detector handles
6127 // thread-local storage (TLS) correctly.
6128 // As of 09-03-30 ThreadSanitizer has a bug:
6129 //   - Thread1 starts
6130 //   - Thread1 touches per_thread_global
6131 //   - Thread1 ends
6132 //   - Thread2 starts (and there is no happens-before relation between it and
6133 //   Thread1)
6134 //   - Thread2 touches per_thread_global
6135 // It may happen so that Thread2 will have per_thread_global in the same address
6136 // as Thread1. Since there is no happens-before relation between threads,
6137 // ThreadSanitizer reports a race.
6138 //
6139 // test131 does the same for stack.
6140 
6141 static __thread int per_thread_global[10] = {0};
6142 
RealWorker()6143 void RealWorker() {  // Touch per_thread_global.
6144   per_thread_global[1]++;
6145   errno++;
6146 }
6147 
Worker()6148 void Worker() {  // Spawn few threads that touch per_thread_global.
6149   MyThreadArray t(RealWorker, RealWorker);
6150   t.Start();
6151   t.Join();
6152 }
Worker0()6153 void Worker0() { sleep(0); Worker(); }
Worker1()6154 void Worker1() { sleep(1); Worker(); }
Worker2()6155 void Worker2() { sleep(2); Worker(); }
Worker3()6156 void Worker3() { sleep(3); Worker(); }
6157 
Run()6158 void Run() {
6159   printf("test130: Per-thread\n");
6160   MyThreadArray t1(Worker0, Worker1, Worker2, Worker3);
6161   t1.Start();
6162   t1.Join();
6163   printf("\tper_thread_global=%d\n", per_thread_global[1]);
6164 }
6165 REGISTER_TEST(Run, 130)
6166 #endif // NO_TLS
6167 }  // namespace test130
6168 
6169 
6170 // test131: TN. Stack. {{{1
6171 namespace test131 {
6172 // Same as test130, but for stack.
6173 
RealWorker()6174 void RealWorker() {  // Touch stack.
6175   int stack_var = 0;
6176   stack_var++;
6177 }
6178 
Worker()6179 void Worker() {  // Spawn few threads that touch stack.
6180   MyThreadArray t(RealWorker, RealWorker);
6181   t.Start();
6182   t.Join();
6183 }
Worker0()6184 void Worker0() { sleep(0); Worker(); }
Worker1()6185 void Worker1() { sleep(1); Worker(); }
Worker2()6186 void Worker2() { sleep(2); Worker(); }
Worker3()6187 void Worker3() { sleep(3); Worker(); }
6188 
Run()6189 void Run() {
6190   printf("test131: stack\n");
6191   MyThreadArray t(Worker0, Worker1, Worker2, Worker3);
6192   t.Start();
6193   t.Join();
6194 }
6195 REGISTER_TEST(Run, 131)
6196 }  // namespace test131
6197 
6198 
6199 // test132: TP. Simple race (write vs write). Works in fast-mode. {{{1
6200 namespace test132 {
6201 int     GLOB = 0;
Worker()6202 void Worker() { GLOB = 1; }
6203 
Run1()6204 void Run1() {
6205   FAST_MODE_INIT(&GLOB);
6206   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test132");
6207   printf("test132: positive; &GLOB=%p\n", &GLOB);
6208   ANNOTATE_TRACE_MEMORY(&GLOB);
6209   GLOB = 7;
6210   MyThreadArray t(Worker, Worker);
6211   t.Start();
6212   t.Join();
6213 }
6214 
Run()6215 void Run() {
6216   Run1();
6217 }
6218 REGISTER_TEST(Run, 132);
6219 }  // namespace test132
6220 
6221 
6222 // test133: TP. Simple race (write vs write). Works in fast mode. {{{1
6223 namespace test133 {
6224 // Same as test132, but everything is run from a separate thread spawned from
6225 // the main thread.
6226 int     GLOB = 0;
Worker()6227 void Worker() { GLOB = 1; }
6228 
Run1()6229 void Run1() {
6230   FAST_MODE_INIT(&GLOB);
6231   ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "test133");
6232   printf("test133: positive; &GLOB=%p\n", &GLOB);
6233   ANNOTATE_TRACE_MEMORY(&GLOB);
6234   GLOB = 7;
6235   MyThreadArray t(Worker, Worker);
6236   t.Start();
6237   t.Join();
6238 }
Run()6239 void Run() {
6240   MyThread t(Run1);
6241   t.Start();
6242   t.Join();
6243 }
6244 REGISTER_TEST(Run, 133);
6245 }  // namespace test133
6246 
6247 
6248 // test134 TN. Swap. Variant of test79. {{{1
6249 namespace test134 {
6250 #if 0
6251 typedef __gnu_cxx::hash_map<int, int> map_t;
6252 #else
6253 typedef std::map<int, int> map_t;
6254 #endif
6255 map_t   map;
6256 Mutex   mu;
6257 // Here we use swap to pass map between threads.
6258 // The synchronization is correct, but w/o the annotation
6259 // any hybrid detector will complain.
6260 
6261 // Swap is very unfriendly to the lock-set (and hybrid) race detectors.
6262 // Since tmp is destructed outside the mutex, we need to have a happens-before
6263 // arc between any prior access to map and here.
6264 // Since the internals of tmp are created ouside the mutex and are passed to
6265 // other thread, we need to have a h-b arc between here and any future access.
6266 // These arcs can be created by HAPPENS_{BEFORE,AFTER} annotations, but it is
6267 // much simpler to apply pure-happens-before mode to the mutex mu.
Swapper()6268 void Swapper() {
6269   map_t tmp;
6270   MutexLock lock(&mu);
6271   ANNOTATE_HAPPENS_AFTER(&map);
6272   // We swap the new empty map 'tmp' with 'map'.
6273   map.swap(tmp);
6274   ANNOTATE_HAPPENS_BEFORE(&map);
6275   // tmp (which is the old version of map) is destroyed here.
6276 }
6277 
Worker()6278 void Worker() {
6279   MutexLock lock(&mu);
6280   ANNOTATE_HAPPENS_AFTER(&map);
6281   map[1]++;
6282   ANNOTATE_HAPPENS_BEFORE(&map);
6283 }
6284 
Run()6285 void Run() {
6286   printf("test134: negative (swap)\n");
6287   // ********************** Shorter way: ***********************
6288   // ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&mu);
6289   MyThreadArray t(Worker, Worker, Swapper, Worker, Worker);
6290   t.Start();
6291   t.Join();
6292 }
6293 REGISTER_TEST(Run, 134)
6294 }  // namespace test134
6295 
6296 // test135 TN. Swap. Variant of test79. {{{1
6297 namespace test135 {
6298 
SubWorker()6299 void SubWorker() {
6300   const long SIZE = 65536;
6301   for (int i = 0; i < 32; i++) {
6302     int *ptr = (int*)mmap(NULL, SIZE, PROT_READ | PROT_WRITE,
6303                           MAP_PRIVATE | MAP_ANON, -1, 0);
6304     *ptr = 42;
6305     munmap(ptr, SIZE);
6306   }
6307 }
6308 
Worker()6309 void Worker() {
6310   MyThreadArray t(SubWorker, SubWorker, SubWorker, SubWorker);
6311   t.Start();
6312   t.Join();
6313 }
6314 
Run()6315 void Run() {
6316   printf("test135: negative (mmap)\n");
6317   MyThreadArray t(Worker, Worker, Worker, Worker);
6318   t.Start();
6319   t.Join();
6320 }
6321 REGISTER_TEST(Run, 135)
6322 }  // namespace test135
6323 
6324 // test136. Unlock twice. {{{1
6325 namespace test136 {
Run()6326 void Run() {
6327   printf("test136: unlock twice\n");
6328   pthread_mutexattr_t attr;
6329   CHECK(0 == pthread_mutexattr_init(&attr));
6330   CHECK(0 == pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_ERRORCHECK));
6331 
6332   pthread_mutex_t mu;
6333   CHECK(0 == pthread_mutex_init(&mu, &attr));
6334   CHECK(0 == pthread_mutex_lock(&mu));
6335   CHECK(0 == pthread_mutex_unlock(&mu));
6336   int ret_unlock = pthread_mutex_unlock(&mu);  // unlocking twice.
6337   int ret_destroy = pthread_mutex_destroy(&mu);
6338   printf("  pthread_mutex_unlock returned %d\n", ret_unlock);
6339   printf("  pthread_mutex_destroy returned %d\n", ret_destroy);
6340 
6341 }
6342 
6343 REGISTER_TEST(Run, 136)
6344 }  // namespace test136
6345 
6346 // test137 TP. Races on stack variables. {{{1
6347 namespace test137 {
6348 int GLOB = 0;
6349 ProducerConsumerQueue q(10);
6350 
Worker()6351 void Worker() {
6352   int stack;
6353   int *tmp = (int*)q.Get();
6354   (*tmp)++;
6355   int *racey = &stack;
6356   q.Put(racey);
6357   (*racey)++;
6358   usleep(150000);
6359   // We may miss the races if we sleep less due to die_memory events...
6360 }
6361 
Run()6362 void Run() {
6363   int tmp = 0;
6364   printf("test137: TP. Races on stack variables.\n");
6365   q.Put(&tmp);
6366   MyThreadArray t(Worker, Worker, Worker, Worker);
6367   t.Start();
6368   t.Join();
6369   q.Get();
6370 }
6371 
6372 REGISTER_TEST2(Run, 137, FEATURE | EXCLUDE_FROM_ALL)
6373 }  // namespace test137
6374 
6375 // test138 FN. Two closures hit the same thread in ThreadPool. {{{1
6376 namespace test138 {
6377 int GLOB = 0;
6378 
Worker()6379 void Worker() {
6380   usleep(100000);
6381   GLOB++;
6382 }
6383 
Run()6384 void Run() {
6385   FAST_MODE_INIT(&GLOB);
6386   printf("test138: FN. Two closures hit the same thread in ThreadPool.\n");
6387 
6388   // When using thread pools, two concurrent callbacks might be scheduled
6389   // onto the same executor thread. As a result, unnecessary happens-before
6390   // relation may be introduced between callbacks.
6391   // If we set the number of executor threads to 1, any known data
6392   // race detector will be silent. However, the same situation may happen
6393   // with any number of executor threads (with some probability).
6394   ThreadPool tp(1);
6395   tp.StartWorkers();
6396   tp.Add(NewCallback(Worker));
6397   tp.Add(NewCallback(Worker));
6398 }
6399 
6400 REGISTER_TEST2(Run, 138, FEATURE)
6401 }  // namespace test138
6402 
6403 // test139: FN. A true race hidden by reference counting annotation. {{{1
6404 namespace test139 {
6405 int GLOB = 0;
6406 RefCountedClass *obj;
6407 
Worker1()6408 void Worker1() {
6409   GLOB++;  // First access.
6410   obj->Unref();
6411 }
6412 
Worker2()6413 void Worker2() {
6414   usleep(100000);
6415   obj->Unref();
6416   GLOB++;  // Second access.
6417 }
6418 
Run()6419 void Run() {
6420   FAST_MODE_INIT(&GLOB);
6421   printf("test139: FN. A true race hidden by reference counting annotation.\n");
6422 
6423   obj = new RefCountedClass;
6424   obj->AnnotateUnref();
6425   obj->Ref();
6426   obj->Ref();
6427   MyThreadArray mt(Worker1, Worker2);
6428   mt.Start();
6429   mt.Join();
6430 }
6431 
6432 REGISTER_TEST2(Run, 139, FEATURE)
6433 }  // namespace test139
6434 
6435 // test140 TN. Swap. Variant of test79 and test134. {{{1
6436 namespace test140 {
6437 #if 0
6438 typedef __gnu_cxx::hash_map<int, int> Container;
6439 #else
6440 typedef std::map<int,int>             Container;
6441 #endif
6442 Mutex mu;
6443 static Container container;
6444 
6445 // Here we use swap to pass a Container between threads.
6446 // The synchronization is correct, but w/o the annotation
6447 // any hybrid detector will complain.
6448 //
6449 // Unlike the test134, we try to have a minimal set of annotations
6450 // so that extra h-b arcs do not hide other races.
6451 
6452 // Swap is very unfriendly to the lock-set (and hybrid) race detectors.
6453 // Since tmp is destructed outside the mutex, we need to have a happens-before
6454 // arc between any prior access to map and here.
6455 // Since the internals of tmp are created ouside the mutex and are passed to
6456 // other thread, we need to have a h-b arc between here and any future access.
6457 //
6458 // We want to be able to annotate swapper so that we don't need to annotate
6459 // anything else.
Swapper()6460 void Swapper() {
6461   Container tmp;
6462   tmp[1] = tmp[2] = tmp[3] = 0;
6463   {
6464     MutexLock lock(&mu);
6465     container.swap(tmp);
6466     // we are unpublishing the old container.
6467     ANNOTATE_UNPUBLISH_MEMORY_RANGE(&container, sizeof(container));
6468     // we are publishing the new container.
6469     ANNOTATE_PUBLISH_MEMORY_RANGE(&container, sizeof(container));
6470   }
6471   tmp[1]++;
6472   tmp[2]++;
6473   // tmp (which is the old version of container) is destroyed here.
6474 }
6475 
Worker()6476 void Worker() {
6477   MutexLock lock(&mu);
6478   container[1]++;
6479   int *v = &container[2];
6480   for (int i = 0; i < 10; i++) {
6481     // if uncommented, this will break ANNOTATE_UNPUBLISH_MEMORY_RANGE():
6482     // ANNOTATE_HAPPENS_BEFORE(v);
6483     if (i % 3) {
6484       (*v)++;
6485     }
6486   }
6487 }
6488 
Run()6489 void Run() {
6490   printf("test140: negative (swap) %p\n", &container);
6491   MyThreadArray t(Worker, Worker, Swapper, Worker, Worker);
6492   t.Start();
6493   t.Join();
6494 }
6495 REGISTER_TEST(Run, 140)
6496 }  // namespace test140
6497 
6498 // test141 FP. unlink/fopen, rmdir/opendir. {{{1
6499 namespace test141 {
6500 int GLOB1 = 0,
6501     GLOB2 = 0;
6502 char *dir_name = NULL,
6503      *filename = NULL;
6504 
Waker1()6505 void Waker1() {
6506   usleep(100000);
6507   GLOB1 = 1;  // Write
6508   // unlink deletes a file 'filename'
6509   // which exits spin-loop in Waiter1().
6510   printf("  Deleting file...\n");
6511   CHECK(unlink(filename) == 0);
6512 }
6513 
Waiter1()6514 void Waiter1() {
6515   FILE *tmp;
6516   while ((tmp = fopen(filename, "r")) != NULL) {
6517     fclose(tmp);
6518     usleep(10000);
6519   }
6520   printf("  ...file has been deleted\n");
6521   GLOB1 = 2;  // Write
6522 }
6523 
Waker2()6524 void Waker2() {
6525   usleep(100000);
6526   GLOB2 = 1;  // Write
6527   // rmdir deletes a directory 'dir_name'
6528   // which exit spin-loop in Waker().
6529   printf("  Deleting directory...\n");
6530   CHECK(rmdir(dir_name) == 0);
6531 }
6532 
Waiter2()6533 void Waiter2() {
6534   DIR *tmp;
6535   while ((tmp = opendir(dir_name)) != NULL) {
6536     closedir(tmp);
6537     usleep(10000);
6538   }
6539   printf("  ...directory has been deleted\n");
6540   GLOB2 = 2;
6541 }
6542 
Run()6543 void Run() {
6544   FAST_MODE_INIT(&GLOB1);
6545   FAST_MODE_INIT(&GLOB2);
6546   printf("test141: FP. unlink/fopen, rmdir/opendir.\n");
6547 
6548   dir_name = strdup("/tmp/tsan-XXXXXX");
6549   IGNORE_RETURN_VALUE(mkdtemp(dir_name));
6550 
6551   filename = strdup((std::string() + dir_name + "/XXXXXX").c_str());
6552   const int fd = mkstemp(filename);
6553   CHECK(fd >= 0);
6554   close(fd);
6555 
6556   MyThreadArray mta1(Waker1, Waiter1);
6557   mta1.Start();
6558   mta1.Join();
6559 
6560   MyThreadArray mta2(Waker2, Waiter2);
6561   mta2.Start();
6562   mta2.Join();
6563   free(filename);
6564   filename = 0;
6565   free(dir_name);
6566   dir_name = 0;
6567 }
6568 REGISTER_TEST(Run, 141)
6569 }  // namespace test141
6570 
6571 
6572 // Simple FIFO queue annotated with PCQ annotations. {{{1
6573 class FifoMessageQueue {
6574  public:
FifoMessageQueue()6575   FifoMessageQueue() { ANNOTATE_PCQ_CREATE(this); }
~FifoMessageQueue()6576   ~FifoMessageQueue() { ANNOTATE_PCQ_DESTROY(this); }
6577   // Send a message. 'message' should be positive.
Put(int message)6578   void Put(int message) {
6579     CHECK(message);
6580     MutexLock lock(&mu_);
6581     ANNOTATE_PCQ_PUT(this);
6582     q_.push(message);
6583   }
6584   // Return the message from the queue and pop it
6585   // or return 0 if there are no messages.
Get()6586   int Get() {
6587     MutexLock lock(&mu_);
6588     if (q_.empty()) return 0;
6589     int res = q_.front();
6590     q_.pop();
6591     ANNOTATE_PCQ_GET(this);
6592     return res;
6593   }
6594  private:
6595   Mutex mu_;
6596   queue<int> q_;
6597 };
6598 
6599 
6600 // test142: TN. Check PCQ_* annotations. {{{1
6601 namespace test142 {
6602 // Putter writes to array[i] and sends a message 'i'.
6603 // Getters receive messages and read array[message].
6604 // PCQ_* annotations calm down the hybrid detectors.
6605 
6606 const int N = 1000;
6607 int array[N+1];
6608 
6609 FifoMessageQueue q;
6610 
Putter()6611 void Putter() {
6612   for (int i = 1; i <= N; i++) {
6613     array[i] = i*i;
6614     q.Put(i);
6615     usleep(1000);
6616   }
6617 }
6618 
Getter()6619 void Getter() {
6620   int non_zero_received  = 0;
6621   for (int i = 1; i <= N; i++) {
6622     int res = q.Get();
6623     if (res > 0) {
6624       CHECK(array[res] = res * res);
6625       non_zero_received++;
6626     }
6627     usleep(1000);
6628   }
6629   printf("T=%zd: non_zero_received=%d\n",
6630          (size_t)pthread_self(), non_zero_received);
6631 }
6632 
Run()6633 void Run() {
6634   printf("test142: tests PCQ annotations\n");
6635   MyThreadArray t(Putter, Getter, Getter);
6636   t.Start();
6637   t.Join();
6638 }
6639 REGISTER_TEST(Run, 142)
6640 }  // namespace test142
6641 
6642 
6643 // test143: TP. Check PCQ_* annotations. {{{1
6644 namespace test143 {
6645 // True positive.
6646 // We have a race on GLOB between Putter and one of the Getters.
6647 // Pure h-b will not see it.
6648 // If FifoMessageQueue was annotated using HAPPENS_BEFORE/AFTER, the race would
6649 // be missed too.
6650 // PCQ_* annotations do not hide this race.
6651 int     GLOB = 0;
6652 
6653 FifoMessageQueue q;
6654 
Putter()6655 void Putter() {
6656   GLOB = 1;
6657   q.Put(1);
6658 }
6659 
Getter()6660 void Getter() {
6661   usleep(10000);
6662   q.Get();
6663   CHECK(GLOB == 1);  // Race here
6664 }
6665 
Run()6666 void Run() {
6667   q.Put(1);
6668   if (!Tsan_PureHappensBefore()) {
6669     ANNOTATE_EXPECT_RACE_FOR_TSAN(&GLOB, "true races");
6670   }
6671   printf("test143: tests PCQ annotations (true positive)\n");
6672   MyThreadArray t(Putter, Getter, Getter);
6673   t.Start();
6674   t.Join();
6675 }
6676 REGISTER_TEST(Run, 143);
6677 }  // namespace test143
6678 
6679 
6680 
6681 
6682 // test300: {{{1
6683 namespace test300 {
6684 int     GLOB = 0;
Run()6685 void Run() {
6686 }
6687 REGISTER_TEST2(Run, 300, RACE_DEMO)
6688 }  // namespace test300
6689 
6690 // test301: Simple race.  {{{1
6691 namespace test301 {
6692 Mutex mu1;  // This Mutex guards var.
6693 Mutex mu2;  // This Mutex is not related to var.
6694 int   var;  // GUARDED_BY(mu1)
6695 
Thread1()6696 void Thread1() {  // Runs in thread named 'test-thread-1'.
6697   MutexLock lock(&mu1);  // Correct Mutex.
6698   var = 1;
6699 }
6700 
Thread2()6701 void Thread2() {  // Runs in thread named 'test-thread-2'.
6702   MutexLock lock(&mu2);  // Wrong Mutex.
6703   var = 2;
6704 }
6705 
Run()6706 void Run() {
6707   var = 0;
6708   printf("test301: simple race.\n");
6709   MyThread t1(Thread1, NULL, "test-thread-1");
6710   MyThread t2(Thread2, NULL, "test-thread-2");
6711   t1.Start();
6712   t2.Start();
6713   t1.Join();
6714   t2.Join();
6715 }
6716 REGISTER_TEST2(Run, 301, RACE_DEMO)
6717 }  // namespace test301
6718 
6719 // test302: Complex race which happens at least twice.  {{{1
6720 namespace test302 {
6721 // In this test we have many different accesses to GLOB and only one access
6722 // is not synchronized properly.
6723 int     GLOB = 0;
6724 
6725 Mutex MU1;
6726 Mutex MU2;
Worker()6727 void Worker() {
6728   for(int i = 0; i < 100; i++) {
6729     switch(i % 4) {
6730       case 0:
6731         // This read is protected correctly.
6732         MU1.Lock(); CHECK(GLOB >= 0); MU1.Unlock();
6733         break;
6734       case 1:
6735         // Here we used the wrong lock! The reason of the race is here.
6736         MU2.Lock(); CHECK(GLOB >= 0); MU2.Unlock();
6737         break;
6738       case 2:
6739         // This read is protected correctly.
6740         MU1.Lock(); CHECK(GLOB >= 0); MU1.Unlock();
6741         break;
6742       case 3:
6743         // This write is protected correctly.
6744         MU1.Lock(); GLOB++; MU1.Unlock();
6745         break;
6746     }
6747     // sleep a bit so that the threads interleave
6748     // and the race happens at least twice.
6749     usleep(100);
6750   }
6751 }
6752 
Run()6753 void Run() {
6754   printf("test302: Complex race that happens twice.\n");
6755   MyThread t1(Worker), t2(Worker);
6756   t1.Start();
6757   t2.Start();
6758   t1.Join();   t2.Join();
6759 }
6760 REGISTER_TEST2(Run, 302, RACE_DEMO)
6761 }  // namespace test302
6762 
6763 
6764 // test303: Need to trace the memory to understand the report. {{{1
6765 namespace test303 {
6766 int     GLOB = 0;
6767 
6768 Mutex MU;
Worker1()6769 void Worker1() { CHECK(GLOB >= 0); }
Worker2()6770 void Worker2() { MU.Lock(); GLOB=1;  MU.Unlock();}
6771 
Run()6772 void Run() {
6773   printf("test303: a race that needs annotations.\n");
6774   ANNOTATE_TRACE_MEMORY(&GLOB);
6775   MyThreadArray t(Worker1, Worker2);
6776   t.Start();
6777   t.Join();
6778 }
6779 REGISTER_TEST2(Run, 303, RACE_DEMO)
6780 }  // namespace test303
6781 
6782 
6783 
6784 // test304: Can not trace the memory, since it is a library object. {{{1
6785 namespace test304 {
6786 string *STR;
6787 Mutex   MU;
6788 
Worker1()6789 void Worker1() {
6790   sleep(0);
6791   ANNOTATE_CONDVAR_SIGNAL((void*)0xDEADBEAF);
6792   MU.Lock(); CHECK(STR->length() >= 4); MU.Unlock();
6793 }
Worker2()6794 void Worker2() {
6795   sleep(1);
6796   ANNOTATE_CONDVAR_SIGNAL((void*)0xDEADBEAF);
6797   CHECK(STR->length() >= 4); // Unprotected!
6798 }
Worker3()6799 void Worker3() {
6800   sleep(2);
6801   ANNOTATE_CONDVAR_SIGNAL((void*)0xDEADBEAF);
6802   MU.Lock(); CHECK(STR->length() >= 4); MU.Unlock();
6803 }
Worker4()6804 void Worker4() {
6805   sleep(3);
6806   ANNOTATE_CONDVAR_SIGNAL((void*)0xDEADBEAF);
6807   MU.Lock(); *STR += " + a very very long string"; MU.Unlock();
6808 }
6809 
Run()6810 void Run() {
6811   STR = new string ("The String");
6812   printf("test304: a race where memory tracing does not work.\n");
6813   MyThreadArray t(Worker1, Worker2, Worker3, Worker4);
6814   t.Start();
6815   t.Join();
6816 
6817   printf("%s\n", STR->c_str());
6818   delete STR;
6819 }
6820 REGISTER_TEST2(Run, 304, RACE_DEMO)
6821 }  // namespace test304
6822 
6823 
6824 
6825 // test305: A bit more tricky: two locks used inconsistenly. {{{1
6826 namespace test305 {
6827 int     GLOB = 0;
6828 
6829 // In this test GLOB is protected by MU1 and MU2, but inconsistently.
6830 // The TRACES observed by helgrind are:
6831 // TRACE[1]: Access{T2/S2 wr} -> new State{Mod; #LS=2; #SS=1; T2/S2}
6832 // TRACE[2]: Access{T4/S9 wr} -> new State{Mod; #LS=1; #SS=2; T2/S2, T4/S9}
6833 // TRACE[3]: Access{T5/S13 wr} -> new State{Mod; #LS=1; #SS=3; T2/S2, T4/S9, T5/S13}
6834 // TRACE[4]: Access{T6/S19 wr} -> new State{Mod; #LS=0; #SS=4; T2/S2, T4/S9, T5/S13, T6/S19}
6835 //
6836 // The guilty access is either Worker2() or Worker4(), depending on
6837 // which mutex is supposed to protect GLOB.
6838 Mutex MU1;
6839 Mutex MU2;
Worker1()6840 void Worker1() { MU1.Lock(); MU2.Lock(); GLOB=1; MU2.Unlock(); MU1.Unlock(); }
Worker2()6841 void Worker2() { MU1.Lock();             GLOB=2;               MU1.Unlock(); }
Worker3()6842 void Worker3() { MU1.Lock(); MU2.Lock(); GLOB=3; MU2.Unlock(); MU1.Unlock(); }
Worker4()6843 void Worker4() {             MU2.Lock(); GLOB=4; MU2.Unlock();               }
6844 
Run()6845 void Run() {
6846   ANNOTATE_TRACE_MEMORY(&GLOB);
6847   printf("test305: simple race.\n");
6848   MyThread t1(Worker1), t2(Worker2), t3(Worker3), t4(Worker4);
6849   t1.Start(); usleep(100);
6850   t2.Start(); usleep(100);
6851   t3.Start(); usleep(100);
6852   t4.Start(); usleep(100);
6853   t1.Join(); t2.Join(); t3.Join(); t4.Join();
6854 }
6855 REGISTER_TEST2(Run, 305, RACE_DEMO)
6856 }  // namespace test305
6857 
6858 // test306: Two locks are used to protect a var.  {{{1
6859 namespace test306 {
6860 int     GLOB = 0;
6861 // Thread1 and Thread2 access the var under two locks.
6862 // Thread3 uses no locks.
6863 
6864 Mutex MU1;
6865 Mutex MU2;
Worker1()6866 void Worker1() { MU1.Lock(); MU2.Lock(); GLOB=1; MU2.Unlock(); MU1.Unlock(); }
Worker2()6867 void Worker2() { MU1.Lock(); MU2.Lock(); GLOB=3; MU2.Unlock(); MU1.Unlock(); }
Worker3()6868 void Worker3() {                         GLOB=4;               }
6869 
Run()6870 void Run() {
6871   ANNOTATE_TRACE_MEMORY(&GLOB);
6872   printf("test306: simple race.\n");
6873   MyThread t1(Worker1), t2(Worker2), t3(Worker3);
6874   t1.Start(); usleep(100);
6875   t2.Start(); usleep(100);
6876   t3.Start(); usleep(100);
6877   t1.Join(); t2.Join(); t3.Join();
6878 }
6879 REGISTER_TEST2(Run, 306, RACE_DEMO)
6880 }  // namespace test306
6881 
6882 // test307: Simple race, code with control flow  {{{1
6883 namespace test307 {
6884 int     *GLOB = 0;
6885 volatile /*to fake the compiler*/ bool some_condition = true;
6886 
6887 
SomeFunc()6888 void SomeFunc() { }
6889 
FunctionWithControlFlow()6890 int FunctionWithControlFlow() {
6891   int unrelated_stuff = 0;
6892   unrelated_stuff++;
6893   SomeFunc();                // "--keep-history=1" will point somewhere here.
6894   if (some_condition) {      // Or here
6895     if (some_condition) {
6896       unrelated_stuff++;     // Or here.
6897       unrelated_stuff++;
6898       (*GLOB)++;             // "--keep-history=2" will point here (experimental).
6899     }
6900   }
6901   usleep(100000);
6902   return unrelated_stuff;
6903 }
6904 
Worker1()6905 void Worker1() { FunctionWithControlFlow(); }
Worker2()6906 void Worker2() { Worker1(); }
Worker3()6907 void Worker3() { Worker2(); }
Worker4()6908 void Worker4() { Worker3(); }
6909 
Run()6910 void Run() {
6911   GLOB = new int;
6912   *GLOB = 1;
6913   printf("test307: simple race, code with control flow\n");
6914   MyThreadArray t1(Worker1, Worker2, Worker3, Worker4);
6915   t1.Start();
6916   t1.Join();
6917 }
6918 REGISTER_TEST2(Run, 307, RACE_DEMO)
6919 }  // namespace test307
6920 
6921 // test308: Example of double-checked-locking  {{{1
6922 namespace test308 {
6923 struct Foo {
6924   int a;
6925 };
6926 
6927 static int   is_inited = 0;
6928 static Mutex lock;
6929 static Foo  *foo;
6930 
InitMe()6931 void InitMe() {
6932   if (!is_inited) {
6933     lock.Lock();
6934       if (!is_inited) {
6935         foo = new Foo;
6936         foo->a = 42;
6937         is_inited = 1;
6938       }
6939     lock.Unlock();
6940   }
6941 }
6942 
UseMe()6943 void UseMe() {
6944   InitMe();
6945   CHECK(foo && foo->a == 42);
6946 }
6947 
Worker1()6948 void Worker1() { UseMe(); }
Worker2()6949 void Worker2() { UseMe(); }
Worker3()6950 void Worker3() { UseMe(); }
6951 
6952 
Run()6953 void Run() {
6954   ANNOTATE_TRACE_MEMORY(&is_inited);
6955   printf("test308: Example of double-checked-locking\n");
6956   MyThreadArray t1(Worker1, Worker2, Worker3);
6957   t1.Start();
6958   t1.Join();
6959 }
6960 REGISTER_TEST2(Run, 308, RACE_DEMO)
6961 }  // namespace test308
6962 
6963 // test309: Simple race on an STL object.  {{{1
6964 namespace test309 {
6965 string  GLOB;
6966 
Worker1()6967 void Worker1() {
6968   GLOB="Thread1";
6969 }
Worker2()6970 void Worker2() {
6971   usleep(100000);
6972   GLOB="Booooooooooo";
6973 }
6974 
Run()6975 void Run() {
6976   printf("test309: simple race on an STL object.\n");
6977   MyThread t1(Worker1), t2(Worker2);
6978   t1.Start();
6979   t2.Start();
6980   t1.Join();   t2.Join();
6981 }
6982 REGISTER_TEST2(Run, 309, RACE_DEMO)
6983 }  // namespace test309
6984 
6985 // test310: One more simple race.  {{{1
6986 namespace test310 {
6987 int     *PTR = NULL;  // GUARDED_BY(mu1)
6988 
6989 Mutex mu1;  // Protects PTR.
6990 Mutex mu2;  // Unrelated to PTR.
6991 Mutex mu3;  // Unrelated to PTR.
6992 
Writer1()6993 void Writer1() {
6994   MutexLock lock3(&mu3);  // This lock is unrelated to PTR.
6995   MutexLock lock1(&mu1);  // Protect PTR.
6996   *PTR = 1;
6997 }
6998 
Writer2()6999 void Writer2() {
7000   MutexLock lock2(&mu2);  // This lock is unrelated to PTR.
7001   MutexLock lock1(&mu1);  // Protect PTR.
7002   int some_unrelated_stuff = 0;
7003   if (some_unrelated_stuff == 0)
7004     some_unrelated_stuff++;
7005   *PTR = 2;
7006 }
7007 
7008 
Reader()7009 void Reader() {
7010   MutexLock lock2(&mu2);  // Oh, gosh, this is a wrong mutex!
7011   CHECK(*PTR <= 2);
7012 }
7013 
7014 // Some functions to make the stack trace non-trivial.
DoWrite1()7015 void DoWrite1() { Writer1();  }
Thread1()7016 void Thread1()  { DoWrite1(); }
7017 
DoWrite2()7018 void DoWrite2() { Writer2();  }
Thread2()7019 void Thread2()  { DoWrite2(); }
7020 
DoRead()7021 void DoRead()  { Reader();  }
Thread3()7022 void Thread3() { DoRead();  }
7023 
Run()7024 void Run() {
7025   printf("test310: simple race.\n");
7026   PTR = new int;
7027   ANNOTATE_TRACE_MEMORY(PTR);
7028   *PTR = 0;
7029   MyThread t1(Thread1, NULL, "writer1"),
7030            t2(Thread2, NULL, "writer2"),
7031            t3(Thread3, NULL, "buggy reader");
7032   t1.Start();
7033   t2.Start();
7034   usleep(100000);  // Let the writers go first.
7035   t3.Start();
7036 
7037   t1.Join();
7038   t2.Join();
7039   t3.Join();
7040 }
7041 REGISTER_TEST2(Run, 310, RACE_DEMO)
7042 }  // namespace test310
7043 
7044 // test311: Yet another simple race.  {{{1
7045 namespace test311 {
7046 int     *PTR = NULL;  // GUARDED_BY(mu1)
7047 
7048 Mutex mu1;  // Protects PTR.
7049 Mutex mu2;  // Unrelated to PTR.
7050 Mutex mu3;  // Unrelated to PTR.
7051 
GoodWriter1()7052 void GoodWriter1() {
7053   MutexLock lock3(&mu3);  // This lock is unrelated to PTR.
7054   MutexLock lock1(&mu1);  // Protect PTR.
7055   *PTR = 1;
7056 }
7057 
GoodWriter2()7058 void GoodWriter2() {
7059   MutexLock lock2(&mu2);  // This lock is unrelated to PTR.
7060   MutexLock lock1(&mu1);  // Protect PTR.
7061   *PTR = 2;
7062 }
7063 
GoodReader()7064 void GoodReader() {
7065   MutexLock lock1(&mu1);  // Protect PTR.
7066   CHECK(*PTR >= 0);
7067 }
7068 
BuggyWriter()7069 void BuggyWriter() {
7070   MutexLock lock2(&mu2);  // Wrong mutex!
7071   *PTR = 3;
7072 }
7073 
7074 // Some functions to make the stack trace non-trivial.
DoWrite1()7075 void DoWrite1() { GoodWriter1();  }
Thread1()7076 void Thread1()  { DoWrite1(); }
7077 
DoWrite2()7078 void DoWrite2() { GoodWriter2();  }
Thread2()7079 void Thread2()  { DoWrite2(); }
7080 
DoGoodRead()7081 void DoGoodRead()  { GoodReader();  }
Thread3()7082 void Thread3()     { DoGoodRead();  }
7083 
DoBadWrite()7084 void DoBadWrite()  { BuggyWriter(); }
Thread4()7085 void Thread4()     { DoBadWrite(); }
7086 
Run()7087 void Run() {
7088   printf("test311: simple race.\n");
7089   PTR = new int;
7090   ANNOTATE_TRACE_MEMORY(PTR);
7091   *PTR = 0;
7092   MyThread t1(Thread1, NULL, "good writer1"),
7093            t2(Thread2, NULL, "good writer2"),
7094            t3(Thread3, NULL, "good reader"),
7095            t4(Thread4, NULL, "buggy writer");
7096   t1.Start();
7097   t3.Start();
7098   // t2 goes after t3. This way a pure happens-before detector has no chance.
7099   usleep(10000);
7100   t2.Start();
7101   usleep(100000);  // Let the good folks go first.
7102   t4.Start();
7103 
7104   t1.Join();
7105   t2.Join();
7106   t3.Join();
7107   t4.Join();
7108 }
7109 REGISTER_TEST2(Run, 311, RACE_DEMO)
7110 }  // namespace test311
7111 
7112 // test312: A test with a very deep stack. {{{1
7113 namespace test312 {
7114 int     GLOB = 0;
RaceyWrite()7115 void RaceyWrite() { GLOB++; }
Func1()7116 void Func1() { RaceyWrite(); }
Func2()7117 void Func2() { Func1(); }
Func3()7118 void Func3() { Func2(); }
Func4()7119 void Func4() { Func3(); }
Func5()7120 void Func5() { Func4(); }
Func6()7121 void Func6() { Func5(); }
Func7()7122 void Func7() { Func6(); }
Func8()7123 void Func8() { Func7(); }
Func9()7124 void Func9() { Func8(); }
Func10()7125 void Func10() { Func9(); }
Func11()7126 void Func11() { Func10(); }
Func12()7127 void Func12() { Func11(); }
Func13()7128 void Func13() { Func12(); }
Func14()7129 void Func14() { Func13(); }
Func15()7130 void Func15() { Func14(); }
Func16()7131 void Func16() { Func15(); }
Func17()7132 void Func17() { Func16(); }
Func18()7133 void Func18() { Func17(); }
Func19()7134 void Func19() { Func18(); }
Worker()7135 void Worker() { Func19(); }
Run()7136 void Run() {
7137   printf("test312: simple race with deep stack.\n");
7138   MyThreadArray t(Worker, Worker, Worker);
7139   t.Start();
7140   t.Join();
7141 }
7142 REGISTER_TEST2(Run, 312, RACE_DEMO)
7143 }  // namespace test312
7144 
7145 // test313 TP: test for thread graph output {{{1
7146 namespace  test313 {
7147 BlockingCounter *blocking_counter;
7148 int     GLOB = 0;
7149 
7150 // Worker(N) will do 2^N increments of GLOB, each increment in a separate thread
Worker(long depth)7151 void Worker(long depth) {
7152   CHECK(depth >= 0);
7153   if (depth > 0) {
7154     ThreadPool pool(2);
7155     pool.StartWorkers();
7156     pool.Add(NewCallback(Worker, depth-1));
7157     pool.Add(NewCallback(Worker, depth-1));
7158   } else {
7159     GLOB++; // Race here
7160   }
7161 }
Run()7162 void Run() {
7163   printf("test313: positive\n");
7164   Worker(4);
7165   printf("\tGLOB=%d\n", GLOB);
7166 }
7167 REGISTER_TEST2(Run, 313, RACE_DEMO)
7168 }  // namespace test313
7169 
7170 
7171 
7172 // test400: Demo of a simple false positive. {{{1
7173 namespace test400 {
7174 static Mutex mu;
7175 static vector<int> *vec; // GUARDED_BY(mu);
7176 
InitAllBeforeStartingThreads()7177 void InitAllBeforeStartingThreads() {
7178   vec = new vector<int>;
7179   vec->push_back(1);
7180   vec->push_back(2);
7181 }
7182 
Thread1()7183 void Thread1() {
7184   MutexLock lock(&mu);
7185   vec->pop_back();
7186 }
7187 
Thread2()7188 void Thread2() {
7189   MutexLock lock(&mu);
7190   vec->pop_back();
7191 }
7192 
7193 //---- Sub-optimal code ---------
NumberOfElementsLeft()7194 size_t NumberOfElementsLeft() {
7195   MutexLock lock(&mu);
7196   return vec->size();
7197 }
7198 
WaitForAllThreadsToFinish_InefficientAndTsanUnfriendly()7199 void WaitForAllThreadsToFinish_InefficientAndTsanUnfriendly() {
7200   while(NumberOfElementsLeft()) {
7201     ; // sleep or print or do nothing.
7202   }
7203   // It is now safe to access vec w/o lock.
7204   // But a hybrid detector (like ThreadSanitizer) can't see it.
7205   // Solutions:
7206   //   1. Use pure happens-before detector (e.g. "tsan --pure-happens-before")
7207   //   2. Call ANNOTATE_MUTEX_IS_USED_AS_CONDVAR(&mu)
7208   //      in InitAllBeforeStartingThreads()
7209   //   3. (preferred) Use WaitForAllThreadsToFinish_Good() (see below).
7210   CHECK(vec->empty());
7211   delete vec;
7212 }
7213 
7214 //----- Better code -----------
7215 
NoElementsLeft(vector<int> * v)7216 bool NoElementsLeft(vector<int> *v) {
7217   return v->empty();
7218 }
7219 
WaitForAllThreadsToFinish_Good()7220 void WaitForAllThreadsToFinish_Good() {
7221   mu.LockWhen(Condition(NoElementsLeft, vec));
7222   mu.Unlock();
7223 
7224   // It is now safe to access vec w/o lock.
7225   CHECK(vec->empty());
7226   delete vec;
7227 }
7228 
7229 
Run()7230 void Run() {
7231   MyThreadArray t(Thread1, Thread2);
7232   InitAllBeforeStartingThreads();
7233   t.Start();
7234   WaitForAllThreadsToFinish_InefficientAndTsanUnfriendly();
7235 //  WaitForAllThreadsToFinish_Good();
7236   t.Join();
7237 }
7238 REGISTER_TEST2(Run, 400, RACE_DEMO)
7239 }  // namespace test400
7240 
7241 // test401: Demo of false positive caused by reference counting. {{{1
7242 namespace test401 {
7243 // A simplified example of reference counting.
7244 // DecRef() does ref count increment in a way unfriendly to race detectors.
7245 // DecRefAnnotated() does the same in a friendly way.
7246 
7247 static vector<int> *vec;
7248 static int ref_count;
7249 
InitAllBeforeStartingThreads(int number_of_threads)7250 void InitAllBeforeStartingThreads(int number_of_threads) {
7251   vec = new vector<int>;
7252   vec->push_back(1);
7253   ref_count = number_of_threads;
7254 }
7255 
7256 // Correct, but unfriendly to race detectors.
DecRef()7257 int DecRef() {
7258   return AtomicIncrement(&ref_count, -1);
7259 }
7260 
7261 // Correct and friendly to race detectors.
DecRefAnnotated()7262 int DecRefAnnotated() {
7263   ANNOTATE_CONDVAR_SIGNAL(&ref_count);
7264   int res = AtomicIncrement(&ref_count, -1);
7265   if (res == 0) {
7266     ANNOTATE_CONDVAR_WAIT(&ref_count);
7267   }
7268   return res;
7269 }
7270 
ThreadWorker()7271 void ThreadWorker() {
7272   CHECK(ref_count > 0);
7273   CHECK(vec->size() == 1);
7274   if (DecRef() == 0) {  // Use DecRefAnnotated() instead!
7275     // No one uses vec now ==> delete it.
7276     delete vec;  // A false race may be reported here.
7277     vec = NULL;
7278   }
7279 }
7280 
Run()7281 void Run() {
7282   MyThreadArray t(ThreadWorker, ThreadWorker, ThreadWorker);
7283   InitAllBeforeStartingThreads(3 /*number of threads*/);
7284   t.Start();
7285   t.Join();
7286   CHECK(vec == 0);
7287 }
7288 REGISTER_TEST2(Run, 401, RACE_DEMO)
7289 }  // namespace test401
7290 
7291 // test501: Manually call PRINT_* annotations {{{1
7292 namespace test501 {
7293 int  COUNTER = 0;
7294 int     GLOB = 0;
7295 Mutex muCounter, muGlob[65];
7296 
Worker()7297 void Worker() {
7298    muCounter.Lock();
7299    int myId = ++COUNTER;
7300    muCounter.Unlock();
7301 
7302    usleep(100);
7303 
7304    muGlob[myId].Lock();
7305    muGlob[0].Lock();
7306    GLOB++;
7307    muGlob[0].Unlock();
7308    muGlob[myId].Unlock();
7309 }
7310 
Worker_1()7311 void Worker_1() {
7312    MyThreadArray ta (Worker, Worker, Worker, Worker);
7313    ta.Start();
7314    usleep(500000);
7315    ta.Join ();
7316 }
7317 
Worker_2()7318 void Worker_2() {
7319    MyThreadArray ta (Worker_1, Worker_1, Worker_1, Worker_1);
7320    ta.Start();
7321    usleep(300000);
7322    ta.Join ();
7323 }
7324 
Run()7325 void Run() {
7326    ANNOTATE_RESET_STATS();
7327    printf("test501: Manually call PRINT_* annotations.\n");
7328    MyThreadArray ta (Worker_2, Worker_2, Worker_2, Worker_2);
7329    ta.Start();
7330    usleep(100000);
7331    ta.Join ();
7332    ANNOTATE_PRINT_MEMORY_USAGE(0);
7333    ANNOTATE_PRINT_STATS();
7334 }
7335 
7336 REGISTER_TEST2(Run, 501, FEATURE | EXCLUDE_FROM_ALL)
7337 }  // namespace test501
7338 
7339 // test502: produce lots of segments without cross-thread relations {{{1
7340 namespace test502 {
7341 
7342 /*
7343  * This test produces ~1Gb of memory usage when run with the following options:
7344  *
7345  * --tool=helgrind
7346  * --trace-after-race=0
7347  * --num-callers=2
7348  * --more-context=no
7349  */
7350 
7351 Mutex MU;
7352 int     GLOB = 0;
7353 
TP()7354 void TP() {
7355    for (int i = 0; i < 750000; i++) {
7356       MU.Lock();
7357       GLOB++;
7358       MU.Unlock();
7359    }
7360 }
7361 
Run()7362 void Run() {
7363    MyThreadArray t(TP, TP);
7364    printf("test502: produce lots of segments without cross-thread relations\n");
7365 
7366    t.Start();
7367    t.Join();
7368 }
7369 
7370 REGISTER_TEST2(Run, 502, MEMORY_USAGE | PRINT_STATS | EXCLUDE_FROM_ALL
7371                               | PERFORMANCE)
7372 }  // namespace test502
7373 
7374 // test503: produce lots of segments with simple HB-relations {{{1
7375 // HB cache-miss rate is ~55%
7376 namespace test503 {
7377 
7378 //  |- |  |  |  |  |
7379 //  | \|  |  |  |  |
7380 //  |  |- |  |  |  |
7381 //  |  | \|  |  |  |
7382 //  |  |  |- |  |  |
7383 //  |  |  | \|  |  |
7384 //  |  |  |  |- |  |
7385 //  |  |  |  | \|  |
7386 //  |  |  |  |  |- |
7387 //  |  |  |  |  | \|
7388 //  |  |  |  |  |  |----
7389 //->|  |  |  |  |  |
7390 //  |- |  |  |  |  |
7391 //  | \|  |  |  |  |
7392 //     ...
7393 
7394 const int N_threads = 32;
7395 const int ARRAY_SIZE = 128;
7396 int       GLOB[ARRAY_SIZE];
7397 ProducerConsumerQueue *Q[N_threads];
7398 int GLOB_limit = 100000;
7399 int count = -1;
7400 
Worker()7401 void Worker(){
7402    int myId = AtomicIncrement(&count, 1);
7403 
7404    ProducerConsumerQueue &myQ = *Q[myId], &nextQ = *Q[(myId+1) % N_threads];
7405 
7406    // this code produces a new SS with each new segment
7407    while (myQ.Get() != NULL) {
7408       for (int i = 0; i < ARRAY_SIZE; i++)
7409          GLOB[i]++;
7410 
7411       if (myId == 0 && GLOB[0] > GLOB_limit) {
7412          // Stop all threads
7413          for (int i = 0; i < N_threads; i++)
7414             Q[i]->Put(NULL);
7415       } else
7416          nextQ.Put(GLOB);
7417    }
7418 }
7419 
Run()7420 void Run() {
7421    printf("test503: produce lots of segments with simple HB-relations\n");
7422    for (int i = 0; i < N_threads; i++)
7423       Q[i] = new ProducerConsumerQueue(1);
7424    Q[0]->Put(GLOB);
7425 
7426    {
7427       ThreadPool pool(N_threads);
7428       pool.StartWorkers();
7429       for (int i = 0; i < N_threads; i++) {
7430          pool.Add(NewCallback(Worker));
7431       }
7432    } // all folks are joined here.
7433 
7434    for (int i = 0; i < N_threads; i++)
7435       delete Q[i];
7436 }
7437 
7438 REGISTER_TEST2(Run, 503, MEMORY_USAGE | PRINT_STATS
7439                   | PERFORMANCE | EXCLUDE_FROM_ALL)
7440 }  // namespace test503
7441 
7442 // test504: force massive cache fetch-wback (50% misses, mostly CacheLineZ) {{{1
7443 namespace test504 {
7444 
7445 const int N_THREADS = 2,
7446           HG_CACHELINE_COUNT = 1 << 16,
7447           HG_CACHELINE_SIZE  = 1 << 6,
7448           HG_CACHE_SIZE = HG_CACHELINE_COUNT * HG_CACHELINE_SIZE;
7449 
7450 // int gives us ~4x speed of the byte test
7451 // 4x array size gives us
7452 // total multiplier of 16x over the cachesize
7453 // so we can neglect the cached-at-the-end memory
7454 const int ARRAY_SIZE = 4 * HG_CACHE_SIZE,
7455           ITERATIONS = 30;
7456 int array[ARRAY_SIZE];
7457 
7458 int count = 0;
7459 Mutex count_mu;
7460 
Worker()7461 void Worker() {
7462    count_mu.Lock();
7463    int myId = ++count;
7464    count_mu.Unlock();
7465 
7466    // all threads write to different memory locations,
7467    // so no synchronization mechanisms are needed
7468    int lower_bound = ARRAY_SIZE * (myId-1) / N_THREADS,
7469        upper_bound = ARRAY_SIZE * ( myId ) / N_THREADS;
7470    for (int j = 0; j < ITERATIONS; j++)
7471    for (int i = lower_bound; i < upper_bound;
7472             i += HG_CACHELINE_SIZE / sizeof(array[0])) {
7473       array[i] = i; // each array-write generates a cache miss
7474    }
7475 }
7476 
Run()7477 void Run() {
7478    printf("test504: force massive CacheLineZ fetch-wback\n");
7479    MyThreadArray t(Worker, Worker);
7480    t.Start();
7481    t.Join();
7482 }
7483 
7484 REGISTER_TEST2(Run, 504, PERFORMANCE | PRINT_STATS | EXCLUDE_FROM_ALL)
7485 }  // namespace test504
7486 
7487 // test505: force massive cache fetch-wback (60% misses) {{{1
7488 // modification of test504 - more threads, byte accesses and lots of mutexes
7489 // so it produces lots of CacheLineF misses (30-50% of CacheLineZ misses)
7490 namespace test505 {
7491 
7492 const int N_THREADS = 2,
7493           HG_CACHELINE_COUNT = 1 << 16,
7494           HG_CACHELINE_SIZE  = 1 << 6,
7495           HG_CACHE_SIZE = HG_CACHELINE_COUNT * HG_CACHELINE_SIZE;
7496 
7497 const int ARRAY_SIZE = 4 * HG_CACHE_SIZE,
7498           ITERATIONS = 3;
7499 int64_t array[ARRAY_SIZE];
7500 
7501 int count = 0;
7502 Mutex count_mu;
7503 
Worker()7504 void Worker() {
7505    const int N_MUTEXES = 5;
7506    Mutex mu[N_MUTEXES];
7507    count_mu.Lock();
7508    int myId = ++count;
7509    count_mu.Unlock();
7510 
7511    // all threads write to different memory locations,
7512    // so no synchronization mechanisms are needed
7513    int lower_bound = ARRAY_SIZE * (myId-1) / N_THREADS,
7514        upper_bound = ARRAY_SIZE * ( myId ) / N_THREADS;
7515    for (int j = 0; j < ITERATIONS; j++)
7516    for (int mutex_id = 0; mutex_id < N_MUTEXES; mutex_id++) {
7517       Mutex *m = & mu[mutex_id];
7518       m->Lock();
7519       for (int i = lower_bound + mutex_id, cnt = 0;
7520                i < upper_bound;
7521                i += HG_CACHELINE_SIZE / sizeof(array[0]), cnt++) {
7522          array[i] = i; // each array-write generates a cache miss
7523       }
7524       m->Unlock();
7525    }
7526 }
7527 
Run()7528 void Run() {
7529    printf("test505: force massive CacheLineF fetch-wback\n");
7530    MyThreadArray t(Worker, Worker);
7531    t.Start();
7532    t.Join();
7533 }
7534 
7535 REGISTER_TEST2(Run, 505, PERFORMANCE | PRINT_STATS | EXCLUDE_FROM_ALL)
7536 }  // namespace test505
7537 
7538 // test506: massive HB's using Barriers {{{1
7539 // HB cache miss is ~40%
7540 // segments consume 10x more memory than SSs
7541 // modification of test39
7542 namespace test506 {
7543 #ifndef NO_BARRIER
7544 // Same as test17 but uses Barrier class (pthread_barrier_t).
7545 int     GLOB = 0;
7546 const int N_threads = 64,
7547           ITERATIONS = 1000;
7548 Barrier *barrier[ITERATIONS];
7549 Mutex   MU;
7550 
Worker()7551 void Worker() {
7552   for (int i = 0; i < ITERATIONS; i++) {
7553      MU.Lock();
7554      GLOB++;
7555      MU.Unlock();
7556      barrier[i]->Block();
7557   }
7558 }
Run()7559 void Run() {
7560   printf("test506: massive HB's using Barriers\n");
7561   for (int i = 0; i < ITERATIONS; i++) {
7562      barrier[i] = new Barrier(N_threads);
7563   }
7564   {
7565     ThreadPool pool(N_threads);
7566     pool.StartWorkers();
7567     for (int i = 0; i < N_threads; i++) {
7568       pool.Add(NewCallback(Worker));
7569     }
7570   } // all folks are joined here.
7571   CHECK(GLOB == N_threads * ITERATIONS);
7572   for (int i = 0; i < ITERATIONS; i++) {
7573      delete barrier[i];
7574   }
7575 }
7576 REGISTER_TEST2(Run, 506, PERFORMANCE | PRINT_STATS | EXCLUDE_FROM_ALL);
7577 #endif // NO_BARRIER
7578 }  // namespace test506
7579 
7580 // test507: vgHelgrind_initIterAtFM/stackClear benchmark {{{1
7581 // vgHelgrind_initIterAtFM/stackClear consume ~8.5%/5.5% CPU
7582 namespace test507 {
7583 const int N_THREADS    = 1,
7584           BUFFER_SIZE  = 1,
7585           ITERATIONS   = 1 << 20;
7586 
Foo()7587 void Foo() {
7588   struct T {
7589     char temp;
7590     T() {
7591       ANNOTATE_RWLOCK_CREATE(&temp);
7592     }
7593     ~T() {
7594       ANNOTATE_RWLOCK_DESTROY(&temp);
7595     }
7596   } s[BUFFER_SIZE];
7597   s->temp = '\0';
7598 }
7599 
Worker()7600 void Worker() {
7601   for (int j = 0; j < ITERATIONS; j++) {
7602     Foo();
7603   }
7604 }
7605 
Run()7606 void Run() {
7607   printf("test507: vgHelgrind_initIterAtFM/stackClear benchmark\n");
7608   {
7609     ThreadPool pool(N_THREADS);
7610     pool.StartWorkers();
7611     for (int i = 0; i < N_THREADS; i++) {
7612       pool.Add(NewCallback(Worker));
7613     }
7614   } // all folks are joined here.
7615 }
7616 REGISTER_TEST2(Run, 507, EXCLUDE_FROM_ALL);
7617 }  // namespace test507
7618 
7619 // test508: cmp_WordVecs_for_FM benchmark {{{1
7620 // 50+% of CPU consumption by cmp_WordVecs_for_FM
7621 namespace test508 {
7622 const int N_THREADS    = 1,
7623           BUFFER_SIZE  = 1 << 10,
7624           ITERATIONS   = 1 << 9;
7625 
Foo()7626 void Foo() {
7627   struct T {
7628     char temp;
7629     T() {
7630       ANNOTATE_RWLOCK_CREATE(&temp);
7631     }
7632     ~T() {
7633       ANNOTATE_RWLOCK_DESTROY(&temp);
7634     }
7635   } s[BUFFER_SIZE];
7636   s->temp = '\0';
7637 }
7638 
Worker()7639 void Worker() {
7640   for (int j = 0; j < ITERATIONS; j++) {
7641     Foo();
7642   }
7643 }
7644 
Run()7645 void Run() {
7646   printf("test508: cmp_WordVecs_for_FM benchmark\n");
7647   {
7648     ThreadPool pool(N_THREADS);
7649     pool.StartWorkers();
7650     for (int i = 0; i < N_THREADS; i++) {
7651       pool.Add(NewCallback(Worker));
7652     }
7653   } // all folks are joined here.
7654 }
7655 REGISTER_TEST2(Run, 508, EXCLUDE_FROM_ALL);
7656 }  // namespace test508
7657 
7658 // test509: avl_find_node benchmark {{{1
7659 // 10+% of CPU consumption by avl_find_node
7660 namespace test509 {
7661 const int N_THREADS    = 16,
7662           ITERATIONS   = 1 << 8;
7663 
Worker()7664 void Worker() {
7665   std::vector<Mutex*> mu_list;
7666   for (int i = 0; i < ITERATIONS; i++) {
7667     Mutex * mu = new Mutex();
7668     mu_list.push_back(mu);
7669     mu->Lock();
7670   }
7671   for (int i = ITERATIONS - 1; i >= 0; i--) {
7672     Mutex * mu = mu_list[i];
7673     mu->Unlock();
7674     delete mu;
7675   }
7676 }
7677 
Run()7678 void Run() {
7679   printf("test509: avl_find_node benchmark\n");
7680   {
7681     ThreadPool pool(N_THREADS);
7682     pool.StartWorkers();
7683     for (int i = 0; i < N_THREADS; i++) {
7684       pool.Add(NewCallback(Worker));
7685     }
7686   } // all folks are joined here.
7687 }
7688 REGISTER_TEST2(Run, 509, EXCLUDE_FROM_ALL);
7689 }  // namespace test509
7690 
7691 // test510: SS-recycle test {{{1
7692 // this tests shows the case where only ~1% of SS are recycled
7693 namespace test510 {
7694 const int N_THREADS    = 16,
7695           ITERATIONS   = 1 << 10;
7696 int GLOB = 0;
7697 
Worker()7698 void Worker() {
7699   usleep(100000);
7700   for (int i = 0; i < ITERATIONS; i++) {
7701     ANNOTATE_CONDVAR_SIGNAL((void*)0xDeadBeef);
7702     GLOB++;
7703     usleep(10);
7704   }
7705 }
7706 
Run()7707 void Run() {
7708   //ANNOTATE_BENIGN_RACE(&GLOB, "Test");
7709   printf("test510: SS-recycle test\n");
7710   {
7711     ThreadPool pool(N_THREADS);
7712     pool.StartWorkers();
7713     for (int i = 0; i < N_THREADS; i++) {
7714       pool.Add(NewCallback(Worker));
7715     }
7716   } // all folks are joined here.
7717 }
7718 REGISTER_TEST2(Run, 510, MEMORY_USAGE | PRINT_STATS | EXCLUDE_FROM_ALL);
7719 }  // namespace test510
7720 
7721 // test511: Segment refcounting test ('1' refcounting) {{{1
7722 namespace test511 {
7723 int GLOB = 0;
7724 
Run()7725 void Run () {
7726    for (int i = 0; i < 300; i++) {
7727       ANNOTATE_CONDVAR_SIGNAL(&GLOB);
7728       usleep(1000);
7729       GLOB++;
7730       ANNOTATE_CONDVAR_WAIT(&GLOB);
7731       if (i % 100 == 0)
7732          ANNOTATE_PRINT_MEMORY_USAGE(0);
7733    }
7734 }
7735 REGISTER_TEST2(Run, 511, MEMORY_USAGE | PRINT_STATS | EXCLUDE_FROM_ALL);
7736 }  // namespace test511
7737 
7738 // test512: Segment refcounting test ('S' refcounting) {{{1
7739 namespace test512 {
7740 int GLOB = 0;
7741 sem_t SEM;
7742 
Run()7743 void Run () {
7744    sem_init(&SEM, 0, 0);
7745    for (int i = 0; i < 300; i++) {
7746       sem_post(&SEM);
7747       usleep(1000);
7748       GLOB++;
7749       sem_wait(&SEM);
7750       /*if (i % 100 == 0)
7751          ANNOTATE_PRINT_MEMORY_USAGE(0);*/
7752    }
7753    sem_destroy(&SEM);
7754 }
7755 REGISTER_TEST2(Run, 512, MEMORY_USAGE | PRINT_STATS | EXCLUDE_FROM_ALL);
7756 }  // namespace test512
7757 
7758 // test513: --fast-mode benchmark {{{1
7759 namespace test513 {
7760 
7761 const int N_THREADS = 2,
7762           HG_CACHELINE_SIZE  = 1 << 6,
7763           ARRAY_SIZE = HG_CACHELINE_SIZE * 512,
7764           MUTEX_ID_BITS = 8;
7765 //          MUTEX_ID_MASK = (1 << MUTEX_ID_BITS) - 1;
7766 
7767 // Each thread has its own cacheline and tackles with it intensively
7768 const int ITERATIONS = 1024;
7769 int array[N_THREADS][ARRAY_SIZE];
7770 
7771 int count = 0;
7772 Mutex count_mu;
7773 Mutex mutex_arr[N_THREADS][MUTEX_ID_BITS];
7774 
Worker()7775 void Worker() {
7776    count_mu.Lock();
7777    int myId = count++;
7778    count_mu.Unlock();
7779 
7780    // all threads write to different memory locations
7781    for (int j = 0; j < ITERATIONS; j++) {
7782       int mutex_mask = j & MUTEX_ID_BITS;
7783       for (int m = 0; m < MUTEX_ID_BITS; m++)
7784          if (mutex_mask & (1 << m))
7785             mutex_arr[myId][m].Lock();
7786 
7787       for (int i = 0; i < ARRAY_SIZE; i++) {
7788          array[myId][i] = i;
7789       }
7790 
7791       for (int m = 0; m < MUTEX_ID_BITS; m++)
7792          if (mutex_mask & (1 << m))
7793             mutex_arr[myId][m].Unlock();
7794    }
7795 }
7796 
Run()7797 void Run() {
7798    printf("test513: --fast-mode benchmark\n");
7799    {
7800       ThreadPool pool(N_THREADS);
7801       pool.StartWorkers();
7802       for (int i = 0; i < N_THREADS; i++) {
7803          pool.Add(NewCallback(Worker));
7804       }
7805    } // all folks are joined here.
7806 }
7807 
7808 REGISTER_TEST2(Run, 513, PERFORMANCE | PRINT_STATS | EXCLUDE_FROM_ALL)
7809 }  // namespace test513
7810 
7811 // End {{{1
7812 // vim:shiftwidth=2:softtabstop=2:expandtab:foldmethod=marker
7813