| blob | 8562b14a8739bf3ef43904646792442937137716 |
1 /*
2 * qsp.c - QEMU Synchronization Profiler
3 *
4 * Copyright (C) 2018, Emilio G. Cota <cota@braap.org>
5 *
6 * License: GNU GPL, version 2 or later.
7 * See the COPYING file in the top-level directory.
8 *
9 * QSP profiles the time spent in synchronization primitives, which can
10 * help diagnose performance problems, e.g. scalability issues when
11 * contention is high.
12 *
13 * The primitives currently supported are mutexes, recursive mutexes and
14 * condition variables. Note that not all related functions are intercepted;
15 * instead we profile only those functions that can have a performance impact,
16 * either due to blocking (e.g. cond_wait, mutex_lock) or cache line
17 * contention (e.g. mutex_lock, mutex_trylock).
18 *
19 * QSP's design focuses on speed and scalability. This is achieved
20 * by having threads do their profiling entirely on thread-local data.
21 * The appropriate thread-local data is found via a QHT, i.e. a concurrent hash
22 * table. To aggregate data in order to generate a report, we iterate over
23 * all entries in the hash table. Depending on the number of threads and
24 * synchronization objects this might be expensive, but note that it is
25 * very rarely called -- reports are generated only when requested by users.
26 *
27 * Reports are generated as a table where each row represents a call site. A
28 * call site is the triplet formed by the __file__ and __LINE__ of the caller
29 * as well as the address of the "object" (i.e. mutex, rec. mutex or condvar)
30 * being operated on. Optionally, call sites that operate on different objects
31 * of the same type can be coalesced, which can be particularly useful when
32 * profiling dynamically-allocated objects.
33 *
34 * Alternative designs considered:
35 *
36 * - Use an off-the-shelf profiler such as mutrace. This is not a viable option
37 * for us because QEMU has __malloc_hook set (by one of the libraries it
38 * uses); leaving this hook unset is required to avoid deadlock in mutrace.
39 *
40 * - Use a glib HT for each thread, protecting each HT with its own lock.
41 * This isn't simpler than the current design, and is 10% slower in the
42 * atomic_add-bench microbenchmark (-m option).
43 *
44 * - For reports, just use a binary tree as we aggregate data, instead of having
45 * an intermediate hash table. This would simplify the code only slightly, but
46 * would perform badly if there were many threads and objects to track.
47 *
48 * - Wrap operations on qsp entries with RCU read-side critical sections, so
49 * that qsp_reset() can delete entries. Unfortunately, the overhead of calling
50 * rcu_read_lock/unlock slows down atomic_add-bench -m by 24%. Having
51 * a snapshot that is updated on qsp_reset() avoids this overhead.
52 *
53 * Related Work:
54 * - Lennart Poettering's mutrace: http://0pointer.de/blog/projects/mutrace.html
55 * - Lozi, David, Thomas, Lawall and Muller. "Remote Core Locking: Migrating
56 * Critical-Section Execution to Improve the Performance of Multithreaded
57 * Applications", USENIX ATC'12.
58 */
69 QSP_MUTEX,
70 QSP_BQL_MUTEX,
71 QSP_REC_MUTEX,
72 QSP_CONDVAR,
73 };
80 };
86 aligned_uint64_t n_acqs;
87 aligned_uint64_t ns;
89 };
95 };
98 /* initial sizing for hash tables */
99 #define QSP_INITIAL_SIZE 64
101 /* If this file is moved, QSP_REL_PATH should be updated accordingly */
104 /* this file's full path. Used to present all call sites with relative paths */
107 /* the address of qsp_thread gives us a unique 'thread ID' */
110 /*
111 * Call sites are the same for all threads, so we track them in a separate hash
112 * table to save memory.
113 */
125 };
131 QemuRecMutexTrylockFunc qemu_rec_mutex_trylock_func =
132 qemu_rec_mutex_trylock_impl;
136 /*
137 * It pays off to _not_ hash callsite->file; hashing a string is slow, and
138 * without it we still get a pretty unique hash.
139 */
142 {
148 }
152 {
154 }
157 {
159 }
162 {
164 }
167 {
169 }
171 /* without the objects we need to hash the file name to get a decent hash */
173 {
180 }
183 {
192 }
195 {
203 }
206 {
211 }
214 {
219 }
222 {
228 }
230 /*
231 * Normally we'd call this from a constructor function, but we want it to work
232 * via libutil as well.
233 */
235 {
236 /* make sure this file's path in the tree is up to date with QSP_REL_PATH */
244 }
247 {
254 }
255 }
256 }
258 /* qsp_init() must be called from _all_ exported functions */
260 {
263 }
265 }
268 {
283 }
284 }
286 }
290 {
302 }
304 }
308 {
314 }
316 }
318 /*
319 * Note: Entries are never removed, so callers do not have to be in an RCU
320 * read-side critical section.
321 */
324 {
325 QSPCallSite callsite = {
330 };
331 QSPEntry orig;
341 }
343 /*
344 * @e is in the global hash table; it is only written to by the current thread,
345 * so we write to it atomically (as in "write once") to prevent torn reads.
346 */
348 {
352 }
353 }
356 {
358 }
360 #define QSP_GEN_VOID(type_, qsp_t_, func_, impl_) \
361 static void func_(type_ *obj, const char *file, int line) \
362 { \
363 QSPEntry *e; \
364 int64_t t0, t1; \
365 \
366 t0 = get_clock(); \
367 impl_(obj, file, line); \
368 t1 = get_clock(); \
369 \
370 e = qsp_entry_get(obj, file, line, qsp_t_); \
371 qsp_entry_record(e, t1 - t0); \
372 }
374 #define QSP_GEN_RET1(type_, qsp_t_, func_, impl_) \
375 static int func_(type_ *obj, const char *file, int line) \
376 { \
377 QSPEntry *e; \
378 int64_t t0, t1; \
379 int err; \
380 \
381 t0 = get_clock(); \
382 err = impl_(obj, file, line); \
383 t1 = get_clock(); \
384 \
385 e = qsp_entry_get(obj, file, line, qsp_t_); \
386 do_qsp_entry_record(e, t1 - t0, !err); \
387 return err; \
388 }
395 qemu_rec_mutex_lock_impl)
397 qemu_rec_mutex_trylock_impl)
399 #undef QSP_GEN_RET1
400 #undef QSP_GEN_VOID
402 static void
404 {
414 }
416 static bool
419 {
431 }
434 {
436 }
439 {
447 }
450 {
458 }
461 {
474 }
477 {
485 }
487 }
490 }
494 /* Break the tie with the object's address */
502 /* same obj. Break the tie with the callsite's file */
506 }
507 /* same callsite file. Break the tie with the callsite's line */
514 /* break the tie with the callsite's type */
516 }
517 }
518 }
521 {
526 }
529 {
537 /*
538 * The entry is in the global hash table; read from it atomically (as in
539 * "read once").
540 */
543 }
546 {
552 /* entries are never deleted, so we must have this one */
554 /* our reading of the stats happened after the snapshot was taken */
561 /* No point in reporting an empty entry */
567 }
568 }
571 {
573 }
576 {
589 }
592 }
595 {
597 }
600 {
604 /*
605 * First, see if there's a prior snapshot, so that we read the global hash
606 * table _after_ the snapshot has been created, which guarantees that
607 * the entries we'll read will be a superset of the snapshot's entries.
608 *
609 * We must remain in an RCU read-side critical section until we're done
610 * with the snapshot.
611 */
615 /* Aggregate all results from the global hash table into a local one */
620 /* compute the difference wrt the snapshot, if any */
623 }
624 }
632 /* free the previous hash table, and point htp to coalesce_ht */
636 }
638 /* sort the hash table elements by using a tree */
641 /* free the hash table, but keep the elements (those are in the tree now) */
643 }
645 /* free string with g_free */
647 {
651 /* remove the absolute path to qemu */
656 }
659 }
669 };
676 };
680 {
687 }
699 }
702 {
710 /* find out the maximum length of all 'callsite' fields */
717 }
718 }
721 /* white space to leave to the right of "Call site" */
727 /* build a horizontal rule with dashes */
743 }
750 }
754 }
757 {
764 }
766 }
770 {
772 QSPReport rep;
786 }
789 {
793 }
796 {
805 /* take a snapshot of the current state */
808 /* replace the previous snapshot, if any */
812 }
813 }