migration: Make threshold_size an uint64_t
[qemu/kevin.git] / migration / dirtyrate.c
blob1d2e85746fb7b10eb7f149976970f9a92125af8a
1 /*
2 * Dirtyrate implement code
4 * Copyright (c) 2020 HUAWEI TECHNOLOGIES CO.,LTD.
6 * Authors:
7 * Chuan Zheng <zhengchuan@huawei.com>
9 * This work is licensed under the terms of the GNU GPL, version 2 or later.
10 * See the COPYING file in the top-level directory.
13 #include "qemu/osdep.h"
14 #include "qemu/error-report.h"
15 #include <zlib.h>
16 #include "hw/core/cpu.h"
17 #include "qapi/error.h"
18 #include "exec/ramblock.h"
19 #include "exec/target_page.h"
20 #include "qemu/rcu_queue.h"
21 #include "qemu/main-loop.h"
22 #include "qapi/qapi-commands-migration.h"
23 #include "ram.h"
24 #include "trace.h"
25 #include "dirtyrate.h"
26 #include "monitor/hmp.h"
27 #include "monitor/monitor.h"
28 #include "qapi/qmp/qdict.h"
29 #include "sysemu/kvm.h"
30 #include "sysemu/runstate.h"
31 #include "exec/memory.h"
32 #include "qemu/xxhash.h"
35 * total_dirty_pages is procted by BQL and is used
36 * to stat dirty pages during the period of two
37 * memory_global_dirty_log_sync
39 uint64_t total_dirty_pages;
41 typedef struct DirtyPageRecord {
42 uint64_t start_pages;
43 uint64_t end_pages;
44 } DirtyPageRecord;
46 static int CalculatingState = DIRTY_RATE_STATUS_UNSTARTED;
47 static struct DirtyRateStat DirtyStat;
48 static DirtyRateMeasureMode dirtyrate_mode =
49 DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING;
51 static int64_t dirty_stat_wait(int64_t msec, int64_t initial_time)
53 int64_t current_time;
55 current_time = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
56 if ((current_time - initial_time) >= msec) {
57 msec = current_time - initial_time;
58 } else {
59 g_usleep((msec + initial_time - current_time) * 1000);
60 /* g_usleep may overshoot */
61 msec = qemu_clock_get_ms(QEMU_CLOCK_REALTIME) - initial_time;
64 return msec;
67 static inline void record_dirtypages(DirtyPageRecord *dirty_pages,
68 CPUState *cpu, bool start)
70 if (start) {
71 dirty_pages[cpu->cpu_index].start_pages = cpu->dirty_pages;
72 } else {
73 dirty_pages[cpu->cpu_index].end_pages = cpu->dirty_pages;
77 static int64_t do_calculate_dirtyrate(DirtyPageRecord dirty_pages,
78 int64_t calc_time_ms)
80 uint64_t increased_dirty_pages =
81 dirty_pages.end_pages - dirty_pages.start_pages;
84 * multiply by 1000ms/s _before_ converting down to megabytes
85 * to avoid losing precision
87 return qemu_target_pages_to_MiB(increased_dirty_pages * 1000) /
88 calc_time_ms;
91 void global_dirty_log_change(unsigned int flag, bool start)
93 bql_lock();
94 if (start) {
95 memory_global_dirty_log_start(flag);
96 } else {
97 memory_global_dirty_log_stop(flag);
99 bql_unlock();
103 * global_dirty_log_sync
104 * 1. sync dirty log from kvm
105 * 2. stop dirty tracking if needed.
107 static void global_dirty_log_sync(unsigned int flag, bool one_shot)
109 bql_lock();
110 memory_global_dirty_log_sync(false);
111 if (one_shot) {
112 memory_global_dirty_log_stop(flag);
114 bql_unlock();
117 static DirtyPageRecord *vcpu_dirty_stat_alloc(VcpuStat *stat)
119 CPUState *cpu;
120 int nvcpu = 0;
122 CPU_FOREACH(cpu) {
123 nvcpu++;
126 stat->nvcpu = nvcpu;
127 stat->rates = g_new0(DirtyRateVcpu, nvcpu);
129 return g_new0(DirtyPageRecord, nvcpu);
132 static void vcpu_dirty_stat_collect(DirtyPageRecord *records,
133 bool start)
135 CPUState *cpu;
137 CPU_FOREACH(cpu) {
138 record_dirtypages(records, cpu, start);
142 int64_t vcpu_calculate_dirtyrate(int64_t calc_time_ms,
143 VcpuStat *stat,
144 unsigned int flag,
145 bool one_shot)
147 DirtyPageRecord *records;
148 int64_t init_time_ms;
149 int64_t duration;
150 int64_t dirtyrate;
151 int i = 0;
152 unsigned int gen_id;
154 retry:
155 init_time_ms = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
157 WITH_QEMU_LOCK_GUARD(&qemu_cpu_list_lock) {
158 gen_id = cpu_list_generation_id_get();
159 records = vcpu_dirty_stat_alloc(stat);
160 vcpu_dirty_stat_collect(records, true);
163 duration = dirty_stat_wait(calc_time_ms, init_time_ms);
165 global_dirty_log_sync(flag, one_shot);
167 WITH_QEMU_LOCK_GUARD(&qemu_cpu_list_lock) {
168 if (gen_id != cpu_list_generation_id_get()) {
169 g_free(records);
170 g_free(stat->rates);
171 cpu_list_unlock();
172 goto retry;
174 vcpu_dirty_stat_collect(records, false);
177 for (i = 0; i < stat->nvcpu; i++) {
178 dirtyrate = do_calculate_dirtyrate(records[i], duration);
180 stat->rates[i].id = i;
181 stat->rates[i].dirty_rate = dirtyrate;
183 trace_dirtyrate_do_calculate_vcpu(i, dirtyrate);
186 g_free(records);
188 return duration;
191 static bool is_calc_time_valid(int64_t msec)
193 if ((msec < MIN_CALC_TIME_MS) || (msec > MAX_CALC_TIME_MS)) {
194 return false;
197 return true;
200 static bool is_sample_pages_valid(int64_t pages)
202 return pages >= MIN_SAMPLE_PAGE_COUNT &&
203 pages <= MAX_SAMPLE_PAGE_COUNT;
206 static int dirtyrate_set_state(int *state, int old_state, int new_state)
208 assert(new_state < DIRTY_RATE_STATUS__MAX);
209 trace_dirtyrate_set_state(DirtyRateStatus_str(new_state));
210 if (qatomic_cmpxchg(state, old_state, new_state) == old_state) {
211 return 0;
212 } else {
213 return -1;
217 /* Decimal power of given time unit relative to one second */
218 static int time_unit_to_power(TimeUnit time_unit)
220 switch (time_unit) {
221 case TIME_UNIT_SECOND:
222 return 0;
223 case TIME_UNIT_MILLISECOND:
224 return -3;
225 default:
226 assert(false); /* unreachable */
227 return 0;
231 static int64_t convert_time_unit(int64_t value, TimeUnit unit_from,
232 TimeUnit unit_to)
234 int power = time_unit_to_power(unit_from) -
235 time_unit_to_power(unit_to);
236 while (power < 0) {
237 value /= 10;
238 power += 1;
240 while (power > 0) {
241 value *= 10;
242 power -= 1;
244 return value;
248 static struct DirtyRateInfo *
249 query_dirty_rate_info(TimeUnit calc_time_unit)
251 int i;
252 int64_t dirty_rate = DirtyStat.dirty_rate;
253 struct DirtyRateInfo *info = g_new0(DirtyRateInfo, 1);
254 DirtyRateVcpuList *head = NULL, **tail = &head;
256 info->status = CalculatingState;
257 info->start_time = DirtyStat.start_time;
258 info->calc_time = convert_time_unit(DirtyStat.calc_time_ms,
259 TIME_UNIT_MILLISECOND,
260 calc_time_unit);
261 info->calc_time_unit = calc_time_unit;
262 info->sample_pages = DirtyStat.sample_pages;
263 info->mode = dirtyrate_mode;
265 if (qatomic_read(&CalculatingState) == DIRTY_RATE_STATUS_MEASURED) {
266 info->has_dirty_rate = true;
267 info->dirty_rate = dirty_rate;
269 if (dirtyrate_mode == DIRTY_RATE_MEASURE_MODE_DIRTY_RING) {
271 * set sample_pages with 0 to indicate page sampling
272 * isn't enabled
274 info->sample_pages = 0;
275 info->has_vcpu_dirty_rate = true;
276 for (i = 0; i < DirtyStat.dirty_ring.nvcpu; i++) {
277 DirtyRateVcpu *rate = g_new0(DirtyRateVcpu, 1);
278 rate->id = DirtyStat.dirty_ring.rates[i].id;
279 rate->dirty_rate = DirtyStat.dirty_ring.rates[i].dirty_rate;
280 QAPI_LIST_APPEND(tail, rate);
282 info->vcpu_dirty_rate = head;
285 if (dirtyrate_mode == DIRTY_RATE_MEASURE_MODE_DIRTY_BITMAP) {
286 info->sample_pages = 0;
290 trace_query_dirty_rate_info(DirtyRateStatus_str(CalculatingState));
292 return info;
295 static void init_dirtyrate_stat(struct DirtyRateConfig config)
297 DirtyStat.dirty_rate = -1;
298 DirtyStat.start_time = qemu_clock_get_ms(QEMU_CLOCK_HOST) / 1000;
299 DirtyStat.calc_time_ms = config.calc_time_ms;
300 DirtyStat.sample_pages = config.sample_pages_per_gigabytes;
302 switch (config.mode) {
303 case DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING:
304 DirtyStat.page_sampling.total_dirty_samples = 0;
305 DirtyStat.page_sampling.total_sample_count = 0;
306 DirtyStat.page_sampling.total_block_mem_MB = 0;
307 break;
308 case DIRTY_RATE_MEASURE_MODE_DIRTY_RING:
309 DirtyStat.dirty_ring.nvcpu = -1;
310 DirtyStat.dirty_ring.rates = NULL;
311 break;
312 default:
313 break;
317 static void cleanup_dirtyrate_stat(struct DirtyRateConfig config)
319 /* last calc-dirty-rate qmp use dirty ring mode */
320 if (dirtyrate_mode == DIRTY_RATE_MEASURE_MODE_DIRTY_RING) {
321 free(DirtyStat.dirty_ring.rates);
322 DirtyStat.dirty_ring.rates = NULL;
326 static void update_dirtyrate_stat(struct RamblockDirtyInfo *info)
328 DirtyStat.page_sampling.total_dirty_samples += info->sample_dirty_count;
329 DirtyStat.page_sampling.total_sample_count += info->sample_pages_count;
330 /* size of total pages in MB */
331 DirtyStat.page_sampling.total_block_mem_MB +=
332 qemu_target_pages_to_MiB(info->ramblock_pages);
335 static void update_dirtyrate(uint64_t msec)
337 uint64_t dirtyrate;
338 uint64_t total_dirty_samples = DirtyStat.page_sampling.total_dirty_samples;
339 uint64_t total_sample_count = DirtyStat.page_sampling.total_sample_count;
340 uint64_t total_block_mem_MB = DirtyStat.page_sampling.total_block_mem_MB;
342 dirtyrate = total_dirty_samples * total_block_mem_MB *
343 1000 / (total_sample_count * msec);
345 DirtyStat.dirty_rate = dirtyrate;
349 * Compute hash of a single page of size TARGET_PAGE_SIZE.
351 static uint32_t compute_page_hash(void *ptr)
353 size_t page_size = qemu_target_page_size();
354 uint32_t i;
355 uint64_t v1, v2, v3, v4;
356 uint64_t res;
357 const uint64_t *p = ptr;
359 v1 = QEMU_XXHASH_SEED + XXH_PRIME64_1 + XXH_PRIME64_2;
360 v2 = QEMU_XXHASH_SEED + XXH_PRIME64_2;
361 v3 = QEMU_XXHASH_SEED + 0;
362 v4 = QEMU_XXHASH_SEED - XXH_PRIME64_1;
363 for (i = 0; i < page_size / 8; i += 4) {
364 v1 = XXH64_round(v1, p[i + 0]);
365 v2 = XXH64_round(v2, p[i + 1]);
366 v3 = XXH64_round(v3, p[i + 2]);
367 v4 = XXH64_round(v4, p[i + 3]);
369 res = XXH64_mergerounds(v1, v2, v3, v4);
370 res += page_size;
371 res = XXH64_avalanche(res);
372 return (uint32_t)(res & UINT32_MAX);
377 * get hash result for the sampled memory with length of TARGET_PAGE_SIZE
378 * in ramblock, which starts from ramblock base address.
380 static uint32_t get_ramblock_vfn_hash(struct RamblockDirtyInfo *info,
381 uint64_t vfn)
383 uint32_t hash;
385 hash = compute_page_hash(info->ramblock_addr +
386 vfn * qemu_target_page_size());
388 trace_get_ramblock_vfn_hash(info->idstr, vfn, hash);
389 return hash;
392 static bool save_ramblock_hash(struct RamblockDirtyInfo *info)
394 unsigned int sample_pages_count;
395 int i;
396 GRand *rand;
398 sample_pages_count = info->sample_pages_count;
400 /* ramblock size less than one page, return success to skip this ramblock */
401 if (unlikely(info->ramblock_pages == 0 || sample_pages_count == 0)) {
402 return true;
405 info->hash_result = g_try_malloc0_n(sample_pages_count,
406 sizeof(uint32_t));
407 if (!info->hash_result) {
408 return false;
411 info->sample_page_vfn = g_try_malloc0_n(sample_pages_count,
412 sizeof(uint64_t));
413 if (!info->sample_page_vfn) {
414 g_free(info->hash_result);
415 return false;
418 rand = g_rand_new();
419 for (i = 0; i < sample_pages_count; i++) {
420 info->sample_page_vfn[i] = g_rand_int_range(rand, 0,
421 info->ramblock_pages - 1);
422 info->hash_result[i] = get_ramblock_vfn_hash(info,
423 info->sample_page_vfn[i]);
425 g_rand_free(rand);
427 return true;
430 static void get_ramblock_dirty_info(RAMBlock *block,
431 struct RamblockDirtyInfo *info,
432 struct DirtyRateConfig *config)
434 uint64_t sample_pages_per_gigabytes = config->sample_pages_per_gigabytes;
436 /* Right shift 30 bits to calc ramblock size in GB */
437 info->sample_pages_count = (qemu_ram_get_used_length(block) *
438 sample_pages_per_gigabytes) >> 30;
439 /* Right shift TARGET_PAGE_BITS to calc page count */
440 info->ramblock_pages = qemu_ram_get_used_length(block) >>
441 qemu_target_page_bits();
442 info->ramblock_addr = qemu_ram_get_host_addr(block);
443 strcpy(info->idstr, qemu_ram_get_idstr(block));
446 static void free_ramblock_dirty_info(struct RamblockDirtyInfo *infos, int count)
448 int i;
450 if (!infos) {
451 return;
454 for (i = 0; i < count; i++) {
455 g_free(infos[i].sample_page_vfn);
456 g_free(infos[i].hash_result);
458 g_free(infos);
461 static bool skip_sample_ramblock(RAMBlock *block)
464 * Sample only blocks larger than MIN_RAMBLOCK_SIZE.
466 if (qemu_ram_get_used_length(block) < (MIN_RAMBLOCK_SIZE << 10)) {
467 trace_skip_sample_ramblock(block->idstr,
468 qemu_ram_get_used_length(block));
469 return true;
472 return false;
475 static bool record_ramblock_hash_info(struct RamblockDirtyInfo **block_dinfo,
476 struct DirtyRateConfig config,
477 int *block_count)
479 struct RamblockDirtyInfo *info = NULL;
480 struct RamblockDirtyInfo *dinfo = NULL;
481 RAMBlock *block = NULL;
482 int total_count = 0;
483 int index = 0;
484 bool ret = false;
486 RAMBLOCK_FOREACH_MIGRATABLE(block) {
487 if (skip_sample_ramblock(block)) {
488 continue;
490 total_count++;
493 dinfo = g_try_malloc0_n(total_count, sizeof(struct RamblockDirtyInfo));
494 if (dinfo == NULL) {
495 goto out;
498 RAMBLOCK_FOREACH_MIGRATABLE(block) {
499 if (skip_sample_ramblock(block)) {
500 continue;
502 if (index >= total_count) {
503 break;
505 info = &dinfo[index];
506 get_ramblock_dirty_info(block, info, &config);
507 if (!save_ramblock_hash(info)) {
508 goto out;
510 index++;
512 ret = true;
514 out:
515 *block_count = index;
516 *block_dinfo = dinfo;
517 return ret;
520 static void calc_page_dirty_rate(struct RamblockDirtyInfo *info)
522 uint32_t hash;
523 int i;
525 for (i = 0; i < info->sample_pages_count; i++) {
526 hash = get_ramblock_vfn_hash(info, info->sample_page_vfn[i]);
527 if (hash != info->hash_result[i]) {
528 trace_calc_page_dirty_rate(info->idstr, hash, info->hash_result[i]);
529 info->sample_dirty_count++;
534 static struct RamblockDirtyInfo *
535 find_block_matched(RAMBlock *block, int count,
536 struct RamblockDirtyInfo *infos)
538 int i;
540 for (i = 0; i < count; i++) {
541 if (!strcmp(infos[i].idstr, qemu_ram_get_idstr(block))) {
542 break;
546 if (i == count) {
547 return NULL;
550 if (infos[i].ramblock_addr != qemu_ram_get_host_addr(block) ||
551 infos[i].ramblock_pages !=
552 (qemu_ram_get_used_length(block) >> qemu_target_page_bits())) {
553 trace_find_page_matched(block->idstr);
554 return NULL;
557 return &infos[i];
560 static bool compare_page_hash_info(struct RamblockDirtyInfo *info,
561 int block_count)
563 struct RamblockDirtyInfo *block_dinfo = NULL;
564 RAMBlock *block = NULL;
566 RAMBLOCK_FOREACH_MIGRATABLE(block) {
567 if (skip_sample_ramblock(block)) {
568 continue;
570 block_dinfo = find_block_matched(block, block_count, info);
571 if (block_dinfo == NULL) {
572 continue;
574 calc_page_dirty_rate(block_dinfo);
575 update_dirtyrate_stat(block_dinfo);
578 if (DirtyStat.page_sampling.total_sample_count == 0) {
579 return false;
582 return true;
585 static inline void record_dirtypages_bitmap(DirtyPageRecord *dirty_pages,
586 bool start)
588 if (start) {
589 dirty_pages->start_pages = total_dirty_pages;
590 } else {
591 dirty_pages->end_pages = total_dirty_pages;
595 static inline void dirtyrate_manual_reset_protect(void)
597 RAMBlock *block = NULL;
599 WITH_RCU_READ_LOCK_GUARD() {
600 RAMBLOCK_FOREACH_MIGRATABLE(block) {
601 memory_region_clear_dirty_bitmap(block->mr, 0,
602 block->used_length);
607 static void calculate_dirtyrate_dirty_bitmap(struct DirtyRateConfig config)
609 int64_t start_time;
610 DirtyPageRecord dirty_pages;
612 bql_lock();
613 memory_global_dirty_log_start(GLOBAL_DIRTY_DIRTY_RATE);
616 * 1'round of log sync may return all 1 bits with
617 * KVM_DIRTY_LOG_INITIALLY_SET enable
618 * skip it unconditionally and start dirty tracking
619 * from 2'round of log sync
621 memory_global_dirty_log_sync(false);
624 * reset page protect manually and unconditionally.
625 * this make sure kvm dirty log be cleared if
626 * KVM_DIRTY_LOG_MANUAL_PROTECT_ENABLE cap is enabled.
628 dirtyrate_manual_reset_protect();
629 bql_unlock();
631 record_dirtypages_bitmap(&dirty_pages, true);
633 start_time = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
634 DirtyStat.start_time = qemu_clock_get_ms(QEMU_CLOCK_HOST) / 1000;
636 DirtyStat.calc_time_ms = dirty_stat_wait(config.calc_time_ms, start_time);
639 * do two things.
640 * 1. fetch dirty bitmap from kvm
641 * 2. stop dirty tracking
643 global_dirty_log_sync(GLOBAL_DIRTY_DIRTY_RATE, true);
645 record_dirtypages_bitmap(&dirty_pages, false);
647 DirtyStat.dirty_rate = do_calculate_dirtyrate(dirty_pages,
648 DirtyStat.calc_time_ms);
651 static void calculate_dirtyrate_dirty_ring(struct DirtyRateConfig config)
653 uint64_t dirtyrate = 0;
654 uint64_t dirtyrate_sum = 0;
655 int i = 0;
657 /* start log sync */
658 global_dirty_log_change(GLOBAL_DIRTY_DIRTY_RATE, true);
660 DirtyStat.start_time = qemu_clock_get_ms(QEMU_CLOCK_HOST) / 1000;
662 /* calculate vcpu dirtyrate */
663 DirtyStat.calc_time_ms = vcpu_calculate_dirtyrate(config.calc_time_ms,
664 &DirtyStat.dirty_ring,
665 GLOBAL_DIRTY_DIRTY_RATE,
666 true);
668 /* calculate vm dirtyrate */
669 for (i = 0; i < DirtyStat.dirty_ring.nvcpu; i++) {
670 dirtyrate = DirtyStat.dirty_ring.rates[i].dirty_rate;
671 DirtyStat.dirty_ring.rates[i].dirty_rate = dirtyrate;
672 dirtyrate_sum += dirtyrate;
675 DirtyStat.dirty_rate = dirtyrate_sum;
678 static void calculate_dirtyrate_sample_vm(struct DirtyRateConfig config)
680 struct RamblockDirtyInfo *block_dinfo = NULL;
681 int block_count = 0;
682 int64_t initial_time;
684 rcu_read_lock();
685 initial_time = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
686 DirtyStat.start_time = qemu_clock_get_ms(QEMU_CLOCK_HOST) / 1000;
687 if (!record_ramblock_hash_info(&block_dinfo, config, &block_count)) {
688 goto out;
690 rcu_read_unlock();
692 DirtyStat.calc_time_ms = dirty_stat_wait(config.calc_time_ms,
693 initial_time);
695 rcu_read_lock();
696 if (!compare_page_hash_info(block_dinfo, block_count)) {
697 goto out;
700 update_dirtyrate(DirtyStat.calc_time_ms);
702 out:
703 rcu_read_unlock();
704 free_ramblock_dirty_info(block_dinfo, block_count);
707 static void calculate_dirtyrate(struct DirtyRateConfig config)
709 if (config.mode == DIRTY_RATE_MEASURE_MODE_DIRTY_BITMAP) {
710 calculate_dirtyrate_dirty_bitmap(config);
711 } else if (config.mode == DIRTY_RATE_MEASURE_MODE_DIRTY_RING) {
712 calculate_dirtyrate_dirty_ring(config);
713 } else {
714 calculate_dirtyrate_sample_vm(config);
717 trace_dirtyrate_calculate(DirtyStat.dirty_rate);
720 void *get_dirtyrate_thread(void *arg)
722 struct DirtyRateConfig config = *(struct DirtyRateConfig *)arg;
723 int ret;
724 rcu_register_thread();
726 ret = dirtyrate_set_state(&CalculatingState, DIRTY_RATE_STATUS_UNSTARTED,
727 DIRTY_RATE_STATUS_MEASURING);
728 if (ret == -1) {
729 error_report("change dirtyrate state failed.");
730 return NULL;
733 calculate_dirtyrate(config);
735 ret = dirtyrate_set_state(&CalculatingState, DIRTY_RATE_STATUS_MEASURING,
736 DIRTY_RATE_STATUS_MEASURED);
737 if (ret == -1) {
738 error_report("change dirtyrate state failed.");
741 rcu_unregister_thread();
742 return NULL;
745 void qmp_calc_dirty_rate(int64_t calc_time,
746 bool has_calc_time_unit,
747 TimeUnit calc_time_unit,
748 bool has_sample_pages,
749 int64_t sample_pages,
750 bool has_mode,
751 DirtyRateMeasureMode mode,
752 Error **errp)
754 static struct DirtyRateConfig config;
755 QemuThread thread;
756 int ret;
759 * If the dirty rate is already being measured, don't attempt to start.
761 if (qatomic_read(&CalculatingState) == DIRTY_RATE_STATUS_MEASURING) {
762 error_setg(errp, "the dirty rate is already being measured.");
763 return;
766 int64_t calc_time_ms = convert_time_unit(
767 calc_time,
768 has_calc_time_unit ? calc_time_unit : TIME_UNIT_SECOND,
769 TIME_UNIT_MILLISECOND
772 if (!is_calc_time_valid(calc_time_ms)) {
773 error_setg(errp, "Calculation time is out of range [%dms, %dms].",
774 MIN_CALC_TIME_MS, MAX_CALC_TIME_MS);
775 return;
778 if (!has_mode) {
779 mode = DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING;
782 if (has_sample_pages && mode != DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING) {
783 error_setg(errp, "sample-pages is used only in page-sampling mode");
784 return;
787 if (has_sample_pages) {
788 if (!is_sample_pages_valid(sample_pages)) {
789 error_setg(errp, "sample-pages is out of range[%d, %d].",
790 MIN_SAMPLE_PAGE_COUNT,
791 MAX_SAMPLE_PAGE_COUNT);
792 return;
794 } else {
795 sample_pages = DIRTYRATE_DEFAULT_SAMPLE_PAGES;
799 * dirty ring mode only works when kvm dirty ring is enabled.
800 * on the contrary, dirty bitmap mode is not.
802 if (((mode == DIRTY_RATE_MEASURE_MODE_DIRTY_RING) &&
803 !kvm_dirty_ring_enabled()) ||
804 ((mode == DIRTY_RATE_MEASURE_MODE_DIRTY_BITMAP) &&
805 kvm_dirty_ring_enabled())) {
806 error_setg(errp, "mode %s is not enabled, use other method instead.",
807 DirtyRateMeasureMode_str(mode));
808 return;
812 * Init calculation state as unstarted.
814 ret = dirtyrate_set_state(&CalculatingState, CalculatingState,
815 DIRTY_RATE_STATUS_UNSTARTED);
816 if (ret == -1) {
817 error_setg(errp, "init dirty rate calculation state failed.");
818 return;
821 config.calc_time_ms = calc_time_ms;
822 config.sample_pages_per_gigabytes = sample_pages;
823 config.mode = mode;
825 cleanup_dirtyrate_stat(config);
828 * update dirty rate mode so that we can figure out what mode has
829 * been used in last calculation
831 dirtyrate_mode = mode;
833 init_dirtyrate_stat(config);
835 qemu_thread_create(&thread, "get_dirtyrate", get_dirtyrate_thread,
836 (void *)&config, QEMU_THREAD_DETACHED);
840 struct DirtyRateInfo *qmp_query_dirty_rate(bool has_calc_time_unit,
841 TimeUnit calc_time_unit,
842 Error **errp)
844 return query_dirty_rate_info(
845 has_calc_time_unit ? calc_time_unit : TIME_UNIT_SECOND);
848 void hmp_info_dirty_rate(Monitor *mon, const QDict *qdict)
850 DirtyRateInfo *info = query_dirty_rate_info(TIME_UNIT_SECOND);
852 monitor_printf(mon, "Status: %s\n",
853 DirtyRateStatus_str(info->status));
854 monitor_printf(mon, "Start Time: %"PRIi64" (ms)\n",
855 info->start_time);
856 if (info->mode == DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING) {
857 monitor_printf(mon, "Sample Pages: %"PRIu64" (per GB)\n",
858 info->sample_pages);
860 monitor_printf(mon, "Period: %"PRIi64" (sec)\n",
861 info->calc_time);
862 monitor_printf(mon, "Mode: %s\n",
863 DirtyRateMeasureMode_str(info->mode));
864 monitor_printf(mon, "Dirty rate: ");
865 if (info->has_dirty_rate) {
866 monitor_printf(mon, "%"PRIi64" (MB/s)\n", info->dirty_rate);
867 if (info->has_vcpu_dirty_rate) {
868 DirtyRateVcpuList *rate, *head = info->vcpu_dirty_rate;
869 for (rate = head; rate != NULL; rate = rate->next) {
870 monitor_printf(mon, "vcpu[%"PRIi64"], Dirty rate: %"PRIi64
871 " (MB/s)\n", rate->value->id,
872 rate->value->dirty_rate);
875 } else {
876 monitor_printf(mon, "(not ready)\n");
879 qapi_free_DirtyRateVcpuList(info->vcpu_dirty_rate);
880 g_free(info);
883 void hmp_calc_dirty_rate(Monitor *mon, const QDict *qdict)
885 int64_t sec = qdict_get_try_int(qdict, "second", 0);
886 int64_t sample_pages = qdict_get_try_int(qdict, "sample_pages_per_GB", -1);
887 bool has_sample_pages = (sample_pages != -1);
888 bool dirty_ring = qdict_get_try_bool(qdict, "dirty_ring", false);
889 bool dirty_bitmap = qdict_get_try_bool(qdict, "dirty_bitmap", false);
890 DirtyRateMeasureMode mode = DIRTY_RATE_MEASURE_MODE_PAGE_SAMPLING;
891 Error *err = NULL;
893 if (!sec) {
894 monitor_printf(mon, "Incorrect period length specified!\n");
895 return;
898 if (dirty_ring && dirty_bitmap) {
899 monitor_printf(mon, "Either dirty ring or dirty bitmap "
900 "can be specified!\n");
901 return;
904 if (dirty_bitmap) {
905 mode = DIRTY_RATE_MEASURE_MODE_DIRTY_BITMAP;
906 } else if (dirty_ring) {
907 mode = DIRTY_RATE_MEASURE_MODE_DIRTY_RING;
910 qmp_calc_dirty_rate(sec, /* calc-time */
911 false, TIME_UNIT_SECOND, /* calc-time-unit */
912 has_sample_pages, sample_pages,
913 true, mode,
914 &err);
915 if (err) {
916 hmp_handle_error(mon, err);
917 return;
920 monitor_printf(mon, "Starting dirty rate measurement with period %"PRIi64
921 " seconds\n", sec);
922 monitor_printf(mon, "[Please use 'info dirty_rate' to check results]\n");