xref: /openbmc/qemu/migration/ram.c (revision 4a9b31b8)
1 /*
2  * QEMU System Emulator
3  *
4  * Copyright (c) 2003-2008 Fabrice Bellard
5  * Copyright (c) 2011-2015 Red Hat Inc
6  *
7  * Authors:
8  *  Juan Quintela <quintela@redhat.com>
9  *
10  * Permission is hereby granted, free of charge, to any person obtaining a copy
11  * of this software and associated documentation files (the "Software"), to deal
12  * in the Software without restriction, including without limitation the rights
13  * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
14  * copies of the Software, and to permit persons to whom the Software is
15  * furnished to do so, subject to the following conditions:
16  *
17  * The above copyright notice and this permission notice shall be included in
18  * all copies or substantial portions of the Software.
19  *
20  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
21  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
22  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
23  * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
24  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
25  * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
26  * THE SOFTWARE.
27  */
28 
29 #include "qemu/osdep.h"
30 #include "cpu.h"
31 #include <zlib.h>
32 #include "qemu/cutils.h"
33 #include "qemu/bitops.h"
34 #include "qemu/bitmap.h"
35 #include "qemu/main-loop.h"
36 #include "qemu/pmem.h"
37 #include "xbzrle.h"
38 #include "ram.h"
39 #include "migration.h"
40 #include "socket.h"
41 #include "migration/register.h"
42 #include "migration/misc.h"
43 #include "qemu-file.h"
44 #include "postcopy-ram.h"
45 #include "page_cache.h"
46 #include "qemu/error-report.h"
47 #include "qapi/error.h"
48 #include "qapi/qapi-events-migration.h"
49 #include "qapi/qmp/qerror.h"
50 #include "trace.h"
51 #include "exec/ram_addr.h"
52 #include "exec/target_page.h"
53 #include "qemu/rcu_queue.h"
54 #include "migration/colo.h"
55 #include "block.h"
56 #include "sysemu/sysemu.h"
57 #include "qemu/uuid.h"
58 #include "savevm.h"
59 #include "qemu/iov.h"
60 
61 /***********************************************************/
62 /* ram save/restore */
63 
64 /* RAM_SAVE_FLAG_ZERO used to be named RAM_SAVE_FLAG_COMPRESS, it
65  * worked for pages that where filled with the same char.  We switched
66  * it to only search for the zero value.  And to avoid confusion with
67  * RAM_SSAVE_FLAG_COMPRESS_PAGE just rename it.
68  */
69 
70 #define RAM_SAVE_FLAG_FULL     0x01 /* Obsolete, not used anymore */
71 #define RAM_SAVE_FLAG_ZERO     0x02
72 #define RAM_SAVE_FLAG_MEM_SIZE 0x04
73 #define RAM_SAVE_FLAG_PAGE     0x08
74 #define RAM_SAVE_FLAG_EOS      0x10
75 #define RAM_SAVE_FLAG_CONTINUE 0x20
76 #define RAM_SAVE_FLAG_XBZRLE   0x40
77 /* 0x80 is reserved in migration.h start with 0x100 next */
78 #define RAM_SAVE_FLAG_COMPRESS_PAGE    0x100
79 
80 static inline bool is_zero_range(uint8_t *p, uint64_t size)
81 {
82     return buffer_is_zero(p, size);
83 }
84 
85 XBZRLECacheStats xbzrle_counters;
86 
87 /* struct contains XBZRLE cache and a static page
88    used by the compression */
89 static struct {
90     /* buffer used for XBZRLE encoding */
91     uint8_t *encoded_buf;
92     /* buffer for storing page content */
93     uint8_t *current_buf;
94     /* Cache for XBZRLE, Protected by lock. */
95     PageCache *cache;
96     QemuMutex lock;
97     /* it will store a page full of zeros */
98     uint8_t *zero_target_page;
99     /* buffer used for XBZRLE decoding */
100     uint8_t *decoded_buf;
101 } XBZRLE;
102 
103 static void XBZRLE_cache_lock(void)
104 {
105     if (migrate_use_xbzrle())
106         qemu_mutex_lock(&XBZRLE.lock);
107 }
108 
109 static void XBZRLE_cache_unlock(void)
110 {
111     if (migrate_use_xbzrle())
112         qemu_mutex_unlock(&XBZRLE.lock);
113 }
114 
115 /**
116  * xbzrle_cache_resize: resize the xbzrle cache
117  *
118  * This function is called from qmp_migrate_set_cache_size in main
119  * thread, possibly while a migration is in progress.  A running
120  * migration may be using the cache and might finish during this call,
121  * hence changes to the cache are protected by XBZRLE.lock().
122  *
123  * Returns 0 for success or -1 for error
124  *
125  * @new_size: new cache size
126  * @errp: set *errp if the check failed, with reason
127  */
128 int xbzrle_cache_resize(int64_t new_size, Error **errp)
129 {
130     PageCache *new_cache;
131     int64_t ret = 0;
132 
133     /* Check for truncation */
134     if (new_size != (size_t)new_size) {
135         error_setg(errp, QERR_INVALID_PARAMETER_VALUE, "cache size",
136                    "exceeding address space");
137         return -1;
138     }
139 
140     if (new_size == migrate_xbzrle_cache_size()) {
141         /* nothing to do */
142         return 0;
143     }
144 
145     XBZRLE_cache_lock();
146 
147     if (XBZRLE.cache != NULL) {
148         new_cache = cache_init(new_size, TARGET_PAGE_SIZE, errp);
149         if (!new_cache) {
150             ret = -1;
151             goto out;
152         }
153 
154         cache_fini(XBZRLE.cache);
155         XBZRLE.cache = new_cache;
156     }
157 out:
158     XBZRLE_cache_unlock();
159     return ret;
160 }
161 
162 /* Should be holding either ram_list.mutex, or the RCU lock. */
163 #define RAMBLOCK_FOREACH_MIGRATABLE(block)             \
164     INTERNAL_RAMBLOCK_FOREACH(block)                   \
165         if (!qemu_ram_is_migratable(block)) {} else
166 
167 #undef RAMBLOCK_FOREACH
168 
169 static void ramblock_recv_map_init(void)
170 {
171     RAMBlock *rb;
172 
173     RAMBLOCK_FOREACH_MIGRATABLE(rb) {
174         assert(!rb->receivedmap);
175         rb->receivedmap = bitmap_new(rb->max_length >> qemu_target_page_bits());
176     }
177 }
178 
179 int ramblock_recv_bitmap_test(RAMBlock *rb, void *host_addr)
180 {
181     return test_bit(ramblock_recv_bitmap_offset(host_addr, rb),
182                     rb->receivedmap);
183 }
184 
185 bool ramblock_recv_bitmap_test_byte_offset(RAMBlock *rb, uint64_t byte_offset)
186 {
187     return test_bit(byte_offset >> TARGET_PAGE_BITS, rb->receivedmap);
188 }
189 
190 void ramblock_recv_bitmap_set(RAMBlock *rb, void *host_addr)
191 {
192     set_bit_atomic(ramblock_recv_bitmap_offset(host_addr, rb), rb->receivedmap);
193 }
194 
195 void ramblock_recv_bitmap_set_range(RAMBlock *rb, void *host_addr,
196                                     size_t nr)
197 {
198     bitmap_set_atomic(rb->receivedmap,
199                       ramblock_recv_bitmap_offset(host_addr, rb),
200                       nr);
201 }
202 
203 #define  RAMBLOCK_RECV_BITMAP_ENDING  (0x0123456789abcdefULL)
204 
205 /*
206  * Format: bitmap_size (8 bytes) + whole_bitmap (N bytes).
207  *
208  * Returns >0 if success with sent bytes, or <0 if error.
209  */
210 int64_t ramblock_recv_bitmap_send(QEMUFile *file,
211                                   const char *block_name)
212 {
213     RAMBlock *block = qemu_ram_block_by_name(block_name);
214     unsigned long *le_bitmap, nbits;
215     uint64_t size;
216 
217     if (!block) {
218         error_report("%s: invalid block name: %s", __func__, block_name);
219         return -1;
220     }
221 
222     nbits = block->used_length >> TARGET_PAGE_BITS;
223 
224     /*
225      * Make sure the tmp bitmap buffer is big enough, e.g., on 32bit
226      * machines we may need 4 more bytes for padding (see below
227      * comment). So extend it a bit before hand.
228      */
229     le_bitmap = bitmap_new(nbits + BITS_PER_LONG);
230 
231     /*
232      * Always use little endian when sending the bitmap. This is
233      * required that when source and destination VMs are not using the
234      * same endianess. (Note: big endian won't work.)
235      */
236     bitmap_to_le(le_bitmap, block->receivedmap, nbits);
237 
238     /* Size of the bitmap, in bytes */
239     size = DIV_ROUND_UP(nbits, 8);
240 
241     /*
242      * size is always aligned to 8 bytes for 64bit machines, but it
243      * may not be true for 32bit machines. We need this padding to
244      * make sure the migration can survive even between 32bit and
245      * 64bit machines.
246      */
247     size = ROUND_UP(size, 8);
248 
249     qemu_put_be64(file, size);
250     qemu_put_buffer(file, (const uint8_t *)le_bitmap, size);
251     /*
252      * Mark as an end, in case the middle part is screwed up due to
253      * some "misterious" reason.
254      */
255     qemu_put_be64(file, RAMBLOCK_RECV_BITMAP_ENDING);
256     qemu_fflush(file);
257 
258     g_free(le_bitmap);
259 
260     if (qemu_file_get_error(file)) {
261         return qemu_file_get_error(file);
262     }
263 
264     return size + sizeof(size);
265 }
266 
267 /*
268  * An outstanding page request, on the source, having been received
269  * and queued
270  */
271 struct RAMSrcPageRequest {
272     RAMBlock *rb;
273     hwaddr    offset;
274     hwaddr    len;
275 
276     QSIMPLEQ_ENTRY(RAMSrcPageRequest) next_req;
277 };
278 
279 /* State of RAM for migration */
280 struct RAMState {
281     /* QEMUFile used for this migration */
282     QEMUFile *f;
283     /* Last block that we have visited searching for dirty pages */
284     RAMBlock *last_seen_block;
285     /* Last block from where we have sent data */
286     RAMBlock *last_sent_block;
287     /* Last dirty target page we have sent */
288     ram_addr_t last_page;
289     /* last ram version we have seen */
290     uint32_t last_version;
291     /* We are in the first round */
292     bool ram_bulk_stage;
293     /* How many times we have dirty too many pages */
294     int dirty_rate_high_cnt;
295     /* these variables are used for bitmap sync */
296     /* last time we did a full bitmap_sync */
297     int64_t time_last_bitmap_sync;
298     /* bytes transferred at start_time */
299     uint64_t bytes_xfer_prev;
300     /* number of dirty pages since start_time */
301     uint64_t num_dirty_pages_period;
302     /* xbzrle misses since the beginning of the period */
303     uint64_t xbzrle_cache_miss_prev;
304 
305     /* compression statistics since the beginning of the period */
306     /* amount of count that no free thread to compress data */
307     uint64_t compress_thread_busy_prev;
308     /* amount bytes after compression */
309     uint64_t compressed_size_prev;
310     /* amount of compressed pages */
311     uint64_t compress_pages_prev;
312 
313     /* total handled target pages at the beginning of period */
314     uint64_t target_page_count_prev;
315     /* total handled target pages since start */
316     uint64_t target_page_count;
317     /* number of dirty bits in the bitmap */
318     uint64_t migration_dirty_pages;
319     /* protects modification of the bitmap */
320     QemuMutex bitmap_mutex;
321     /* The RAMBlock used in the last src_page_requests */
322     RAMBlock *last_req_rb;
323     /* Queue of outstanding page requests from the destination */
324     QemuMutex src_page_req_mutex;
325     QSIMPLEQ_HEAD(src_page_requests, RAMSrcPageRequest) src_page_requests;
326 };
327 typedef struct RAMState RAMState;
328 
329 static RAMState *ram_state;
330 
331 uint64_t ram_bytes_remaining(void)
332 {
333     return ram_state ? (ram_state->migration_dirty_pages * TARGET_PAGE_SIZE) :
334                        0;
335 }
336 
337 MigrationStats ram_counters;
338 
339 /* used by the search for pages to send */
340 struct PageSearchStatus {
341     /* Current block being searched */
342     RAMBlock    *block;
343     /* Current page to search from */
344     unsigned long page;
345     /* Set once we wrap around */
346     bool         complete_round;
347 };
348 typedef struct PageSearchStatus PageSearchStatus;
349 
350 CompressionStats compression_counters;
351 
352 struct CompressParam {
353     bool done;
354     bool quit;
355     bool zero_page;
356     QEMUFile *file;
357     QemuMutex mutex;
358     QemuCond cond;
359     RAMBlock *block;
360     ram_addr_t offset;
361 
362     /* internally used fields */
363     z_stream stream;
364     uint8_t *originbuf;
365 };
366 typedef struct CompressParam CompressParam;
367 
368 struct DecompressParam {
369     bool done;
370     bool quit;
371     QemuMutex mutex;
372     QemuCond cond;
373     void *des;
374     uint8_t *compbuf;
375     int len;
376     z_stream stream;
377 };
378 typedef struct DecompressParam DecompressParam;
379 
380 static CompressParam *comp_param;
381 static QemuThread *compress_threads;
382 /* comp_done_cond is used to wake up the migration thread when
383  * one of the compression threads has finished the compression.
384  * comp_done_lock is used to co-work with comp_done_cond.
385  */
386 static QemuMutex comp_done_lock;
387 static QemuCond comp_done_cond;
388 /* The empty QEMUFileOps will be used by file in CompressParam */
389 static const QEMUFileOps empty_ops = { };
390 
391 static QEMUFile *decomp_file;
392 static DecompressParam *decomp_param;
393 static QemuThread *decompress_threads;
394 static QemuMutex decomp_done_lock;
395 static QemuCond decomp_done_cond;
396 
397 static bool do_compress_ram_page(QEMUFile *f, z_stream *stream, RAMBlock *block,
398                                  ram_addr_t offset, uint8_t *source_buf);
399 
400 static void *do_data_compress(void *opaque)
401 {
402     CompressParam *param = opaque;
403     RAMBlock *block;
404     ram_addr_t offset;
405     bool zero_page;
406 
407     qemu_mutex_lock(&param->mutex);
408     while (!param->quit) {
409         if (param->block) {
410             block = param->block;
411             offset = param->offset;
412             param->block = NULL;
413             qemu_mutex_unlock(&param->mutex);
414 
415             zero_page = do_compress_ram_page(param->file, &param->stream,
416                                              block, offset, param->originbuf);
417 
418             qemu_mutex_lock(&comp_done_lock);
419             param->done = true;
420             param->zero_page = zero_page;
421             qemu_cond_signal(&comp_done_cond);
422             qemu_mutex_unlock(&comp_done_lock);
423 
424             qemu_mutex_lock(&param->mutex);
425         } else {
426             qemu_cond_wait(&param->cond, &param->mutex);
427         }
428     }
429     qemu_mutex_unlock(&param->mutex);
430 
431     return NULL;
432 }
433 
434 static void compress_threads_save_cleanup(void)
435 {
436     int i, thread_count;
437 
438     if (!migrate_use_compression() || !comp_param) {
439         return;
440     }
441 
442     thread_count = migrate_compress_threads();
443     for (i = 0; i < thread_count; i++) {
444         /*
445          * we use it as a indicator which shows if the thread is
446          * properly init'd or not
447          */
448         if (!comp_param[i].file) {
449             break;
450         }
451 
452         qemu_mutex_lock(&comp_param[i].mutex);
453         comp_param[i].quit = true;
454         qemu_cond_signal(&comp_param[i].cond);
455         qemu_mutex_unlock(&comp_param[i].mutex);
456 
457         qemu_thread_join(compress_threads + i);
458         qemu_mutex_destroy(&comp_param[i].mutex);
459         qemu_cond_destroy(&comp_param[i].cond);
460         deflateEnd(&comp_param[i].stream);
461         g_free(comp_param[i].originbuf);
462         qemu_fclose(comp_param[i].file);
463         comp_param[i].file = NULL;
464     }
465     qemu_mutex_destroy(&comp_done_lock);
466     qemu_cond_destroy(&comp_done_cond);
467     g_free(compress_threads);
468     g_free(comp_param);
469     compress_threads = NULL;
470     comp_param = NULL;
471 }
472 
473 static int compress_threads_save_setup(void)
474 {
475     int i, thread_count;
476 
477     if (!migrate_use_compression()) {
478         return 0;
479     }
480     thread_count = migrate_compress_threads();
481     compress_threads = g_new0(QemuThread, thread_count);
482     comp_param = g_new0(CompressParam, thread_count);
483     qemu_cond_init(&comp_done_cond);
484     qemu_mutex_init(&comp_done_lock);
485     for (i = 0; i < thread_count; i++) {
486         comp_param[i].originbuf = g_try_malloc(TARGET_PAGE_SIZE);
487         if (!comp_param[i].originbuf) {
488             goto exit;
489         }
490 
491         if (deflateInit(&comp_param[i].stream,
492                         migrate_compress_level()) != Z_OK) {
493             g_free(comp_param[i].originbuf);
494             goto exit;
495         }
496 
497         /* comp_param[i].file is just used as a dummy buffer to save data,
498          * set its ops to empty.
499          */
500         comp_param[i].file = qemu_fopen_ops(NULL, &empty_ops);
501         comp_param[i].done = true;
502         comp_param[i].quit = false;
503         qemu_mutex_init(&comp_param[i].mutex);
504         qemu_cond_init(&comp_param[i].cond);
505         qemu_thread_create(compress_threads + i, "compress",
506                            do_data_compress, comp_param + i,
507                            QEMU_THREAD_JOINABLE);
508     }
509     return 0;
510 
511 exit:
512     compress_threads_save_cleanup();
513     return -1;
514 }
515 
516 /* Multiple fd's */
517 
518 #define MULTIFD_MAGIC 0x11223344U
519 #define MULTIFD_VERSION 1
520 
521 #define MULTIFD_FLAG_SYNC (1 << 0)
522 
523 typedef struct {
524     uint32_t magic;
525     uint32_t version;
526     unsigned char uuid[16]; /* QemuUUID */
527     uint8_t id;
528 } __attribute__((packed)) MultiFDInit_t;
529 
530 typedef struct {
531     uint32_t magic;
532     uint32_t version;
533     uint32_t flags;
534     uint32_t size;
535     uint32_t used;
536     uint64_t packet_num;
537     char ramblock[256];
538     uint64_t offset[];
539 } __attribute__((packed)) MultiFDPacket_t;
540 
541 typedef struct {
542     /* number of used pages */
543     uint32_t used;
544     /* number of allocated pages */
545     uint32_t allocated;
546     /* global number of generated multifd packets */
547     uint64_t packet_num;
548     /* offset of each page */
549     ram_addr_t *offset;
550     /* pointer to each page */
551     struct iovec *iov;
552     RAMBlock *block;
553 } MultiFDPages_t;
554 
555 typedef struct {
556     /* this fields are not changed once the thread is created */
557     /* channel number */
558     uint8_t id;
559     /* channel thread name */
560     char *name;
561     /* channel thread id */
562     QemuThread thread;
563     /* communication channel */
564     QIOChannel *c;
565     /* sem where to wait for more work */
566     QemuSemaphore sem;
567     /* this mutex protects the following parameters */
568     QemuMutex mutex;
569     /* is this channel thread running */
570     bool running;
571     /* should this thread finish */
572     bool quit;
573     /* thread has work to do */
574     int pending_job;
575     /* array of pages to sent */
576     MultiFDPages_t *pages;
577     /* packet allocated len */
578     uint32_t packet_len;
579     /* pointer to the packet */
580     MultiFDPacket_t *packet;
581     /* multifd flags for each packet */
582     uint32_t flags;
583     /* global number of generated multifd packets */
584     uint64_t packet_num;
585     /* thread local variables */
586     /* packets sent through this channel */
587     uint64_t num_packets;
588     /* pages sent through this channel */
589     uint64_t num_pages;
590     /* syncs main thread and channels */
591     QemuSemaphore sem_sync;
592 }  MultiFDSendParams;
593 
594 typedef struct {
595     /* this fields are not changed once the thread is created */
596     /* channel number */
597     uint8_t id;
598     /* channel thread name */
599     char *name;
600     /* channel thread id */
601     QemuThread thread;
602     /* communication channel */
603     QIOChannel *c;
604     /* this mutex protects the following parameters */
605     QemuMutex mutex;
606     /* is this channel thread running */
607     bool running;
608     /* array of pages to receive */
609     MultiFDPages_t *pages;
610     /* packet allocated len */
611     uint32_t packet_len;
612     /* pointer to the packet */
613     MultiFDPacket_t *packet;
614     /* multifd flags for each packet */
615     uint32_t flags;
616     /* global number of generated multifd packets */
617     uint64_t packet_num;
618     /* thread local variables */
619     /* packets sent through this channel */
620     uint64_t num_packets;
621     /* pages sent through this channel */
622     uint64_t num_pages;
623     /* syncs main thread and channels */
624     QemuSemaphore sem_sync;
625 } MultiFDRecvParams;
626 
627 static int multifd_send_initial_packet(MultiFDSendParams *p, Error **errp)
628 {
629     MultiFDInit_t msg;
630     int ret;
631 
632     msg.magic = cpu_to_be32(MULTIFD_MAGIC);
633     msg.version = cpu_to_be32(MULTIFD_VERSION);
634     msg.id = p->id;
635     memcpy(msg.uuid, &qemu_uuid.data, sizeof(msg.uuid));
636 
637     ret = qio_channel_write_all(p->c, (char *)&msg, sizeof(msg), errp);
638     if (ret != 0) {
639         return -1;
640     }
641     return 0;
642 }
643 
644 static int multifd_recv_initial_packet(QIOChannel *c, Error **errp)
645 {
646     MultiFDInit_t msg;
647     int ret;
648 
649     ret = qio_channel_read_all(c, (char *)&msg, sizeof(msg), errp);
650     if (ret != 0) {
651         return -1;
652     }
653 
654     msg.magic = be32_to_cpu(msg.magic);
655     msg.version = be32_to_cpu(msg.version);
656 
657     if (msg.magic != MULTIFD_MAGIC) {
658         error_setg(errp, "multifd: received packet magic %x "
659                    "expected %x", msg.magic, MULTIFD_MAGIC);
660         return -1;
661     }
662 
663     if (msg.version != MULTIFD_VERSION) {
664         error_setg(errp, "multifd: received packet version %d "
665                    "expected %d", msg.version, MULTIFD_VERSION);
666         return -1;
667     }
668 
669     if (memcmp(msg.uuid, &qemu_uuid, sizeof(qemu_uuid))) {
670         char *uuid = qemu_uuid_unparse_strdup(&qemu_uuid);
671         char *msg_uuid = qemu_uuid_unparse_strdup((const QemuUUID *)msg.uuid);
672 
673         error_setg(errp, "multifd: received uuid '%s' and expected "
674                    "uuid '%s' for channel %hhd", msg_uuid, uuid, msg.id);
675         g_free(uuid);
676         g_free(msg_uuid);
677         return -1;
678     }
679 
680     if (msg.id > migrate_multifd_channels()) {
681         error_setg(errp, "multifd: received channel version %d "
682                    "expected %d", msg.version, MULTIFD_VERSION);
683         return -1;
684     }
685 
686     return msg.id;
687 }
688 
689 static MultiFDPages_t *multifd_pages_init(size_t size)
690 {
691     MultiFDPages_t *pages = g_new0(MultiFDPages_t, 1);
692 
693     pages->allocated = size;
694     pages->iov = g_new0(struct iovec, size);
695     pages->offset = g_new0(ram_addr_t, size);
696 
697     return pages;
698 }
699 
700 static void multifd_pages_clear(MultiFDPages_t *pages)
701 {
702     pages->used = 0;
703     pages->allocated = 0;
704     pages->packet_num = 0;
705     pages->block = NULL;
706     g_free(pages->iov);
707     pages->iov = NULL;
708     g_free(pages->offset);
709     pages->offset = NULL;
710     g_free(pages);
711 }
712 
713 static void multifd_send_fill_packet(MultiFDSendParams *p)
714 {
715     MultiFDPacket_t *packet = p->packet;
716     int i;
717 
718     packet->magic = cpu_to_be32(MULTIFD_MAGIC);
719     packet->version = cpu_to_be32(MULTIFD_VERSION);
720     packet->flags = cpu_to_be32(p->flags);
721     packet->size = cpu_to_be32(migrate_multifd_page_count());
722     packet->used = cpu_to_be32(p->pages->used);
723     packet->packet_num = cpu_to_be64(p->packet_num);
724 
725     if (p->pages->block) {
726         strncpy(packet->ramblock, p->pages->block->idstr, 256);
727     }
728 
729     for (i = 0; i < p->pages->used; i++) {
730         packet->offset[i] = cpu_to_be64(p->pages->offset[i]);
731     }
732 }
733 
734 static int multifd_recv_unfill_packet(MultiFDRecvParams *p, Error **errp)
735 {
736     MultiFDPacket_t *packet = p->packet;
737     RAMBlock *block;
738     int i;
739 
740     packet->magic = be32_to_cpu(packet->magic);
741     if (packet->magic != MULTIFD_MAGIC) {
742         error_setg(errp, "multifd: received packet "
743                    "magic %x and expected magic %x",
744                    packet->magic, MULTIFD_MAGIC);
745         return -1;
746     }
747 
748     packet->version = be32_to_cpu(packet->version);
749     if (packet->version != MULTIFD_VERSION) {
750         error_setg(errp, "multifd: received packet "
751                    "version %d and expected version %d",
752                    packet->version, MULTIFD_VERSION);
753         return -1;
754     }
755 
756     p->flags = be32_to_cpu(packet->flags);
757 
758     packet->size = be32_to_cpu(packet->size);
759     if (packet->size > migrate_multifd_page_count()) {
760         error_setg(errp, "multifd: received packet "
761                    "with size %d and expected maximum size %d",
762                    packet->size, migrate_multifd_page_count()) ;
763         return -1;
764     }
765 
766     p->pages->used = be32_to_cpu(packet->used);
767     if (p->pages->used > packet->size) {
768         error_setg(errp, "multifd: received packet "
769                    "with size %d and expected maximum size %d",
770                    p->pages->used, packet->size) ;
771         return -1;
772     }
773 
774     p->packet_num = be64_to_cpu(packet->packet_num);
775 
776     if (p->pages->used) {
777         /* make sure that ramblock is 0 terminated */
778         packet->ramblock[255] = 0;
779         block = qemu_ram_block_by_name(packet->ramblock);
780         if (!block) {
781             error_setg(errp, "multifd: unknown ram block %s",
782                        packet->ramblock);
783             return -1;
784         }
785     }
786 
787     for (i = 0; i < p->pages->used; i++) {
788         ram_addr_t offset = be64_to_cpu(packet->offset[i]);
789 
790         if (offset > (block->used_length - TARGET_PAGE_SIZE)) {
791             error_setg(errp, "multifd: offset too long " RAM_ADDR_FMT
792                        " (max " RAM_ADDR_FMT ")",
793                        offset, block->max_length);
794             return -1;
795         }
796         p->pages->iov[i].iov_base = block->host + offset;
797         p->pages->iov[i].iov_len = TARGET_PAGE_SIZE;
798     }
799 
800     return 0;
801 }
802 
803 struct {
804     MultiFDSendParams *params;
805     /* number of created threads */
806     int count;
807     /* array of pages to sent */
808     MultiFDPages_t *pages;
809     /* syncs main thread and channels */
810     QemuSemaphore sem_sync;
811     /* global number of generated multifd packets */
812     uint64_t packet_num;
813     /* send channels ready */
814     QemuSemaphore channels_ready;
815 } *multifd_send_state;
816 
817 /*
818  * How we use multifd_send_state->pages and channel->pages?
819  *
820  * We create a pages for each channel, and a main one.  Each time that
821  * we need to send a batch of pages we interchange the ones between
822  * multifd_send_state and the channel that is sending it.  There are
823  * two reasons for that:
824  *    - to not have to do so many mallocs during migration
825  *    - to make easier to know what to free at the end of migration
826  *
827  * This way we always know who is the owner of each "pages" struct,
828  * and we don't need any loocking.  It belongs to the migration thread
829  * or to the channel thread.  Switching is safe because the migration
830  * thread is using the channel mutex when changing it, and the channel
831  * have to had finish with its own, otherwise pending_job can't be
832  * false.
833  */
834 
835 static void multifd_send_pages(void)
836 {
837     int i;
838     static int next_channel;
839     MultiFDSendParams *p = NULL; /* make happy gcc */
840     MultiFDPages_t *pages = multifd_send_state->pages;
841     uint64_t transferred;
842 
843     qemu_sem_wait(&multifd_send_state->channels_ready);
844     for (i = next_channel;; i = (i + 1) % migrate_multifd_channels()) {
845         p = &multifd_send_state->params[i];
846 
847         qemu_mutex_lock(&p->mutex);
848         if (!p->pending_job) {
849             p->pending_job++;
850             next_channel = (i + 1) % migrate_multifd_channels();
851             break;
852         }
853         qemu_mutex_unlock(&p->mutex);
854     }
855     p->pages->used = 0;
856 
857     p->packet_num = multifd_send_state->packet_num++;
858     p->pages->block = NULL;
859     multifd_send_state->pages = p->pages;
860     p->pages = pages;
861     transferred = ((uint64_t) pages->used) * TARGET_PAGE_SIZE + p->packet_len;
862     ram_counters.multifd_bytes += transferred;
863     ram_counters.transferred += transferred;;
864     qemu_mutex_unlock(&p->mutex);
865     qemu_sem_post(&p->sem);
866 }
867 
868 static void multifd_queue_page(RAMBlock *block, ram_addr_t offset)
869 {
870     MultiFDPages_t *pages = multifd_send_state->pages;
871 
872     if (!pages->block) {
873         pages->block = block;
874     }
875 
876     if (pages->block == block) {
877         pages->offset[pages->used] = offset;
878         pages->iov[pages->used].iov_base = block->host + offset;
879         pages->iov[pages->used].iov_len = TARGET_PAGE_SIZE;
880         pages->used++;
881 
882         if (pages->used < pages->allocated) {
883             return;
884         }
885     }
886 
887     multifd_send_pages();
888 
889     if (pages->block != block) {
890         multifd_queue_page(block, offset);
891     }
892 }
893 
894 static void multifd_send_terminate_threads(Error *err)
895 {
896     int i;
897 
898     if (err) {
899         MigrationState *s = migrate_get_current();
900         migrate_set_error(s, err);
901         if (s->state == MIGRATION_STATUS_SETUP ||
902             s->state == MIGRATION_STATUS_PRE_SWITCHOVER ||
903             s->state == MIGRATION_STATUS_DEVICE ||
904             s->state == MIGRATION_STATUS_ACTIVE) {
905             migrate_set_state(&s->state, s->state,
906                               MIGRATION_STATUS_FAILED);
907         }
908     }
909 
910     for (i = 0; i < migrate_multifd_channels(); i++) {
911         MultiFDSendParams *p = &multifd_send_state->params[i];
912 
913         qemu_mutex_lock(&p->mutex);
914         p->quit = true;
915         qemu_sem_post(&p->sem);
916         qemu_mutex_unlock(&p->mutex);
917     }
918 }
919 
920 int multifd_save_cleanup(Error **errp)
921 {
922     int i;
923     int ret = 0;
924 
925     if (!migrate_use_multifd()) {
926         return 0;
927     }
928     multifd_send_terminate_threads(NULL);
929     for (i = 0; i < migrate_multifd_channels(); i++) {
930         MultiFDSendParams *p = &multifd_send_state->params[i];
931 
932         if (p->running) {
933             qemu_thread_join(&p->thread);
934         }
935         socket_send_channel_destroy(p->c);
936         p->c = NULL;
937         qemu_mutex_destroy(&p->mutex);
938         qemu_sem_destroy(&p->sem);
939         qemu_sem_destroy(&p->sem_sync);
940         g_free(p->name);
941         p->name = NULL;
942         multifd_pages_clear(p->pages);
943         p->pages = NULL;
944         p->packet_len = 0;
945         g_free(p->packet);
946         p->packet = NULL;
947     }
948     qemu_sem_destroy(&multifd_send_state->channels_ready);
949     qemu_sem_destroy(&multifd_send_state->sem_sync);
950     g_free(multifd_send_state->params);
951     multifd_send_state->params = NULL;
952     multifd_pages_clear(multifd_send_state->pages);
953     multifd_send_state->pages = NULL;
954     g_free(multifd_send_state);
955     multifd_send_state = NULL;
956     return ret;
957 }
958 
959 static void multifd_send_sync_main(void)
960 {
961     int i;
962 
963     if (!migrate_use_multifd()) {
964         return;
965     }
966     if (multifd_send_state->pages->used) {
967         multifd_send_pages();
968     }
969     for (i = 0; i < migrate_multifd_channels(); i++) {
970         MultiFDSendParams *p = &multifd_send_state->params[i];
971 
972         trace_multifd_send_sync_main_signal(p->id);
973 
974         qemu_mutex_lock(&p->mutex);
975 
976         p->packet_num = multifd_send_state->packet_num++;
977         p->flags |= MULTIFD_FLAG_SYNC;
978         p->pending_job++;
979         qemu_mutex_unlock(&p->mutex);
980         qemu_sem_post(&p->sem);
981     }
982     for (i = 0; i < migrate_multifd_channels(); i++) {
983         MultiFDSendParams *p = &multifd_send_state->params[i];
984 
985         trace_multifd_send_sync_main_wait(p->id);
986         qemu_sem_wait(&multifd_send_state->sem_sync);
987     }
988     trace_multifd_send_sync_main(multifd_send_state->packet_num);
989 }
990 
991 static void *multifd_send_thread(void *opaque)
992 {
993     MultiFDSendParams *p = opaque;
994     Error *local_err = NULL;
995     int ret;
996 
997     trace_multifd_send_thread_start(p->id);
998     rcu_register_thread();
999 
1000     if (multifd_send_initial_packet(p, &local_err) < 0) {
1001         goto out;
1002     }
1003     /* initial packet */
1004     p->num_packets = 1;
1005 
1006     while (true) {
1007         qemu_sem_wait(&p->sem);
1008         qemu_mutex_lock(&p->mutex);
1009 
1010         if (p->pending_job) {
1011             uint32_t used = p->pages->used;
1012             uint64_t packet_num = p->packet_num;
1013             uint32_t flags = p->flags;
1014 
1015             multifd_send_fill_packet(p);
1016             p->flags = 0;
1017             p->num_packets++;
1018             p->num_pages += used;
1019             p->pages->used = 0;
1020             qemu_mutex_unlock(&p->mutex);
1021 
1022             trace_multifd_send(p->id, packet_num, used, flags);
1023 
1024             ret = qio_channel_write_all(p->c, (void *)p->packet,
1025                                         p->packet_len, &local_err);
1026             if (ret != 0) {
1027                 break;
1028             }
1029 
1030             ret = qio_channel_writev_all(p->c, p->pages->iov, used, &local_err);
1031             if (ret != 0) {
1032                 break;
1033             }
1034 
1035             qemu_mutex_lock(&p->mutex);
1036             p->pending_job--;
1037             qemu_mutex_unlock(&p->mutex);
1038 
1039             if (flags & MULTIFD_FLAG_SYNC) {
1040                 qemu_sem_post(&multifd_send_state->sem_sync);
1041             }
1042             qemu_sem_post(&multifd_send_state->channels_ready);
1043         } else if (p->quit) {
1044             qemu_mutex_unlock(&p->mutex);
1045             break;
1046         } else {
1047             qemu_mutex_unlock(&p->mutex);
1048             /* sometimes there are spurious wakeups */
1049         }
1050     }
1051 
1052 out:
1053     if (local_err) {
1054         multifd_send_terminate_threads(local_err);
1055     }
1056 
1057     qemu_mutex_lock(&p->mutex);
1058     p->running = false;
1059     qemu_mutex_unlock(&p->mutex);
1060 
1061     rcu_unregister_thread();
1062     trace_multifd_send_thread_end(p->id, p->num_packets, p->num_pages);
1063 
1064     return NULL;
1065 }
1066 
1067 static void multifd_new_send_channel_async(QIOTask *task, gpointer opaque)
1068 {
1069     MultiFDSendParams *p = opaque;
1070     QIOChannel *sioc = QIO_CHANNEL(qio_task_get_source(task));
1071     Error *local_err = NULL;
1072 
1073     if (qio_task_propagate_error(task, &local_err)) {
1074         if (multifd_save_cleanup(&local_err) != 0) {
1075             migrate_set_error(migrate_get_current(), local_err);
1076         }
1077     } else {
1078         p->c = QIO_CHANNEL(sioc);
1079         qio_channel_set_delay(p->c, false);
1080         p->running = true;
1081         qemu_thread_create(&p->thread, p->name, multifd_send_thread, p,
1082                            QEMU_THREAD_JOINABLE);
1083 
1084         atomic_inc(&multifd_send_state->count);
1085     }
1086 }
1087 
1088 int multifd_save_setup(void)
1089 {
1090     int thread_count;
1091     uint32_t page_count = migrate_multifd_page_count();
1092     uint8_t i;
1093 
1094     if (!migrate_use_multifd()) {
1095         return 0;
1096     }
1097     thread_count = migrate_multifd_channels();
1098     multifd_send_state = g_malloc0(sizeof(*multifd_send_state));
1099     multifd_send_state->params = g_new0(MultiFDSendParams, thread_count);
1100     atomic_set(&multifd_send_state->count, 0);
1101     multifd_send_state->pages = multifd_pages_init(page_count);
1102     qemu_sem_init(&multifd_send_state->sem_sync, 0);
1103     qemu_sem_init(&multifd_send_state->channels_ready, 0);
1104 
1105     for (i = 0; i < thread_count; i++) {
1106         MultiFDSendParams *p = &multifd_send_state->params[i];
1107 
1108         qemu_mutex_init(&p->mutex);
1109         qemu_sem_init(&p->sem, 0);
1110         qemu_sem_init(&p->sem_sync, 0);
1111         p->quit = false;
1112         p->pending_job = 0;
1113         p->id = i;
1114         p->pages = multifd_pages_init(page_count);
1115         p->packet_len = sizeof(MultiFDPacket_t)
1116                       + sizeof(ram_addr_t) * page_count;
1117         p->packet = g_malloc0(p->packet_len);
1118         p->name = g_strdup_printf("multifdsend_%d", i);
1119         socket_send_channel_create(multifd_new_send_channel_async, p);
1120     }
1121     return 0;
1122 }
1123 
1124 struct {
1125     MultiFDRecvParams *params;
1126     /* number of created threads */
1127     int count;
1128     /* syncs main thread and channels */
1129     QemuSemaphore sem_sync;
1130     /* global number of generated multifd packets */
1131     uint64_t packet_num;
1132 } *multifd_recv_state;
1133 
1134 static void multifd_recv_terminate_threads(Error *err)
1135 {
1136     int i;
1137 
1138     if (err) {
1139         MigrationState *s = migrate_get_current();
1140         migrate_set_error(s, err);
1141         if (s->state == MIGRATION_STATUS_SETUP ||
1142             s->state == MIGRATION_STATUS_ACTIVE) {
1143             migrate_set_state(&s->state, s->state,
1144                               MIGRATION_STATUS_FAILED);
1145         }
1146     }
1147 
1148     for (i = 0; i < migrate_multifd_channels(); i++) {
1149         MultiFDRecvParams *p = &multifd_recv_state->params[i];
1150 
1151         qemu_mutex_lock(&p->mutex);
1152         /* We could arrive here for two reasons:
1153            - normal quit, i.e. everything went fine, just finished
1154            - error quit: We close the channels so the channel threads
1155              finish the qio_channel_read_all_eof() */
1156         qio_channel_shutdown(p->c, QIO_CHANNEL_SHUTDOWN_BOTH, NULL);
1157         qemu_mutex_unlock(&p->mutex);
1158     }
1159 }
1160 
1161 int multifd_load_cleanup(Error **errp)
1162 {
1163     int i;
1164     int ret = 0;
1165 
1166     if (!migrate_use_multifd()) {
1167         return 0;
1168     }
1169     multifd_recv_terminate_threads(NULL);
1170     for (i = 0; i < migrate_multifd_channels(); i++) {
1171         MultiFDRecvParams *p = &multifd_recv_state->params[i];
1172 
1173         if (p->running) {
1174             qemu_thread_join(&p->thread);
1175         }
1176         object_unref(OBJECT(p->c));
1177         p->c = NULL;
1178         qemu_mutex_destroy(&p->mutex);
1179         qemu_sem_destroy(&p->sem_sync);
1180         g_free(p->name);
1181         p->name = NULL;
1182         multifd_pages_clear(p->pages);
1183         p->pages = NULL;
1184         p->packet_len = 0;
1185         g_free(p->packet);
1186         p->packet = NULL;
1187     }
1188     qemu_sem_destroy(&multifd_recv_state->sem_sync);
1189     g_free(multifd_recv_state->params);
1190     multifd_recv_state->params = NULL;
1191     g_free(multifd_recv_state);
1192     multifd_recv_state = NULL;
1193 
1194     return ret;
1195 }
1196 
1197 static void multifd_recv_sync_main(void)
1198 {
1199     int i;
1200 
1201     if (!migrate_use_multifd()) {
1202         return;
1203     }
1204     for (i = 0; i < migrate_multifd_channels(); i++) {
1205         MultiFDRecvParams *p = &multifd_recv_state->params[i];
1206 
1207         trace_multifd_recv_sync_main_wait(p->id);
1208         qemu_sem_wait(&multifd_recv_state->sem_sync);
1209         qemu_mutex_lock(&p->mutex);
1210         if (multifd_recv_state->packet_num < p->packet_num) {
1211             multifd_recv_state->packet_num = p->packet_num;
1212         }
1213         qemu_mutex_unlock(&p->mutex);
1214     }
1215     for (i = 0; i < migrate_multifd_channels(); i++) {
1216         MultiFDRecvParams *p = &multifd_recv_state->params[i];
1217 
1218         trace_multifd_recv_sync_main_signal(p->id);
1219         qemu_sem_post(&p->sem_sync);
1220     }
1221     trace_multifd_recv_sync_main(multifd_recv_state->packet_num);
1222 }
1223 
1224 static void *multifd_recv_thread(void *opaque)
1225 {
1226     MultiFDRecvParams *p = opaque;
1227     Error *local_err = NULL;
1228     int ret;
1229 
1230     trace_multifd_recv_thread_start(p->id);
1231     rcu_register_thread();
1232 
1233     while (true) {
1234         uint32_t used;
1235         uint32_t flags;
1236 
1237         ret = qio_channel_read_all_eof(p->c, (void *)p->packet,
1238                                        p->packet_len, &local_err);
1239         if (ret == 0) {   /* EOF */
1240             break;
1241         }
1242         if (ret == -1) {   /* Error */
1243             break;
1244         }
1245 
1246         qemu_mutex_lock(&p->mutex);
1247         ret = multifd_recv_unfill_packet(p, &local_err);
1248         if (ret) {
1249             qemu_mutex_unlock(&p->mutex);
1250             break;
1251         }
1252 
1253         used = p->pages->used;
1254         flags = p->flags;
1255         trace_multifd_recv(p->id, p->packet_num, used, flags);
1256         p->num_packets++;
1257         p->num_pages += used;
1258         qemu_mutex_unlock(&p->mutex);
1259 
1260         ret = qio_channel_readv_all(p->c, p->pages->iov, used, &local_err);
1261         if (ret != 0) {
1262             break;
1263         }
1264 
1265         if (flags & MULTIFD_FLAG_SYNC) {
1266             qemu_sem_post(&multifd_recv_state->sem_sync);
1267             qemu_sem_wait(&p->sem_sync);
1268         }
1269     }
1270 
1271     if (local_err) {
1272         multifd_recv_terminate_threads(local_err);
1273     }
1274     qemu_mutex_lock(&p->mutex);
1275     p->running = false;
1276     qemu_mutex_unlock(&p->mutex);
1277 
1278     rcu_unregister_thread();
1279     trace_multifd_recv_thread_end(p->id, p->num_packets, p->num_pages);
1280 
1281     return NULL;
1282 }
1283 
1284 int multifd_load_setup(void)
1285 {
1286     int thread_count;
1287     uint32_t page_count = migrate_multifd_page_count();
1288     uint8_t i;
1289 
1290     if (!migrate_use_multifd()) {
1291         return 0;
1292     }
1293     thread_count = migrate_multifd_channels();
1294     multifd_recv_state = g_malloc0(sizeof(*multifd_recv_state));
1295     multifd_recv_state->params = g_new0(MultiFDRecvParams, thread_count);
1296     atomic_set(&multifd_recv_state->count, 0);
1297     qemu_sem_init(&multifd_recv_state->sem_sync, 0);
1298 
1299     for (i = 0; i < thread_count; i++) {
1300         MultiFDRecvParams *p = &multifd_recv_state->params[i];
1301 
1302         qemu_mutex_init(&p->mutex);
1303         qemu_sem_init(&p->sem_sync, 0);
1304         p->id = i;
1305         p->pages = multifd_pages_init(page_count);
1306         p->packet_len = sizeof(MultiFDPacket_t)
1307                       + sizeof(ram_addr_t) * page_count;
1308         p->packet = g_malloc0(p->packet_len);
1309         p->name = g_strdup_printf("multifdrecv_%d", i);
1310     }
1311     return 0;
1312 }
1313 
1314 bool multifd_recv_all_channels_created(void)
1315 {
1316     int thread_count = migrate_multifd_channels();
1317 
1318     if (!migrate_use_multifd()) {
1319         return true;
1320     }
1321 
1322     return thread_count == atomic_read(&multifd_recv_state->count);
1323 }
1324 
1325 /* Return true if multifd is ready for the migration, otherwise false */
1326 bool multifd_recv_new_channel(QIOChannel *ioc)
1327 {
1328     MultiFDRecvParams *p;
1329     Error *local_err = NULL;
1330     int id;
1331 
1332     id = multifd_recv_initial_packet(ioc, &local_err);
1333     if (id < 0) {
1334         multifd_recv_terminate_threads(local_err);
1335         return false;
1336     }
1337 
1338     p = &multifd_recv_state->params[id];
1339     if (p->c != NULL) {
1340         error_setg(&local_err, "multifd: received id '%d' already setup'",
1341                    id);
1342         multifd_recv_terminate_threads(local_err);
1343         return false;
1344     }
1345     p->c = ioc;
1346     object_ref(OBJECT(ioc));
1347     /* initial packet */
1348     p->num_packets = 1;
1349 
1350     p->running = true;
1351     qemu_thread_create(&p->thread, p->name, multifd_recv_thread, p,
1352                        QEMU_THREAD_JOINABLE);
1353     atomic_inc(&multifd_recv_state->count);
1354     return multifd_recv_state->count == migrate_multifd_channels();
1355 }
1356 
1357 /**
1358  * save_page_header: write page header to wire
1359  *
1360  * If this is the 1st block, it also writes the block identification
1361  *
1362  * Returns the number of bytes written
1363  *
1364  * @f: QEMUFile where to send the data
1365  * @block: block that contains the page we want to send
1366  * @offset: offset inside the block for the page
1367  *          in the lower bits, it contains flags
1368  */
1369 static size_t save_page_header(RAMState *rs, QEMUFile *f,  RAMBlock *block,
1370                                ram_addr_t offset)
1371 {
1372     size_t size, len;
1373 
1374     if (block == rs->last_sent_block) {
1375         offset |= RAM_SAVE_FLAG_CONTINUE;
1376     }
1377     qemu_put_be64(f, offset);
1378     size = 8;
1379 
1380     if (!(offset & RAM_SAVE_FLAG_CONTINUE)) {
1381         len = strlen(block->idstr);
1382         qemu_put_byte(f, len);
1383         qemu_put_buffer(f, (uint8_t *)block->idstr, len);
1384         size += 1 + len;
1385         rs->last_sent_block = block;
1386     }
1387     return size;
1388 }
1389 
1390 /**
1391  * mig_throttle_guest_down: throotle down the guest
1392  *
1393  * Reduce amount of guest cpu execution to hopefully slow down memory
1394  * writes. If guest dirty memory rate is reduced below the rate at
1395  * which we can transfer pages to the destination then we should be
1396  * able to complete migration. Some workloads dirty memory way too
1397  * fast and will not effectively converge, even with auto-converge.
1398  */
1399 static void mig_throttle_guest_down(void)
1400 {
1401     MigrationState *s = migrate_get_current();
1402     uint64_t pct_initial = s->parameters.cpu_throttle_initial;
1403     uint64_t pct_icrement = s->parameters.cpu_throttle_increment;
1404     int pct_max = s->parameters.max_cpu_throttle;
1405 
1406     /* We have not started throttling yet. Let's start it. */
1407     if (!cpu_throttle_active()) {
1408         cpu_throttle_set(pct_initial);
1409     } else {
1410         /* Throttling already on, just increase the rate */
1411         cpu_throttle_set(MIN(cpu_throttle_get_percentage() + pct_icrement,
1412                          pct_max));
1413     }
1414 }
1415 
1416 /**
1417  * xbzrle_cache_zero_page: insert a zero page in the XBZRLE cache
1418  *
1419  * @rs: current RAM state
1420  * @current_addr: address for the zero page
1421  *
1422  * Update the xbzrle cache to reflect a page that's been sent as all 0.
1423  * The important thing is that a stale (not-yet-0'd) page be replaced
1424  * by the new data.
1425  * As a bonus, if the page wasn't in the cache it gets added so that
1426  * when a small write is made into the 0'd page it gets XBZRLE sent.
1427  */
1428 static void xbzrle_cache_zero_page(RAMState *rs, ram_addr_t current_addr)
1429 {
1430     if (rs->ram_bulk_stage || !migrate_use_xbzrle()) {
1431         return;
1432     }
1433 
1434     /* We don't care if this fails to allocate a new cache page
1435      * as long as it updated an old one */
1436     cache_insert(XBZRLE.cache, current_addr, XBZRLE.zero_target_page,
1437                  ram_counters.dirty_sync_count);
1438 }
1439 
1440 #define ENCODING_FLAG_XBZRLE 0x1
1441 
1442 /**
1443  * save_xbzrle_page: compress and send current page
1444  *
1445  * Returns: 1 means that we wrote the page
1446  *          0 means that page is identical to the one already sent
1447  *          -1 means that xbzrle would be longer than normal
1448  *
1449  * @rs: current RAM state
1450  * @current_data: pointer to the address of the page contents
1451  * @current_addr: addr of the page
1452  * @block: block that contains the page we want to send
1453  * @offset: offset inside the block for the page
1454  * @last_stage: if we are at the completion stage
1455  */
1456 static int save_xbzrle_page(RAMState *rs, uint8_t **current_data,
1457                             ram_addr_t current_addr, RAMBlock *block,
1458                             ram_addr_t offset, bool last_stage)
1459 {
1460     int encoded_len = 0, bytes_xbzrle;
1461     uint8_t *prev_cached_page;
1462 
1463     if (!cache_is_cached(XBZRLE.cache, current_addr,
1464                          ram_counters.dirty_sync_count)) {
1465         xbzrle_counters.cache_miss++;
1466         if (!last_stage) {
1467             if (cache_insert(XBZRLE.cache, current_addr, *current_data,
1468                              ram_counters.dirty_sync_count) == -1) {
1469                 return -1;
1470             } else {
1471                 /* update *current_data when the page has been
1472                    inserted into cache */
1473                 *current_data = get_cached_data(XBZRLE.cache, current_addr);
1474             }
1475         }
1476         return -1;
1477     }
1478 
1479     prev_cached_page = get_cached_data(XBZRLE.cache, current_addr);
1480 
1481     /* save current buffer into memory */
1482     memcpy(XBZRLE.current_buf, *current_data, TARGET_PAGE_SIZE);
1483 
1484     /* XBZRLE encoding (if there is no overflow) */
1485     encoded_len = xbzrle_encode_buffer(prev_cached_page, XBZRLE.current_buf,
1486                                        TARGET_PAGE_SIZE, XBZRLE.encoded_buf,
1487                                        TARGET_PAGE_SIZE);
1488     if (encoded_len == 0) {
1489         trace_save_xbzrle_page_skipping();
1490         return 0;
1491     } else if (encoded_len == -1) {
1492         trace_save_xbzrle_page_overflow();
1493         xbzrle_counters.overflow++;
1494         /* update data in the cache */
1495         if (!last_stage) {
1496             memcpy(prev_cached_page, *current_data, TARGET_PAGE_SIZE);
1497             *current_data = prev_cached_page;
1498         }
1499         return -1;
1500     }
1501 
1502     /* we need to update the data in the cache, in order to get the same data */
1503     if (!last_stage) {
1504         memcpy(prev_cached_page, XBZRLE.current_buf, TARGET_PAGE_SIZE);
1505     }
1506 
1507     /* Send XBZRLE based compressed page */
1508     bytes_xbzrle = save_page_header(rs, rs->f, block,
1509                                     offset | RAM_SAVE_FLAG_XBZRLE);
1510     qemu_put_byte(rs->f, ENCODING_FLAG_XBZRLE);
1511     qemu_put_be16(rs->f, encoded_len);
1512     qemu_put_buffer(rs->f, XBZRLE.encoded_buf, encoded_len);
1513     bytes_xbzrle += encoded_len + 1 + 2;
1514     xbzrle_counters.pages++;
1515     xbzrle_counters.bytes += bytes_xbzrle;
1516     ram_counters.transferred += bytes_xbzrle;
1517 
1518     return 1;
1519 }
1520 
1521 /**
1522  * migration_bitmap_find_dirty: find the next dirty page from start
1523  *
1524  * Called with rcu_read_lock() to protect migration_bitmap
1525  *
1526  * Returns the byte offset within memory region of the start of a dirty page
1527  *
1528  * @rs: current RAM state
1529  * @rb: RAMBlock where to search for dirty pages
1530  * @start: page where we start the search
1531  */
1532 static inline
1533 unsigned long migration_bitmap_find_dirty(RAMState *rs, RAMBlock *rb,
1534                                           unsigned long start)
1535 {
1536     unsigned long size = rb->used_length >> TARGET_PAGE_BITS;
1537     unsigned long *bitmap = rb->bmap;
1538     unsigned long next;
1539 
1540     if (!qemu_ram_is_migratable(rb)) {
1541         return size;
1542     }
1543 
1544     if (rs->ram_bulk_stage && start > 0) {
1545         next = start + 1;
1546     } else {
1547         next = find_next_bit(bitmap, size, start);
1548     }
1549 
1550     return next;
1551 }
1552 
1553 static inline bool migration_bitmap_clear_dirty(RAMState *rs,
1554                                                 RAMBlock *rb,
1555                                                 unsigned long page)
1556 {
1557     bool ret;
1558 
1559     ret = test_and_clear_bit(page, rb->bmap);
1560 
1561     if (ret) {
1562         rs->migration_dirty_pages--;
1563     }
1564     return ret;
1565 }
1566 
1567 static void migration_bitmap_sync_range(RAMState *rs, RAMBlock *rb,
1568                                         ram_addr_t start, ram_addr_t length)
1569 {
1570     rs->migration_dirty_pages +=
1571         cpu_physical_memory_sync_dirty_bitmap(rb, start, length,
1572                                               &rs->num_dirty_pages_period);
1573 }
1574 
1575 /**
1576  * ram_pagesize_summary: calculate all the pagesizes of a VM
1577  *
1578  * Returns a summary bitmap of the page sizes of all RAMBlocks
1579  *
1580  * For VMs with just normal pages this is equivalent to the host page
1581  * size. If it's got some huge pages then it's the OR of all the
1582  * different page sizes.
1583  */
1584 uint64_t ram_pagesize_summary(void)
1585 {
1586     RAMBlock *block;
1587     uint64_t summary = 0;
1588 
1589     RAMBLOCK_FOREACH_MIGRATABLE(block) {
1590         summary |= block->page_size;
1591     }
1592 
1593     return summary;
1594 }
1595 
1596 static void migration_update_rates(RAMState *rs, int64_t end_time)
1597 {
1598     uint64_t page_count = rs->target_page_count - rs->target_page_count_prev;
1599     double compressed_size;
1600 
1601     /* calculate period counters */
1602     ram_counters.dirty_pages_rate = rs->num_dirty_pages_period * 1000
1603                 / (end_time - rs->time_last_bitmap_sync);
1604 
1605     if (!page_count) {
1606         return;
1607     }
1608 
1609     if (migrate_use_xbzrle()) {
1610         xbzrle_counters.cache_miss_rate = (double)(xbzrle_counters.cache_miss -
1611             rs->xbzrle_cache_miss_prev) / page_count;
1612         rs->xbzrle_cache_miss_prev = xbzrle_counters.cache_miss;
1613     }
1614 
1615     if (migrate_use_compression()) {
1616         compression_counters.busy_rate = (double)(compression_counters.busy -
1617             rs->compress_thread_busy_prev) / page_count;
1618         rs->compress_thread_busy_prev = compression_counters.busy;
1619 
1620         compressed_size = compression_counters.compressed_size -
1621                           rs->compressed_size_prev;
1622         if (compressed_size) {
1623             double uncompressed_size = (compression_counters.pages -
1624                                     rs->compress_pages_prev) * TARGET_PAGE_SIZE;
1625 
1626             /* Compression-Ratio = Uncompressed-size / Compressed-size */
1627             compression_counters.compression_rate =
1628                                         uncompressed_size / compressed_size;
1629 
1630             rs->compress_pages_prev = compression_counters.pages;
1631             rs->compressed_size_prev = compression_counters.compressed_size;
1632         }
1633     }
1634 }
1635 
1636 static void migration_bitmap_sync(RAMState *rs)
1637 {
1638     RAMBlock *block;
1639     int64_t end_time;
1640     uint64_t bytes_xfer_now;
1641 
1642     ram_counters.dirty_sync_count++;
1643 
1644     if (!rs->time_last_bitmap_sync) {
1645         rs->time_last_bitmap_sync = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
1646     }
1647 
1648     trace_migration_bitmap_sync_start();
1649     memory_global_dirty_log_sync();
1650 
1651     qemu_mutex_lock(&rs->bitmap_mutex);
1652     rcu_read_lock();
1653     RAMBLOCK_FOREACH_MIGRATABLE(block) {
1654         migration_bitmap_sync_range(rs, block, 0, block->used_length);
1655     }
1656     ram_counters.remaining = ram_bytes_remaining();
1657     rcu_read_unlock();
1658     qemu_mutex_unlock(&rs->bitmap_mutex);
1659 
1660     trace_migration_bitmap_sync_end(rs->num_dirty_pages_period);
1661 
1662     end_time = qemu_clock_get_ms(QEMU_CLOCK_REALTIME);
1663 
1664     /* more than 1 second = 1000 millisecons */
1665     if (end_time > rs->time_last_bitmap_sync + 1000) {
1666         bytes_xfer_now = ram_counters.transferred;
1667 
1668         /* During block migration the auto-converge logic incorrectly detects
1669          * that ram migration makes no progress. Avoid this by disabling the
1670          * throttling logic during the bulk phase of block migration. */
1671         if (migrate_auto_converge() && !blk_mig_bulk_active()) {
1672             /* The following detection logic can be refined later. For now:
1673                Check to see if the dirtied bytes is 50% more than the approx.
1674                amount of bytes that just got transferred since the last time we
1675                were in this routine. If that happens twice, start or increase
1676                throttling */
1677 
1678             if ((rs->num_dirty_pages_period * TARGET_PAGE_SIZE >
1679                    (bytes_xfer_now - rs->bytes_xfer_prev) / 2) &&
1680                 (++rs->dirty_rate_high_cnt >= 2)) {
1681                     trace_migration_throttle();
1682                     rs->dirty_rate_high_cnt = 0;
1683                     mig_throttle_guest_down();
1684             }
1685         }
1686 
1687         migration_update_rates(rs, end_time);
1688 
1689         rs->target_page_count_prev = rs->target_page_count;
1690 
1691         /* reset period counters */
1692         rs->time_last_bitmap_sync = end_time;
1693         rs->num_dirty_pages_period = 0;
1694         rs->bytes_xfer_prev = bytes_xfer_now;
1695     }
1696     if (migrate_use_events()) {
1697         qapi_event_send_migration_pass(ram_counters.dirty_sync_count);
1698     }
1699 }
1700 
1701 /**
1702  * save_zero_page_to_file: send the zero page to the file
1703  *
1704  * Returns the size of data written to the file, 0 means the page is not
1705  * a zero page
1706  *
1707  * @rs: current RAM state
1708  * @file: the file where the data is saved
1709  * @block: block that contains the page we want to send
1710  * @offset: offset inside the block for the page
1711  */
1712 static int save_zero_page_to_file(RAMState *rs, QEMUFile *file,
1713                                   RAMBlock *block, ram_addr_t offset)
1714 {
1715     uint8_t *p = block->host + offset;
1716     int len = 0;
1717 
1718     if (is_zero_range(p, TARGET_PAGE_SIZE)) {
1719         len += save_page_header(rs, file, block, offset | RAM_SAVE_FLAG_ZERO);
1720         qemu_put_byte(file, 0);
1721         len += 1;
1722     }
1723     return len;
1724 }
1725 
1726 /**
1727  * save_zero_page: send the zero page to the stream
1728  *
1729  * Returns the number of pages written.
1730  *
1731  * @rs: current RAM state
1732  * @block: block that contains the page we want to send
1733  * @offset: offset inside the block for the page
1734  */
1735 static int save_zero_page(RAMState *rs, RAMBlock *block, ram_addr_t offset)
1736 {
1737     int len = save_zero_page_to_file(rs, rs->f, block, offset);
1738 
1739     if (len) {
1740         ram_counters.duplicate++;
1741         ram_counters.transferred += len;
1742         return 1;
1743     }
1744     return -1;
1745 }
1746 
1747 static void ram_release_pages(const char *rbname, uint64_t offset, int pages)
1748 {
1749     if (!migrate_release_ram() || !migration_in_postcopy()) {
1750         return;
1751     }
1752 
1753     ram_discard_range(rbname, offset, pages << TARGET_PAGE_BITS);
1754 }
1755 
1756 /*
1757  * @pages: the number of pages written by the control path,
1758  *        < 0 - error
1759  *        > 0 - number of pages written
1760  *
1761  * Return true if the pages has been saved, otherwise false is returned.
1762  */
1763 static bool control_save_page(RAMState *rs, RAMBlock *block, ram_addr_t offset,
1764                               int *pages)
1765 {
1766     uint64_t bytes_xmit = 0;
1767     int ret;
1768 
1769     *pages = -1;
1770     ret = ram_control_save_page(rs->f, block->offset, offset, TARGET_PAGE_SIZE,
1771                                 &bytes_xmit);
1772     if (ret == RAM_SAVE_CONTROL_NOT_SUPP) {
1773         return false;
1774     }
1775 
1776     if (bytes_xmit) {
1777         ram_counters.transferred += bytes_xmit;
1778         *pages = 1;
1779     }
1780 
1781     if (ret == RAM_SAVE_CONTROL_DELAYED) {
1782         return true;
1783     }
1784 
1785     if (bytes_xmit > 0) {
1786         ram_counters.normal++;
1787     } else if (bytes_xmit == 0) {
1788         ram_counters.duplicate++;
1789     }
1790 
1791     return true;
1792 }
1793 
1794 /*
1795  * directly send the page to the stream
1796  *
1797  * Returns the number of pages written.
1798  *
1799  * @rs: current RAM state
1800  * @block: block that contains the page we want to send
1801  * @offset: offset inside the block for the page
1802  * @buf: the page to be sent
1803  * @async: send to page asyncly
1804  */
1805 static int save_normal_page(RAMState *rs, RAMBlock *block, ram_addr_t offset,
1806                             uint8_t *buf, bool async)
1807 {
1808     ram_counters.transferred += save_page_header(rs, rs->f, block,
1809                                                  offset | RAM_SAVE_FLAG_PAGE);
1810     if (async) {
1811         qemu_put_buffer_async(rs->f, buf, TARGET_PAGE_SIZE,
1812                               migrate_release_ram() &
1813                               migration_in_postcopy());
1814     } else {
1815         qemu_put_buffer(rs->f, buf, TARGET_PAGE_SIZE);
1816     }
1817     ram_counters.transferred += TARGET_PAGE_SIZE;
1818     ram_counters.normal++;
1819     return 1;
1820 }
1821 
1822 /**
1823  * ram_save_page: send the given page to the stream
1824  *
1825  * Returns the number of pages written.
1826  *          < 0 - error
1827  *          >=0 - Number of pages written - this might legally be 0
1828  *                if xbzrle noticed the page was the same.
1829  *
1830  * @rs: current RAM state
1831  * @block: block that contains the page we want to send
1832  * @offset: offset inside the block for the page
1833  * @last_stage: if we are at the completion stage
1834  */
1835 static int ram_save_page(RAMState *rs, PageSearchStatus *pss, bool last_stage)
1836 {
1837     int pages = -1;
1838     uint8_t *p;
1839     bool send_async = true;
1840     RAMBlock *block = pss->block;
1841     ram_addr_t offset = pss->page << TARGET_PAGE_BITS;
1842     ram_addr_t current_addr = block->offset + offset;
1843 
1844     p = block->host + offset;
1845     trace_ram_save_page(block->idstr, (uint64_t)offset, p);
1846 
1847     XBZRLE_cache_lock();
1848     if (!rs->ram_bulk_stage && !migration_in_postcopy() &&
1849         migrate_use_xbzrle()) {
1850         pages = save_xbzrle_page(rs, &p, current_addr, block,
1851                                  offset, last_stage);
1852         if (!last_stage) {
1853             /* Can't send this cached data async, since the cache page
1854              * might get updated before it gets to the wire
1855              */
1856             send_async = false;
1857         }
1858     }
1859 
1860     /* XBZRLE overflow or normal page */
1861     if (pages == -1) {
1862         pages = save_normal_page(rs, block, offset, p, send_async);
1863     }
1864 
1865     XBZRLE_cache_unlock();
1866 
1867     return pages;
1868 }
1869 
1870 static int ram_save_multifd_page(RAMState *rs, RAMBlock *block,
1871                                  ram_addr_t offset)
1872 {
1873     multifd_queue_page(block, offset);
1874     ram_counters.normal++;
1875 
1876     return 1;
1877 }
1878 
1879 static bool do_compress_ram_page(QEMUFile *f, z_stream *stream, RAMBlock *block,
1880                                  ram_addr_t offset, uint8_t *source_buf)
1881 {
1882     RAMState *rs = ram_state;
1883     uint8_t *p = block->host + (offset & TARGET_PAGE_MASK);
1884     bool zero_page = false;
1885     int ret;
1886 
1887     if (save_zero_page_to_file(rs, f, block, offset)) {
1888         zero_page = true;
1889         goto exit;
1890     }
1891 
1892     save_page_header(rs, f, block, offset | RAM_SAVE_FLAG_COMPRESS_PAGE);
1893 
1894     /*
1895      * copy it to a internal buffer to avoid it being modified by VM
1896      * so that we can catch up the error during compression and
1897      * decompression
1898      */
1899     memcpy(source_buf, p, TARGET_PAGE_SIZE);
1900     ret = qemu_put_compression_data(f, stream, source_buf, TARGET_PAGE_SIZE);
1901     if (ret < 0) {
1902         qemu_file_set_error(migrate_get_current()->to_dst_file, ret);
1903         error_report("compressed data failed!");
1904         return false;
1905     }
1906 
1907 exit:
1908     ram_release_pages(block->idstr, offset & TARGET_PAGE_MASK, 1);
1909     return zero_page;
1910 }
1911 
1912 static void
1913 update_compress_thread_counts(const CompressParam *param, int bytes_xmit)
1914 {
1915     ram_counters.transferred += bytes_xmit;
1916 
1917     if (param->zero_page) {
1918         ram_counters.duplicate++;
1919         return;
1920     }
1921 
1922     /* 8 means a header with RAM_SAVE_FLAG_CONTINUE. */
1923     compression_counters.compressed_size += bytes_xmit - 8;
1924     compression_counters.pages++;
1925 }
1926 
1927 static bool save_page_use_compression(RAMState *rs);
1928 
1929 static void flush_compressed_data(RAMState *rs)
1930 {
1931     int idx, len, thread_count;
1932 
1933     if (!save_page_use_compression(rs)) {
1934         return;
1935     }
1936     thread_count = migrate_compress_threads();
1937 
1938     qemu_mutex_lock(&comp_done_lock);
1939     for (idx = 0; idx < thread_count; idx++) {
1940         while (!comp_param[idx].done) {
1941             qemu_cond_wait(&comp_done_cond, &comp_done_lock);
1942         }
1943     }
1944     qemu_mutex_unlock(&comp_done_lock);
1945 
1946     for (idx = 0; idx < thread_count; idx++) {
1947         qemu_mutex_lock(&comp_param[idx].mutex);
1948         if (!comp_param[idx].quit) {
1949             len = qemu_put_qemu_file(rs->f, comp_param[idx].file);
1950             /*
1951              * it's safe to fetch zero_page without holding comp_done_lock
1952              * as there is no further request submitted to the thread,
1953              * i.e, the thread should be waiting for a request at this point.
1954              */
1955             update_compress_thread_counts(&comp_param[idx], len);
1956         }
1957         qemu_mutex_unlock(&comp_param[idx].mutex);
1958     }
1959 }
1960 
1961 static inline void set_compress_params(CompressParam *param, RAMBlock *block,
1962                                        ram_addr_t offset)
1963 {
1964     param->block = block;
1965     param->offset = offset;
1966 }
1967 
1968 static int compress_page_with_multi_thread(RAMState *rs, RAMBlock *block,
1969                                            ram_addr_t offset)
1970 {
1971     int idx, thread_count, bytes_xmit = -1, pages = -1;
1972     bool wait = migrate_compress_wait_thread();
1973 
1974     thread_count = migrate_compress_threads();
1975     qemu_mutex_lock(&comp_done_lock);
1976 retry:
1977     for (idx = 0; idx < thread_count; idx++) {
1978         if (comp_param[idx].done) {
1979             comp_param[idx].done = false;
1980             bytes_xmit = qemu_put_qemu_file(rs->f, comp_param[idx].file);
1981             qemu_mutex_lock(&comp_param[idx].mutex);
1982             set_compress_params(&comp_param[idx], block, offset);
1983             qemu_cond_signal(&comp_param[idx].cond);
1984             qemu_mutex_unlock(&comp_param[idx].mutex);
1985             pages = 1;
1986             update_compress_thread_counts(&comp_param[idx], bytes_xmit);
1987             break;
1988         }
1989     }
1990 
1991     /*
1992      * wait for the free thread if the user specifies 'compress-wait-thread',
1993      * otherwise we will post the page out in the main thread as normal page.
1994      */
1995     if (pages < 0 && wait) {
1996         qemu_cond_wait(&comp_done_cond, &comp_done_lock);
1997         goto retry;
1998     }
1999     qemu_mutex_unlock(&comp_done_lock);
2000 
2001     return pages;
2002 }
2003 
2004 /**
2005  * find_dirty_block: find the next dirty page and update any state
2006  * associated with the search process.
2007  *
2008  * Returns if a page is found
2009  *
2010  * @rs: current RAM state
2011  * @pss: data about the state of the current dirty page scan
2012  * @again: set to false if the search has scanned the whole of RAM
2013  */
2014 static bool find_dirty_block(RAMState *rs, PageSearchStatus *pss, bool *again)
2015 {
2016     pss->page = migration_bitmap_find_dirty(rs, pss->block, pss->page);
2017     if (pss->complete_round && pss->block == rs->last_seen_block &&
2018         pss->page >= rs->last_page) {
2019         /*
2020          * We've been once around the RAM and haven't found anything.
2021          * Give up.
2022          */
2023         *again = false;
2024         return false;
2025     }
2026     if ((pss->page << TARGET_PAGE_BITS) >= pss->block->used_length) {
2027         /* Didn't find anything in this RAM Block */
2028         pss->page = 0;
2029         pss->block = QLIST_NEXT_RCU(pss->block, next);
2030         if (!pss->block) {
2031             /*
2032              * If memory migration starts over, we will meet a dirtied page
2033              * which may still exists in compression threads's ring, so we
2034              * should flush the compressed data to make sure the new page
2035              * is not overwritten by the old one in the destination.
2036              *
2037              * Also If xbzrle is on, stop using the data compression at this
2038              * point. In theory, xbzrle can do better than compression.
2039              */
2040             flush_compressed_data(rs);
2041 
2042             /* Hit the end of the list */
2043             pss->block = QLIST_FIRST_RCU(&ram_list.blocks);
2044             /* Flag that we've looped */
2045             pss->complete_round = true;
2046             rs->ram_bulk_stage = false;
2047         }
2048         /* Didn't find anything this time, but try again on the new block */
2049         *again = true;
2050         return false;
2051     } else {
2052         /* Can go around again, but... */
2053         *again = true;
2054         /* We've found something so probably don't need to */
2055         return true;
2056     }
2057 }
2058 
2059 /**
2060  * unqueue_page: gets a page of the queue
2061  *
2062  * Helper for 'get_queued_page' - gets a page off the queue
2063  *
2064  * Returns the block of the page (or NULL if none available)
2065  *
2066  * @rs: current RAM state
2067  * @offset: used to return the offset within the RAMBlock
2068  */
2069 static RAMBlock *unqueue_page(RAMState *rs, ram_addr_t *offset)
2070 {
2071     RAMBlock *block = NULL;
2072 
2073     if (QSIMPLEQ_EMPTY_ATOMIC(&rs->src_page_requests)) {
2074         return NULL;
2075     }
2076 
2077     qemu_mutex_lock(&rs->src_page_req_mutex);
2078     if (!QSIMPLEQ_EMPTY(&rs->src_page_requests)) {
2079         struct RAMSrcPageRequest *entry =
2080                                 QSIMPLEQ_FIRST(&rs->src_page_requests);
2081         block = entry->rb;
2082         *offset = entry->offset;
2083 
2084         if (entry->len > TARGET_PAGE_SIZE) {
2085             entry->len -= TARGET_PAGE_SIZE;
2086             entry->offset += TARGET_PAGE_SIZE;
2087         } else {
2088             memory_region_unref(block->mr);
2089             QSIMPLEQ_REMOVE_HEAD(&rs->src_page_requests, next_req);
2090             g_free(entry);
2091             migration_consume_urgent_request();
2092         }
2093     }
2094     qemu_mutex_unlock(&rs->src_page_req_mutex);
2095 
2096     return block;
2097 }
2098 
2099 /**
2100  * get_queued_page: unqueue a page from the postocpy requests
2101  *
2102  * Skips pages that are already sent (!dirty)
2103  *
2104  * Returns if a queued page is found
2105  *
2106  * @rs: current RAM state
2107  * @pss: data about the state of the current dirty page scan
2108  */
2109 static bool get_queued_page(RAMState *rs, PageSearchStatus *pss)
2110 {
2111     RAMBlock  *block;
2112     ram_addr_t offset;
2113     bool dirty;
2114 
2115     do {
2116         block = unqueue_page(rs, &offset);
2117         /*
2118          * We're sending this page, and since it's postcopy nothing else
2119          * will dirty it, and we must make sure it doesn't get sent again
2120          * even if this queue request was received after the background
2121          * search already sent it.
2122          */
2123         if (block) {
2124             unsigned long page;
2125 
2126             page = offset >> TARGET_PAGE_BITS;
2127             dirty = test_bit(page, block->bmap);
2128             if (!dirty) {
2129                 trace_get_queued_page_not_dirty(block->idstr, (uint64_t)offset,
2130                        page, test_bit(page, block->unsentmap));
2131             } else {
2132                 trace_get_queued_page(block->idstr, (uint64_t)offset, page);
2133             }
2134         }
2135 
2136     } while (block && !dirty);
2137 
2138     if (block) {
2139         /*
2140          * As soon as we start servicing pages out of order, then we have
2141          * to kill the bulk stage, since the bulk stage assumes
2142          * in (migration_bitmap_find_and_reset_dirty) that every page is
2143          * dirty, that's no longer true.
2144          */
2145         rs->ram_bulk_stage = false;
2146 
2147         /*
2148          * We want the background search to continue from the queued page
2149          * since the guest is likely to want other pages near to the page
2150          * it just requested.
2151          */
2152         pss->block = block;
2153         pss->page = offset >> TARGET_PAGE_BITS;
2154     }
2155 
2156     return !!block;
2157 }
2158 
2159 /**
2160  * migration_page_queue_free: drop any remaining pages in the ram
2161  * request queue
2162  *
2163  * It should be empty at the end anyway, but in error cases there may
2164  * be some left.  in case that there is any page left, we drop it.
2165  *
2166  */
2167 static void migration_page_queue_free(RAMState *rs)
2168 {
2169     struct RAMSrcPageRequest *mspr, *next_mspr;
2170     /* This queue generally should be empty - but in the case of a failed
2171      * migration might have some droppings in.
2172      */
2173     rcu_read_lock();
2174     QSIMPLEQ_FOREACH_SAFE(mspr, &rs->src_page_requests, next_req, next_mspr) {
2175         memory_region_unref(mspr->rb->mr);
2176         QSIMPLEQ_REMOVE_HEAD(&rs->src_page_requests, next_req);
2177         g_free(mspr);
2178     }
2179     rcu_read_unlock();
2180 }
2181 
2182 /**
2183  * ram_save_queue_pages: queue the page for transmission
2184  *
2185  * A request from postcopy destination for example.
2186  *
2187  * Returns zero on success or negative on error
2188  *
2189  * @rbname: Name of the RAMBLock of the request. NULL means the
2190  *          same that last one.
2191  * @start: starting address from the start of the RAMBlock
2192  * @len: length (in bytes) to send
2193  */
2194 int ram_save_queue_pages(const char *rbname, ram_addr_t start, ram_addr_t len)
2195 {
2196     RAMBlock *ramblock;
2197     RAMState *rs = ram_state;
2198 
2199     ram_counters.postcopy_requests++;
2200     rcu_read_lock();
2201     if (!rbname) {
2202         /* Reuse last RAMBlock */
2203         ramblock = rs->last_req_rb;
2204 
2205         if (!ramblock) {
2206             /*
2207              * Shouldn't happen, we can't reuse the last RAMBlock if
2208              * it's the 1st request.
2209              */
2210             error_report("ram_save_queue_pages no previous block");
2211             goto err;
2212         }
2213     } else {
2214         ramblock = qemu_ram_block_by_name(rbname);
2215 
2216         if (!ramblock) {
2217             /* We shouldn't be asked for a non-existent RAMBlock */
2218             error_report("ram_save_queue_pages no block '%s'", rbname);
2219             goto err;
2220         }
2221         rs->last_req_rb = ramblock;
2222     }
2223     trace_ram_save_queue_pages(ramblock->idstr, start, len);
2224     if (start+len > ramblock->used_length) {
2225         error_report("%s request overrun start=" RAM_ADDR_FMT " len="
2226                      RAM_ADDR_FMT " blocklen=" RAM_ADDR_FMT,
2227                      __func__, start, len, ramblock->used_length);
2228         goto err;
2229     }
2230 
2231     struct RAMSrcPageRequest *new_entry =
2232         g_malloc0(sizeof(struct RAMSrcPageRequest));
2233     new_entry->rb = ramblock;
2234     new_entry->offset = start;
2235     new_entry->len = len;
2236 
2237     memory_region_ref(ramblock->mr);
2238     qemu_mutex_lock(&rs->src_page_req_mutex);
2239     QSIMPLEQ_INSERT_TAIL(&rs->src_page_requests, new_entry, next_req);
2240     migration_make_urgent_request();
2241     qemu_mutex_unlock(&rs->src_page_req_mutex);
2242     rcu_read_unlock();
2243 
2244     return 0;
2245 
2246 err:
2247     rcu_read_unlock();
2248     return -1;
2249 }
2250 
2251 static bool save_page_use_compression(RAMState *rs)
2252 {
2253     if (!migrate_use_compression()) {
2254         return false;
2255     }
2256 
2257     /*
2258      * If xbzrle is on, stop using the data compression after first
2259      * round of migration even if compression is enabled. In theory,
2260      * xbzrle can do better than compression.
2261      */
2262     if (rs->ram_bulk_stage || !migrate_use_xbzrle()) {
2263         return true;
2264     }
2265 
2266     return false;
2267 }
2268 
2269 /*
2270  * try to compress the page before posting it out, return true if the page
2271  * has been properly handled by compression, otherwise needs other
2272  * paths to handle it
2273  */
2274 static bool save_compress_page(RAMState *rs, RAMBlock *block, ram_addr_t offset)
2275 {
2276     if (!save_page_use_compression(rs)) {
2277         return false;
2278     }
2279 
2280     /*
2281      * When starting the process of a new block, the first page of
2282      * the block should be sent out before other pages in the same
2283      * block, and all the pages in last block should have been sent
2284      * out, keeping this order is important, because the 'cont' flag
2285      * is used to avoid resending the block name.
2286      *
2287      * We post the fist page as normal page as compression will take
2288      * much CPU resource.
2289      */
2290     if (block != rs->last_sent_block) {
2291         flush_compressed_data(rs);
2292         return false;
2293     }
2294 
2295     if (compress_page_with_multi_thread(rs, block, offset) > 0) {
2296         return true;
2297     }
2298 
2299     compression_counters.busy++;
2300     return false;
2301 }
2302 
2303 /**
2304  * ram_save_target_page: save one target page
2305  *
2306  * Returns the number of pages written
2307  *
2308  * @rs: current RAM state
2309  * @pss: data about the page we want to send
2310  * @last_stage: if we are at the completion stage
2311  */
2312 static int ram_save_target_page(RAMState *rs, PageSearchStatus *pss,
2313                                 bool last_stage)
2314 {
2315     RAMBlock *block = pss->block;
2316     ram_addr_t offset = pss->page << TARGET_PAGE_BITS;
2317     int res;
2318 
2319     if (control_save_page(rs, block, offset, &res)) {
2320         return res;
2321     }
2322 
2323     if (save_compress_page(rs, block, offset)) {
2324         return 1;
2325     }
2326 
2327     res = save_zero_page(rs, block, offset);
2328     if (res > 0) {
2329         /* Must let xbzrle know, otherwise a previous (now 0'd) cached
2330          * page would be stale
2331          */
2332         if (!save_page_use_compression(rs)) {
2333             XBZRLE_cache_lock();
2334             xbzrle_cache_zero_page(rs, block->offset + offset);
2335             XBZRLE_cache_unlock();
2336         }
2337         ram_release_pages(block->idstr, offset, res);
2338         return res;
2339     }
2340 
2341     /*
2342      * do not use multifd for compression as the first page in the new
2343      * block should be posted out before sending the compressed page
2344      */
2345     if (!save_page_use_compression(rs) && migrate_use_multifd()) {
2346         return ram_save_multifd_page(rs, block, offset);
2347     }
2348 
2349     return ram_save_page(rs, pss, last_stage);
2350 }
2351 
2352 /**
2353  * ram_save_host_page: save a whole host page
2354  *
2355  * Starting at *offset send pages up to the end of the current host
2356  * page. It's valid for the initial offset to point into the middle of
2357  * a host page in which case the remainder of the hostpage is sent.
2358  * Only dirty target pages are sent. Note that the host page size may
2359  * be a huge page for this block.
2360  * The saving stops at the boundary of the used_length of the block
2361  * if the RAMBlock isn't a multiple of the host page size.
2362  *
2363  * Returns the number of pages written or negative on error
2364  *
2365  * @rs: current RAM state
2366  * @ms: current migration state
2367  * @pss: data about the page we want to send
2368  * @last_stage: if we are at the completion stage
2369  */
2370 static int ram_save_host_page(RAMState *rs, PageSearchStatus *pss,
2371                               bool last_stage)
2372 {
2373     int tmppages, pages = 0;
2374     size_t pagesize_bits =
2375         qemu_ram_pagesize(pss->block) >> TARGET_PAGE_BITS;
2376 
2377     if (!qemu_ram_is_migratable(pss->block)) {
2378         error_report("block %s should not be migrated !", pss->block->idstr);
2379         return 0;
2380     }
2381 
2382     do {
2383         /* Check the pages is dirty and if it is send it */
2384         if (!migration_bitmap_clear_dirty(rs, pss->block, pss->page)) {
2385             pss->page++;
2386             continue;
2387         }
2388 
2389         tmppages = ram_save_target_page(rs, pss, last_stage);
2390         if (tmppages < 0) {
2391             return tmppages;
2392         }
2393 
2394         pages += tmppages;
2395         if (pss->block->unsentmap) {
2396             clear_bit(pss->page, pss->block->unsentmap);
2397         }
2398 
2399         pss->page++;
2400     } while ((pss->page & (pagesize_bits - 1)) &&
2401              offset_in_ramblock(pss->block, pss->page << TARGET_PAGE_BITS));
2402 
2403     /* The offset we leave with is the last one we looked at */
2404     pss->page--;
2405     return pages;
2406 }
2407 
2408 /**
2409  * ram_find_and_save_block: finds a dirty page and sends it to f
2410  *
2411  * Called within an RCU critical section.
2412  *
2413  * Returns the number of pages written where zero means no dirty pages,
2414  * or negative on error
2415  *
2416  * @rs: current RAM state
2417  * @last_stage: if we are at the completion stage
2418  *
2419  * On systems where host-page-size > target-page-size it will send all the
2420  * pages in a host page that are dirty.
2421  */
2422 
2423 static int ram_find_and_save_block(RAMState *rs, bool last_stage)
2424 {
2425     PageSearchStatus pss;
2426     int pages = 0;
2427     bool again, found;
2428 
2429     /* No dirty page as there is zero RAM */
2430     if (!ram_bytes_total()) {
2431         return pages;
2432     }
2433 
2434     pss.block = rs->last_seen_block;
2435     pss.page = rs->last_page;
2436     pss.complete_round = false;
2437 
2438     if (!pss.block) {
2439         pss.block = QLIST_FIRST_RCU(&ram_list.blocks);
2440     }
2441 
2442     do {
2443         again = true;
2444         found = get_queued_page(rs, &pss);
2445 
2446         if (!found) {
2447             /* priority queue empty, so just search for something dirty */
2448             found = find_dirty_block(rs, &pss, &again);
2449         }
2450 
2451         if (found) {
2452             pages = ram_save_host_page(rs, &pss, last_stage);
2453         }
2454     } while (!pages && again);
2455 
2456     rs->last_seen_block = pss.block;
2457     rs->last_page = pss.page;
2458 
2459     return pages;
2460 }
2461 
2462 void acct_update_position(QEMUFile *f, size_t size, bool zero)
2463 {
2464     uint64_t pages = size / TARGET_PAGE_SIZE;
2465 
2466     if (zero) {
2467         ram_counters.duplicate += pages;
2468     } else {
2469         ram_counters.normal += pages;
2470         ram_counters.transferred += size;
2471         qemu_update_position(f, size);
2472     }
2473 }
2474 
2475 uint64_t ram_bytes_total(void)
2476 {
2477     RAMBlock *block;
2478     uint64_t total = 0;
2479 
2480     rcu_read_lock();
2481     RAMBLOCK_FOREACH_MIGRATABLE(block) {
2482         total += block->used_length;
2483     }
2484     rcu_read_unlock();
2485     return total;
2486 }
2487 
2488 static void xbzrle_load_setup(void)
2489 {
2490     XBZRLE.decoded_buf = g_malloc(TARGET_PAGE_SIZE);
2491 }
2492 
2493 static void xbzrle_load_cleanup(void)
2494 {
2495     g_free(XBZRLE.decoded_buf);
2496     XBZRLE.decoded_buf = NULL;
2497 }
2498 
2499 static void ram_state_cleanup(RAMState **rsp)
2500 {
2501     if (*rsp) {
2502         migration_page_queue_free(*rsp);
2503         qemu_mutex_destroy(&(*rsp)->bitmap_mutex);
2504         qemu_mutex_destroy(&(*rsp)->src_page_req_mutex);
2505         g_free(*rsp);
2506         *rsp = NULL;
2507     }
2508 }
2509 
2510 static void xbzrle_cleanup(void)
2511 {
2512     XBZRLE_cache_lock();
2513     if (XBZRLE.cache) {
2514         cache_fini(XBZRLE.cache);
2515         g_free(XBZRLE.encoded_buf);
2516         g_free(XBZRLE.current_buf);
2517         g_free(XBZRLE.zero_target_page);
2518         XBZRLE.cache = NULL;
2519         XBZRLE.encoded_buf = NULL;
2520         XBZRLE.current_buf = NULL;
2521         XBZRLE.zero_target_page = NULL;
2522     }
2523     XBZRLE_cache_unlock();
2524 }
2525 
2526 static void ram_save_cleanup(void *opaque)
2527 {
2528     RAMState **rsp = opaque;
2529     RAMBlock *block;
2530 
2531     /* caller have hold iothread lock or is in a bh, so there is
2532      * no writing race against this migration_bitmap
2533      */
2534     memory_global_dirty_log_stop();
2535 
2536     RAMBLOCK_FOREACH_MIGRATABLE(block) {
2537         g_free(block->bmap);
2538         block->bmap = NULL;
2539         g_free(block->unsentmap);
2540         block->unsentmap = NULL;
2541     }
2542 
2543     xbzrle_cleanup();
2544     compress_threads_save_cleanup();
2545     ram_state_cleanup(rsp);
2546 }
2547 
2548 static void ram_state_reset(RAMState *rs)
2549 {
2550     rs->last_seen_block = NULL;
2551     rs->last_sent_block = NULL;
2552     rs->last_page = 0;
2553     rs->last_version = ram_list.version;
2554     rs->ram_bulk_stage = true;
2555 }
2556 
2557 #define MAX_WAIT 50 /* ms, half buffered_file limit */
2558 
2559 /*
2560  * 'expected' is the value you expect the bitmap mostly to be full
2561  * of; it won't bother printing lines that are all this value.
2562  * If 'todump' is null the migration bitmap is dumped.
2563  */
2564 void ram_debug_dump_bitmap(unsigned long *todump, bool expected,
2565                            unsigned long pages)
2566 {
2567     int64_t cur;
2568     int64_t linelen = 128;
2569     char linebuf[129];
2570 
2571     for (cur = 0; cur < pages; cur += linelen) {
2572         int64_t curb;
2573         bool found = false;
2574         /*
2575          * Last line; catch the case where the line length
2576          * is longer than remaining ram
2577          */
2578         if (cur + linelen > pages) {
2579             linelen = pages - cur;
2580         }
2581         for (curb = 0; curb < linelen; curb++) {
2582             bool thisbit = test_bit(cur + curb, todump);
2583             linebuf[curb] = thisbit ? '1' : '.';
2584             found = found || (thisbit != expected);
2585         }
2586         if (found) {
2587             linebuf[curb] = '\0';
2588             fprintf(stderr,  "0x%08" PRIx64 " : %s\n", cur, linebuf);
2589         }
2590     }
2591 }
2592 
2593 /* **** functions for postcopy ***** */
2594 
2595 void ram_postcopy_migrated_memory_release(MigrationState *ms)
2596 {
2597     struct RAMBlock *block;
2598 
2599     RAMBLOCK_FOREACH_MIGRATABLE(block) {
2600         unsigned long *bitmap = block->bmap;
2601         unsigned long range = block->used_length >> TARGET_PAGE_BITS;
2602         unsigned long run_start = find_next_zero_bit(bitmap, range, 0);
2603 
2604         while (run_start < range) {
2605             unsigned long run_end = find_next_bit(bitmap, range, run_start + 1);
2606             ram_discard_range(block->idstr, run_start << TARGET_PAGE_BITS,
2607                               (run_end - run_start) << TARGET_PAGE_BITS);
2608             run_start = find_next_zero_bit(bitmap, range, run_end + 1);
2609         }
2610     }
2611 }
2612 
2613 /**
2614  * postcopy_send_discard_bm_ram: discard a RAMBlock
2615  *
2616  * Returns zero on success
2617  *
2618  * Callback from postcopy_each_ram_send_discard for each RAMBlock
2619  * Note: At this point the 'unsentmap' is the processed bitmap combined
2620  *       with the dirtymap; so a '1' means it's either dirty or unsent.
2621  *
2622  * @ms: current migration state
2623  * @pds: state for postcopy
2624  * @start: RAMBlock starting page
2625  * @length: RAMBlock size
2626  */
2627 static int postcopy_send_discard_bm_ram(MigrationState *ms,
2628                                         PostcopyDiscardState *pds,
2629                                         RAMBlock *block)
2630 {
2631     unsigned long end = block->used_length >> TARGET_PAGE_BITS;
2632     unsigned long current;
2633     unsigned long *unsentmap = block->unsentmap;
2634 
2635     for (current = 0; current < end; ) {
2636         unsigned long one = find_next_bit(unsentmap, end, current);
2637 
2638         if (one <= end) {
2639             unsigned long zero = find_next_zero_bit(unsentmap, end, one + 1);
2640             unsigned long discard_length;
2641 
2642             if (zero >= end) {
2643                 discard_length = end - one;
2644             } else {
2645                 discard_length = zero - one;
2646             }
2647             if (discard_length) {
2648                 postcopy_discard_send_range(ms, pds, one, discard_length);
2649             }
2650             current = one + discard_length;
2651         } else {
2652             current = one;
2653         }
2654     }
2655 
2656     return 0;
2657 }
2658 
2659 /**
2660  * postcopy_each_ram_send_discard: discard all RAMBlocks
2661  *
2662  * Returns 0 for success or negative for error
2663  *
2664  * Utility for the outgoing postcopy code.
2665  *   Calls postcopy_send_discard_bm_ram for each RAMBlock
2666  *   passing it bitmap indexes and name.
2667  * (qemu_ram_foreach_block ends up passing unscaled lengths
2668  *  which would mean postcopy code would have to deal with target page)
2669  *
2670  * @ms: current migration state
2671  */
2672 static int postcopy_each_ram_send_discard(MigrationState *ms)
2673 {
2674     struct RAMBlock *block;
2675     int ret;
2676 
2677     RAMBLOCK_FOREACH_MIGRATABLE(block) {
2678         PostcopyDiscardState *pds =
2679             postcopy_discard_send_init(ms, block->idstr);
2680 
2681         /*
2682          * Postcopy sends chunks of bitmap over the wire, but it
2683          * just needs indexes at this point, avoids it having
2684          * target page specific code.
2685          */
2686         ret = postcopy_send_discard_bm_ram(ms, pds, block);
2687         postcopy_discard_send_finish(ms, pds);
2688         if (ret) {
2689             return ret;
2690         }
2691     }
2692 
2693     return 0;
2694 }
2695 
2696 /**
2697  * postcopy_chunk_hostpages_pass: canocalize bitmap in hostpages
2698  *
2699  * Helper for postcopy_chunk_hostpages; it's called twice to
2700  * canonicalize the two bitmaps, that are similar, but one is
2701  * inverted.
2702  *
2703  * Postcopy requires that all target pages in a hostpage are dirty or
2704  * clean, not a mix.  This function canonicalizes the bitmaps.
2705  *
2706  * @ms: current migration state
2707  * @unsent_pass: if true we need to canonicalize partially unsent host pages
2708  *               otherwise we need to canonicalize partially dirty host pages
2709  * @block: block that contains the page we want to canonicalize
2710  * @pds: state for postcopy
2711  */
2712 static void postcopy_chunk_hostpages_pass(MigrationState *ms, bool unsent_pass,
2713                                           RAMBlock *block,
2714                                           PostcopyDiscardState *pds)
2715 {
2716     RAMState *rs = ram_state;
2717     unsigned long *bitmap = block->bmap;
2718     unsigned long *unsentmap = block->unsentmap;
2719     unsigned int host_ratio = block->page_size / TARGET_PAGE_SIZE;
2720     unsigned long pages = block->used_length >> TARGET_PAGE_BITS;
2721     unsigned long run_start;
2722 
2723     if (block->page_size == TARGET_PAGE_SIZE) {
2724         /* Easy case - TPS==HPS for a non-huge page RAMBlock */
2725         return;
2726     }
2727 
2728     if (unsent_pass) {
2729         /* Find a sent page */
2730         run_start = find_next_zero_bit(unsentmap, pages, 0);
2731     } else {
2732         /* Find a dirty page */
2733         run_start = find_next_bit(bitmap, pages, 0);
2734     }
2735 
2736     while (run_start < pages) {
2737         bool do_fixup = false;
2738         unsigned long fixup_start_addr;
2739         unsigned long host_offset;
2740 
2741         /*
2742          * If the start of this run of pages is in the middle of a host
2743          * page, then we need to fixup this host page.
2744          */
2745         host_offset = run_start % host_ratio;
2746         if (host_offset) {
2747             do_fixup = true;
2748             run_start -= host_offset;
2749             fixup_start_addr = run_start;
2750             /* For the next pass */
2751             run_start = run_start + host_ratio;
2752         } else {
2753             /* Find the end of this run */
2754             unsigned long run_end;
2755             if (unsent_pass) {
2756                 run_end = find_next_bit(unsentmap, pages, run_start + 1);
2757             } else {
2758                 run_end = find_next_zero_bit(bitmap, pages, run_start + 1);
2759             }
2760             /*
2761              * If the end isn't at the start of a host page, then the
2762              * run doesn't finish at the end of a host page
2763              * and we need to discard.
2764              */
2765             host_offset = run_end % host_ratio;
2766             if (host_offset) {
2767                 do_fixup = true;
2768                 fixup_start_addr = run_end - host_offset;
2769                 /*
2770                  * This host page has gone, the next loop iteration starts
2771                  * from after the fixup
2772                  */
2773                 run_start = fixup_start_addr + host_ratio;
2774             } else {
2775                 /*
2776                  * No discards on this iteration, next loop starts from
2777                  * next sent/dirty page
2778                  */
2779                 run_start = run_end + 1;
2780             }
2781         }
2782 
2783         if (do_fixup) {
2784             unsigned long page;
2785 
2786             /* Tell the destination to discard this page */
2787             if (unsent_pass || !test_bit(fixup_start_addr, unsentmap)) {
2788                 /* For the unsent_pass we:
2789                  *     discard partially sent pages
2790                  * For the !unsent_pass (dirty) we:
2791                  *     discard partially dirty pages that were sent
2792                  *     (any partially sent pages were already discarded
2793                  *     by the previous unsent_pass)
2794                  */
2795                 postcopy_discard_send_range(ms, pds, fixup_start_addr,
2796                                             host_ratio);
2797             }
2798 
2799             /* Clean up the bitmap */
2800             for (page = fixup_start_addr;
2801                  page < fixup_start_addr + host_ratio; page++) {
2802                 /* All pages in this host page are now not sent */
2803                 set_bit(page, unsentmap);
2804 
2805                 /*
2806                  * Remark them as dirty, updating the count for any pages
2807                  * that weren't previously dirty.
2808                  */
2809                 rs->migration_dirty_pages += !test_and_set_bit(page, bitmap);
2810             }
2811         }
2812 
2813         if (unsent_pass) {
2814             /* Find the next sent page for the next iteration */
2815             run_start = find_next_zero_bit(unsentmap, pages, run_start);
2816         } else {
2817             /* Find the next dirty page for the next iteration */
2818             run_start = find_next_bit(bitmap, pages, run_start);
2819         }
2820     }
2821 }
2822 
2823 /**
2824  * postcopy_chuck_hostpages: discrad any partially sent host page
2825  *
2826  * Utility for the outgoing postcopy code.
2827  *
2828  * Discard any partially sent host-page size chunks, mark any partially
2829  * dirty host-page size chunks as all dirty.  In this case the host-page
2830  * is the host-page for the particular RAMBlock, i.e. it might be a huge page
2831  *
2832  * Returns zero on success
2833  *
2834  * @ms: current migration state
2835  * @block: block we want to work with
2836  */
2837 static int postcopy_chunk_hostpages(MigrationState *ms, RAMBlock *block)
2838 {
2839     PostcopyDiscardState *pds =
2840         postcopy_discard_send_init(ms, block->idstr);
2841 
2842     /* First pass: Discard all partially sent host pages */
2843     postcopy_chunk_hostpages_pass(ms, true, block, pds);
2844     /*
2845      * Second pass: Ensure that all partially dirty host pages are made
2846      * fully dirty.
2847      */
2848     postcopy_chunk_hostpages_pass(ms, false, block, pds);
2849 
2850     postcopy_discard_send_finish(ms, pds);
2851     return 0;
2852 }
2853 
2854 /**
2855  * ram_postcopy_send_discard_bitmap: transmit the discard bitmap
2856  *
2857  * Returns zero on success
2858  *
2859  * Transmit the set of pages to be discarded after precopy to the target
2860  * these are pages that:
2861  *     a) Have been previously transmitted but are now dirty again
2862  *     b) Pages that have never been transmitted, this ensures that
2863  *        any pages on the destination that have been mapped by background
2864  *        tasks get discarded (transparent huge pages is the specific concern)
2865  * Hopefully this is pretty sparse
2866  *
2867  * @ms: current migration state
2868  */
2869 int ram_postcopy_send_discard_bitmap(MigrationState *ms)
2870 {
2871     RAMState *rs = ram_state;
2872     RAMBlock *block;
2873     int ret;
2874 
2875     rcu_read_lock();
2876 
2877     /* This should be our last sync, the src is now paused */
2878     migration_bitmap_sync(rs);
2879 
2880     /* Easiest way to make sure we don't resume in the middle of a host-page */
2881     rs->last_seen_block = NULL;
2882     rs->last_sent_block = NULL;
2883     rs->last_page = 0;
2884 
2885     RAMBLOCK_FOREACH_MIGRATABLE(block) {
2886         unsigned long pages = block->used_length >> TARGET_PAGE_BITS;
2887         unsigned long *bitmap = block->bmap;
2888         unsigned long *unsentmap = block->unsentmap;
2889 
2890         if (!unsentmap) {
2891             /* We don't have a safe way to resize the sentmap, so
2892              * if the bitmap was resized it will be NULL at this
2893              * point.
2894              */
2895             error_report("migration ram resized during precopy phase");
2896             rcu_read_unlock();
2897             return -EINVAL;
2898         }
2899         /* Deal with TPS != HPS and huge pages */
2900         ret = postcopy_chunk_hostpages(ms, block);
2901         if (ret) {
2902             rcu_read_unlock();
2903             return ret;
2904         }
2905 
2906         /*
2907          * Update the unsentmap to be unsentmap = unsentmap | dirty
2908          */
2909         bitmap_or(unsentmap, unsentmap, bitmap, pages);
2910 #ifdef DEBUG_POSTCOPY
2911         ram_debug_dump_bitmap(unsentmap, true, pages);
2912 #endif
2913     }
2914     trace_ram_postcopy_send_discard_bitmap();
2915 
2916     ret = postcopy_each_ram_send_discard(ms);
2917     rcu_read_unlock();
2918 
2919     return ret;
2920 }
2921 
2922 /**
2923  * ram_discard_range: discard dirtied pages at the beginning of postcopy
2924  *
2925  * Returns zero on success
2926  *
2927  * @rbname: name of the RAMBlock of the request. NULL means the
2928  *          same that last one.
2929  * @start: RAMBlock starting page
2930  * @length: RAMBlock size
2931  */
2932 int ram_discard_range(const char *rbname, uint64_t start, size_t length)
2933 {
2934     int ret = -1;
2935 
2936     trace_ram_discard_range(rbname, start, length);
2937 
2938     rcu_read_lock();
2939     RAMBlock *rb = qemu_ram_block_by_name(rbname);
2940 
2941     if (!rb) {
2942         error_report("ram_discard_range: Failed to find block '%s'", rbname);
2943         goto err;
2944     }
2945 
2946     /*
2947      * On source VM, we don't need to update the received bitmap since
2948      * we don't even have one.
2949      */
2950     if (rb->receivedmap) {
2951         bitmap_clear(rb->receivedmap, start >> qemu_target_page_bits(),
2952                      length >> qemu_target_page_bits());
2953     }
2954 
2955     ret = ram_block_discard_range(rb, start, length);
2956 
2957 err:
2958     rcu_read_unlock();
2959 
2960     return ret;
2961 }
2962 
2963 /*
2964  * For every allocation, we will try not to crash the VM if the
2965  * allocation failed.
2966  */
2967 static int xbzrle_init(void)
2968 {
2969     Error *local_err = NULL;
2970 
2971     if (!migrate_use_xbzrle()) {
2972         return 0;
2973     }
2974 
2975     XBZRLE_cache_lock();
2976 
2977     XBZRLE.zero_target_page = g_try_malloc0(TARGET_PAGE_SIZE);
2978     if (!XBZRLE.zero_target_page) {
2979         error_report("%s: Error allocating zero page", __func__);
2980         goto err_out;
2981     }
2982 
2983     XBZRLE.cache = cache_init(migrate_xbzrle_cache_size(),
2984                               TARGET_PAGE_SIZE, &local_err);
2985     if (!XBZRLE.cache) {
2986         error_report_err(local_err);
2987         goto free_zero_page;
2988     }
2989 
2990     XBZRLE.encoded_buf = g_try_malloc0(TARGET_PAGE_SIZE);
2991     if (!XBZRLE.encoded_buf) {
2992         error_report("%s: Error allocating encoded_buf", __func__);
2993         goto free_cache;
2994     }
2995 
2996     XBZRLE.current_buf = g_try_malloc(TARGET_PAGE_SIZE);
2997     if (!XBZRLE.current_buf) {
2998         error_report("%s: Error allocating current_buf", __func__);
2999         goto free_encoded_buf;
3000     }
3001 
3002     /* We are all good */
3003     XBZRLE_cache_unlock();
3004     return 0;
3005 
3006 free_encoded_buf:
3007     g_free(XBZRLE.encoded_buf);
3008     XBZRLE.encoded_buf = NULL;
3009 free_cache:
3010     cache_fini(XBZRLE.cache);
3011     XBZRLE.cache = NULL;
3012 free_zero_page:
3013     g_free(XBZRLE.zero_target_page);
3014     XBZRLE.zero_target_page = NULL;
3015 err_out:
3016     XBZRLE_cache_unlock();
3017     return -ENOMEM;
3018 }
3019 
3020 static int ram_state_init(RAMState **rsp)
3021 {
3022     *rsp = g_try_new0(RAMState, 1);
3023 
3024     if (!*rsp) {
3025         error_report("%s: Init ramstate fail", __func__);
3026         return -1;
3027     }
3028 
3029     qemu_mutex_init(&(*rsp)->bitmap_mutex);
3030     qemu_mutex_init(&(*rsp)->src_page_req_mutex);
3031     QSIMPLEQ_INIT(&(*rsp)->src_page_requests);
3032 
3033     /*
3034      * Count the total number of pages used by ram blocks not including any
3035      * gaps due to alignment or unplugs.
3036      */
3037     (*rsp)->migration_dirty_pages = ram_bytes_total() >> TARGET_PAGE_BITS;
3038 
3039     ram_state_reset(*rsp);
3040 
3041     return 0;
3042 }
3043 
3044 static void ram_list_init_bitmaps(void)
3045 {
3046     RAMBlock *block;
3047     unsigned long pages;
3048 
3049     /* Skip setting bitmap if there is no RAM */
3050     if (ram_bytes_total()) {
3051         RAMBLOCK_FOREACH_MIGRATABLE(block) {
3052             pages = block->max_length >> TARGET_PAGE_BITS;
3053             block->bmap = bitmap_new(pages);
3054             bitmap_set(block->bmap, 0, pages);
3055             if (migrate_postcopy_ram()) {
3056                 block->unsentmap = bitmap_new(pages);
3057                 bitmap_set(block->unsentmap, 0, pages);
3058             }
3059         }
3060     }
3061 }
3062 
3063 static void ram_init_bitmaps(RAMState *rs)
3064 {
3065     /* For memory_global_dirty_log_start below.  */
3066     qemu_mutex_lock_iothread();
3067     qemu_mutex_lock_ramlist();
3068     rcu_read_lock();
3069 
3070     ram_list_init_bitmaps();
3071     memory_global_dirty_log_start();
3072     migration_bitmap_sync(rs);
3073 
3074     rcu_read_unlock();
3075     qemu_mutex_unlock_ramlist();
3076     qemu_mutex_unlock_iothread();
3077 }
3078 
3079 static int ram_init_all(RAMState **rsp)
3080 {
3081     if (ram_state_init(rsp)) {
3082         return -1;
3083     }
3084 
3085     if (xbzrle_init()) {
3086         ram_state_cleanup(rsp);
3087         return -1;
3088     }
3089 
3090     ram_init_bitmaps(*rsp);
3091 
3092     return 0;
3093 }
3094 
3095 static void ram_state_resume_prepare(RAMState *rs, QEMUFile *out)
3096 {
3097     RAMBlock *block;
3098     uint64_t pages = 0;
3099 
3100     /*
3101      * Postcopy is not using xbzrle/compression, so no need for that.
3102      * Also, since source are already halted, we don't need to care
3103      * about dirty page logging as well.
3104      */
3105 
3106     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3107         pages += bitmap_count_one(block->bmap,
3108                                   block->used_length >> TARGET_PAGE_BITS);
3109     }
3110 
3111     /* This may not be aligned with current bitmaps. Recalculate. */
3112     rs->migration_dirty_pages = pages;
3113 
3114     rs->last_seen_block = NULL;
3115     rs->last_sent_block = NULL;
3116     rs->last_page = 0;
3117     rs->last_version = ram_list.version;
3118     /*
3119      * Disable the bulk stage, otherwise we'll resend the whole RAM no
3120      * matter what we have sent.
3121      */
3122     rs->ram_bulk_stage = false;
3123 
3124     /* Update RAMState cache of output QEMUFile */
3125     rs->f = out;
3126 
3127     trace_ram_state_resume_prepare(pages);
3128 }
3129 
3130 /*
3131  * Each of ram_save_setup, ram_save_iterate and ram_save_complete has
3132  * long-running RCU critical section.  When rcu-reclaims in the code
3133  * start to become numerous it will be necessary to reduce the
3134  * granularity of these critical sections.
3135  */
3136 
3137 /**
3138  * ram_save_setup: Setup RAM for migration
3139  *
3140  * Returns zero to indicate success and negative for error
3141  *
3142  * @f: QEMUFile where to send the data
3143  * @opaque: RAMState pointer
3144  */
3145 static int ram_save_setup(QEMUFile *f, void *opaque)
3146 {
3147     RAMState **rsp = opaque;
3148     RAMBlock *block;
3149 
3150     if (compress_threads_save_setup()) {
3151         return -1;
3152     }
3153 
3154     /* migration has already setup the bitmap, reuse it. */
3155     if (!migration_in_colo_state()) {
3156         if (ram_init_all(rsp) != 0) {
3157             compress_threads_save_cleanup();
3158             return -1;
3159         }
3160     }
3161     (*rsp)->f = f;
3162 
3163     rcu_read_lock();
3164 
3165     qemu_put_be64(f, ram_bytes_total() | RAM_SAVE_FLAG_MEM_SIZE);
3166 
3167     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3168         qemu_put_byte(f, strlen(block->idstr));
3169         qemu_put_buffer(f, (uint8_t *)block->idstr, strlen(block->idstr));
3170         qemu_put_be64(f, block->used_length);
3171         if (migrate_postcopy_ram() && block->page_size != qemu_host_page_size) {
3172             qemu_put_be64(f, block->page_size);
3173         }
3174     }
3175 
3176     rcu_read_unlock();
3177 
3178     ram_control_before_iterate(f, RAM_CONTROL_SETUP);
3179     ram_control_after_iterate(f, RAM_CONTROL_SETUP);
3180 
3181     multifd_send_sync_main();
3182     qemu_put_be64(f, RAM_SAVE_FLAG_EOS);
3183     qemu_fflush(f);
3184 
3185     return 0;
3186 }
3187 
3188 /**
3189  * ram_save_iterate: iterative stage for migration
3190  *
3191  * Returns zero to indicate success and negative for error
3192  *
3193  * @f: QEMUFile where to send the data
3194  * @opaque: RAMState pointer
3195  */
3196 static int ram_save_iterate(QEMUFile *f, void *opaque)
3197 {
3198     RAMState **temp = opaque;
3199     RAMState *rs = *temp;
3200     int ret;
3201     int i;
3202     int64_t t0;
3203     int done = 0;
3204 
3205     if (blk_mig_bulk_active()) {
3206         /* Avoid transferring ram during bulk phase of block migration as
3207          * the bulk phase will usually take a long time and transferring
3208          * ram updates during that time is pointless. */
3209         goto out;
3210     }
3211 
3212     rcu_read_lock();
3213     if (ram_list.version != rs->last_version) {
3214         ram_state_reset(rs);
3215     }
3216 
3217     /* Read version before ram_list.blocks */
3218     smp_rmb();
3219 
3220     ram_control_before_iterate(f, RAM_CONTROL_ROUND);
3221 
3222     t0 = qemu_clock_get_ns(QEMU_CLOCK_REALTIME);
3223     i = 0;
3224     while ((ret = qemu_file_rate_limit(f)) == 0 ||
3225             !QSIMPLEQ_EMPTY(&rs->src_page_requests)) {
3226         int pages;
3227 
3228         if (qemu_file_get_error(f)) {
3229             break;
3230         }
3231 
3232         pages = ram_find_and_save_block(rs, false);
3233         /* no more pages to sent */
3234         if (pages == 0) {
3235             done = 1;
3236             break;
3237         }
3238 
3239         if (pages < 0) {
3240             qemu_file_set_error(f, pages);
3241             break;
3242         }
3243 
3244         rs->target_page_count += pages;
3245 
3246         /* we want to check in the 1st loop, just in case it was the 1st time
3247            and we had to sync the dirty bitmap.
3248            qemu_get_clock_ns() is a bit expensive, so we only check each some
3249            iterations
3250         */
3251         if ((i & 63) == 0) {
3252             uint64_t t1 = (qemu_clock_get_ns(QEMU_CLOCK_REALTIME) - t0) / 1000000;
3253             if (t1 > MAX_WAIT) {
3254                 trace_ram_save_iterate_big_wait(t1, i);
3255                 break;
3256             }
3257         }
3258         i++;
3259     }
3260     rcu_read_unlock();
3261 
3262     /*
3263      * Must occur before EOS (or any QEMUFile operation)
3264      * because of RDMA protocol.
3265      */
3266     ram_control_after_iterate(f, RAM_CONTROL_ROUND);
3267 
3268     multifd_send_sync_main();
3269 out:
3270     qemu_put_be64(f, RAM_SAVE_FLAG_EOS);
3271     qemu_fflush(f);
3272     ram_counters.transferred += 8;
3273 
3274     ret = qemu_file_get_error(f);
3275     if (ret < 0) {
3276         return ret;
3277     }
3278 
3279     return done;
3280 }
3281 
3282 /**
3283  * ram_save_complete: function called to send the remaining amount of ram
3284  *
3285  * Returns zero to indicate success or negative on error
3286  *
3287  * Called with iothread lock
3288  *
3289  * @f: QEMUFile where to send the data
3290  * @opaque: RAMState pointer
3291  */
3292 static int ram_save_complete(QEMUFile *f, void *opaque)
3293 {
3294     RAMState **temp = opaque;
3295     RAMState *rs = *temp;
3296     int ret = 0;
3297 
3298     rcu_read_lock();
3299 
3300     if (!migration_in_postcopy()) {
3301         migration_bitmap_sync(rs);
3302     }
3303 
3304     ram_control_before_iterate(f, RAM_CONTROL_FINISH);
3305 
3306     /* try transferring iterative blocks of memory */
3307 
3308     /* flush all remaining blocks regardless of rate limiting */
3309     while (true) {
3310         int pages;
3311 
3312         pages = ram_find_and_save_block(rs, !migration_in_colo_state());
3313         /* no more blocks to sent */
3314         if (pages == 0) {
3315             break;
3316         }
3317         if (pages < 0) {
3318             ret = pages;
3319             break;
3320         }
3321     }
3322 
3323     flush_compressed_data(rs);
3324     ram_control_after_iterate(f, RAM_CONTROL_FINISH);
3325 
3326     rcu_read_unlock();
3327 
3328     multifd_send_sync_main();
3329     qemu_put_be64(f, RAM_SAVE_FLAG_EOS);
3330     qemu_fflush(f);
3331 
3332     return ret;
3333 }
3334 
3335 static void ram_save_pending(QEMUFile *f, void *opaque, uint64_t max_size,
3336                              uint64_t *res_precopy_only,
3337                              uint64_t *res_compatible,
3338                              uint64_t *res_postcopy_only)
3339 {
3340     RAMState **temp = opaque;
3341     RAMState *rs = *temp;
3342     uint64_t remaining_size;
3343 
3344     remaining_size = rs->migration_dirty_pages * TARGET_PAGE_SIZE;
3345 
3346     if (!migration_in_postcopy() &&
3347         remaining_size < max_size) {
3348         qemu_mutex_lock_iothread();
3349         rcu_read_lock();
3350         migration_bitmap_sync(rs);
3351         rcu_read_unlock();
3352         qemu_mutex_unlock_iothread();
3353         remaining_size = rs->migration_dirty_pages * TARGET_PAGE_SIZE;
3354     }
3355 
3356     if (migrate_postcopy_ram()) {
3357         /* We can do postcopy, and all the data is postcopiable */
3358         *res_compatible += remaining_size;
3359     } else {
3360         *res_precopy_only += remaining_size;
3361     }
3362 }
3363 
3364 static int load_xbzrle(QEMUFile *f, ram_addr_t addr, void *host)
3365 {
3366     unsigned int xh_len;
3367     int xh_flags;
3368     uint8_t *loaded_data;
3369 
3370     /* extract RLE header */
3371     xh_flags = qemu_get_byte(f);
3372     xh_len = qemu_get_be16(f);
3373 
3374     if (xh_flags != ENCODING_FLAG_XBZRLE) {
3375         error_report("Failed to load XBZRLE page - wrong compression!");
3376         return -1;
3377     }
3378 
3379     if (xh_len > TARGET_PAGE_SIZE) {
3380         error_report("Failed to load XBZRLE page - len overflow!");
3381         return -1;
3382     }
3383     loaded_data = XBZRLE.decoded_buf;
3384     /* load data and decode */
3385     /* it can change loaded_data to point to an internal buffer */
3386     qemu_get_buffer_in_place(f, &loaded_data, xh_len);
3387 
3388     /* decode RLE */
3389     if (xbzrle_decode_buffer(loaded_data, xh_len, host,
3390                              TARGET_PAGE_SIZE) == -1) {
3391         error_report("Failed to load XBZRLE page - decode error!");
3392         return -1;
3393     }
3394 
3395     return 0;
3396 }
3397 
3398 /**
3399  * ram_block_from_stream: read a RAMBlock id from the migration stream
3400  *
3401  * Must be called from within a rcu critical section.
3402  *
3403  * Returns a pointer from within the RCU-protected ram_list.
3404  *
3405  * @f: QEMUFile where to read the data from
3406  * @flags: Page flags (mostly to see if it's a continuation of previous block)
3407  */
3408 static inline RAMBlock *ram_block_from_stream(QEMUFile *f, int flags)
3409 {
3410     static RAMBlock *block = NULL;
3411     char id[256];
3412     uint8_t len;
3413 
3414     if (flags & RAM_SAVE_FLAG_CONTINUE) {
3415         if (!block) {
3416             error_report("Ack, bad migration stream!");
3417             return NULL;
3418         }
3419         return block;
3420     }
3421 
3422     len = qemu_get_byte(f);
3423     qemu_get_buffer(f, (uint8_t *)id, len);
3424     id[len] = 0;
3425 
3426     block = qemu_ram_block_by_name(id);
3427     if (!block) {
3428         error_report("Can't find block %s", id);
3429         return NULL;
3430     }
3431 
3432     if (!qemu_ram_is_migratable(block)) {
3433         error_report("block %s should not be migrated !", id);
3434         return NULL;
3435     }
3436 
3437     return block;
3438 }
3439 
3440 static inline void *host_from_ram_block_offset(RAMBlock *block,
3441                                                ram_addr_t offset)
3442 {
3443     if (!offset_in_ramblock(block, offset)) {
3444         return NULL;
3445     }
3446 
3447     return block->host + offset;
3448 }
3449 
3450 static inline void *colo_cache_from_block_offset(RAMBlock *block,
3451                                                  ram_addr_t offset)
3452 {
3453     if (!offset_in_ramblock(block, offset)) {
3454         return NULL;
3455     }
3456     if (!block->colo_cache) {
3457         error_report("%s: colo_cache is NULL in block :%s",
3458                      __func__, block->idstr);
3459         return NULL;
3460     }
3461 
3462     /*
3463     * During colo checkpoint, we need bitmap of these migrated pages.
3464     * It help us to decide which pages in ram cache should be flushed
3465     * into VM's RAM later.
3466     */
3467     if (!test_and_set_bit(offset >> TARGET_PAGE_BITS, block->bmap)) {
3468         ram_state->migration_dirty_pages++;
3469     }
3470     return block->colo_cache + offset;
3471 }
3472 
3473 /**
3474  * ram_handle_compressed: handle the zero page case
3475  *
3476  * If a page (or a whole RDMA chunk) has been
3477  * determined to be zero, then zap it.
3478  *
3479  * @host: host address for the zero page
3480  * @ch: what the page is filled from.  We only support zero
3481  * @size: size of the zero page
3482  */
3483 void ram_handle_compressed(void *host, uint8_t ch, uint64_t size)
3484 {
3485     if (ch != 0 || !is_zero_range(host, size)) {
3486         memset(host, ch, size);
3487     }
3488 }
3489 
3490 /* return the size after decompression, or negative value on error */
3491 static int
3492 qemu_uncompress_data(z_stream *stream, uint8_t *dest, size_t dest_len,
3493                      const uint8_t *source, size_t source_len)
3494 {
3495     int err;
3496 
3497     err = inflateReset(stream);
3498     if (err != Z_OK) {
3499         return -1;
3500     }
3501 
3502     stream->avail_in = source_len;
3503     stream->next_in = (uint8_t *)source;
3504     stream->avail_out = dest_len;
3505     stream->next_out = dest;
3506 
3507     err = inflate(stream, Z_NO_FLUSH);
3508     if (err != Z_STREAM_END) {
3509         return -1;
3510     }
3511 
3512     return stream->total_out;
3513 }
3514 
3515 static void *do_data_decompress(void *opaque)
3516 {
3517     DecompressParam *param = opaque;
3518     unsigned long pagesize;
3519     uint8_t *des;
3520     int len, ret;
3521 
3522     qemu_mutex_lock(&param->mutex);
3523     while (!param->quit) {
3524         if (param->des) {
3525             des = param->des;
3526             len = param->len;
3527             param->des = 0;
3528             qemu_mutex_unlock(&param->mutex);
3529 
3530             pagesize = TARGET_PAGE_SIZE;
3531 
3532             ret = qemu_uncompress_data(&param->stream, des, pagesize,
3533                                        param->compbuf, len);
3534             if (ret < 0 && migrate_get_current()->decompress_error_check) {
3535                 error_report("decompress data failed");
3536                 qemu_file_set_error(decomp_file, ret);
3537             }
3538 
3539             qemu_mutex_lock(&decomp_done_lock);
3540             param->done = true;
3541             qemu_cond_signal(&decomp_done_cond);
3542             qemu_mutex_unlock(&decomp_done_lock);
3543 
3544             qemu_mutex_lock(&param->mutex);
3545         } else {
3546             qemu_cond_wait(&param->cond, &param->mutex);
3547         }
3548     }
3549     qemu_mutex_unlock(&param->mutex);
3550 
3551     return NULL;
3552 }
3553 
3554 static int wait_for_decompress_done(void)
3555 {
3556     int idx, thread_count;
3557 
3558     if (!migrate_use_compression()) {
3559         return 0;
3560     }
3561 
3562     thread_count = migrate_decompress_threads();
3563     qemu_mutex_lock(&decomp_done_lock);
3564     for (idx = 0; idx < thread_count; idx++) {
3565         while (!decomp_param[idx].done) {
3566             qemu_cond_wait(&decomp_done_cond, &decomp_done_lock);
3567         }
3568     }
3569     qemu_mutex_unlock(&decomp_done_lock);
3570     return qemu_file_get_error(decomp_file);
3571 }
3572 
3573 static void compress_threads_load_cleanup(void)
3574 {
3575     int i, thread_count;
3576 
3577     if (!migrate_use_compression()) {
3578         return;
3579     }
3580     thread_count = migrate_decompress_threads();
3581     for (i = 0; i < thread_count; i++) {
3582         /*
3583          * we use it as a indicator which shows if the thread is
3584          * properly init'd or not
3585          */
3586         if (!decomp_param[i].compbuf) {
3587             break;
3588         }
3589 
3590         qemu_mutex_lock(&decomp_param[i].mutex);
3591         decomp_param[i].quit = true;
3592         qemu_cond_signal(&decomp_param[i].cond);
3593         qemu_mutex_unlock(&decomp_param[i].mutex);
3594     }
3595     for (i = 0; i < thread_count; i++) {
3596         if (!decomp_param[i].compbuf) {
3597             break;
3598         }
3599 
3600         qemu_thread_join(decompress_threads + i);
3601         qemu_mutex_destroy(&decomp_param[i].mutex);
3602         qemu_cond_destroy(&decomp_param[i].cond);
3603         inflateEnd(&decomp_param[i].stream);
3604         g_free(decomp_param[i].compbuf);
3605         decomp_param[i].compbuf = NULL;
3606     }
3607     g_free(decompress_threads);
3608     g_free(decomp_param);
3609     decompress_threads = NULL;
3610     decomp_param = NULL;
3611     decomp_file = NULL;
3612 }
3613 
3614 static int compress_threads_load_setup(QEMUFile *f)
3615 {
3616     int i, thread_count;
3617 
3618     if (!migrate_use_compression()) {
3619         return 0;
3620     }
3621 
3622     thread_count = migrate_decompress_threads();
3623     decompress_threads = g_new0(QemuThread, thread_count);
3624     decomp_param = g_new0(DecompressParam, thread_count);
3625     qemu_mutex_init(&decomp_done_lock);
3626     qemu_cond_init(&decomp_done_cond);
3627     decomp_file = f;
3628     for (i = 0; i < thread_count; i++) {
3629         if (inflateInit(&decomp_param[i].stream) != Z_OK) {
3630             goto exit;
3631         }
3632 
3633         decomp_param[i].compbuf = g_malloc0(compressBound(TARGET_PAGE_SIZE));
3634         qemu_mutex_init(&decomp_param[i].mutex);
3635         qemu_cond_init(&decomp_param[i].cond);
3636         decomp_param[i].done = true;
3637         decomp_param[i].quit = false;
3638         qemu_thread_create(decompress_threads + i, "decompress",
3639                            do_data_decompress, decomp_param + i,
3640                            QEMU_THREAD_JOINABLE);
3641     }
3642     return 0;
3643 exit:
3644     compress_threads_load_cleanup();
3645     return -1;
3646 }
3647 
3648 static void decompress_data_with_multi_threads(QEMUFile *f,
3649                                                void *host, int len)
3650 {
3651     int idx, thread_count;
3652 
3653     thread_count = migrate_decompress_threads();
3654     qemu_mutex_lock(&decomp_done_lock);
3655     while (true) {
3656         for (idx = 0; idx < thread_count; idx++) {
3657             if (decomp_param[idx].done) {
3658                 decomp_param[idx].done = false;
3659                 qemu_mutex_lock(&decomp_param[idx].mutex);
3660                 qemu_get_buffer(f, decomp_param[idx].compbuf, len);
3661                 decomp_param[idx].des = host;
3662                 decomp_param[idx].len = len;
3663                 qemu_cond_signal(&decomp_param[idx].cond);
3664                 qemu_mutex_unlock(&decomp_param[idx].mutex);
3665                 break;
3666             }
3667         }
3668         if (idx < thread_count) {
3669             break;
3670         } else {
3671             qemu_cond_wait(&decomp_done_cond, &decomp_done_lock);
3672         }
3673     }
3674     qemu_mutex_unlock(&decomp_done_lock);
3675 }
3676 
3677 /*
3678  * colo cache: this is for secondary VM, we cache the whole
3679  * memory of the secondary VM, it is need to hold the global lock
3680  * to call this helper.
3681  */
3682 int colo_init_ram_cache(void)
3683 {
3684     RAMBlock *block;
3685 
3686     rcu_read_lock();
3687     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3688         block->colo_cache = qemu_anon_ram_alloc(block->used_length,
3689                                                 NULL,
3690                                                 false);
3691         if (!block->colo_cache) {
3692             error_report("%s: Can't alloc memory for COLO cache of block %s,"
3693                          "size 0x" RAM_ADDR_FMT, __func__, block->idstr,
3694                          block->used_length);
3695             goto out_locked;
3696         }
3697         memcpy(block->colo_cache, block->host, block->used_length);
3698     }
3699     rcu_read_unlock();
3700     /*
3701     * Record the dirty pages that sent by PVM, we use this dirty bitmap together
3702     * with to decide which page in cache should be flushed into SVM's RAM. Here
3703     * we use the same name 'ram_bitmap' as for migration.
3704     */
3705     if (ram_bytes_total()) {
3706         RAMBlock *block;
3707 
3708         RAMBLOCK_FOREACH_MIGRATABLE(block) {
3709             unsigned long pages = block->max_length >> TARGET_PAGE_BITS;
3710 
3711             block->bmap = bitmap_new(pages);
3712             bitmap_set(block->bmap, 0, pages);
3713         }
3714     }
3715     ram_state = g_new0(RAMState, 1);
3716     ram_state->migration_dirty_pages = 0;
3717     memory_global_dirty_log_start();
3718 
3719     return 0;
3720 
3721 out_locked:
3722 
3723     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3724         if (block->colo_cache) {
3725             qemu_anon_ram_free(block->colo_cache, block->used_length);
3726             block->colo_cache = NULL;
3727         }
3728     }
3729 
3730     rcu_read_unlock();
3731     return -errno;
3732 }
3733 
3734 /* It is need to hold the global lock to call this helper */
3735 void colo_release_ram_cache(void)
3736 {
3737     RAMBlock *block;
3738 
3739     memory_global_dirty_log_stop();
3740     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3741         g_free(block->bmap);
3742         block->bmap = NULL;
3743     }
3744 
3745     rcu_read_lock();
3746 
3747     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3748         if (block->colo_cache) {
3749             qemu_anon_ram_free(block->colo_cache, block->used_length);
3750             block->colo_cache = NULL;
3751         }
3752     }
3753 
3754     rcu_read_unlock();
3755     g_free(ram_state);
3756     ram_state = NULL;
3757 }
3758 
3759 /**
3760  * ram_load_setup: Setup RAM for migration incoming side
3761  *
3762  * Returns zero to indicate success and negative for error
3763  *
3764  * @f: QEMUFile where to receive the data
3765  * @opaque: RAMState pointer
3766  */
3767 static int ram_load_setup(QEMUFile *f, void *opaque)
3768 {
3769     if (compress_threads_load_setup(f)) {
3770         return -1;
3771     }
3772 
3773     xbzrle_load_setup();
3774     ramblock_recv_map_init();
3775 
3776     return 0;
3777 }
3778 
3779 static int ram_load_cleanup(void *opaque)
3780 {
3781     RAMBlock *rb;
3782 
3783     RAMBLOCK_FOREACH_MIGRATABLE(rb) {
3784         if (ramblock_is_pmem(rb)) {
3785             pmem_persist(rb->host, rb->used_length);
3786         }
3787     }
3788 
3789     xbzrle_load_cleanup();
3790     compress_threads_load_cleanup();
3791 
3792     RAMBLOCK_FOREACH_MIGRATABLE(rb) {
3793         g_free(rb->receivedmap);
3794         rb->receivedmap = NULL;
3795     }
3796 
3797     return 0;
3798 }
3799 
3800 /**
3801  * ram_postcopy_incoming_init: allocate postcopy data structures
3802  *
3803  * Returns 0 for success and negative if there was one error
3804  *
3805  * @mis: current migration incoming state
3806  *
3807  * Allocate data structures etc needed by incoming migration with
3808  * postcopy-ram. postcopy-ram's similarly names
3809  * postcopy_ram_incoming_init does the work.
3810  */
3811 int ram_postcopy_incoming_init(MigrationIncomingState *mis)
3812 {
3813     return postcopy_ram_incoming_init(mis);
3814 }
3815 
3816 /**
3817  * ram_load_postcopy: load a page in postcopy case
3818  *
3819  * Returns 0 for success or -errno in case of error
3820  *
3821  * Called in postcopy mode by ram_load().
3822  * rcu_read_lock is taken prior to this being called.
3823  *
3824  * @f: QEMUFile where to send the data
3825  */
3826 static int ram_load_postcopy(QEMUFile *f)
3827 {
3828     int flags = 0, ret = 0;
3829     bool place_needed = false;
3830     bool matches_target_page_size = false;
3831     MigrationIncomingState *mis = migration_incoming_get_current();
3832     /* Temporary page that is later 'placed' */
3833     void *postcopy_host_page = postcopy_get_tmp_page(mis);
3834     void *last_host = NULL;
3835     bool all_zero = false;
3836 
3837     while (!ret && !(flags & RAM_SAVE_FLAG_EOS)) {
3838         ram_addr_t addr;
3839         void *host = NULL;
3840         void *page_buffer = NULL;
3841         void *place_source = NULL;
3842         RAMBlock *block = NULL;
3843         uint8_t ch;
3844 
3845         addr = qemu_get_be64(f);
3846 
3847         /*
3848          * If qemu file error, we should stop here, and then "addr"
3849          * may be invalid
3850          */
3851         ret = qemu_file_get_error(f);
3852         if (ret) {
3853             break;
3854         }
3855 
3856         flags = addr & ~TARGET_PAGE_MASK;
3857         addr &= TARGET_PAGE_MASK;
3858 
3859         trace_ram_load_postcopy_loop((uint64_t)addr, flags);
3860         place_needed = false;
3861         if (flags & (RAM_SAVE_FLAG_ZERO | RAM_SAVE_FLAG_PAGE)) {
3862             block = ram_block_from_stream(f, flags);
3863 
3864             host = host_from_ram_block_offset(block, addr);
3865             if (!host) {
3866                 error_report("Illegal RAM offset " RAM_ADDR_FMT, addr);
3867                 ret = -EINVAL;
3868                 break;
3869             }
3870             matches_target_page_size = block->page_size == TARGET_PAGE_SIZE;
3871             /*
3872              * Postcopy requires that we place whole host pages atomically;
3873              * these may be huge pages for RAMBlocks that are backed by
3874              * hugetlbfs.
3875              * To make it atomic, the data is read into a temporary page
3876              * that's moved into place later.
3877              * The migration protocol uses,  possibly smaller, target-pages
3878              * however the source ensures it always sends all the components
3879              * of a host page in order.
3880              */
3881             page_buffer = postcopy_host_page +
3882                           ((uintptr_t)host & (block->page_size - 1));
3883             /* If all TP are zero then we can optimise the place */
3884             if (!((uintptr_t)host & (block->page_size - 1))) {
3885                 all_zero = true;
3886             } else {
3887                 /* not the 1st TP within the HP */
3888                 if (host != (last_host + TARGET_PAGE_SIZE)) {
3889                     error_report("Non-sequential target page %p/%p",
3890                                   host, last_host);
3891                     ret = -EINVAL;
3892                     break;
3893                 }
3894             }
3895 
3896 
3897             /*
3898              * If it's the last part of a host page then we place the host
3899              * page
3900              */
3901             place_needed = (((uintptr_t)host + TARGET_PAGE_SIZE) &
3902                                      (block->page_size - 1)) == 0;
3903             place_source = postcopy_host_page;
3904         }
3905         last_host = host;
3906 
3907         switch (flags & ~RAM_SAVE_FLAG_CONTINUE) {
3908         case RAM_SAVE_FLAG_ZERO:
3909             ch = qemu_get_byte(f);
3910             memset(page_buffer, ch, TARGET_PAGE_SIZE);
3911             if (ch) {
3912                 all_zero = false;
3913             }
3914             break;
3915 
3916         case RAM_SAVE_FLAG_PAGE:
3917             all_zero = false;
3918             if (!matches_target_page_size) {
3919                 /* For huge pages, we always use temporary buffer */
3920                 qemu_get_buffer(f, page_buffer, TARGET_PAGE_SIZE);
3921             } else {
3922                 /*
3923                  * For small pages that matches target page size, we
3924                  * avoid the qemu_file copy.  Instead we directly use
3925                  * the buffer of QEMUFile to place the page.  Note: we
3926                  * cannot do any QEMUFile operation before using that
3927                  * buffer to make sure the buffer is valid when
3928                  * placing the page.
3929                  */
3930                 qemu_get_buffer_in_place(f, (uint8_t **)&place_source,
3931                                          TARGET_PAGE_SIZE);
3932             }
3933             break;
3934         case RAM_SAVE_FLAG_EOS:
3935             /* normal exit */
3936             multifd_recv_sync_main();
3937             break;
3938         default:
3939             error_report("Unknown combination of migration flags: %#x"
3940                          " (postcopy mode)", flags);
3941             ret = -EINVAL;
3942             break;
3943         }
3944 
3945         /* Detect for any possible file errors */
3946         if (!ret && qemu_file_get_error(f)) {
3947             ret = qemu_file_get_error(f);
3948         }
3949 
3950         if (!ret && place_needed) {
3951             /* This gets called at the last target page in the host page */
3952             void *place_dest = host + TARGET_PAGE_SIZE - block->page_size;
3953 
3954             if (all_zero) {
3955                 ret = postcopy_place_page_zero(mis, place_dest,
3956                                                block);
3957             } else {
3958                 ret = postcopy_place_page(mis, place_dest,
3959                                           place_source, block);
3960             }
3961         }
3962     }
3963 
3964     return ret;
3965 }
3966 
3967 static bool postcopy_is_advised(void)
3968 {
3969     PostcopyState ps = postcopy_state_get();
3970     return ps >= POSTCOPY_INCOMING_ADVISE && ps < POSTCOPY_INCOMING_END;
3971 }
3972 
3973 static bool postcopy_is_running(void)
3974 {
3975     PostcopyState ps = postcopy_state_get();
3976     return ps >= POSTCOPY_INCOMING_LISTENING && ps < POSTCOPY_INCOMING_END;
3977 }
3978 
3979 /*
3980  * Flush content of RAM cache into SVM's memory.
3981  * Only flush the pages that be dirtied by PVM or SVM or both.
3982  */
3983 static void colo_flush_ram_cache(void)
3984 {
3985     RAMBlock *block = NULL;
3986     void *dst_host;
3987     void *src_host;
3988     unsigned long offset = 0;
3989 
3990     memory_global_dirty_log_sync();
3991     rcu_read_lock();
3992     RAMBLOCK_FOREACH_MIGRATABLE(block) {
3993         migration_bitmap_sync_range(ram_state, block, 0, block->used_length);
3994     }
3995     rcu_read_unlock();
3996 
3997     trace_colo_flush_ram_cache_begin(ram_state->migration_dirty_pages);
3998     rcu_read_lock();
3999     block = QLIST_FIRST_RCU(&ram_list.blocks);
4000 
4001     while (block) {
4002         offset = migration_bitmap_find_dirty(ram_state, block, offset);
4003 
4004         if (offset << TARGET_PAGE_BITS >= block->used_length) {
4005             offset = 0;
4006             block = QLIST_NEXT_RCU(block, next);
4007         } else {
4008             migration_bitmap_clear_dirty(ram_state, block, offset);
4009             dst_host = block->host + (offset << TARGET_PAGE_BITS);
4010             src_host = block->colo_cache + (offset << TARGET_PAGE_BITS);
4011             memcpy(dst_host, src_host, TARGET_PAGE_SIZE);
4012         }
4013     }
4014 
4015     rcu_read_unlock();
4016     trace_colo_flush_ram_cache_end();
4017 }
4018 
4019 static int ram_load(QEMUFile *f, void *opaque, int version_id)
4020 {
4021     int flags = 0, ret = 0, invalid_flags = 0;
4022     static uint64_t seq_iter;
4023     int len = 0;
4024     /*
4025      * If system is running in postcopy mode, page inserts to host memory must
4026      * be atomic
4027      */
4028     bool postcopy_running = postcopy_is_running();
4029     /* ADVISE is earlier, it shows the source has the postcopy capability on */
4030     bool postcopy_advised = postcopy_is_advised();
4031 
4032     seq_iter++;
4033 
4034     if (version_id != 4) {
4035         ret = -EINVAL;
4036     }
4037 
4038     if (!migrate_use_compression()) {
4039         invalid_flags |= RAM_SAVE_FLAG_COMPRESS_PAGE;
4040     }
4041     /* This RCU critical section can be very long running.
4042      * When RCU reclaims in the code start to become numerous,
4043      * it will be necessary to reduce the granularity of this
4044      * critical section.
4045      */
4046     rcu_read_lock();
4047 
4048     if (postcopy_running) {
4049         ret = ram_load_postcopy(f);
4050     }
4051 
4052     while (!postcopy_running && !ret && !(flags & RAM_SAVE_FLAG_EOS)) {
4053         ram_addr_t addr, total_ram_bytes;
4054         void *host = NULL;
4055         uint8_t ch;
4056 
4057         addr = qemu_get_be64(f);
4058         flags = addr & ~TARGET_PAGE_MASK;
4059         addr &= TARGET_PAGE_MASK;
4060 
4061         if (flags & invalid_flags) {
4062             if (flags & invalid_flags & RAM_SAVE_FLAG_COMPRESS_PAGE) {
4063                 error_report("Received an unexpected compressed page");
4064             }
4065 
4066             ret = -EINVAL;
4067             break;
4068         }
4069 
4070         if (flags & (RAM_SAVE_FLAG_ZERO | RAM_SAVE_FLAG_PAGE |
4071                      RAM_SAVE_FLAG_COMPRESS_PAGE | RAM_SAVE_FLAG_XBZRLE)) {
4072             RAMBlock *block = ram_block_from_stream(f, flags);
4073 
4074             /*
4075              * After going into COLO, we should load the Page into colo_cache.
4076              */
4077             if (migration_incoming_in_colo_state()) {
4078                 host = colo_cache_from_block_offset(block, addr);
4079             } else {
4080                 host = host_from_ram_block_offset(block, addr);
4081             }
4082             if (!host) {
4083                 error_report("Illegal RAM offset " RAM_ADDR_FMT, addr);
4084                 ret = -EINVAL;
4085                 break;
4086             }
4087 
4088             if (!migration_incoming_in_colo_state()) {
4089                 ramblock_recv_bitmap_set(block, host);
4090             }
4091 
4092             trace_ram_load_loop(block->idstr, (uint64_t)addr, flags, host);
4093         }
4094 
4095         switch (flags & ~RAM_SAVE_FLAG_CONTINUE) {
4096         case RAM_SAVE_FLAG_MEM_SIZE:
4097             /* Synchronize RAM block list */
4098             total_ram_bytes = addr;
4099             while (!ret && total_ram_bytes) {
4100                 RAMBlock *block;
4101                 char id[256];
4102                 ram_addr_t length;
4103 
4104                 len = qemu_get_byte(f);
4105                 qemu_get_buffer(f, (uint8_t *)id, len);
4106                 id[len] = 0;
4107                 length = qemu_get_be64(f);
4108 
4109                 block = qemu_ram_block_by_name(id);
4110                 if (block && !qemu_ram_is_migratable(block)) {
4111                     error_report("block %s should not be migrated !", id);
4112                     ret = -EINVAL;
4113                 } else if (block) {
4114                     if (length != block->used_length) {
4115                         Error *local_err = NULL;
4116 
4117                         ret = qemu_ram_resize(block, length,
4118                                               &local_err);
4119                         if (local_err) {
4120                             error_report_err(local_err);
4121                         }
4122                     }
4123                     /* For postcopy we need to check hugepage sizes match */
4124                     if (postcopy_advised &&
4125                         block->page_size != qemu_host_page_size) {
4126                         uint64_t remote_page_size = qemu_get_be64(f);
4127                         if (remote_page_size != block->page_size) {
4128                             error_report("Mismatched RAM page size %s "
4129                                          "(local) %zd != %" PRId64,
4130                                          id, block->page_size,
4131                                          remote_page_size);
4132                             ret = -EINVAL;
4133                         }
4134                     }
4135                     ram_control_load_hook(f, RAM_CONTROL_BLOCK_REG,
4136                                           block->idstr);
4137                 } else {
4138                     error_report("Unknown ramblock \"%s\", cannot "
4139                                  "accept migration", id);
4140                     ret = -EINVAL;
4141                 }
4142 
4143                 total_ram_bytes -= length;
4144             }
4145             break;
4146 
4147         case RAM_SAVE_FLAG_ZERO:
4148             ch = qemu_get_byte(f);
4149             ram_handle_compressed(host, ch, TARGET_PAGE_SIZE);
4150             break;
4151 
4152         case RAM_SAVE_FLAG_PAGE:
4153             qemu_get_buffer(f, host, TARGET_PAGE_SIZE);
4154             break;
4155 
4156         case RAM_SAVE_FLAG_COMPRESS_PAGE:
4157             len = qemu_get_be32(f);
4158             if (len < 0 || len > compressBound(TARGET_PAGE_SIZE)) {
4159                 error_report("Invalid compressed data length: %d", len);
4160                 ret = -EINVAL;
4161                 break;
4162             }
4163             decompress_data_with_multi_threads(f, host, len);
4164             break;
4165 
4166         case RAM_SAVE_FLAG_XBZRLE:
4167             if (load_xbzrle(f, addr, host) < 0) {
4168                 error_report("Failed to decompress XBZRLE page at "
4169                              RAM_ADDR_FMT, addr);
4170                 ret = -EINVAL;
4171                 break;
4172             }
4173             break;
4174         case RAM_SAVE_FLAG_EOS:
4175             /* normal exit */
4176             multifd_recv_sync_main();
4177             break;
4178         default:
4179             if (flags & RAM_SAVE_FLAG_HOOK) {
4180                 ram_control_load_hook(f, RAM_CONTROL_HOOK, NULL);
4181             } else {
4182                 error_report("Unknown combination of migration flags: %#x",
4183                              flags);
4184                 ret = -EINVAL;
4185             }
4186         }
4187         if (!ret) {
4188             ret = qemu_file_get_error(f);
4189         }
4190     }
4191 
4192     ret |= wait_for_decompress_done();
4193     rcu_read_unlock();
4194     trace_ram_load_complete(ret, seq_iter);
4195 
4196     if (!ret  && migration_incoming_in_colo_state()) {
4197         colo_flush_ram_cache();
4198     }
4199     return ret;
4200 }
4201 
4202 static bool ram_has_postcopy(void *opaque)
4203 {
4204     RAMBlock *rb;
4205     RAMBLOCK_FOREACH_MIGRATABLE(rb) {
4206         if (ramblock_is_pmem(rb)) {
4207             info_report("Block: %s, host: %p is a nvdimm memory, postcopy"
4208                          "is not supported now!", rb->idstr, rb->host);
4209             return false;
4210         }
4211     }
4212 
4213     return migrate_postcopy_ram();
4214 }
4215 
4216 /* Sync all the dirty bitmap with destination VM.  */
4217 static int ram_dirty_bitmap_sync_all(MigrationState *s, RAMState *rs)
4218 {
4219     RAMBlock *block;
4220     QEMUFile *file = s->to_dst_file;
4221     int ramblock_count = 0;
4222 
4223     trace_ram_dirty_bitmap_sync_start();
4224 
4225     RAMBLOCK_FOREACH_MIGRATABLE(block) {
4226         qemu_savevm_send_recv_bitmap(file, block->idstr);
4227         trace_ram_dirty_bitmap_request(block->idstr);
4228         ramblock_count++;
4229     }
4230 
4231     trace_ram_dirty_bitmap_sync_wait();
4232 
4233     /* Wait until all the ramblocks' dirty bitmap synced */
4234     while (ramblock_count--) {
4235         qemu_sem_wait(&s->rp_state.rp_sem);
4236     }
4237 
4238     trace_ram_dirty_bitmap_sync_complete();
4239 
4240     return 0;
4241 }
4242 
4243 static void ram_dirty_bitmap_reload_notify(MigrationState *s)
4244 {
4245     qemu_sem_post(&s->rp_state.rp_sem);
4246 }
4247 
4248 /*
4249  * Read the received bitmap, revert it as the initial dirty bitmap.
4250  * This is only used when the postcopy migration is paused but wants
4251  * to resume from a middle point.
4252  */
4253 int ram_dirty_bitmap_reload(MigrationState *s, RAMBlock *block)
4254 {
4255     int ret = -EINVAL;
4256     QEMUFile *file = s->rp_state.from_dst_file;
4257     unsigned long *le_bitmap, nbits = block->used_length >> TARGET_PAGE_BITS;
4258     uint64_t local_size = DIV_ROUND_UP(nbits, 8);
4259     uint64_t size, end_mark;
4260 
4261     trace_ram_dirty_bitmap_reload_begin(block->idstr);
4262 
4263     if (s->state != MIGRATION_STATUS_POSTCOPY_RECOVER) {
4264         error_report("%s: incorrect state %s", __func__,
4265                      MigrationStatus_str(s->state));
4266         return -EINVAL;
4267     }
4268 
4269     /*
4270      * Note: see comments in ramblock_recv_bitmap_send() on why we
4271      * need the endianess convertion, and the paddings.
4272      */
4273     local_size = ROUND_UP(local_size, 8);
4274 
4275     /* Add paddings */
4276     le_bitmap = bitmap_new(nbits + BITS_PER_LONG);
4277 
4278     size = qemu_get_be64(file);
4279 
4280     /* The size of the bitmap should match with our ramblock */
4281     if (size != local_size) {
4282         error_report("%s: ramblock '%s' bitmap size mismatch "
4283                      "(0x%"PRIx64" != 0x%"PRIx64")", __func__,
4284                      block->idstr, size, local_size);
4285         ret = -EINVAL;
4286         goto out;
4287     }
4288 
4289     size = qemu_get_buffer(file, (uint8_t *)le_bitmap, local_size);
4290     end_mark = qemu_get_be64(file);
4291 
4292     ret = qemu_file_get_error(file);
4293     if (ret || size != local_size) {
4294         error_report("%s: read bitmap failed for ramblock '%s': %d"
4295                      " (size 0x%"PRIx64", got: 0x%"PRIx64")",
4296                      __func__, block->idstr, ret, local_size, size);
4297         ret = -EIO;
4298         goto out;
4299     }
4300 
4301     if (end_mark != RAMBLOCK_RECV_BITMAP_ENDING) {
4302         error_report("%s: ramblock '%s' end mark incorrect: 0x%"PRIu64,
4303                      __func__, block->idstr, end_mark);
4304         ret = -EINVAL;
4305         goto out;
4306     }
4307 
4308     /*
4309      * Endianess convertion. We are during postcopy (though paused).
4310      * The dirty bitmap won't change. We can directly modify it.
4311      */
4312     bitmap_from_le(block->bmap, le_bitmap, nbits);
4313 
4314     /*
4315      * What we received is "received bitmap". Revert it as the initial
4316      * dirty bitmap for this ramblock.
4317      */
4318     bitmap_complement(block->bmap, block->bmap, nbits);
4319 
4320     trace_ram_dirty_bitmap_reload_complete(block->idstr);
4321 
4322     /*
4323      * We succeeded to sync bitmap for current ramblock. If this is
4324      * the last one to sync, we need to notify the main send thread.
4325      */
4326     ram_dirty_bitmap_reload_notify(s);
4327 
4328     ret = 0;
4329 out:
4330     g_free(le_bitmap);
4331     return ret;
4332 }
4333 
4334 static int ram_resume_prepare(MigrationState *s, void *opaque)
4335 {
4336     RAMState *rs = *(RAMState **)opaque;
4337     int ret;
4338 
4339     ret = ram_dirty_bitmap_sync_all(s, rs);
4340     if (ret) {
4341         return ret;
4342     }
4343 
4344     ram_state_resume_prepare(rs, s->to_dst_file);
4345 
4346     return 0;
4347 }
4348 
4349 static SaveVMHandlers savevm_ram_handlers = {
4350     .save_setup = ram_save_setup,
4351     .save_live_iterate = ram_save_iterate,
4352     .save_live_complete_postcopy = ram_save_complete,
4353     .save_live_complete_precopy = ram_save_complete,
4354     .has_postcopy = ram_has_postcopy,
4355     .save_live_pending = ram_save_pending,
4356     .load_state = ram_load,
4357     .save_cleanup = ram_save_cleanup,
4358     .load_setup = ram_load_setup,
4359     .load_cleanup = ram_load_cleanup,
4360     .resume_prepare = ram_resume_prepare,
4361 };
4362 
4363 void ram_mig_init(void)
4364 {
4365     qemu_mutex_init(&XBZRLE.lock);
4366     register_savevm_live(NULL, "ram", 0, 4, &savevm_ram_handlers, &ram_state);
4367 }
4368