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e2641e09 | 1 | #include "redis.h" |
2 | ||
3 | #include <fcntl.h> | |
4 | #include <pthread.h> | |
5 | #include <math.h> | |
6 | #include <signal.h> | |
7 | ||
33388d43 | 8 | /* dscache.c - Disk store cache for disk store backend. |
9 | * | |
10 | * When Redis is configured for using disk as backend instead of memory, the | |
11 | * memory is used as a cache, so that recently accessed keys are taken in | |
12 | * memory for fast read and write operations. | |
13 | * | |
14 | * Modified keys are marked to be flushed on disk, and will be flushed | |
15 | * as long as the maxium configured flush time elapsed. | |
16 | * | |
17 | * This file implements the whole caching subsystem and contains further | |
18 | * documentation. */ | |
19 | ||
20 | /* TODO: | |
133cf28e | 21 | * |
22 | * WARNING: most of the following todo items and design issues are no | |
23 | * longer relevant with the new design. Here as a checklist to see if | |
24 | * some old ideas still apply. | |
33388d43 | 25 | * |
16d77878 | 26 | * - What happens when an object is destroyed? |
27 | * | |
d158dc28 | 28 | * If the object is destroyed since semantically it was deleted or |
29 | * replaced with something new, we don't care if there was a SAVE | |
30 | * job pending for it. Anyway when the IO JOb will be created we'll get | |
31 | * the pointer of the current value. | |
16d77878 | 32 | * |
d158dc28 | 33 | * If the object is already a REDIS_IO_SAVEINPROG object, then it is |
34 | * impossible that we get a decrRefCount() that will reach refcount of zero | |
35 | * since the object is both in the dataset and in the io job entry. | |
16d77878 | 36 | * |
37 | * - What happens with MULTI/EXEC? | |
38 | * | |
d158dc28 | 39 | * Good question. Without some kind of versioning with a global counter |
40 | * it is not possible to have trasactions on disk, but they are still | |
41 | * useful since from the point of view of memory and client bugs it is | |
42 | * a protection anyway. Also it's useful for WATCH. | |
4ab98823 | 43 | * |
d158dc28 | 44 | * Btw there is to check what happens when WATCH gets combined to keys |
45 | * that gets removed from the object cache. Should be save but better | |
46 | * to check. | |
98a9abb6 | 47 | * |
d158dc28 | 48 | * - Check if/why INCR will not update the LRU info for the object. |
8e6bb671 | 49 | * |
50 | * - Fix/Check the following race condition: a key gets a DEL so there is | |
51 | * a write operation scheduled against this key. Later the same key will | |
52 | * be the argument of a GET, but the write operation was still not | |
53 | * completed (to delete the file). If the GET will be for some reason | |
54 | * a blocking loading (via lookup) we can load the old value on memory. | |
55 | * | |
56 | * This problems can be fixed with negative caching. We can use it | |
57 | * to optimize the system, but also when a key is deleted we mark | |
58 | * it as non existing on disk as well (in a way that this cache | |
59 | * entry can't be evicted, setting time to 0), then we avoid looking at | |
60 | * the disk at all if the key can't be there. When an IO Job complete | |
61 | * a deletion, we set the time of the negative caching to a non zero | |
62 | * value so it will be evicted later. | |
63 | * | |
64 | * Are there other patterns like this where we load stale data? | |
d934e1e8 | 65 | * |
66 | * Also, make sure that key preloading is ONLY done for keys that are | |
67 | * not marked as cacheKeyDoesNotExist(), otherwise, again, we can load | |
68 | * data from disk that should instead be deleted. | |
aa81e4d5 | 69 | * |
d158dc28 | 70 | * - dsSet() should use rename(2) in order to avoid corruptions. |
4942145d | 71 | * |
72 | * - Don't add a LOAD if there is already a LOADINPROGRESS, or is this | |
73 | * impossible since anyway the io_keys stuff will work as lock? | |
d158dc28 | 74 | * |
75 | * - Serialize special encoded things in a raw form. | |
fad97fbe | 76 | * |
77 | * - When putting IO read operations on top of the queue, do this only if | |
78 | * the already-on-top operation is not a save or if it is a save that | |
79 | * is scheduled for later execution. If there is a save that is ready to | |
80 | * fire, let's insert the load operation just before the first save that | |
81 | * is scheduled for later exection for instance. | |
82 | * | |
83 | * - Support MULTI/EXEC transactions via a journal file, that is played on | |
84 | * startup to check if there is cleanup to do. This way we can implement | |
85 | * transactions with our simple file based KV store. | |
33388d43 | 86 | */ |
87 | ||
e2641e09 | 88 | /* Virtual Memory is composed mainly of two subsystems: |
89 | * - Blocking Virutal Memory | |
90 | * - Threaded Virtual Memory I/O | |
91 | * The two parts are not fully decoupled, but functions are split among two | |
92 | * different sections of the source code (delimited by comments) in order to | |
93 | * make more clear what functionality is about the blocking VM and what about | |
94 | * the threaded (not blocking) VM. | |
95 | * | |
96 | * Redis VM design: | |
97 | * | |
98 | * Redis VM is a blocking VM (one that blocks reading swapped values from | |
99 | * disk into memory when a value swapped out is needed in memory) that is made | |
100 | * unblocking by trying to examine the command argument vector in order to | |
101 | * load in background values that will likely be needed in order to exec | |
102 | * the command. The command is executed only once all the relevant keys | |
103 | * are loaded into memory. | |
104 | * | |
105 | * This basically is almost as simple of a blocking VM, but almost as parallel | |
106 | * as a fully non-blocking VM. | |
107 | */ | |
108 | ||
f34a6cd8 | 109 | void spawnIOThread(void); |
f771dc23 | 110 | int cacheScheduleIOPushJobs(int flags); |
111 | int processActiveIOJobs(int max); | |
f34a6cd8 | 112 | |
e2641e09 | 113 | /* =================== Virtual Memory - Blocking Side ====================== */ |
114 | ||
f2da3a62 | 115 | void dsInit(void) { |
e2641e09 | 116 | int pipefds[2]; |
117 | size_t stacksize; | |
e2641e09 | 118 | |
f2da3a62 | 119 | zmalloc_enable_thread_safeness(); /* we need thread safe zmalloc() */ |
e2641e09 | 120 | |
67b0b41c | 121 | redisLog(REDIS_NOTICE,"Opening Disk Store: %s", server.ds_path); |
f2da3a62 | 122 | /* Open Disk Store */ |
123 | if (dsOpen() != REDIS_OK) { | |
124 | redisLog(REDIS_WARNING,"Fatal error opening disk store. Exiting."); | |
e2641e09 | 125 | exit(1); |
f2da3a62 | 126 | }; |
e2641e09 | 127 | |
f2da3a62 | 128 | /* Initialize threaded I/O for Object Cache */ |
e2641e09 | 129 | server.io_newjobs = listCreate(); |
130 | server.io_processing = listCreate(); | |
131 | server.io_processed = listCreate(); | |
132 | server.io_ready_clients = listCreate(); | |
133 | pthread_mutex_init(&server.io_mutex,NULL); | |
98a9abb6 | 134 | pthread_cond_init(&server.io_condvar,NULL); |
36c17a53 | 135 | pthread_mutex_init(&server.bgsavethread_mutex,NULL); |
e2641e09 | 136 | server.io_active_threads = 0; |
137 | if (pipe(pipefds) == -1) { | |
f2da3a62 | 138 | redisLog(REDIS_WARNING,"Unable to intialized DS: pipe(2): %s. Exiting." |
e2641e09 | 139 | ,strerror(errno)); |
140 | exit(1); | |
141 | } | |
142 | server.io_ready_pipe_read = pipefds[0]; | |
143 | server.io_ready_pipe_write = pipefds[1]; | |
144 | redisAssert(anetNonBlock(NULL,server.io_ready_pipe_read) != ANET_ERR); | |
145 | /* LZF requires a lot of stack */ | |
146 | pthread_attr_init(&server.io_threads_attr); | |
147 | pthread_attr_getstacksize(&server.io_threads_attr, &stacksize); | |
556bdfba | 148 | |
149 | /* Solaris may report a stacksize of 0, let's set it to 1 otherwise | |
150 | * multiplying it by 2 in the while loop later will not really help ;) */ | |
151 | if (!stacksize) stacksize = 1; | |
152 | ||
e2641e09 | 153 | while (stacksize < REDIS_THREAD_STACK_SIZE) stacksize *= 2; |
154 | pthread_attr_setstacksize(&server.io_threads_attr, stacksize); | |
155 | /* Listen for events in the threaded I/O pipe */ | |
156 | if (aeCreateFileEvent(server.el, server.io_ready_pipe_read, AE_READABLE, | |
157 | vmThreadedIOCompletedJob, NULL) == AE_ERR) | |
158 | oom("creating file event"); | |
e2641e09 | 159 | |
f2da3a62 | 160 | /* Spawn our I/O thread */ |
161 | spawnIOThread(); | |
e2641e09 | 162 | } |
163 | ||
f2da3a62 | 164 | /* Compute how good candidate the specified object is for eviction. |
165 | * An higher number means a better candidate. */ | |
e2641e09 | 166 | double computeObjectSwappability(robj *o) { |
167 | /* actual age can be >= minage, but not < minage. As we use wrapping | |
168 | * 21 bit clocks with minutes resolution for the LRU. */ | |
f081eaf1 | 169 | return (double) estimateObjectIdleTime(o); |
e2641e09 | 170 | } |
171 | ||
f2da3a62 | 172 | /* Try to free one entry from the diskstore object cache */ |
173 | int cacheFreeOneEntry(void) { | |
e2641e09 | 174 | int j, i; |
175 | struct dictEntry *best = NULL; | |
176 | double best_swappability = 0; | |
177 | redisDb *best_db = NULL; | |
178 | robj *val; | |
179 | sds key; | |
180 | ||
181 | for (j = 0; j < server.dbnum; j++) { | |
182 | redisDb *db = server.db+j; | |
183 | /* Why maxtries is set to 100? | |
184 | * Because this way (usually) we'll find 1 object even if just 1% - 2% | |
185 | * are swappable objects */ | |
186 | int maxtries = 100; | |
187 | ||
69bfffb4 | 188 | for (i = 0; i < 5 && dictSize(db->dict); i++) { |
e2641e09 | 189 | dictEntry *de; |
190 | double swappability; | |
3be00d7e | 191 | robj keyobj; |
192 | sds keystr; | |
e2641e09 | 193 | |
194 | if (maxtries) maxtries--; | |
195 | de = dictGetRandomKey(db->dict); | |
3be00d7e | 196 | keystr = dictGetEntryKey(de); |
e2641e09 | 197 | val = dictGetEntryVal(de); |
3be00d7e | 198 | initStaticStringObject(keyobj,keystr); |
199 | ||
200 | /* Don't remove objects that are currently target of a | |
201 | * read or write operation. */ | |
202 | if (cacheScheduleIOGetFlags(db,&keyobj) != 0) { | |
e2641e09 | 203 | if (maxtries) i--; /* don't count this try */ |
204 | continue; | |
205 | } | |
206 | swappability = computeObjectSwappability(val); | |
207 | if (!best || swappability > best_swappability) { | |
208 | best = de; | |
209 | best_swappability = swappability; | |
210 | best_db = db; | |
211 | } | |
212 | } | |
213 | } | |
f2da3a62 | 214 | if (best == NULL) { |
c5b6f461 | 215 | /* Not able to free a single object? we should check if our |
418d5eaf | 216 | * IO queues have stuff in queue, and try to consume the queue |
217 | * otherwise we'll use an infinite amount of memory if changes to | |
218 | * the dataset are faster than I/O */ | |
219 | if (listLength(server.cache_io_queue) > 0) { | |
f771dc23 | 220 | redisLog(REDIS_DEBUG,"--- Busy waiting IO to reclaim memory"); |
221 | cacheScheduleIOPushJobs(REDIS_IO_ASAP); | |
222 | processActiveIOJobs(1); | |
418d5eaf | 223 | return REDIS_OK; |
224 | } | |
225 | /* Nothing to free at all... */ | |
f2da3a62 | 226 | return REDIS_ERR; |
227 | } | |
e2641e09 | 228 | key = dictGetEntryKey(best); |
229 | val = dictGetEntryVal(best); | |
230 | ||
f2da3a62 | 231 | redisLog(REDIS_DEBUG,"Key selected for cache eviction: %s swappability:%f", |
e2641e09 | 232 | key, best_swappability); |
233 | ||
f2da3a62 | 234 | /* Delete this key from memory */ |
235 | { | |
236 | robj *kobj = createStringObject(key,sdslen(key)); | |
237 | dbDelete(best_db,kobj); | |
238 | decrRefCount(kobj); | |
e2641e09 | 239 | } |
5ef64098 | 240 | return REDIS_OK; |
e2641e09 | 241 | } |
242 | ||
d934e1e8 | 243 | /* ==================== Disk store negative caching ======================== |
244 | * | |
245 | * When disk store is enabled, we need negative caching, that is, to remember | |
246 | * keys that are for sure *not* on the disk key-value store. | |
247 | * | |
3be00d7e | 248 | * This is usefuls because without negative caching cache misses will cost us |
249 | * a disk lookup, even if the same non existing key is accessed again and again. | |
d934e1e8 | 250 | * |
3be00d7e | 251 | * With negative caching we remember that the key is not on disk, so if it's |
252 | * not in memory and we have a negative cache entry, we don't try a disk | |
253 | * access at all. | |
254 | */ | |
d934e1e8 | 255 | |
3be00d7e | 256 | /* Returns true if the specified key may exists on disk, that is, we don't |
257 | * have an entry in our negative cache for this key */ | |
d934e1e8 | 258 | int cacheKeyMayExist(redisDb *db, robj *key) { |
259 | return dictFind(db->io_negcache,key) == NULL; | |
260 | } | |
261 | ||
3be00d7e | 262 | /* Set the specified key as an entry that may possibily exist on disk, that is, |
263 | * remove the negative cache entry for this key if any. */ | |
d934e1e8 | 264 | void cacheSetKeyMayExist(redisDb *db, robj *key) { |
265 | dictDelete(db->io_negcache,key); | |
266 | } | |
267 | ||
3be00d7e | 268 | /* Set the specified key as non existing on disk, that is, create a negative |
269 | * cache entry for this key. */ | |
d934e1e8 | 270 | void cacheSetKeyDoesNotExist(redisDb *db, robj *key) { |
d934e1e8 | 271 | if (dictReplace(db->io_negcache,key,(void*)time(NULL))) { |
272 | incrRefCount(key); | |
273 | } | |
274 | } | |
275 | ||
c15a3887 | 276 | /* Remove one entry from negative cache using approximated LRU. */ |
277 | int negativeCacheEvictOneEntry(void) { | |
278 | struct dictEntry *de; | |
279 | robj *best = NULL; | |
280 | redisDb *best_db = NULL; | |
281 | time_t time, best_time = 0; | |
282 | int j; | |
283 | ||
284 | for (j = 0; j < server.dbnum; j++) { | |
285 | redisDb *db = server.db+j; | |
286 | int i; | |
287 | ||
288 | if (dictSize(db->io_negcache) == 0) continue; | |
289 | for (i = 0; i < 3; i++) { | |
290 | de = dictGetRandomKey(db->io_negcache); | |
291 | time = (time_t) dictGetEntryVal(de); | |
292 | ||
293 | if (best == NULL || time < best_time) { | |
294 | best = dictGetEntryKey(de); | |
295 | best_db = db; | |
296 | best_time = time; | |
297 | } | |
298 | } | |
299 | } | |
300 | if (best) { | |
301 | dictDelete(best_db->io_negcache,best); | |
302 | return REDIS_OK; | |
303 | } else { | |
304 | return REDIS_ERR; | |
305 | } | |
306 | } | |
307 | ||
d934e1e8 | 308 | /* ================== Disk store cache - Threaded I/O ====================== */ |
e2641e09 | 309 | |
310 | void freeIOJob(iojob *j) { | |
e2641e09 | 311 | decrRefCount(j->key); |
5ef64098 | 312 | /* j->val can be NULL if the job is about deleting the key from disk. */ |
313 | if (j->val) decrRefCount(j->val); | |
e2641e09 | 314 | zfree(j); |
315 | } | |
316 | ||
317 | /* Every time a thread finished a Job, it writes a byte into the write side | |
318 | * of an unix pipe in order to "awake" the main thread, and this function | |
419e1cca | 319 | * is called. |
320 | * | |
d9fac6c0 | 321 | * If privdata == NULL the function will try to put more jobs in the queue |
322 | * of IO jobs to process as more room is made. privdata is equal to NULL | |
323 | * when the function is called from the event loop, so we want to push | |
324 | * more IO jobs in the queue. Instead when the function is called by | |
325 | * other functions that want to create a write-barrier to avoid race | |
326 | * conditions we don't push new jobs in the queue. */ | |
e2641e09 | 327 | void vmThreadedIOCompletedJob(aeEventLoop *el, int fd, void *privdata, |
328 | int mask) | |
329 | { | |
330 | char buf[1]; | |
f34a6cd8 | 331 | int retval, processed = 0, toprocess = -1; |
e2641e09 | 332 | REDIS_NOTUSED(el); |
333 | REDIS_NOTUSED(mask); | |
e2641e09 | 334 | |
335 | /* For every byte we read in the read side of the pipe, there is one | |
336 | * I/O job completed to process. */ | |
337 | while((retval = read(fd,buf,1)) == 1) { | |
338 | iojob *j; | |
339 | listNode *ln; | |
e2641e09 | 340 | |
341 | redisLog(REDIS_DEBUG,"Processing I/O completed job"); | |
342 | ||
343 | /* Get the processed element (the oldest one) */ | |
344 | lockThreadedIO(); | |
345 | redisAssert(listLength(server.io_processed) != 0); | |
346 | if (toprocess == -1) { | |
347 | toprocess = (listLength(server.io_processed)*REDIS_MAX_COMPLETED_JOBS_PROCESSED)/100; | |
348 | if (toprocess <= 0) toprocess = 1; | |
349 | } | |
350 | ln = listFirst(server.io_processed); | |
351 | j = ln->value; | |
352 | listDelNode(server.io_processed,ln); | |
353 | unlockThreadedIO(); | |
f34a6cd8 | 354 | |
e2641e09 | 355 | /* Post process it in the main thread, as there are things we |
356 | * can do just here to avoid race conditions and/or invasive locks */ | |
5ef64098 | 357 | redisLog(REDIS_DEBUG,"COMPLETED Job type %s, key: %s", |
358 | (j->type == REDIS_IOJOB_LOAD) ? "load" : "save", | |
359 | (unsigned char*)j->key->ptr); | |
e2641e09 | 360 | if (j->type == REDIS_IOJOB_LOAD) { |
5ef64098 | 361 | /* Create the key-value pair in the in-memory database */ |
4ab98823 | 362 | if (j->val != NULL) { |
3be00d7e | 363 | /* Note: it's possible that the key is already in memory |
364 | * due to a blocking load operation. */ | |
365 | if (dbAdd(j->db,j->key,j->val) == REDIS_OK) { | |
ad01a255 | 366 | incrRefCount(j->val); |
367 | if (j->expire != -1) setExpire(j->db,j->key,j->expire); | |
368 | } | |
5d46e370 | 369 | } else { |
370 | /* Key not found on disk. If it is also not in memory | |
371 | * as a cached object, nor there is a job writing it | |
372 | * in background, we are sure the key does not exist | |
373 | * currently. | |
374 | * | |
375 | * So we set a negative cache entry avoiding that the | |
376 | * resumed client will block load what does not exist... */ | |
bafa88c8 | 377 | if (dictFind(j->db->dict,j->key->ptr) == NULL && |
5d46e370 | 378 | (cacheScheduleIOGetFlags(j->db,j->key) & |
379 | (REDIS_IO_SAVE|REDIS_IO_SAVEINPROG)) == 0) | |
380 | { | |
381 | cacheSetKeyDoesNotExist(j->db,j->key); | |
382 | } | |
4ab98823 | 383 | } |
3be00d7e | 384 | cacheScheduleIODelFlag(j->db,j->key,REDIS_IO_LOADINPROG); |
5ef64098 | 385 | handleClientsBlockedOnSwappedKey(j->db,j->key); |
5f6e1183 | 386 | } else if (j->type == REDIS_IOJOB_SAVE) { |
3be00d7e | 387 | cacheScheduleIODelFlag(j->db,j->key,REDIS_IO_SAVEINPROG); |
e2641e09 | 388 | } |
3a21cb99 | 389 | freeIOJob(j); |
e2641e09 | 390 | processed++; |
d9fac6c0 | 391 | if (privdata == NULL) cacheScheduleIOPushJobs(0); |
e2641e09 | 392 | if (processed == toprocess) return; |
393 | } | |
394 | if (retval < 0 && errno != EAGAIN) { | |
395 | redisLog(REDIS_WARNING, | |
396 | "WARNING: read(2) error in vmThreadedIOCompletedJob() %s", | |
397 | strerror(errno)); | |
398 | } | |
399 | } | |
400 | ||
401 | void lockThreadedIO(void) { | |
402 | pthread_mutex_lock(&server.io_mutex); | |
403 | } | |
404 | ||
405 | void unlockThreadedIO(void) { | |
406 | pthread_mutex_unlock(&server.io_mutex); | |
407 | } | |
408 | ||
e2641e09 | 409 | void *IOThreadEntryPoint(void *arg) { |
410 | iojob *j; | |
411 | listNode *ln; | |
412 | REDIS_NOTUSED(arg); | |
419e1cca | 413 | long long start; |
e2641e09 | 414 | |
415 | pthread_detach(pthread_self()); | |
98a9abb6 | 416 | lockThreadedIO(); |
e2641e09 | 417 | while(1) { |
418 | /* Get a new job to process */ | |
e2641e09 | 419 | if (listLength(server.io_newjobs) == 0) { |
a440ecf0 | 420 | /* Wait for more work to do */ |
05600eb8 | 421 | redisLog(REDIS_DEBUG,"[T] wait for signal"); |
a440ecf0 | 422 | pthread_cond_wait(&server.io_condvar,&server.io_mutex); |
05600eb8 | 423 | redisLog(REDIS_DEBUG,"[T] signal received"); |
1609a1c4 | 424 | continue; |
e2641e09 | 425 | } |
419e1cca | 426 | start = ustime(); |
05600eb8 | 427 | redisLog(REDIS_DEBUG,"[T] %ld IO jobs to process", |
c4b64a13 | 428 | listLength(server.io_newjobs)); |
e2641e09 | 429 | ln = listFirst(server.io_newjobs); |
430 | j = ln->value; | |
431 | listDelNode(server.io_newjobs,ln); | |
432 | /* Add the job in the processing queue */ | |
e2641e09 | 433 | listAddNodeTail(server.io_processing,j); |
434 | ln = listLast(server.io_processing); /* We use ln later to remove it */ | |
435 | unlockThreadedIO(); | |
98a9abb6 | 436 | |
05600eb8 | 437 | redisLog(REDIS_DEBUG,"[T] %ld: new job type %s: %p about key '%s'", |
5ef64098 | 438 | (long) pthread_self(), |
439 | (j->type == REDIS_IOJOB_LOAD) ? "load" : "save", | |
440 | (void*)j, (char*)j->key->ptr); | |
e2641e09 | 441 | |
442 | /* Process the Job */ | |
443 | if (j->type == REDIS_IOJOB_LOAD) { | |
4ab98823 | 444 | time_t expire; |
445 | ||
446 | j->val = dsGet(j->db,j->key,&expire); | |
447 | if (j->val) j->expire = expire; | |
5ef64098 | 448 | } else if (j->type == REDIS_IOJOB_SAVE) { |
31222292 | 449 | if (j->val) { |
05600eb8 | 450 | dsSet(j->db,j->key,j->val,j->expire); |
31222292 | 451 | } else { |
5ef64098 | 452 | dsDel(j->db,j->key); |
31222292 | 453 | } |
e2641e09 | 454 | } |
455 | ||
456 | /* Done: insert the job into the processed queue */ | |
05600eb8 | 457 | redisLog(REDIS_DEBUG,"[T] %ld completed the job: %p (key %s)", |
e2641e09 | 458 | (long) pthread_self(), (void*)j, (char*)j->key->ptr); |
98a9abb6 | 459 | |
05600eb8 | 460 | redisLog(REDIS_DEBUG,"[T] lock IO"); |
e2641e09 | 461 | lockThreadedIO(); |
05600eb8 | 462 | redisLog(REDIS_DEBUG,"[T] IO locked"); |
e2641e09 | 463 | listDelNode(server.io_processing,ln); |
464 | listAddNodeTail(server.io_processed,j); | |
e2641e09 | 465 | |
466 | /* Signal the main thread there is new stuff to process */ | |
467 | redisAssert(write(server.io_ready_pipe_write,"x",1) == 1); | |
8b108ed3 | 468 | redisLog(REDIS_DEBUG,"TIME (%c): %lld\n", j->type == REDIS_IOJOB_LOAD ? 'L' : 'S', ustime()-start); |
e2641e09 | 469 | } |
98a9abb6 | 470 | /* never reached, but that's the full pattern... */ |
471 | unlockThreadedIO(); | |
472 | return NULL; | |
e2641e09 | 473 | } |
474 | ||
475 | void spawnIOThread(void) { | |
476 | pthread_t thread; | |
477 | sigset_t mask, omask; | |
478 | int err; | |
479 | ||
480 | sigemptyset(&mask); | |
481 | sigaddset(&mask,SIGCHLD); | |
482 | sigaddset(&mask,SIGHUP); | |
483 | sigaddset(&mask,SIGPIPE); | |
484 | pthread_sigmask(SIG_SETMASK, &mask, &omask); | |
485 | while ((err = pthread_create(&thread,&server.io_threads_attr,IOThreadEntryPoint,NULL)) != 0) { | |
486 | redisLog(REDIS_WARNING,"Unable to spawn an I/O thread: %s", | |
487 | strerror(err)); | |
488 | usleep(1000000); | |
489 | } | |
490 | pthread_sigmask(SIG_SETMASK, &omask, NULL); | |
491 | server.io_active_threads++; | |
492 | } | |
493 | ||
f771dc23 | 494 | /* Wait that up to 'max' pending IO Jobs are processed by the I/O thread. |
495 | * From our point of view an IO job processed means that the count of | |
496 | * server.io_processed must increase by one. | |
497 | * | |
498 | * If max is -1, all the pending IO jobs will be processed. | |
499 | * | |
500 | * Returns the number of IO jobs processed. | |
501 | * | |
502 | * NOTE: while this may appear like a busy loop, we are actually blocked | |
503 | * by IO since we continuously acquire/release the IO lock. */ | |
504 | int processActiveIOJobs(int max) { | |
505 | int processed = 0; | |
506 | ||
507 | while(max == -1 || max > 0) { | |
e2641e09 | 508 | int io_processed_len; |
509 | ||
05600eb8 | 510 | redisLog(REDIS_DEBUG,"[P] lock IO"); |
e2641e09 | 511 | lockThreadedIO(); |
05600eb8 | 512 | redisLog(REDIS_DEBUG,"Waiting IO jobs processing: new:%d proessing:%d processed:%d",listLength(server.io_newjobs),listLength(server.io_processing),listLength(server.io_processed)); |
513 | ||
e2641e09 | 514 | if (listLength(server.io_newjobs) == 0 && |
8d51fb6a | 515 | listLength(server.io_processing) == 0) |
e2641e09 | 516 | { |
f771dc23 | 517 | /* There is nothing more to process */ |
05600eb8 | 518 | redisLog(REDIS_DEBUG,"[P] Nothing to process, unlock IO, return"); |
e2641e09 | 519 | unlockThreadedIO(); |
f771dc23 | 520 | break; |
e2641e09 | 521 | } |
f771dc23 | 522 | |
05600eb8 | 523 | #if 1 |
a440ecf0 | 524 | /* If there are new jobs we need to signal the thread to |
249ad25f | 525 | * process the next one. FIXME: drop this if useless. */ |
05600eb8 | 526 | redisLog(REDIS_DEBUG,"[P] waitEmptyIOJobsQueue: new %d, processing %d, processed %d", |
a440ecf0 | 527 | listLength(server.io_newjobs), |
05600eb8 | 528 | listLength(server.io_processing), |
529 | listLength(server.io_processed)); | |
5d46e370 | 530 | |
a440ecf0 | 531 | if (listLength(server.io_newjobs)) { |
05600eb8 | 532 | redisLog(REDIS_DEBUG,"[P] There are new jobs, signal"); |
a440ecf0 | 533 | pthread_cond_signal(&server.io_condvar); |
534 | } | |
f771dc23 | 535 | #endif |
536 | ||
537 | /* Check if we can process some finished job */ | |
e2641e09 | 538 | io_processed_len = listLength(server.io_processed); |
05600eb8 | 539 | redisLog(REDIS_DEBUG,"[P] Unblock IO"); |
e2641e09 | 540 | unlockThreadedIO(); |
05600eb8 | 541 | redisLog(REDIS_DEBUG,"[P] Wait"); |
542 | usleep(10000); | |
e2641e09 | 543 | if (io_processed_len) { |
c1ae36ae | 544 | vmThreadedIOCompletedJob(NULL,server.io_ready_pipe_read, |
545 | (void*)0xdeadbeef,0); | |
f771dc23 | 546 | processed++; |
547 | if (max != -1) max--; | |
e2641e09 | 548 | } |
549 | } | |
f771dc23 | 550 | return processed; |
e2641e09 | 551 | } |
552 | ||
f771dc23 | 553 | void waitEmptyIOJobsQueue(void) { |
554 | processActiveIOJobs(-1); | |
555 | } | |
556 | ||
557 | /* Process up to 'max' IO Jobs already completed by threads but still waiting | |
558 | * processing from the main thread. | |
559 | * | |
560 | * If max == -1 all the pending jobs are processed. | |
561 | * | |
562 | * The number of processed jobs is returned. */ | |
563 | int processPendingIOJobs(int max) { | |
564 | int processed = 0; | |
565 | ||
566 | while(max == -1 || max > 0) { | |
8d51fb6a | 567 | int io_processed_len; |
568 | ||
569 | lockThreadedIO(); | |
570 | io_processed_len = listLength(server.io_processed); | |
571 | unlockThreadedIO(); | |
f771dc23 | 572 | if (io_processed_len == 0) break; |
8d51fb6a | 573 | vmThreadedIOCompletedJob(NULL,server.io_ready_pipe_read, |
574 | (void*)0xdeadbeef,0); | |
f771dc23 | 575 | if (max != -1) max--; |
576 | processed++; | |
8d51fb6a | 577 | } |
f771dc23 | 578 | return processed; |
579 | } | |
580 | ||
581 | void processAllPendingIOJobs(void) { | |
582 | processPendingIOJobs(-1); | |
8d51fb6a | 583 | } |
584 | ||
e2641e09 | 585 | /* This function must be called while with threaded IO locked */ |
586 | void queueIOJob(iojob *j) { | |
587 | redisLog(REDIS_DEBUG,"Queued IO Job %p type %d about key '%s'\n", | |
588 | (void*)j, j->type, (char*)j->key->ptr); | |
589 | listAddNodeTail(server.io_newjobs,j); | |
e2641e09 | 590 | } |
591 | ||
249ad25f | 592 | /* Consume all the IO scheduled operations, and all the thread IO jobs |
593 | * so that eventually the state of diskstore is a point-in-time snapshot. | |
594 | * | |
595 | * This is useful when we need to BGSAVE with diskstore enabled. */ | |
596 | void cacheForcePointInTime(void) { | |
597 | redisLog(REDIS_NOTICE,"Diskstore: synching on disk to reach point-in-time state."); | |
598 | while (listLength(server.cache_io_queue) != 0) { | |
599 | cacheScheduleIOPushJobs(REDIS_IO_ASAP); | |
600 | processActiveIOJobs(1); | |
601 | } | |
602 | waitEmptyIOJobsQueue(); | |
603 | processAllPendingIOJobs(); | |
604 | } | |
605 | ||
05600eb8 | 606 | void cacheCreateIOJob(int type, redisDb *db, robj *key, robj *val, time_t expire) { |
e2641e09 | 607 | iojob *j; |
608 | ||
609 | j = zmalloc(sizeof(*j)); | |
5ef64098 | 610 | j->type = type; |
e2641e09 | 611 | j->db = db; |
612 | j->key = key; | |
613 | incrRefCount(key); | |
5ef64098 | 614 | j->val = val; |
1609a1c4 | 615 | if (val) incrRefCount(val); |
05600eb8 | 616 | j->expire = expire; |
e2641e09 | 617 | |
618 | lockThreadedIO(); | |
619 | queueIOJob(j); | |
98a9abb6 | 620 | pthread_cond_signal(&server.io_condvar); |
e2641e09 | 621 | unlockThreadedIO(); |
e2641e09 | 622 | } |
623 | ||
3be00d7e | 624 | /* ============= Disk store cache - Scheduling of IO operations ============= |
625 | * | |
626 | * We use a queue and an hash table to hold the state of IO operations | |
627 | * so that's fast to lookup if there is already an IO operation in queue | |
628 | * for a given key. | |
629 | * | |
630 | * There are two types of IO operations for a given key: | |
631 | * REDIS_IO_LOAD and REDIS_IO_SAVE. | |
632 | * | |
633 | * The function cacheScheduleIO() function pushes the specified IO operation | |
634 | * in the queue, but avoid adding the same key for the same operation | |
635 | * multiple times, thanks to the associated hash table. | |
636 | * | |
637 | * We take a set of flags per every key, so when the scheduled IO operation | |
638 | * gets moved from the scheduled queue to the actual IO Jobs queue that | |
639 | * is processed by the IO thread, we flag it as IO_LOADINPROG or | |
640 | * IO_SAVEINPROG. | |
641 | * | |
642 | * So for every given key we always know if there is some IO operation | |
643 | * scheduled, or in progress, for this key. | |
644 | * | |
645 | * NOTE: all this is very important in order to guarantee correctness of | |
646 | * the Disk Store Cache. Jobs are always queued here. Load jobs are | |
647 | * queued at the head for faster execution only in the case there is not | |
648 | * already a write operation of some kind for this job. | |
649 | * | |
650 | * So we have ordering, but can do exceptions when there are no already | |
651 | * operations for a given key. Also when we need to block load a given | |
652 | * key, for an immediate lookup operation, we can check if the key can | |
653 | * be accessed synchronously without race conditions (no IN PROGRESS | |
654 | * operations for this key), otherwise we blocking wait for completion. */ | |
655 | ||
656 | #define REDIS_IO_LOAD 1 | |
657 | #define REDIS_IO_SAVE 2 | |
658 | #define REDIS_IO_LOADINPROG 4 | |
659 | #define REDIS_IO_SAVEINPROG 8 | |
660 | ||
661 | void cacheScheduleIOAddFlag(redisDb *db, robj *key, long flag) { | |
662 | struct dictEntry *de = dictFind(db->io_queued,key); | |
663 | ||
664 | if (!de) { | |
665 | dictAdd(db->io_queued,key,(void*)flag); | |
666 | incrRefCount(key); | |
667 | return; | |
668 | } else { | |
669 | long flags = (long) dictGetEntryVal(de); | |
e37efb0d | 670 | |
671 | if (flags & flag) { | |
672 | redisLog(REDIS_WARNING,"Adding the same flag again: was: %ld, addede: %ld",flags,flag); | |
673 | redisAssert(!(flags & flag)); | |
674 | } | |
3be00d7e | 675 | flags |= flag; |
676 | dictGetEntryVal(de) = (void*) flags; | |
f63f0928 | 677 | } |
3be00d7e | 678 | } |
679 | ||
680 | void cacheScheduleIODelFlag(redisDb *db, robj *key, long flag) { | |
681 | struct dictEntry *de = dictFind(db->io_queued,key); | |
682 | long flags; | |
683 | ||
684 | redisAssert(de != NULL); | |
685 | flags = (long) dictGetEntryVal(de); | |
686 | redisAssert(flags & flag); | |
687 | flags &= ~flag; | |
688 | if (flags == 0) { | |
689 | dictDelete(db->io_queued,key); | |
690 | } else { | |
691 | dictGetEntryVal(de) = (void*) flags; | |
692 | } | |
693 | } | |
f63f0928 | 694 | |
3be00d7e | 695 | int cacheScheduleIOGetFlags(redisDb *db, robj *key) { |
696 | struct dictEntry *de = dictFind(db->io_queued,key); | |
697 | ||
698 | return (de == NULL) ? 0 : ((long) dictGetEntryVal(de)); | |
699 | } | |
700 | ||
701 | void cacheScheduleIO(redisDb *db, robj *key, int type) { | |
702 | ioop *op; | |
703 | long flags; | |
704 | ||
705 | if ((flags = cacheScheduleIOGetFlags(db,key)) & type) return; | |
706 | ||
707 | redisLog(REDIS_DEBUG,"Scheduling key %s for %s", | |
708 | key->ptr, type == REDIS_IO_LOAD ? "loading" : "saving"); | |
709 | cacheScheduleIOAddFlag(db,key,type); | |
710 | op = zmalloc(sizeof(*op)); | |
711 | op->type = type; | |
712 | op->db = db; | |
713 | op->key = key; | |
f63f0928 | 714 | incrRefCount(key); |
3be00d7e | 715 | op->ctime = time(NULL); |
716 | ||
717 | /* Give priority to load operations if there are no save already | |
718 | * in queue for the same key. */ | |
719 | if (type == REDIS_IO_LOAD && !(flags & REDIS_IO_SAVE)) { | |
720 | listAddNodeHead(server.cache_io_queue, op); | |
f771dc23 | 721 | cacheScheduleIOPushJobs(REDIS_IO_ONLYLOADS); |
3be00d7e | 722 | } else { |
723 | /* FIXME: probably when this happens we want to at least move | |
724 | * the write job about this queue on top, and set the creation time | |
725 | * to a value that will force processing ASAP. */ | |
726 | listAddNodeTail(server.cache_io_queue, op); | |
727 | } | |
f63f0928 | 728 | } |
729 | ||
9b24d8ad | 730 | /* Push scheduled IO operations into IO Jobs that the IO thread can process. |
f771dc23 | 731 | * |
732 | * If flags include REDIS_IO_ONLYLOADS only load jobs are processed:this is | |
733 | * useful since it's safe to push LOAD IO jobs from any place of the code, while | |
9b24d8ad | 734 | * SAVE io jobs should never be pushed while we are processing a command |
735 | * (not protected by lookupKey() that will block on keys in IO_SAVEINPROG | |
f771dc23 | 736 | * state. |
737 | * | |
738 | * The REDIS_IO_ASAP flag tells the function to don't wait for the IO job | |
739 | * scheduled completion time, but just do the operation ASAP. This is useful | |
740 | * when we need to reclaim memory from the IO queue. | |
741 | */ | |
419e1cca | 742 | #define MAX_IO_JOBS_QUEUE 10 |
f771dc23 | 743 | int cacheScheduleIOPushJobs(int flags) { |
f63f0928 | 744 | time_t now = time(NULL); |
745 | listNode *ln; | |
418d5eaf | 746 | int jobs, topush = 0, pushed = 0; |
c4b64a13 | 747 | |
f03fe802 | 748 | /* Don't push new jobs if there is a threaded BGSAVE in progress. */ |
749 | if (server.bgsavethread != (pthread_t) -1) return 0; | |
750 | ||
9b24d8ad | 751 | /* Sync stuff on disk, but only if we have less |
752 | * than MAX_IO_JOBS_QUEUE IO jobs. */ | |
c4b64a13 | 753 | lockThreadedIO(); |
754 | jobs = listLength(server.io_newjobs); | |
755 | unlockThreadedIO(); | |
756 | ||
9b24d8ad | 757 | topush = MAX_IO_JOBS_QUEUE-jobs; |
c4b64a13 | 758 | if (topush < 0) topush = 0; |
e37efb0d | 759 | if (topush > (signed)listLength(server.cache_io_queue)) |
760 | topush = listLength(server.cache_io_queue); | |
f63f0928 | 761 | |
3be00d7e | 762 | while((ln = listFirst(server.cache_io_queue)) != NULL) { |
763 | ioop *op = ln->value; | |
f771dc23 | 764 | struct dictEntry *de; |
765 | robj *val; | |
f63f0928 | 766 | |
c4b64a13 | 767 | if (!topush) break; |
768 | topush--; | |
769 | ||
f771dc23 | 770 | if (op->type != REDIS_IO_LOAD && flags & REDIS_IO_ONLYLOADS) break; |
771 | ||
f1df1739 | 772 | /* Don't execute SAVE before the scheduled time for completion */ |
773 | if (op->type == REDIS_IO_SAVE && !(flags & REDIS_IO_ASAP) && | |
f771dc23 | 774 | (now - op->ctime) < server.cache_flush_delay) break; |
775 | ||
776 | /* Don't add a SAVE job in the IO thread queue if there is already | |
777 | * a save in progress for the same key. */ | |
778 | if (op->type == REDIS_IO_SAVE && | |
779 | cacheScheduleIOGetFlags(op->db,op->key) & REDIS_IO_SAVEINPROG) | |
3be00d7e | 780 | { |
f771dc23 | 781 | /* Move the operation at the end of the list if there |
782 | * are other operations, so we can try to process the next one. | |
783 | * Otherwise break, nothing to do here. */ | |
784 | if (listLength(server.cache_io_queue) > 1) { | |
785 | listDelNode(server.cache_io_queue,ln); | |
786 | listAddNodeTail(server.cache_io_queue,op); | |
787 | continue; | |
788 | } else { | |
789 | break; | |
e37efb0d | 790 | } |
f771dc23 | 791 | } |
e37efb0d | 792 | |
f771dc23 | 793 | redisLog(REDIS_DEBUG,"Creating IO %s Job for key %s", |
794 | op->type == REDIS_IO_LOAD ? "load" : "save", op->key->ptr); | |
3be00d7e | 795 | |
f771dc23 | 796 | if (op->type == REDIS_IO_LOAD) { |
05600eb8 | 797 | cacheCreateIOJob(REDIS_IOJOB_LOAD,op->db,op->key,NULL,0); |
f771dc23 | 798 | } else { |
05600eb8 | 799 | time_t expire = -1; |
800 | ||
f771dc23 | 801 | /* Lookup the key, in order to put the current value in the IO |
802 | * Job. Otherwise if the key does not exists we schedule a disk | |
803 | * store delete operation, setting the value to NULL. */ | |
804 | de = dictFind(op->db->dict,op->key->ptr); | |
805 | if (de) { | |
806 | val = dictGetEntryVal(de); | |
05600eb8 | 807 | expire = getExpire(op->db,op->key); |
f63f0928 | 808 | } else { |
f771dc23 | 809 | /* Setting the value to NULL tells the IO thread to delete |
810 | * the key on disk. */ | |
811 | val = NULL; | |
f63f0928 | 812 | } |
05600eb8 | 813 | cacheCreateIOJob(REDIS_IOJOB_SAVE,op->db,op->key,val,expire); |
f63f0928 | 814 | } |
f771dc23 | 815 | /* Mark the operation as in progress. */ |
816 | cacheScheduleIODelFlag(op->db,op->key,op->type); | |
817 | cacheScheduleIOAddFlag(op->db,op->key, | |
818 | (op->type == REDIS_IO_LOAD) ? REDIS_IO_LOADINPROG : | |
819 | REDIS_IO_SAVEINPROG); | |
820 | /* Finally remove the operation from the queue. | |
821 | * But we'll have trace of it in the hash table. */ | |
822 | listDelNode(server.cache_io_queue,ln); | |
823 | decrRefCount(op->key); | |
824 | zfree(op); | |
825 | pushed++; | |
f63f0928 | 826 | } |
418d5eaf | 827 | return pushed; |
9b24d8ad | 828 | } |
829 | ||
830 | void cacheCron(void) { | |
831 | /* Push jobs */ | |
832 | cacheScheduleIOPushJobs(0); | |
f63f0928 | 833 | |
834 | /* Reclaim memory from the object cache */ | |
835 | while (server.ds_enabled && zmalloc_used_memory() > | |
836 | server.cache_max_memory) | |
837 | { | |
c15a3887 | 838 | int done = 0; |
839 | ||
840 | if (cacheFreeOneEntry() == REDIS_OK) done++; | |
841 | if (negativeCacheEvictOneEntry() == REDIS_OK) done++; | |
842 | if (done == 0) break; /* nothing more to free */ | |
f63f0928 | 843 | } |
844 | } | |
845 | ||
3be00d7e | 846 | /* ========== Disk store cache - Blocking clients on missing keys =========== */ |
e2641e09 | 847 | |
848 | /* This function makes the clinet 'c' waiting for the key 'key' to be loaded. | |
3be00d7e | 849 | * If the key is already in memory we don't need to block. |
f63f0928 | 850 | * |
5ef64098 | 851 | * FIXME: we should try if it's actually better to suspend the client |
852 | * accessing an object that is being saved, and awake it only when | |
853 | * the saving was completed. | |
854 | * | |
855 | * Otherwise if the key is not in memory, we block the client and start | |
856 | * an IO Job to load it: | |
857 | * | |
858 | * the key is added to the io_keys list in the client structure, and also | |
e2641e09 | 859 | * in the hash table mapping swapped keys to waiting clients, that is, |
860 | * server.io_waited_keys. */ | |
861 | int waitForSwappedKey(redisClient *c, robj *key) { | |
862 | struct dictEntry *de; | |
e2641e09 | 863 | list *l; |
864 | ||
5ef64098 | 865 | /* Return ASAP if the key is in memory */ |
e2641e09 | 866 | de = dictFind(c->db->dict,key->ptr); |
5ef64098 | 867 | if (de != NULL) return 0; |
e2641e09 | 868 | |
d934e1e8 | 869 | /* Don't wait for keys we are sure are not on disk either */ |
870 | if (!cacheKeyMayExist(c->db,key)) return 0; | |
871 | ||
e2641e09 | 872 | /* Add the key to the list of keys this client is waiting for. |
873 | * This maps clients to keys they are waiting for. */ | |
874 | listAddNodeTail(c->io_keys,key); | |
875 | incrRefCount(key); | |
876 | ||
877 | /* Add the client to the swapped keys => clients waiting map. */ | |
878 | de = dictFind(c->db->io_keys,key); | |
879 | if (de == NULL) { | |
880 | int retval; | |
881 | ||
882 | /* For every key we take a list of clients blocked for it */ | |
883 | l = listCreate(); | |
884 | retval = dictAdd(c->db->io_keys,key,l); | |
885 | incrRefCount(key); | |
886 | redisAssert(retval == DICT_OK); | |
887 | } else { | |
888 | l = dictGetEntryVal(de); | |
889 | } | |
890 | listAddNodeTail(l,c); | |
891 | ||
892 | /* Are we already loading the key from disk? If not create a job */ | |
7493d2a0 | 893 | if (de == NULL) { |
894 | int flags = cacheScheduleIOGetFlags(c->db,key); | |
895 | ||
896 | /* It is possible that even if there are no clients waiting for | |
897 | * a load operation, still we have a load operation in progress. | |
898 | * For instance think to a client performing a GET and then | |
899 | * closing the connection */ | |
900 | if ((flags & (REDIS_IO_LOAD|REDIS_IO_LOADINPROG)) == 0) | |
901 | cacheScheduleIO(c->db,key,REDIS_IO_LOAD); | |
902 | } | |
e2641e09 | 903 | return 1; |
904 | } | |
905 | ||
906 | /* Preload keys for any command with first, last and step values for | |
907 | * the command keys prototype, as defined in the command table. */ | |
908 | void waitForMultipleSwappedKeys(redisClient *c, struct redisCommand *cmd, int argc, robj **argv) { | |
909 | int j, last; | |
910 | if (cmd->vm_firstkey == 0) return; | |
911 | last = cmd->vm_lastkey; | |
912 | if (last < 0) last = argc+last; | |
913 | for (j = cmd->vm_firstkey; j <= last; j += cmd->vm_keystep) { | |
914 | redisAssert(j < argc); | |
915 | waitForSwappedKey(c,argv[j]); | |
916 | } | |
917 | } | |
918 | ||
919 | /* Preload keys needed for the ZUNIONSTORE and ZINTERSTORE commands. | |
920 | * Note that the number of keys to preload is user-defined, so we need to | |
921 | * apply a sanity check against argc. */ | |
922 | void zunionInterBlockClientOnSwappedKeys(redisClient *c, struct redisCommand *cmd, int argc, robj **argv) { | |
923 | int i, num; | |
924 | REDIS_NOTUSED(cmd); | |
925 | ||
926 | num = atoi(argv[2]->ptr); | |
927 | if (num > (argc-3)) return; | |
928 | for (i = 0; i < num; i++) { | |
929 | waitForSwappedKey(c,argv[3+i]); | |
930 | } | |
931 | } | |
932 | ||
933 | /* Preload keys needed to execute the entire MULTI/EXEC block. | |
934 | * | |
935 | * This function is called by blockClientOnSwappedKeys when EXEC is issued, | |
936 | * and will block the client when any command requires a swapped out value. */ | |
937 | void execBlockClientOnSwappedKeys(redisClient *c, struct redisCommand *cmd, int argc, robj **argv) { | |
938 | int i, margc; | |
939 | struct redisCommand *mcmd; | |
940 | robj **margv; | |
941 | REDIS_NOTUSED(cmd); | |
942 | REDIS_NOTUSED(argc); | |
943 | REDIS_NOTUSED(argv); | |
944 | ||
945 | if (!(c->flags & REDIS_MULTI)) return; | |
946 | for (i = 0; i < c->mstate.count; i++) { | |
947 | mcmd = c->mstate.commands[i].cmd; | |
948 | margc = c->mstate.commands[i].argc; | |
949 | margv = c->mstate.commands[i].argv; | |
950 | ||
951 | if (mcmd->vm_preload_proc != NULL) { | |
952 | mcmd->vm_preload_proc(c,mcmd,margc,margv); | |
953 | } else { | |
954 | waitForMultipleSwappedKeys(c,mcmd,margc,margv); | |
955 | } | |
956 | } | |
957 | } | |
958 | ||
959 | /* Is this client attempting to run a command against swapped keys? | |
960 | * If so, block it ASAP, load the keys in background, then resume it. | |
961 | * | |
962 | * The important idea about this function is that it can fail! If keys will | |
963 | * still be swapped when the client is resumed, this key lookups will | |
964 | * just block loading keys from disk. In practical terms this should only | |
965 | * happen with SORT BY command or if there is a bug in this function. | |
966 | * | |
967 | * Return 1 if the client is marked as blocked, 0 if the client can | |
968 | * continue as the keys it is going to access appear to be in memory. */ | |
969 | int blockClientOnSwappedKeys(redisClient *c, struct redisCommand *cmd) { | |
970 | if (cmd->vm_preload_proc != NULL) { | |
971 | cmd->vm_preload_proc(c,cmd,c->argc,c->argv); | |
972 | } else { | |
973 | waitForMultipleSwappedKeys(c,cmd,c->argc,c->argv); | |
974 | } | |
975 | ||
976 | /* If the client was blocked for at least one key, mark it as blocked. */ | |
977 | if (listLength(c->io_keys)) { | |
978 | c->flags |= REDIS_IO_WAIT; | |
979 | aeDeleteFileEvent(server.el,c->fd,AE_READABLE); | |
5ef64098 | 980 | server.cache_blocked_clients++; |
e2641e09 | 981 | return 1; |
982 | } else { | |
983 | return 0; | |
984 | } | |
985 | } | |
986 | ||
987 | /* Remove the 'key' from the list of blocked keys for a given client. | |
988 | * | |
989 | * The function returns 1 when there are no longer blocking keys after | |
990 | * the current one was removed (and the client can be unblocked). */ | |
991 | int dontWaitForSwappedKey(redisClient *c, robj *key) { | |
992 | list *l; | |
993 | listNode *ln; | |
994 | listIter li; | |
995 | struct dictEntry *de; | |
996 | ||
c8a10631 PN |
997 | /* The key object might be destroyed when deleted from the c->io_keys |
998 | * list (and the "key" argument is physically the same object as the | |
999 | * object inside the list), so we need to protect it. */ | |
1000 | incrRefCount(key); | |
1001 | ||
e2641e09 | 1002 | /* Remove the key from the list of keys this client is waiting for. */ |
1003 | listRewind(c->io_keys,&li); | |
1004 | while ((ln = listNext(&li)) != NULL) { | |
1005 | if (equalStringObjects(ln->value,key)) { | |
1006 | listDelNode(c->io_keys,ln); | |
1007 | break; | |
1008 | } | |
1009 | } | |
1010 | redisAssert(ln != NULL); | |
1011 | ||
1012 | /* Remove the client form the key => waiting clients map. */ | |
1013 | de = dictFind(c->db->io_keys,key); | |
1014 | redisAssert(de != NULL); | |
1015 | l = dictGetEntryVal(de); | |
1016 | ln = listSearchKey(l,c); | |
1017 | redisAssert(ln != NULL); | |
1018 | listDelNode(l,ln); | |
1019 | if (listLength(l) == 0) | |
1020 | dictDelete(c->db->io_keys,key); | |
1021 | ||
c8a10631 | 1022 | decrRefCount(key); |
e2641e09 | 1023 | return listLength(c->io_keys) == 0; |
1024 | } | |
1025 | ||
1026 | /* Every time we now a key was loaded back in memory, we handle clients | |
1027 | * waiting for this key if any. */ | |
1028 | void handleClientsBlockedOnSwappedKey(redisDb *db, robj *key) { | |
1029 | struct dictEntry *de; | |
1030 | list *l; | |
1031 | listNode *ln; | |
1032 | int len; | |
1033 | ||
1034 | de = dictFind(db->io_keys,key); | |
1035 | if (!de) return; | |
1036 | ||
1037 | l = dictGetEntryVal(de); | |
1038 | len = listLength(l); | |
1039 | /* Note: we can't use something like while(listLength(l)) as the list | |
1040 | * can be freed by the calling function when we remove the last element. */ | |
1041 | while (len--) { | |
1042 | ln = listFirst(l); | |
1043 | redisClient *c = ln->value; | |
1044 | ||
1045 | if (dontWaitForSwappedKey(c,key)) { | |
1046 | /* Put the client in the list of clients ready to go as we | |
1047 | * loaded all the keys about it. */ | |
1048 | listAddNodeTail(server.io_ready_clients,c); | |
1049 | } | |
1050 | } | |
1051 | } |