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1 /*
2 * Copyright (c) 2009-2010, Salvatore Sanfilippo <antirez at gmail dot com>
3 * All rights reserved.
4 *
5 * Redistribution and use in source and binary forms, with or without
6 * modification, are permitted provided that the following conditions are met:
7 *
8 * * Redistributions of source code must retain the above copyright notice,
9 * this list of conditions and the following disclaimer.
10 * * Redistributions in binary form must reproduce the above copyright
11 * notice, this list of conditions and the following disclaimer in the
12 * documentation and/or other materials provided with the distribution.
13 * * Neither the name of Redis nor the names of its contributors may be used
14 * to endorse or promote products derived from this software without
15 * specific prior written permission.
16 *
17 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
18 * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
19 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
20 * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
21 * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
22 * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
23 * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
24 * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
25 * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
26 * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
27 * POSSIBILITY OF SUCH DAMAGE.
28 */
29
30 #define REDIS_VERSION "1.3.10"
31
32 #include "fmacros.h"
33 #include "config.h"
34
35 #include <stdio.h>
36 #include <stdlib.h>
37 #include <string.h>
38 #include <time.h>
39 #include <unistd.h>
40 #define __USE_POSIX199309
41 #define __USE_UNIX98
42 #include <signal.h>
43
44 #ifdef HAVE_BACKTRACE
45 #include <execinfo.h>
46 #include <ucontext.h>
47 #endif /* HAVE_BACKTRACE */
48
49 #include <sys/wait.h>
50 #include <errno.h>
51 #include <assert.h>
52 #include <ctype.h>
53 #include <stdarg.h>
54 #include <inttypes.h>
55 #include <arpa/inet.h>
56 #include <sys/stat.h>
57 #include <fcntl.h>
58 #include <sys/time.h>
59 #include <sys/resource.h>
60 #include <sys/uio.h>
61 #include <limits.h>
62 #include <math.h>
63 #include <pthread.h>
64
65 #if defined(__sun)
66 #include "solarisfixes.h"
67 #endif
68
69 #include "redis.h"
70 #include "ae.h" /* Event driven programming library */
71 #include "sds.h" /* Dynamic safe strings */
72 #include "anet.h" /* Networking the easy way */
73 #include "dict.h" /* Hash tables */
74 #include "adlist.h" /* Linked lists */
75 #include "zmalloc.h" /* total memory usage aware version of malloc/free */
76 #include "lzf.h" /* LZF compression library */
77 #include "pqsort.h" /* Partial qsort for SORT+LIMIT */
78 #include "zipmap.h"
79
80 /* Error codes */
81 #define REDIS_OK 0
82 #define REDIS_ERR -1
83
84 /* Static server configuration */
85 #define REDIS_SERVERPORT 6379 /* TCP port */
86 #define REDIS_MAXIDLETIME (60*5) /* default client timeout */
87 #define REDIS_IOBUF_LEN 1024
88 #define REDIS_LOADBUF_LEN 1024
89 #define REDIS_STATIC_ARGS 8
90 #define REDIS_DEFAULT_DBNUM 16
91 #define REDIS_CONFIGLINE_MAX 1024
92 #define REDIS_OBJFREELIST_MAX 1000000 /* Max number of objects to cache */
93 #define REDIS_MAX_SYNC_TIME 60 /* Slave can't take more to sync */
94 #define REDIS_EXPIRELOOKUPS_PER_CRON 10 /* lookup 10 expires per loop */
95 #define REDIS_MAX_WRITE_PER_EVENT (1024*64)
96 #define REDIS_REQUEST_MAX_SIZE (1024*1024*256) /* max bytes in inline command */
97
98 /* If more then REDIS_WRITEV_THRESHOLD write packets are pending use writev */
99 #define REDIS_WRITEV_THRESHOLD 3
100 /* Max number of iovecs used for each writev call */
101 #define REDIS_WRITEV_IOVEC_COUNT 256
102
103 /* Hash table parameters */
104 #define REDIS_HT_MINFILL 10 /* Minimal hash table fill 10% */
105
106 /* Command flags */
107 #define REDIS_CMD_BULK 1 /* Bulk write command */
108 #define REDIS_CMD_INLINE 2 /* Inline command */
109 /* REDIS_CMD_DENYOOM reserves a longer comment: all the commands marked with
110 this flags will return an error when the 'maxmemory' option is set in the
111 config file and the server is using more than maxmemory bytes of memory.
112 In short this commands are denied on low memory conditions. */
113 #define REDIS_CMD_DENYOOM 4
114 #define REDIS_CMD_FORCE_REPLICATION 8 /* Force replication even if dirty is 0 */
115
116 /* Object types */
117 #define REDIS_STRING 0
118 #define REDIS_LIST 1
119 #define REDIS_SET 2
120 #define REDIS_ZSET 3
121 #define REDIS_HASH 4
122
123 /* Objects encoding. Some kind of objects like Strings and Hashes can be
124 * internally represented in multiple ways. The 'encoding' field of the object
125 * is set to one of this fields for this object. */
126 #define REDIS_ENCODING_RAW 0 /* Raw representation */
127 #define REDIS_ENCODING_INT 1 /* Encoded as integer */
128 #define REDIS_ENCODING_ZIPMAP 2 /* Encoded as zipmap */
129 #define REDIS_ENCODING_HT 3 /* Encoded as an hash table */
130
131 static char* strencoding[] = {
132 "raw", "int", "zipmap", "hashtable"
133 };
134
135 /* Object types only used for dumping to disk */
136 #define REDIS_EXPIRETIME 253
137 #define REDIS_SELECTDB 254
138 #define REDIS_EOF 255
139
140 /* Defines related to the dump file format. To store 32 bits lengths for short
141 * keys requires a lot of space, so we check the most significant 2 bits of
142 * the first byte to interpreter the length:
143 *
144 * 00|000000 => if the two MSB are 00 the len is the 6 bits of this byte
145 * 01|000000 00000000 => 01, the len is 14 byes, 6 bits + 8 bits of next byte
146 * 10|000000 [32 bit integer] => if it's 01, a full 32 bit len will follow
147 * 11|000000 this means: specially encoded object will follow. The six bits
148 * number specify the kind of object that follows.
149 * See the REDIS_RDB_ENC_* defines.
150 *
151 * Lenghts up to 63 are stored using a single byte, most DB keys, and may
152 * values, will fit inside. */
153 #define REDIS_RDB_6BITLEN 0
154 #define REDIS_RDB_14BITLEN 1
155 #define REDIS_RDB_32BITLEN 2
156 #define REDIS_RDB_ENCVAL 3
157 #define REDIS_RDB_LENERR UINT_MAX
158
159 /* When a length of a string object stored on disk has the first two bits
160 * set, the remaining two bits specify a special encoding for the object
161 * accordingly to the following defines: */
162 #define REDIS_RDB_ENC_INT8 0 /* 8 bit signed integer */
163 #define REDIS_RDB_ENC_INT16 1 /* 16 bit signed integer */
164 #define REDIS_RDB_ENC_INT32 2 /* 32 bit signed integer */
165 #define REDIS_RDB_ENC_LZF 3 /* string compressed with FASTLZ */
166
167 /* Virtual memory object->where field. */
168 #define REDIS_VM_MEMORY 0 /* The object is on memory */
169 #define REDIS_VM_SWAPPED 1 /* The object is on disk */
170 #define REDIS_VM_SWAPPING 2 /* Redis is swapping this object on disk */
171 #define REDIS_VM_LOADING 3 /* Redis is loading this object from disk */
172
173 /* Virtual memory static configuration stuff.
174 * Check vmFindContiguousPages() to know more about this magic numbers. */
175 #define REDIS_VM_MAX_NEAR_PAGES 65536
176 #define REDIS_VM_MAX_RANDOM_JUMP 4096
177 #define REDIS_VM_MAX_THREADS 32
178 #define REDIS_THREAD_STACK_SIZE (1024*1024*4)
179 /* The following is the *percentage* of completed I/O jobs to process when the
180 * handelr is called. While Virtual Memory I/O operations are performed by
181 * threads, this operations must be processed by the main thread when completed
182 * in order to take effect. */
183 #define REDIS_MAX_COMPLETED_JOBS_PROCESSED 1
184
185 /* Client flags */
186 #define REDIS_SLAVE 1 /* This client is a slave server */
187 #define REDIS_MASTER 2 /* This client is a master server */
188 #define REDIS_MONITOR 4 /* This client is a slave monitor, see MONITOR */
189 #define REDIS_MULTI 8 /* This client is in a MULTI context */
190 #define REDIS_BLOCKED 16 /* The client is waiting in a blocking operation */
191 #define REDIS_IO_WAIT 32 /* The client is waiting for Virtual Memory I/O */
192
193 /* Slave replication state - slave side */
194 #define REDIS_REPL_NONE 0 /* No active replication */
195 #define REDIS_REPL_CONNECT 1 /* Must connect to master */
196 #define REDIS_REPL_CONNECTED 2 /* Connected to master */
197
198 /* Slave replication state - from the point of view of master
199 * Note that in SEND_BULK and ONLINE state the slave receives new updates
200 * in its output queue. In the WAIT_BGSAVE state instead the server is waiting
201 * to start the next background saving in order to send updates to it. */
202 #define REDIS_REPL_WAIT_BGSAVE_START 3 /* master waits bgsave to start feeding it */
203 #define REDIS_REPL_WAIT_BGSAVE_END 4 /* master waits bgsave to start bulk DB transmission */
204 #define REDIS_REPL_SEND_BULK 5 /* master is sending the bulk DB */
205 #define REDIS_REPL_ONLINE 6 /* bulk DB already transmitted, receive updates */
206
207 /* List related stuff */
208 #define REDIS_HEAD 0
209 #define REDIS_TAIL 1
210
211 /* Sort operations */
212 #define REDIS_SORT_GET 0
213 #define REDIS_SORT_ASC 1
214 #define REDIS_SORT_DESC 2
215 #define REDIS_SORTKEY_MAX 1024
216
217 /* Log levels */
218 #define REDIS_DEBUG 0
219 #define REDIS_VERBOSE 1
220 #define REDIS_NOTICE 2
221 #define REDIS_WARNING 3
222
223 /* Anti-warning macro... */
224 #define REDIS_NOTUSED(V) ((void) V)
225
226 #define ZSKIPLIST_MAXLEVEL 32 /* Should be enough for 2^32 elements */
227 #define ZSKIPLIST_P 0.25 /* Skiplist P = 1/4 */
228
229 /* Append only defines */
230 #define APPENDFSYNC_NO 0
231 #define APPENDFSYNC_ALWAYS 1
232 #define APPENDFSYNC_EVERYSEC 2
233
234 /* Hashes related defaults */
235 #define REDIS_HASH_MAX_ZIPMAP_ENTRIES 64
236 #define REDIS_HASH_MAX_ZIPMAP_VALUE 512
237
238 /* We can print the stacktrace, so our assert is defined this way: */
239 #define redisAssert(_e) ((_e)?(void)0 : (_redisAssert(#_e,__FILE__,__LINE__),_exit(1)))
240 #define redisPanic(_e) _redisPanic(#_e,__FILE__,__LINE__),_exit(1)
241 static void _redisAssert(char *estr, char *file, int line);
242 static void _redisPanic(char *msg, char *file, int line);
243
244 /*================================= Data types ============================== */
245
246 /* A redis object, that is a type able to hold a string / list / set */
247
248 /* The VM object structure */
249 struct redisObjectVM {
250 off_t page; /* the page at witch the object is stored on disk */
251 off_t usedpages; /* number of pages used on disk */
252 time_t atime; /* Last access time */
253 } vm;
254
255 /* The actual Redis Object */
256 typedef struct redisObject {
257 void *ptr;
258 unsigned char type;
259 unsigned char encoding;
260 unsigned char storage; /* If this object is a key, where is the value?
261 * REDIS_VM_MEMORY, REDIS_VM_SWAPPED, ... */
262 unsigned char vtype; /* If this object is a key, and value is swapped out,
263 * this is the type of the swapped out object. */
264 int refcount;
265 /* VM fields, this are only allocated if VM is active, otherwise the
266 * object allocation function will just allocate
267 * sizeof(redisObjct) minus sizeof(redisObjectVM), so using
268 * Redis without VM active will not have any overhead. */
269 struct redisObjectVM vm;
270 } robj;
271
272 /* Macro used to initalize a Redis object allocated on the stack.
273 * Note that this macro is taken near the structure definition to make sure
274 * we'll update it when the structure is changed, to avoid bugs like
275 * bug #85 introduced exactly in this way. */
276 #define initStaticStringObject(_var,_ptr) do { \
277 _var.refcount = 1; \
278 _var.type = REDIS_STRING; \
279 _var.encoding = REDIS_ENCODING_RAW; \
280 _var.ptr = _ptr; \
281 if (server.vm_enabled) _var.storage = REDIS_VM_MEMORY; \
282 } while(0);
283
284 typedef struct redisDb {
285 dict *dict; /* The keyspace for this DB */
286 dict *expires; /* Timeout of keys with a timeout set */
287 dict *blockingkeys; /* Keys with clients waiting for data (BLPOP) */
288 dict *io_keys; /* Keys with clients waiting for VM I/O */
289 int id;
290 } redisDb;
291
292 /* Client MULTI/EXEC state */
293 typedef struct multiCmd {
294 robj **argv;
295 int argc;
296 struct redisCommand *cmd;
297 } multiCmd;
298
299 typedef struct multiState {
300 multiCmd *commands; /* Array of MULTI commands */
301 int count; /* Total number of MULTI commands */
302 } multiState;
303
304 /* With multiplexing we need to take per-clinet state.
305 * Clients are taken in a liked list. */
306 typedef struct redisClient {
307 int fd;
308 redisDb *db;
309 int dictid;
310 sds querybuf;
311 robj **argv, **mbargv;
312 int argc, mbargc;
313 int bulklen; /* bulk read len. -1 if not in bulk read mode */
314 int multibulk; /* multi bulk command format active */
315 list *reply;
316 int sentlen;
317 time_t lastinteraction; /* time of the last interaction, used for timeout */
318 int flags; /* REDIS_SLAVE | REDIS_MONITOR | REDIS_MULTI ... */
319 int slaveseldb; /* slave selected db, if this client is a slave */
320 int authenticated; /* when requirepass is non-NULL */
321 int replstate; /* replication state if this is a slave */
322 int repldbfd; /* replication DB file descriptor */
323 long repldboff; /* replication DB file offset */
324 off_t repldbsize; /* replication DB file size */
325 multiState mstate; /* MULTI/EXEC state */
326 robj **blockingkeys; /* The key we are waiting to terminate a blocking
327 * operation such as BLPOP. Otherwise NULL. */
328 int blockingkeysnum; /* Number of blocking keys */
329 time_t blockingto; /* Blocking operation timeout. If UNIX current time
330 * is >= blockingto then the operation timed out. */
331 list *io_keys; /* Keys this client is waiting to be loaded from the
332 * swap file in order to continue. */
333 dict *pubsub_channels; /* channels a client is interested in (SUBSCRIBE) */
334 list *pubsub_patterns; /* patterns a client is interested in (SUBSCRIBE) */
335 } redisClient;
336
337 struct saveparam {
338 time_t seconds;
339 int changes;
340 };
341
342 /* Global server state structure */
343 struct redisServer {
344 int port;
345 int fd;
346 redisDb *db;
347 long long dirty; /* changes to DB from the last save */
348 list *clients;
349 list *slaves, *monitors;
350 char neterr[ANET_ERR_LEN];
351 aeEventLoop *el;
352 int cronloops; /* number of times the cron function run */
353 list *objfreelist; /* A list of freed objects to avoid malloc() */
354 time_t lastsave; /* Unix time of last save succeeede */
355 /* Fields used only for stats */
356 time_t stat_starttime; /* server start time */
357 long long stat_numcommands; /* number of processed commands */
358 long long stat_numconnections; /* number of connections received */
359 long long stat_expiredkeys; /* number of expired keys */
360 /* Configuration */
361 int verbosity;
362 int glueoutputbuf;
363 int maxidletime;
364 int dbnum;
365 int daemonize;
366 int appendonly;
367 int appendfsync;
368 time_t lastfsync;
369 int appendfd;
370 int appendseldb;
371 char *pidfile;
372 pid_t bgsavechildpid;
373 pid_t bgrewritechildpid;
374 sds bgrewritebuf; /* buffer taken by parent during oppend only rewrite */
375 struct saveparam *saveparams;
376 int saveparamslen;
377 char *logfile;
378 char *bindaddr;
379 char *dbfilename;
380 char *appendfilename;
381 char *requirepass;
382 int shareobjects;
383 int rdbcompression;
384 int activerehashing;
385 /* Replication related */
386 int isslave;
387 char *masterauth;
388 char *masterhost;
389 int masterport;
390 redisClient *master; /* client that is master for this slave */
391 int replstate;
392 unsigned int maxclients;
393 unsigned long long maxmemory;
394 unsigned int blpop_blocked_clients;
395 unsigned int vm_blocked_clients;
396 /* Sort parameters - qsort_r() is only available under BSD so we
397 * have to take this state global, in order to pass it to sortCompare() */
398 int sort_desc;
399 int sort_alpha;
400 int sort_bypattern;
401 /* Virtual memory configuration */
402 int vm_enabled;
403 char *vm_swap_file;
404 off_t vm_page_size;
405 off_t vm_pages;
406 unsigned long long vm_max_memory;
407 /* Hashes config */
408 size_t hash_max_zipmap_entries;
409 size_t hash_max_zipmap_value;
410 /* Virtual memory state */
411 FILE *vm_fp;
412 int vm_fd;
413 off_t vm_next_page; /* Next probably empty page */
414 off_t vm_near_pages; /* Number of pages allocated sequentially */
415 unsigned char *vm_bitmap; /* Bitmap of free/used pages */
416 time_t unixtime; /* Unix time sampled every second. */
417 /* Virtual memory I/O threads stuff */
418 /* An I/O thread process an element taken from the io_jobs queue and
419 * put the result of the operation in the io_done list. While the
420 * job is being processed, it's put on io_processing queue. */
421 list *io_newjobs; /* List of VM I/O jobs yet to be processed */
422 list *io_processing; /* List of VM I/O jobs being processed */
423 list *io_processed; /* List of VM I/O jobs already processed */
424 list *io_ready_clients; /* Clients ready to be unblocked. All keys loaded */
425 pthread_mutex_t io_mutex; /* lock to access io_jobs/io_done/io_thread_job */
426 pthread_mutex_t obj_freelist_mutex; /* safe redis objects creation/free */
427 pthread_mutex_t io_swapfile_mutex; /* So we can lseek + write */
428 pthread_attr_t io_threads_attr; /* attributes for threads creation */
429 int io_active_threads; /* Number of running I/O threads */
430 int vm_max_threads; /* Max number of I/O threads running at the same time */
431 /* Our main thread is blocked on the event loop, locking for sockets ready
432 * to be read or written, so when a threaded I/O operation is ready to be
433 * processed by the main thread, the I/O thread will use a unix pipe to
434 * awake the main thread. The followings are the two pipe FDs. */
435 int io_ready_pipe_read;
436 int io_ready_pipe_write;
437 /* Virtual memory stats */
438 unsigned long long vm_stats_used_pages;
439 unsigned long long vm_stats_swapped_objects;
440 unsigned long long vm_stats_swapouts;
441 unsigned long long vm_stats_swapins;
442 /* Pubsub */
443 dict *pubsub_channels; /* Map channels to list of subscribed clients */
444 list *pubsub_patterns; /* A list of pubsub_patterns */
445 /* Misc */
446 FILE *devnull;
447 };
448
449 typedef struct pubsubPattern {
450 redisClient *client;
451 robj *pattern;
452 } pubsubPattern;
453
454 typedef void redisCommandProc(redisClient *c);
455 struct redisCommand {
456 char *name;
457 redisCommandProc *proc;
458 int arity;
459 int flags;
460 /* Use a function to determine which keys need to be loaded
461 * in the background prior to executing this command. Takes precedence
462 * over vm_firstkey and others, ignored when NULL */
463 redisCommandProc *vm_preload_proc;
464 /* What keys should be loaded in background when calling this command? */
465 int vm_firstkey; /* The first argument that's a key (0 = no keys) */
466 int vm_lastkey; /* THe last argument that's a key */
467 int vm_keystep; /* The step between first and last key */
468 };
469
470 struct redisFunctionSym {
471 char *name;
472 unsigned long pointer;
473 };
474
475 typedef struct _redisSortObject {
476 robj *obj;
477 union {
478 double score;
479 robj *cmpobj;
480 } u;
481 } redisSortObject;
482
483 typedef struct _redisSortOperation {
484 int type;
485 robj *pattern;
486 } redisSortOperation;
487
488 /* ZSETs use a specialized version of Skiplists */
489
490 typedef struct zskiplistNode {
491 struct zskiplistNode **forward;
492 struct zskiplistNode *backward;
493 unsigned int *span;
494 double score;
495 robj *obj;
496 } zskiplistNode;
497
498 typedef struct zskiplist {
499 struct zskiplistNode *header, *tail;
500 unsigned long length;
501 int level;
502 } zskiplist;
503
504 typedef struct zset {
505 dict *dict;
506 zskiplist *zsl;
507 } zset;
508
509 /* Our shared "common" objects */
510
511 #define REDIS_SHARED_INTEGERS 10000
512 struct sharedObjectsStruct {
513 robj *crlf, *ok, *err, *emptybulk, *czero, *cone, *pong, *space,
514 *colon, *nullbulk, *nullmultibulk, *queued,
515 *emptymultibulk, *wrongtypeerr, *nokeyerr, *syntaxerr, *sameobjecterr,
516 *outofrangeerr, *plus,
517 *select0, *select1, *select2, *select3, *select4,
518 *select5, *select6, *select7, *select8, *select9,
519 *messagebulk, *subscribebulk, *unsubscribebulk, *mbulk3,
520 *psubscribebulk, *punsubscribebulk, *integers[REDIS_SHARED_INTEGERS];
521 } shared;
522
523 /* Global vars that are actally used as constants. The following double
524 * values are used for double on-disk serialization, and are initialized
525 * at runtime to avoid strange compiler optimizations. */
526
527 static double R_Zero, R_PosInf, R_NegInf, R_Nan;
528
529 /* VM threaded I/O request message */
530 #define REDIS_IOJOB_LOAD 0 /* Load from disk to memory */
531 #define REDIS_IOJOB_PREPARE_SWAP 1 /* Compute needed pages */
532 #define REDIS_IOJOB_DO_SWAP 2 /* Swap from memory to disk */
533 typedef struct iojob {
534 int type; /* Request type, REDIS_IOJOB_* */
535 redisDb *db;/* Redis database */
536 robj *key; /* This I/O request is about swapping this key */
537 robj *val; /* the value to swap for REDIS_IOREQ_*_SWAP, otherwise this
538 * field is populated by the I/O thread for REDIS_IOREQ_LOAD. */
539 off_t page; /* Swap page where to read/write the object */
540 off_t pages; /* Swap pages needed to save object. PREPARE_SWAP return val */
541 int canceled; /* True if this command was canceled by blocking side of VM */
542 pthread_t thread; /* ID of the thread processing this entry */
543 } iojob;
544
545 /*================================ Prototypes =============================== */
546
547 static void freeStringObject(robj *o);
548 static void freeListObject(robj *o);
549 static void freeSetObject(robj *o);
550 static void decrRefCount(void *o);
551 static robj *createObject(int type, void *ptr);
552 static void freeClient(redisClient *c);
553 static int rdbLoad(char *filename);
554 static void addReply(redisClient *c, robj *obj);
555 static void addReplySds(redisClient *c, sds s);
556 static void incrRefCount(robj *o);
557 static int rdbSaveBackground(char *filename);
558 static robj *createStringObject(char *ptr, size_t len);
559 static robj *dupStringObject(robj *o);
560 static void replicationFeedSlaves(list *slaves, int dictid, robj **argv, int argc);
561 static void feedAppendOnlyFile(struct redisCommand *cmd, int dictid, robj **argv, int argc);
562 static int syncWithMaster(void);
563 static robj *tryObjectEncoding(robj *o);
564 static robj *getDecodedObject(robj *o);
565 static int removeExpire(redisDb *db, robj *key);
566 static int expireIfNeeded(redisDb *db, robj *key);
567 static int deleteIfVolatile(redisDb *db, robj *key);
568 static int deleteIfSwapped(redisDb *db, robj *key);
569 static int deleteKey(redisDb *db, robj *key);
570 static time_t getExpire(redisDb *db, robj *key);
571 static int setExpire(redisDb *db, robj *key, time_t when);
572 static void updateSlavesWaitingBgsave(int bgsaveerr);
573 static void freeMemoryIfNeeded(void);
574 static int processCommand(redisClient *c);
575 static void setupSigSegvAction(void);
576 static void rdbRemoveTempFile(pid_t childpid);
577 static void aofRemoveTempFile(pid_t childpid);
578 static size_t stringObjectLen(robj *o);
579 static void processInputBuffer(redisClient *c);
580 static zskiplist *zslCreate(void);
581 static void zslFree(zskiplist *zsl);
582 static void zslInsert(zskiplist *zsl, double score, robj *obj);
583 static void sendReplyToClientWritev(aeEventLoop *el, int fd, void *privdata, int mask);
584 static void initClientMultiState(redisClient *c);
585 static void freeClientMultiState(redisClient *c);
586 static void queueMultiCommand(redisClient *c, struct redisCommand *cmd);
587 static void unblockClientWaitingData(redisClient *c);
588 static int handleClientsWaitingListPush(redisClient *c, robj *key, robj *ele);
589 static void vmInit(void);
590 static void vmMarkPagesFree(off_t page, off_t count);
591 static robj *vmLoadObject(robj *key);
592 static robj *vmPreviewObject(robj *key);
593 static int vmSwapOneObjectBlocking(void);
594 static int vmSwapOneObjectThreaded(void);
595 static int vmCanSwapOut(void);
596 static int tryFreeOneObjectFromFreelist(void);
597 static void acceptHandler(aeEventLoop *el, int fd, void *privdata, int mask);
598 static void vmThreadedIOCompletedJob(aeEventLoop *el, int fd, void *privdata, int mask);
599 static void vmCancelThreadedIOJob(robj *o);
600 static void lockThreadedIO(void);
601 static void unlockThreadedIO(void);
602 static int vmSwapObjectThreaded(robj *key, robj *val, redisDb *db);
603 static void freeIOJob(iojob *j);
604 static void queueIOJob(iojob *j);
605 static int vmWriteObjectOnSwap(robj *o, off_t page);
606 static robj *vmReadObjectFromSwap(off_t page, int type);
607 static void waitEmptyIOJobsQueue(void);
608 static void vmReopenSwapFile(void);
609 static int vmFreePage(off_t page);
610 static void zunionInterBlockClientOnSwappedKeys(redisClient *c);
611 static int blockClientOnSwappedKeys(struct redisCommand *cmd, redisClient *c);
612 static int dontWaitForSwappedKey(redisClient *c, robj *key);
613 static void handleClientsBlockedOnSwappedKey(redisDb *db, robj *key);
614 static void readQueryFromClient(aeEventLoop *el, int fd, void *privdata, int mask);
615 static struct redisCommand *lookupCommand(char *name);
616 static void call(redisClient *c, struct redisCommand *cmd);
617 static void resetClient(redisClient *c);
618 static void convertToRealHash(robj *o);
619 static int pubsubUnsubscribeAllChannels(redisClient *c, int notify);
620 static int pubsubUnsubscribeAllPatterns(redisClient *c, int notify);
621 static void freePubsubPattern(void *p);
622 static int listMatchPubsubPattern(void *a, void *b);
623 static int compareStringObjects(robj *a, robj *b);
624 static void usage();
625
626 static void authCommand(redisClient *c);
627 static void pingCommand(redisClient *c);
628 static void echoCommand(redisClient *c);
629 static void setCommand(redisClient *c);
630 static void setnxCommand(redisClient *c);
631 static void getCommand(redisClient *c);
632 static void delCommand(redisClient *c);
633 static void existsCommand(redisClient *c);
634 static void incrCommand(redisClient *c);
635 static void decrCommand(redisClient *c);
636 static void incrbyCommand(redisClient *c);
637 static void decrbyCommand(redisClient *c);
638 static void selectCommand(redisClient *c);
639 static void randomkeyCommand(redisClient *c);
640 static void keysCommand(redisClient *c);
641 static void dbsizeCommand(redisClient *c);
642 static void lastsaveCommand(redisClient *c);
643 static void saveCommand(redisClient *c);
644 static void bgsaveCommand(redisClient *c);
645 static void bgrewriteaofCommand(redisClient *c);
646 static void shutdownCommand(redisClient *c);
647 static void moveCommand(redisClient *c);
648 static void renameCommand(redisClient *c);
649 static void renamenxCommand(redisClient *c);
650 static void lpushCommand(redisClient *c);
651 static void rpushCommand(redisClient *c);
652 static void lpopCommand(redisClient *c);
653 static void rpopCommand(redisClient *c);
654 static void llenCommand(redisClient *c);
655 static void lindexCommand(redisClient *c);
656 static void lrangeCommand(redisClient *c);
657 static void ltrimCommand(redisClient *c);
658 static void typeCommand(redisClient *c);
659 static void lsetCommand(redisClient *c);
660 static void saddCommand(redisClient *c);
661 static void sremCommand(redisClient *c);
662 static void smoveCommand(redisClient *c);
663 static void sismemberCommand(redisClient *c);
664 static void scardCommand(redisClient *c);
665 static void spopCommand(redisClient *c);
666 static void srandmemberCommand(redisClient *c);
667 static void sinterCommand(redisClient *c);
668 static void sinterstoreCommand(redisClient *c);
669 static void sunionCommand(redisClient *c);
670 static void sunionstoreCommand(redisClient *c);
671 static void sdiffCommand(redisClient *c);
672 static void sdiffstoreCommand(redisClient *c);
673 static void syncCommand(redisClient *c);
674 static void flushdbCommand(redisClient *c);
675 static void flushallCommand(redisClient *c);
676 static void sortCommand(redisClient *c);
677 static void lremCommand(redisClient *c);
678 static void rpoplpushcommand(redisClient *c);
679 static void infoCommand(redisClient *c);
680 static void mgetCommand(redisClient *c);
681 static void monitorCommand(redisClient *c);
682 static void expireCommand(redisClient *c);
683 static void expireatCommand(redisClient *c);
684 static void getsetCommand(redisClient *c);
685 static void ttlCommand(redisClient *c);
686 static void slaveofCommand(redisClient *c);
687 static void debugCommand(redisClient *c);
688 static void msetCommand(redisClient *c);
689 static void msetnxCommand(redisClient *c);
690 static void zaddCommand(redisClient *c);
691 static void zincrbyCommand(redisClient *c);
692 static void zrangeCommand(redisClient *c);
693 static void zrangebyscoreCommand(redisClient *c);
694 static void zcountCommand(redisClient *c);
695 static void zrevrangeCommand(redisClient *c);
696 static void zcardCommand(redisClient *c);
697 static void zremCommand(redisClient *c);
698 static void zscoreCommand(redisClient *c);
699 static void zremrangebyscoreCommand(redisClient *c);
700 static void multiCommand(redisClient *c);
701 static void execCommand(redisClient *c);
702 static void discardCommand(redisClient *c);
703 static void blpopCommand(redisClient *c);
704 static void brpopCommand(redisClient *c);
705 static void appendCommand(redisClient *c);
706 static void substrCommand(redisClient *c);
707 static void zrankCommand(redisClient *c);
708 static void zrevrankCommand(redisClient *c);
709 static void hsetCommand(redisClient *c);
710 static void hsetnxCommand(redisClient *c);
711 static void hgetCommand(redisClient *c);
712 static void hmsetCommand(redisClient *c);
713 static void hmgetCommand(redisClient *c);
714 static void hdelCommand(redisClient *c);
715 static void hlenCommand(redisClient *c);
716 static void zremrangebyrankCommand(redisClient *c);
717 static void zunionCommand(redisClient *c);
718 static void zinterCommand(redisClient *c);
719 static void hkeysCommand(redisClient *c);
720 static void hvalsCommand(redisClient *c);
721 static void hgetallCommand(redisClient *c);
722 static void hexistsCommand(redisClient *c);
723 static void configCommand(redisClient *c);
724 static void hincrbyCommand(redisClient *c);
725 static void subscribeCommand(redisClient *c);
726 static void unsubscribeCommand(redisClient *c);
727 static void psubscribeCommand(redisClient *c);
728 static void punsubscribeCommand(redisClient *c);
729 static void publishCommand(redisClient *c);
730
731 /*================================= Globals ================================= */
732
733 /* Global vars */
734 static struct redisServer server; /* server global state */
735 static struct redisCommand cmdTable[] = {
736 {"get",getCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
737 {"set",setCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,0,0,0},
738 {"setnx",setnxCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,0,0,0},
739 {"append",appendCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
740 {"substr",substrCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
741 {"del",delCommand,-2,REDIS_CMD_INLINE,NULL,0,0,0},
742 {"exists",existsCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
743 {"incr",incrCommand,2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
744 {"decr",decrCommand,2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
745 {"mget",mgetCommand,-2,REDIS_CMD_INLINE,NULL,1,-1,1},
746 {"rpush",rpushCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
747 {"lpush",lpushCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
748 {"rpop",rpopCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
749 {"lpop",lpopCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
750 {"brpop",brpopCommand,-3,REDIS_CMD_INLINE,NULL,1,1,1},
751 {"blpop",blpopCommand,-3,REDIS_CMD_INLINE,NULL,1,1,1},
752 {"llen",llenCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
753 {"lindex",lindexCommand,3,REDIS_CMD_INLINE,NULL,1,1,1},
754 {"lset",lsetCommand,4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
755 {"lrange",lrangeCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
756 {"ltrim",ltrimCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
757 {"lrem",lremCommand,4,REDIS_CMD_BULK,NULL,1,1,1},
758 {"rpoplpush",rpoplpushcommand,3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,2,1},
759 {"sadd",saddCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
760 {"srem",sremCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
761 {"smove",smoveCommand,4,REDIS_CMD_BULK,NULL,1,2,1},
762 {"sismember",sismemberCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
763 {"scard",scardCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
764 {"spop",spopCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
765 {"srandmember",srandmemberCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
766 {"sinter",sinterCommand,-2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,-1,1},
767 {"sinterstore",sinterstoreCommand,-3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,2,-1,1},
768 {"sunion",sunionCommand,-2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,-1,1},
769 {"sunionstore",sunionstoreCommand,-3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,2,-1,1},
770 {"sdiff",sdiffCommand,-2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,-1,1},
771 {"sdiffstore",sdiffstoreCommand,-3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,2,-1,1},
772 {"smembers",sinterCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
773 {"zadd",zaddCommand,4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
774 {"zincrby",zincrbyCommand,4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
775 {"zrem",zremCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
776 {"zremrangebyscore",zremrangebyscoreCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
777 {"zremrangebyrank",zremrangebyrankCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
778 {"zunion",zunionCommand,-4,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,zunionInterBlockClientOnSwappedKeys,0,0,0},
779 {"zinter",zinterCommand,-4,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,zunionInterBlockClientOnSwappedKeys,0,0,0},
780 {"zrange",zrangeCommand,-4,REDIS_CMD_INLINE,NULL,1,1,1},
781 {"zrangebyscore",zrangebyscoreCommand,-4,REDIS_CMD_INLINE,NULL,1,1,1},
782 {"zcount",zcountCommand,4,REDIS_CMD_INLINE,NULL,1,1,1},
783 {"zrevrange",zrevrangeCommand,-4,REDIS_CMD_INLINE,NULL,1,1,1},
784 {"zcard",zcardCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
785 {"zscore",zscoreCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
786 {"zrank",zrankCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
787 {"zrevrank",zrevrankCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
788 {"hset",hsetCommand,4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
789 {"hsetnx",hsetnxCommand,4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
790 {"hget",hgetCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
791 {"hmset",hmsetCommand,-4,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
792 {"hmget",hmgetCommand,-3,REDIS_CMD_BULK,NULL,1,1,1},
793 {"hincrby",hincrbyCommand,4,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
794 {"hdel",hdelCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
795 {"hlen",hlenCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
796 {"hkeys",hkeysCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
797 {"hvals",hvalsCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
798 {"hgetall",hgetallCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
799 {"hexists",hexistsCommand,3,REDIS_CMD_BULK,NULL,1,1,1},
800 {"incrby",incrbyCommand,3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
801 {"decrby",decrbyCommand,3,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
802 {"getset",getsetCommand,3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,1,1},
803 {"mset",msetCommand,-3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,-1,2},
804 {"msetnx",msetnxCommand,-3,REDIS_CMD_BULK|REDIS_CMD_DENYOOM,NULL,1,-1,2},
805 {"randomkey",randomkeyCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
806 {"select",selectCommand,2,REDIS_CMD_INLINE,NULL,0,0,0},
807 {"move",moveCommand,3,REDIS_CMD_INLINE,NULL,1,1,1},
808 {"rename",renameCommand,3,REDIS_CMD_INLINE,NULL,1,1,1},
809 {"renamenx",renamenxCommand,3,REDIS_CMD_INLINE,NULL,1,1,1},
810 {"expire",expireCommand,3,REDIS_CMD_INLINE,NULL,0,0,0},
811 {"expireat",expireatCommand,3,REDIS_CMD_INLINE,NULL,0,0,0},
812 {"keys",keysCommand,2,REDIS_CMD_INLINE,NULL,0,0,0},
813 {"dbsize",dbsizeCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
814 {"auth",authCommand,2,REDIS_CMD_INLINE,NULL,0,0,0},
815 {"ping",pingCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
816 {"echo",echoCommand,2,REDIS_CMD_BULK,NULL,0,0,0},
817 {"save",saveCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
818 {"bgsave",bgsaveCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
819 {"bgrewriteaof",bgrewriteaofCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
820 {"shutdown",shutdownCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
821 {"lastsave",lastsaveCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
822 {"type",typeCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
823 {"multi",multiCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
824 {"exec",execCommand,1,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,0,0,0},
825 {"discard",discardCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
826 {"sync",syncCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
827 {"flushdb",flushdbCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
828 {"flushall",flushallCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
829 {"sort",sortCommand,-2,REDIS_CMD_INLINE|REDIS_CMD_DENYOOM,NULL,1,1,1},
830 {"info",infoCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
831 {"monitor",monitorCommand,1,REDIS_CMD_INLINE,NULL,0,0,0},
832 {"ttl",ttlCommand,2,REDIS_CMD_INLINE,NULL,1,1,1},
833 {"slaveof",slaveofCommand,3,REDIS_CMD_INLINE,NULL,0,0,0},
834 {"debug",debugCommand,-2,REDIS_CMD_INLINE,NULL,0,0,0},
835 {"config",configCommand,-2,REDIS_CMD_BULK,NULL,0,0,0},
836 {"subscribe",subscribeCommand,-2,REDIS_CMD_INLINE,NULL,0,0,0},
837 {"unsubscribe",unsubscribeCommand,-1,REDIS_CMD_INLINE,NULL,0,0,0},
838 {"psubscribe",psubscribeCommand,-2,REDIS_CMD_INLINE,NULL,0,0,0},
839 {"punsubscribe",punsubscribeCommand,-1,REDIS_CMD_INLINE,NULL,0,0,0},
840 {"publish",publishCommand,3,REDIS_CMD_BULK|REDIS_CMD_FORCE_REPLICATION,NULL,0,0,0},
841 {NULL,NULL,0,0,NULL,0,0,0}
842 };
843
844 /*============================ Utility functions ============================ */
845
846 /* Glob-style pattern matching. */
847 static int stringmatchlen(const char *pattern, int patternLen,
848 const char *string, int stringLen, int nocase)
849 {
850 while(patternLen) {
851 switch(pattern[0]) {
852 case '*':
853 while (pattern[1] == '*') {
854 pattern++;
855 patternLen--;
856 }
857 if (patternLen == 1)
858 return 1; /* match */
859 while(stringLen) {
860 if (stringmatchlen(pattern+1, patternLen-1,
861 string, stringLen, nocase))
862 return 1; /* match */
863 string++;
864 stringLen--;
865 }
866 return 0; /* no match */
867 break;
868 case '?':
869 if (stringLen == 0)
870 return 0; /* no match */
871 string++;
872 stringLen--;
873 break;
874 case '[':
875 {
876 int not, match;
877
878 pattern++;
879 patternLen--;
880 not = pattern[0] == '^';
881 if (not) {
882 pattern++;
883 patternLen--;
884 }
885 match = 0;
886 while(1) {
887 if (pattern[0] == '\\') {
888 pattern++;
889 patternLen--;
890 if (pattern[0] == string[0])
891 match = 1;
892 } else if (pattern[0] == ']') {
893 break;
894 } else if (patternLen == 0) {
895 pattern--;
896 patternLen++;
897 break;
898 } else if (pattern[1] == '-' && patternLen >= 3) {
899 int start = pattern[0];
900 int end = pattern[2];
901 int c = string[0];
902 if (start > end) {
903 int t = start;
904 start = end;
905 end = t;
906 }
907 if (nocase) {
908 start = tolower(start);
909 end = tolower(end);
910 c = tolower(c);
911 }
912 pattern += 2;
913 patternLen -= 2;
914 if (c >= start && c <= end)
915 match = 1;
916 } else {
917 if (!nocase) {
918 if (pattern[0] == string[0])
919 match = 1;
920 } else {
921 if (tolower((int)pattern[0]) == tolower((int)string[0]))
922 match = 1;
923 }
924 }
925 pattern++;
926 patternLen--;
927 }
928 if (not)
929 match = !match;
930 if (!match)
931 return 0; /* no match */
932 string++;
933 stringLen--;
934 break;
935 }
936 case '\\':
937 if (patternLen >= 2) {
938 pattern++;
939 patternLen--;
940 }
941 /* fall through */
942 default:
943 if (!nocase) {
944 if (pattern[0] != string[0])
945 return 0; /* no match */
946 } else {
947 if (tolower((int)pattern[0]) != tolower((int)string[0]))
948 return 0; /* no match */
949 }
950 string++;
951 stringLen--;
952 break;
953 }
954 pattern++;
955 patternLen--;
956 if (stringLen == 0) {
957 while(*pattern == '*') {
958 pattern++;
959 patternLen--;
960 }
961 break;
962 }
963 }
964 if (patternLen == 0 && stringLen == 0)
965 return 1;
966 return 0;
967 }
968
969 static int stringmatch(const char *pattern, const char *string, int nocase) {
970 return stringmatchlen(pattern,strlen(pattern),string,strlen(string),nocase);
971 }
972
973 static void redisLog(int level, const char *fmt, ...) {
974 va_list ap;
975 FILE *fp;
976
977 fp = (server.logfile == NULL) ? stdout : fopen(server.logfile,"a");
978 if (!fp) return;
979
980 va_start(ap, fmt);
981 if (level >= server.verbosity) {
982 char *c = ".-*#";
983 char buf[64];
984 time_t now;
985
986 now = time(NULL);
987 strftime(buf,64,"%d %b %H:%M:%S",localtime(&now));
988 fprintf(fp,"[%d] %s %c ",(int)getpid(),buf,c[level]);
989 vfprintf(fp, fmt, ap);
990 fprintf(fp,"\n");
991 fflush(fp);
992 }
993 va_end(ap);
994
995 if (server.logfile) fclose(fp);
996 }
997
998 /*====================== Hash table type implementation ==================== */
999
1000 /* This is an hash table type that uses the SDS dynamic strings libary as
1001 * keys and radis objects as values (objects can hold SDS strings,
1002 * lists, sets). */
1003
1004 static void dictVanillaFree(void *privdata, void *val)
1005 {
1006 DICT_NOTUSED(privdata);
1007 zfree(val);
1008 }
1009
1010 static void dictListDestructor(void *privdata, void *val)
1011 {
1012 DICT_NOTUSED(privdata);
1013 listRelease((list*)val);
1014 }
1015
1016 static int sdsDictKeyCompare(void *privdata, const void *key1,
1017 const void *key2)
1018 {
1019 int l1,l2;
1020 DICT_NOTUSED(privdata);
1021
1022 l1 = sdslen((sds)key1);
1023 l2 = sdslen((sds)key2);
1024 if (l1 != l2) return 0;
1025 return memcmp(key1, key2, l1) == 0;
1026 }
1027
1028 static void dictRedisObjectDestructor(void *privdata, void *val)
1029 {
1030 DICT_NOTUSED(privdata);
1031
1032 if (val == NULL) return; /* Values of swapped out keys as set to NULL */
1033 decrRefCount(val);
1034 }
1035
1036 static int dictObjKeyCompare(void *privdata, const void *key1,
1037 const void *key2)
1038 {
1039 const robj *o1 = key1, *o2 = key2;
1040 return sdsDictKeyCompare(privdata,o1->ptr,o2->ptr);
1041 }
1042
1043 static unsigned int dictObjHash(const void *key) {
1044 const robj *o = key;
1045 return dictGenHashFunction(o->ptr, sdslen((sds)o->ptr));
1046 }
1047
1048 static int dictEncObjKeyCompare(void *privdata, const void *key1,
1049 const void *key2)
1050 {
1051 robj *o1 = (robj*) key1, *o2 = (robj*) key2;
1052 int cmp;
1053
1054 if (o1->encoding == REDIS_ENCODING_INT &&
1055 o2->encoding == REDIS_ENCODING_INT &&
1056 o1->ptr == o2->ptr) return 1;
1057
1058 o1 = getDecodedObject(o1);
1059 o2 = getDecodedObject(o2);
1060 cmp = sdsDictKeyCompare(privdata,o1->ptr,o2->ptr);
1061 decrRefCount(o1);
1062 decrRefCount(o2);
1063 return cmp;
1064 }
1065
1066 static unsigned int dictEncObjHash(const void *key) {
1067 robj *o = (robj*) key;
1068
1069 if (o->encoding == REDIS_ENCODING_RAW) {
1070 return dictGenHashFunction(o->ptr, sdslen((sds)o->ptr));
1071 } else {
1072 if (o->encoding == REDIS_ENCODING_INT) {
1073 char buf[32];
1074 int len;
1075
1076 len = snprintf(buf,32,"%ld",(long)o->ptr);
1077 return dictGenHashFunction((unsigned char*)buf, len);
1078 } else {
1079 unsigned int hash;
1080
1081 o = getDecodedObject(o);
1082 hash = dictGenHashFunction(o->ptr, sdslen((sds)o->ptr));
1083 decrRefCount(o);
1084 return hash;
1085 }
1086 }
1087 }
1088
1089 /* Sets type and expires */
1090 static dictType setDictType = {
1091 dictEncObjHash, /* hash function */
1092 NULL, /* key dup */
1093 NULL, /* val dup */
1094 dictEncObjKeyCompare, /* key compare */
1095 dictRedisObjectDestructor, /* key destructor */
1096 NULL /* val destructor */
1097 };
1098
1099 /* Sorted sets hash (note: a skiplist is used in addition to the hash table) */
1100 static dictType zsetDictType = {
1101 dictEncObjHash, /* hash function */
1102 NULL, /* key dup */
1103 NULL, /* val dup */
1104 dictEncObjKeyCompare, /* key compare */
1105 dictRedisObjectDestructor, /* key destructor */
1106 dictVanillaFree /* val destructor of malloc(sizeof(double)) */
1107 };
1108
1109 /* Db->dict */
1110 static dictType dbDictType = {
1111 dictObjHash, /* hash function */
1112 NULL, /* key dup */
1113 NULL, /* val dup */
1114 dictObjKeyCompare, /* key compare */
1115 dictRedisObjectDestructor, /* key destructor */
1116 dictRedisObjectDestructor /* val destructor */
1117 };
1118
1119 /* Db->expires */
1120 static dictType keyptrDictType = {
1121 dictObjHash, /* hash function */
1122 NULL, /* key dup */
1123 NULL, /* val dup */
1124 dictObjKeyCompare, /* key compare */
1125 dictRedisObjectDestructor, /* key destructor */
1126 NULL /* val destructor */
1127 };
1128
1129 /* Hash type hash table (note that small hashes are represented with zimpaps) */
1130 static dictType hashDictType = {
1131 dictEncObjHash, /* hash function */
1132 NULL, /* key dup */
1133 NULL, /* val dup */
1134 dictEncObjKeyCompare, /* key compare */
1135 dictRedisObjectDestructor, /* key destructor */
1136 dictRedisObjectDestructor /* val destructor */
1137 };
1138
1139 /* Keylist hash table type has unencoded redis objects as keys and
1140 * lists as values. It's used for blocking operations (BLPOP) and to
1141 * map swapped keys to a list of clients waiting for this keys to be loaded. */
1142 static dictType keylistDictType = {
1143 dictObjHash, /* hash function */
1144 NULL, /* key dup */
1145 NULL, /* val dup */
1146 dictObjKeyCompare, /* key compare */
1147 dictRedisObjectDestructor, /* key destructor */
1148 dictListDestructor /* val destructor */
1149 };
1150
1151 static void version();
1152
1153 /* ========================= Random utility functions ======================= */
1154
1155 /* Redis generally does not try to recover from out of memory conditions
1156 * when allocating objects or strings, it is not clear if it will be possible
1157 * to report this condition to the client since the networking layer itself
1158 * is based on heap allocation for send buffers, so we simply abort.
1159 * At least the code will be simpler to read... */
1160 static void oom(const char *msg) {
1161 redisLog(REDIS_WARNING, "%s: Out of memory\n",msg);
1162 sleep(1);
1163 abort();
1164 }
1165
1166 /* ====================== Redis server networking stuff ===================== */
1167 static void closeTimedoutClients(void) {
1168 redisClient *c;
1169 listNode *ln;
1170 time_t now = time(NULL);
1171 listIter li;
1172
1173 listRewind(server.clients,&li);
1174 while ((ln = listNext(&li)) != NULL) {
1175 c = listNodeValue(ln);
1176 if (server.maxidletime &&
1177 !(c->flags & REDIS_SLAVE) && /* no timeout for slaves */
1178 !(c->flags & REDIS_MASTER) && /* no timeout for masters */
1179 dictSize(c->pubsub_channels) == 0 && /* no timeout for pubsub */
1180 listLength(c->pubsub_patterns) == 0 &&
1181 (now - c->lastinteraction > server.maxidletime))
1182 {
1183 redisLog(REDIS_VERBOSE,"Closing idle client");
1184 freeClient(c);
1185 } else if (c->flags & REDIS_BLOCKED) {
1186 if (c->blockingto != 0 && c->blockingto < now) {
1187 addReply(c,shared.nullmultibulk);
1188 unblockClientWaitingData(c);
1189 }
1190 }
1191 }
1192 }
1193
1194 static int htNeedsResize(dict *dict) {
1195 long long size, used;
1196
1197 size = dictSlots(dict);
1198 used = dictSize(dict);
1199 return (size && used && size > DICT_HT_INITIAL_SIZE &&
1200 (used*100/size < REDIS_HT_MINFILL));
1201 }
1202
1203 /* If the percentage of used slots in the HT reaches REDIS_HT_MINFILL
1204 * we resize the hash table to save memory */
1205 static void tryResizeHashTables(void) {
1206 int j;
1207
1208 for (j = 0; j < server.dbnum; j++) {
1209 if (htNeedsResize(server.db[j].dict))
1210 dictResize(server.db[j].dict);
1211 if (htNeedsResize(server.db[j].expires))
1212 dictResize(server.db[j].expires);
1213 }
1214 }
1215
1216 /* Our hash table implementation performs rehashing incrementally while
1217 * we write/read from the hash table. Still if the server is idle, the hash
1218 * table will use two tables for a long time. So we try to use 1 millisecond
1219 * of CPU time at every serverCron() loop in order to rehash some key. */
1220 static void incrementallyRehash(void) {
1221 int j;
1222
1223 for (j = 0; j < server.dbnum; j++) {
1224 if (dictIsRehashing(server.db[j].dict)) {
1225 dictRehashMilliseconds(server.db[j].dict,1);
1226 break; /* already used our millisecond for this loop... */
1227 }
1228 }
1229 }
1230
1231 /* A background saving child (BGSAVE) terminated its work. Handle this. */
1232 void backgroundSaveDoneHandler(int statloc) {
1233 int exitcode = WEXITSTATUS(statloc);
1234 int bysignal = WIFSIGNALED(statloc);
1235
1236 if (!bysignal && exitcode == 0) {
1237 redisLog(REDIS_NOTICE,
1238 "Background saving terminated with success");
1239 server.dirty = 0;
1240 server.lastsave = time(NULL);
1241 } else if (!bysignal && exitcode != 0) {
1242 redisLog(REDIS_WARNING, "Background saving error");
1243 } else {
1244 redisLog(REDIS_WARNING,
1245 "Background saving terminated by signal %d", WTERMSIG(statloc));
1246 rdbRemoveTempFile(server.bgsavechildpid);
1247 }
1248 server.bgsavechildpid = -1;
1249 /* Possibly there are slaves waiting for a BGSAVE in order to be served
1250 * (the first stage of SYNC is a bulk transfer of dump.rdb) */
1251 updateSlavesWaitingBgsave(exitcode == 0 ? REDIS_OK : REDIS_ERR);
1252 }
1253
1254 /* A background append only file rewriting (BGREWRITEAOF) terminated its work.
1255 * Handle this. */
1256 void backgroundRewriteDoneHandler(int statloc) {
1257 int exitcode = WEXITSTATUS(statloc);
1258 int bysignal = WIFSIGNALED(statloc);
1259
1260 if (!bysignal && exitcode == 0) {
1261 int fd;
1262 char tmpfile[256];
1263
1264 redisLog(REDIS_NOTICE,
1265 "Background append only file rewriting terminated with success");
1266 /* Now it's time to flush the differences accumulated by the parent */
1267 snprintf(tmpfile,256,"temp-rewriteaof-bg-%d.aof", (int) server.bgrewritechildpid);
1268 fd = open(tmpfile,O_WRONLY|O_APPEND);
1269 if (fd == -1) {
1270 redisLog(REDIS_WARNING, "Not able to open the temp append only file produced by the child: %s", strerror(errno));
1271 goto cleanup;
1272 }
1273 /* Flush our data... */
1274 if (write(fd,server.bgrewritebuf,sdslen(server.bgrewritebuf)) !=
1275 (signed) sdslen(server.bgrewritebuf)) {
1276 redisLog(REDIS_WARNING, "Error or short write trying to flush the parent diff of the append log file in the child temp file: %s", strerror(errno));
1277 close(fd);
1278 goto cleanup;
1279 }
1280 redisLog(REDIS_NOTICE,"Parent diff flushed into the new append log file with success (%lu bytes)",sdslen(server.bgrewritebuf));
1281 /* Now our work is to rename the temp file into the stable file. And
1282 * switch the file descriptor used by the server for append only. */
1283 if (rename(tmpfile,server.appendfilename) == -1) {
1284 redisLog(REDIS_WARNING,"Can't rename the temp append only file into the stable one: %s", strerror(errno));
1285 close(fd);
1286 goto cleanup;
1287 }
1288 /* Mission completed... almost */
1289 redisLog(REDIS_NOTICE,"Append only file successfully rewritten.");
1290 if (server.appendfd != -1) {
1291 /* If append only is actually enabled... */
1292 close(server.appendfd);
1293 server.appendfd = fd;
1294 fsync(fd);
1295 server.appendseldb = -1; /* Make sure it will issue SELECT */
1296 redisLog(REDIS_NOTICE,"The new append only file was selected for future appends.");
1297 } else {
1298 /* If append only is disabled we just generate a dump in this
1299 * format. Why not? */
1300 close(fd);
1301 }
1302 } else if (!bysignal && exitcode != 0) {
1303 redisLog(REDIS_WARNING, "Background append only file rewriting error");
1304 } else {
1305 redisLog(REDIS_WARNING,
1306 "Background append only file rewriting terminated by signal %d",
1307 WTERMSIG(statloc));
1308 }
1309 cleanup:
1310 sdsfree(server.bgrewritebuf);
1311 server.bgrewritebuf = sdsempty();
1312 aofRemoveTempFile(server.bgrewritechildpid);
1313 server.bgrewritechildpid = -1;
1314 }
1315
1316 /* This function is called once a background process of some kind terminates,
1317 * as we want to avoid resizing the hash tables when there is a child in order
1318 * to play well with copy-on-write (otherwise when a resize happens lots of
1319 * memory pages are copied). The goal of this function is to update the ability
1320 * for dict.c to resize the hash tables accordingly to the fact we have o not
1321 * running childs. */
1322 static void updateDictResizePolicy(void) {
1323 if (server.bgsavechildpid == -1 && server.bgrewritechildpid == -1)
1324 dictEnableResize();
1325 else
1326 dictDisableResize();
1327 }
1328
1329 static int serverCron(struct aeEventLoop *eventLoop, long long id, void *clientData) {
1330 int j, loops = server.cronloops++;
1331 REDIS_NOTUSED(eventLoop);
1332 REDIS_NOTUSED(id);
1333 REDIS_NOTUSED(clientData);
1334
1335 /* We take a cached value of the unix time in the global state because
1336 * with virtual memory and aging there is to store the current time
1337 * in objects at every object access, and accuracy is not needed.
1338 * To access a global var is faster than calling time(NULL) */
1339 server.unixtime = time(NULL);
1340
1341 /* Show some info about non-empty databases */
1342 for (j = 0; j < server.dbnum; j++) {
1343 long long size, used, vkeys;
1344
1345 size = dictSlots(server.db[j].dict);
1346 used = dictSize(server.db[j].dict);
1347 vkeys = dictSize(server.db[j].expires);
1348 if (!(loops % 50) && (used || vkeys)) {
1349 redisLog(REDIS_VERBOSE,"DB %d: %lld keys (%lld volatile) in %lld slots HT.",j,used,vkeys,size);
1350 /* dictPrintStats(server.dict); */
1351 }
1352 }
1353
1354 /* We don't want to resize the hash tables while a bacground saving
1355 * is in progress: the saving child is created using fork() that is
1356 * implemented with a copy-on-write semantic in most modern systems, so
1357 * if we resize the HT while there is the saving child at work actually
1358 * a lot of memory movements in the parent will cause a lot of pages
1359 * copied. */
1360 if (server.bgsavechildpid == -1 && server.bgrewritechildpid == -1) {
1361 if (!(loops % 10)) tryResizeHashTables();
1362 if (server.activerehashing) incrementallyRehash();
1363 }
1364
1365 /* Show information about connected clients */
1366 if (!(loops % 50)) {
1367 redisLog(REDIS_VERBOSE,"%d clients connected (%d slaves), %zu bytes in use",
1368 listLength(server.clients)-listLength(server.slaves),
1369 listLength(server.slaves),
1370 zmalloc_used_memory());
1371 }
1372
1373 /* Close connections of timedout clients */
1374 if ((server.maxidletime && !(loops % 100)) || server.blpop_blocked_clients)
1375 closeTimedoutClients();
1376
1377 /* Check if a background saving or AOF rewrite in progress terminated */
1378 if (server.bgsavechildpid != -1 || server.bgrewritechildpid != -1) {
1379 int statloc;
1380 pid_t pid;
1381
1382 if ((pid = wait3(&statloc,WNOHANG,NULL)) != 0) {
1383 if (pid == server.bgsavechildpid) {
1384 backgroundSaveDoneHandler(statloc);
1385 } else {
1386 backgroundRewriteDoneHandler(statloc);
1387 }
1388 updateDictResizePolicy();
1389 }
1390 } else {
1391 /* If there is not a background saving in progress check if
1392 * we have to save now */
1393 time_t now = time(NULL);
1394 for (j = 0; j < server.saveparamslen; j++) {
1395 struct saveparam *sp = server.saveparams+j;
1396
1397 if (server.dirty >= sp->changes &&
1398 now-server.lastsave > sp->seconds) {
1399 redisLog(REDIS_NOTICE,"%d changes in %d seconds. Saving...",
1400 sp->changes, sp->seconds);
1401 rdbSaveBackground(server.dbfilename);
1402 break;
1403 }
1404 }
1405 }
1406
1407 /* Try to expire a few timed out keys. The algorithm used is adaptive and
1408 * will use few CPU cycles if there are few expiring keys, otherwise
1409 * it will get more aggressive to avoid that too much memory is used by
1410 * keys that can be removed from the keyspace. */
1411 for (j = 0; j < server.dbnum; j++) {
1412 int expired;
1413 redisDb *db = server.db+j;
1414
1415 /* Continue to expire if at the end of the cycle more than 25%
1416 * of the keys were expired. */
1417 do {
1418 long num = dictSize(db->expires);
1419 time_t now = time(NULL);
1420
1421 expired = 0;
1422 if (num > REDIS_EXPIRELOOKUPS_PER_CRON)
1423 num = REDIS_EXPIRELOOKUPS_PER_CRON;
1424 while (num--) {
1425 dictEntry *de;
1426 time_t t;
1427
1428 if ((de = dictGetRandomKey(db->expires)) == NULL) break;
1429 t = (time_t) dictGetEntryVal(de);
1430 if (now > t) {
1431 deleteKey(db,dictGetEntryKey(de));
1432 expired++;
1433 server.stat_expiredkeys++;
1434 }
1435 }
1436 } while (expired > REDIS_EXPIRELOOKUPS_PER_CRON/4);
1437 }
1438
1439 /* Swap a few keys on disk if we are over the memory limit and VM
1440 * is enbled. Try to free objects from the free list first. */
1441 if (vmCanSwapOut()) {
1442 while (server.vm_enabled && zmalloc_used_memory() >
1443 server.vm_max_memory)
1444 {
1445 int retval;
1446
1447 if (tryFreeOneObjectFromFreelist() == REDIS_OK) continue;
1448 retval = (server.vm_max_threads == 0) ?
1449 vmSwapOneObjectBlocking() :
1450 vmSwapOneObjectThreaded();
1451 if (retval == REDIS_ERR && !(loops % 300) &&
1452 zmalloc_used_memory() >
1453 (server.vm_max_memory+server.vm_max_memory/10))
1454 {
1455 redisLog(REDIS_WARNING,"WARNING: vm-max-memory limit exceeded by more than 10%% but unable to swap more objects out!");
1456 }
1457 /* Note that when using threade I/O we free just one object,
1458 * because anyway when the I/O thread in charge to swap this
1459 * object out will finish, the handler of completed jobs
1460 * will try to swap more objects if we are still out of memory. */
1461 if (retval == REDIS_ERR || server.vm_max_threads > 0) break;
1462 }
1463 }
1464
1465 /* Check if we should connect to a MASTER */
1466 if (server.replstate == REDIS_REPL_CONNECT && !(loops % 10)) {
1467 redisLog(REDIS_NOTICE,"Connecting to MASTER...");
1468 if (syncWithMaster() == REDIS_OK) {
1469 redisLog(REDIS_NOTICE,"MASTER <-> SLAVE sync succeeded");
1470 }
1471 }
1472 return 100;
1473 }
1474
1475 /* This function gets called every time Redis is entering the
1476 * main loop of the event driven library, that is, before to sleep
1477 * for ready file descriptors. */
1478 static void beforeSleep(struct aeEventLoop *eventLoop) {
1479 REDIS_NOTUSED(eventLoop);
1480
1481 if (server.vm_enabled && listLength(server.io_ready_clients)) {
1482 listIter li;
1483 listNode *ln;
1484
1485 listRewind(server.io_ready_clients,&li);
1486 while((ln = listNext(&li))) {
1487 redisClient *c = ln->value;
1488 struct redisCommand *cmd;
1489
1490 /* Resume the client. */
1491 listDelNode(server.io_ready_clients,ln);
1492 c->flags &= (~REDIS_IO_WAIT);
1493 server.vm_blocked_clients--;
1494 aeCreateFileEvent(server.el, c->fd, AE_READABLE,
1495 readQueryFromClient, c);
1496 cmd = lookupCommand(c->argv[0]->ptr);
1497 assert(cmd != NULL);
1498 call(c,cmd);
1499 resetClient(c);
1500 /* There may be more data to process in the input buffer. */
1501 if (c->querybuf && sdslen(c->querybuf) > 0)
1502 processInputBuffer(c);
1503 }
1504 }
1505 }
1506
1507 static void createSharedObjects(void) {
1508 int j;
1509
1510 shared.crlf = createObject(REDIS_STRING,sdsnew("\r\n"));
1511 shared.ok = createObject(REDIS_STRING,sdsnew("+OK\r\n"));
1512 shared.err = createObject(REDIS_STRING,sdsnew("-ERR\r\n"));
1513 shared.emptybulk = createObject(REDIS_STRING,sdsnew("$0\r\n\r\n"));
1514 shared.czero = createObject(REDIS_STRING,sdsnew(":0\r\n"));
1515 shared.cone = createObject(REDIS_STRING,sdsnew(":1\r\n"));
1516 shared.nullbulk = createObject(REDIS_STRING,sdsnew("$-1\r\n"));
1517 shared.nullmultibulk = createObject(REDIS_STRING,sdsnew("*-1\r\n"));
1518 shared.emptymultibulk = createObject(REDIS_STRING,sdsnew("*0\r\n"));
1519 shared.pong = createObject(REDIS_STRING,sdsnew("+PONG\r\n"));
1520 shared.queued = createObject(REDIS_STRING,sdsnew("+QUEUED\r\n"));
1521 shared.wrongtypeerr = createObject(REDIS_STRING,sdsnew(
1522 "-ERR Operation against a key holding the wrong kind of value\r\n"));
1523 shared.nokeyerr = createObject(REDIS_STRING,sdsnew(
1524 "-ERR no such key\r\n"));
1525 shared.syntaxerr = createObject(REDIS_STRING,sdsnew(
1526 "-ERR syntax error\r\n"));
1527 shared.sameobjecterr = createObject(REDIS_STRING,sdsnew(
1528 "-ERR source and destination objects are the same\r\n"));
1529 shared.outofrangeerr = createObject(REDIS_STRING,sdsnew(
1530 "-ERR index out of range\r\n"));
1531 shared.space = createObject(REDIS_STRING,sdsnew(" "));
1532 shared.colon = createObject(REDIS_STRING,sdsnew(":"));
1533 shared.plus = createObject(REDIS_STRING,sdsnew("+"));
1534 shared.select0 = createStringObject("select 0\r\n",10);
1535 shared.select1 = createStringObject("select 1\r\n",10);
1536 shared.select2 = createStringObject("select 2\r\n",10);
1537 shared.select3 = createStringObject("select 3\r\n",10);
1538 shared.select4 = createStringObject("select 4\r\n",10);
1539 shared.select5 = createStringObject("select 5\r\n",10);
1540 shared.select6 = createStringObject("select 6\r\n",10);
1541 shared.select7 = createStringObject("select 7\r\n",10);
1542 shared.select8 = createStringObject("select 8\r\n",10);
1543 shared.select9 = createStringObject("select 9\r\n",10);
1544 shared.messagebulk = createStringObject("$7\r\nmessage\r\n",13);
1545 shared.subscribebulk = createStringObject("$9\r\nsubscribe\r\n",15);
1546 shared.unsubscribebulk = createStringObject("$11\r\nunsubscribe\r\n",18);
1547 shared.psubscribebulk = createStringObject("$10\r\npsubscribe\r\n",17);
1548 shared.punsubscribebulk = createStringObject("$12\r\npunsubscribe\r\n",19);
1549 shared.mbulk3 = createStringObject("*3\r\n",4);
1550 for (j = 0; j < REDIS_SHARED_INTEGERS; j++) {
1551 shared.integers[j] = createObject(REDIS_STRING,(void*)(long)j);
1552 shared.integers[j]->encoding = REDIS_ENCODING_INT;
1553 }
1554 }
1555
1556 static void appendServerSaveParams(time_t seconds, int changes) {
1557 server.saveparams = zrealloc(server.saveparams,sizeof(struct saveparam)*(server.saveparamslen+1));
1558 server.saveparams[server.saveparamslen].seconds = seconds;
1559 server.saveparams[server.saveparamslen].changes = changes;
1560 server.saveparamslen++;
1561 }
1562
1563 static void resetServerSaveParams() {
1564 zfree(server.saveparams);
1565 server.saveparams = NULL;
1566 server.saveparamslen = 0;
1567 }
1568
1569 static void initServerConfig() {
1570 server.dbnum = REDIS_DEFAULT_DBNUM;
1571 server.port = REDIS_SERVERPORT;
1572 server.verbosity = REDIS_VERBOSE;
1573 server.maxidletime = REDIS_MAXIDLETIME;
1574 server.saveparams = NULL;
1575 server.logfile = NULL; /* NULL = log on standard output */
1576 server.bindaddr = NULL;
1577 server.glueoutputbuf = 1;
1578 server.daemonize = 0;
1579 server.appendonly = 0;
1580 server.appendfsync = APPENDFSYNC_ALWAYS;
1581 server.lastfsync = time(NULL);
1582 server.appendfd = -1;
1583 server.appendseldb = -1; /* Make sure the first time will not match */
1584 server.pidfile = zstrdup("/var/run/redis.pid");
1585 server.dbfilename = zstrdup("dump.rdb");
1586 server.appendfilename = zstrdup("appendonly.aof");
1587 server.requirepass = NULL;
1588 server.shareobjects = 0;
1589 server.rdbcompression = 1;
1590 server.activerehashing = 1;
1591 server.maxclients = 0;
1592 server.blpop_blocked_clients = 0;
1593 server.maxmemory = 0;
1594 server.vm_enabled = 0;
1595 server.vm_swap_file = zstrdup("/tmp/redis-%p.vm");
1596 server.vm_page_size = 256; /* 256 bytes per page */
1597 server.vm_pages = 1024*1024*100; /* 104 millions of pages */
1598 server.vm_max_memory = 1024LL*1024*1024*1; /* 1 GB of RAM */
1599 server.vm_max_threads = 4;
1600 server.vm_blocked_clients = 0;
1601 server.hash_max_zipmap_entries = REDIS_HASH_MAX_ZIPMAP_ENTRIES;
1602 server.hash_max_zipmap_value = REDIS_HASH_MAX_ZIPMAP_VALUE;
1603
1604 resetServerSaveParams();
1605
1606 appendServerSaveParams(60*60,1); /* save after 1 hour and 1 change */
1607 appendServerSaveParams(300,100); /* save after 5 minutes and 100 changes */
1608 appendServerSaveParams(60,10000); /* save after 1 minute and 10000 changes */
1609 /* Replication related */
1610 server.isslave = 0;
1611 server.masterauth = NULL;
1612 server.masterhost = NULL;
1613 server.masterport = 6379;
1614 server.master = NULL;
1615 server.replstate = REDIS_REPL_NONE;
1616
1617 /* Double constants initialization */
1618 R_Zero = 0.0;
1619 R_PosInf = 1.0/R_Zero;
1620 R_NegInf = -1.0/R_Zero;
1621 R_Nan = R_Zero/R_Zero;
1622 }
1623
1624 static void initServer() {
1625 int j;
1626
1627 signal(SIGHUP, SIG_IGN);
1628 signal(SIGPIPE, SIG_IGN);
1629 setupSigSegvAction();
1630
1631 server.devnull = fopen("/dev/null","w");
1632 if (server.devnull == NULL) {
1633 redisLog(REDIS_WARNING, "Can't open /dev/null: %s", server.neterr);
1634 exit(1);
1635 }
1636 server.clients = listCreate();
1637 server.slaves = listCreate();
1638 server.monitors = listCreate();
1639 server.objfreelist = listCreate();
1640 createSharedObjects();
1641 server.el = aeCreateEventLoop();
1642 server.db = zmalloc(sizeof(redisDb)*server.dbnum);
1643 server.fd = anetTcpServer(server.neterr, server.port, server.bindaddr);
1644 if (server.fd == -1) {
1645 redisLog(REDIS_WARNING, "Opening TCP port: %s", server.neterr);
1646 exit(1);
1647 }
1648 for (j = 0; j < server.dbnum; j++) {
1649 server.db[j].dict = dictCreate(&dbDictType,NULL);
1650 server.db[j].expires = dictCreate(&keyptrDictType,NULL);
1651 server.db[j].blockingkeys = dictCreate(&keylistDictType,NULL);
1652 if (server.vm_enabled)
1653 server.db[j].io_keys = dictCreate(&keylistDictType,NULL);
1654 server.db[j].id = j;
1655 }
1656 server.pubsub_channels = dictCreate(&keylistDictType,NULL);
1657 server.pubsub_patterns = listCreate();
1658 listSetFreeMethod(server.pubsub_patterns,freePubsubPattern);
1659 listSetMatchMethod(server.pubsub_patterns,listMatchPubsubPattern);
1660 server.cronloops = 0;
1661 server.bgsavechildpid = -1;
1662 server.bgrewritechildpid = -1;
1663 server.bgrewritebuf = sdsempty();
1664 server.lastsave = time(NULL);
1665 server.dirty = 0;
1666 server.stat_numcommands = 0;
1667 server.stat_numconnections = 0;
1668 server.stat_expiredkeys = 0;
1669 server.stat_starttime = time(NULL);
1670 server.unixtime = time(NULL);
1671 aeCreateTimeEvent(server.el, 1, serverCron, NULL, NULL);
1672 if (aeCreateFileEvent(server.el, server.fd, AE_READABLE,
1673 acceptHandler, NULL) == AE_ERR) oom("creating file event");
1674
1675 if (server.appendonly) {
1676 server.appendfd = open(server.appendfilename,O_WRONLY|O_APPEND|O_CREAT,0644);
1677 if (server.appendfd == -1) {
1678 redisLog(REDIS_WARNING, "Can't open the append-only file: %s",
1679 strerror(errno));
1680 exit(1);
1681 }
1682 }
1683
1684 if (server.vm_enabled) vmInit();
1685 }
1686
1687 /* Empty the whole database */
1688 static long long emptyDb() {
1689 int j;
1690 long long removed = 0;
1691
1692 for (j = 0; j < server.dbnum; j++) {
1693 removed += dictSize(server.db[j].dict);
1694 dictEmpty(server.db[j].dict);
1695 dictEmpty(server.db[j].expires);
1696 }
1697 return removed;
1698 }
1699
1700 static int yesnotoi(char *s) {
1701 if (!strcasecmp(s,"yes")) return 1;
1702 else if (!strcasecmp(s,"no")) return 0;
1703 else return -1;
1704 }
1705
1706 /* I agree, this is a very rudimental way to load a configuration...
1707 will improve later if the config gets more complex */
1708 static void loadServerConfig(char *filename) {
1709 FILE *fp;
1710 char buf[REDIS_CONFIGLINE_MAX+1], *err = NULL;
1711 int linenum = 0;
1712 sds line = NULL;
1713
1714 if (filename[0] == '-' && filename[1] == '\0')
1715 fp = stdin;
1716 else {
1717 if ((fp = fopen(filename,"r")) == NULL) {
1718 redisLog(REDIS_WARNING, "Fatal error, can't open config file '%s'", filename);
1719 exit(1);
1720 }
1721 }
1722
1723 while(fgets(buf,REDIS_CONFIGLINE_MAX+1,fp) != NULL) {
1724 sds *argv;
1725 int argc, j;
1726
1727 linenum++;
1728 line = sdsnew(buf);
1729 line = sdstrim(line," \t\r\n");
1730
1731 /* Skip comments and blank lines*/
1732 if (line[0] == '#' || line[0] == '\0') {
1733 sdsfree(line);
1734 continue;
1735 }
1736
1737 /* Split into arguments */
1738 argv = sdssplitlen(line,sdslen(line)," ",1,&argc);
1739 sdstolower(argv[0]);
1740
1741 /* Execute config directives */
1742 if (!strcasecmp(argv[0],"timeout") && argc == 2) {
1743 server.maxidletime = atoi(argv[1]);
1744 if (server.maxidletime < 0) {
1745 err = "Invalid timeout value"; goto loaderr;
1746 }
1747 } else if (!strcasecmp(argv[0],"port") && argc == 2) {
1748 server.port = atoi(argv[1]);
1749 if (server.port < 1 || server.port > 65535) {
1750 err = "Invalid port"; goto loaderr;
1751 }
1752 } else if (!strcasecmp(argv[0],"bind") && argc == 2) {
1753 server.bindaddr = zstrdup(argv[1]);
1754 } else if (!strcasecmp(argv[0],"save") && argc == 3) {
1755 int seconds = atoi(argv[1]);
1756 int changes = atoi(argv[2]);
1757 if (seconds < 1 || changes < 0) {
1758 err = "Invalid save parameters"; goto loaderr;
1759 }
1760 appendServerSaveParams(seconds,changes);
1761 } else if (!strcasecmp(argv[0],"dir") && argc == 2) {
1762 if (chdir(argv[1]) == -1) {
1763 redisLog(REDIS_WARNING,"Can't chdir to '%s': %s",
1764 argv[1], strerror(errno));
1765 exit(1);
1766 }
1767 } else if (!strcasecmp(argv[0],"loglevel") && argc == 2) {
1768 if (!strcasecmp(argv[1],"debug")) server.verbosity = REDIS_DEBUG;
1769 else if (!strcasecmp(argv[1],"verbose")) server.verbosity = REDIS_VERBOSE;
1770 else if (!strcasecmp(argv[1],"notice")) server.verbosity = REDIS_NOTICE;
1771 else if (!strcasecmp(argv[1],"warning")) server.verbosity = REDIS_WARNING;
1772 else {
1773 err = "Invalid log level. Must be one of debug, notice, warning";
1774 goto loaderr;
1775 }
1776 } else if (!strcasecmp(argv[0],"logfile") && argc == 2) {
1777 FILE *logfp;
1778
1779 server.logfile = zstrdup(argv[1]);
1780 if (!strcasecmp(server.logfile,"stdout")) {
1781 zfree(server.logfile);
1782 server.logfile = NULL;
1783 }
1784 if (server.logfile) {
1785 /* Test if we are able to open the file. The server will not
1786 * be able to abort just for this problem later... */
1787 logfp = fopen(server.logfile,"a");
1788 if (logfp == NULL) {
1789 err = sdscatprintf(sdsempty(),
1790 "Can't open the log file: %s", strerror(errno));
1791 goto loaderr;
1792 }
1793 fclose(logfp);
1794 }
1795 } else if (!strcasecmp(argv[0],"databases") && argc == 2) {
1796 server.dbnum = atoi(argv[1]);
1797 if (server.dbnum < 1) {
1798 err = "Invalid number of databases"; goto loaderr;
1799 }
1800 } else if (!strcasecmp(argv[0],"include") && argc == 2) {
1801 loadServerConfig(argv[1]);
1802 } else if (!strcasecmp(argv[0],"maxclients") && argc == 2) {
1803 server.maxclients = atoi(argv[1]);
1804 } else if (!strcasecmp(argv[0],"maxmemory") && argc == 2) {
1805 server.maxmemory = strtoll(argv[1], NULL, 10);
1806 } else if (!strcasecmp(argv[0],"slaveof") && argc == 3) {
1807 server.masterhost = sdsnew(argv[1]);
1808 server.masterport = atoi(argv[2]);
1809 server.replstate = REDIS_REPL_CONNECT;
1810 } else if (!strcasecmp(argv[0],"masterauth") && argc == 2) {
1811 server.masterauth = zstrdup(argv[1]);
1812 } else if (!strcasecmp(argv[0],"glueoutputbuf") && argc == 2) {
1813 if ((server.glueoutputbuf = yesnotoi(argv[1])) == -1) {
1814 err = "argument must be 'yes' or 'no'"; goto loaderr;
1815 }
1816 } else if (!strcasecmp(argv[0],"shareobjects") && argc == 2) {
1817 if ((server.shareobjects = yesnotoi(argv[1])) == -1) {
1818 err = "argument must be 'yes' or 'no'"; goto loaderr;
1819 }
1820 } else if (!strcasecmp(argv[0],"rdbcompression") && argc == 2) {
1821 if ((server.rdbcompression = yesnotoi(argv[1])) == -1) {
1822 err = "argument must be 'yes' or 'no'"; goto loaderr;
1823 }
1824 } else if (!strcasecmp(argv[0],"activerehashing") && argc == 2) {
1825 if ((server.activerehashing = yesnotoi(argv[1])) == -1) {
1826 err = "argument must be 'yes' or 'no'"; goto loaderr;
1827 }
1828 } else if (!strcasecmp(argv[0],"daemonize") && argc == 2) {
1829 if ((server.daemonize = yesnotoi(argv[1])) == -1) {
1830 err = "argument must be 'yes' or 'no'"; goto loaderr;
1831 }
1832 } else if (!strcasecmp(argv[0],"appendonly") && argc == 2) {
1833 if ((server.appendonly = yesnotoi(argv[1])) == -1) {
1834 err = "argument must be 'yes' or 'no'"; goto loaderr;
1835 }
1836 } else if (!strcasecmp(argv[0],"appendfsync") && argc == 2) {
1837 if (!strcasecmp(argv[1],"no")) {
1838 server.appendfsync = APPENDFSYNC_NO;
1839 } else if (!strcasecmp(argv[1],"always")) {
1840 server.appendfsync = APPENDFSYNC_ALWAYS;
1841 } else if (!strcasecmp(argv[1],"everysec")) {
1842 server.appendfsync = APPENDFSYNC_EVERYSEC;
1843 } else {
1844 err = "argument must be 'no', 'always' or 'everysec'";
1845 goto loaderr;
1846 }
1847 } else if (!strcasecmp(argv[0],"requirepass") && argc == 2) {
1848 server.requirepass = zstrdup(argv[1]);
1849 } else if (!strcasecmp(argv[0],"pidfile") && argc == 2) {
1850 zfree(server.pidfile);
1851 server.pidfile = zstrdup(argv[1]);
1852 } else if (!strcasecmp(argv[0],"dbfilename") && argc == 2) {
1853 zfree(server.dbfilename);
1854 server.dbfilename = zstrdup(argv[1]);
1855 } else if (!strcasecmp(argv[0],"vm-enabled") && argc == 2) {
1856 if ((server.vm_enabled = yesnotoi(argv[1])) == -1) {
1857 err = "argument must be 'yes' or 'no'"; goto loaderr;
1858 }
1859 } else if (!strcasecmp(argv[0],"vm-swap-file") && argc == 2) {
1860 zfree(server.vm_swap_file);
1861 server.vm_swap_file = zstrdup(argv[1]);
1862 } else if (!strcasecmp(argv[0],"vm-max-memory") && argc == 2) {
1863 server.vm_max_memory = strtoll(argv[1], NULL, 10);
1864 } else if (!strcasecmp(argv[0],"vm-page-size") && argc == 2) {
1865 server.vm_page_size = strtoll(argv[1], NULL, 10);
1866 } else if (!strcasecmp(argv[0],"vm-pages") && argc == 2) {
1867 server.vm_pages = strtoll(argv[1], NULL, 10);
1868 } else if (!strcasecmp(argv[0],"vm-max-threads") && argc == 2) {
1869 server.vm_max_threads = strtoll(argv[1], NULL, 10);
1870 } else if (!strcasecmp(argv[0],"hash-max-zipmap-entries") && argc == 2){
1871 server.hash_max_zipmap_entries = strtol(argv[1], NULL, 10);
1872 } else if (!strcasecmp(argv[0],"hash-max-zipmap-value") && argc == 2){
1873 server.hash_max_zipmap_value = strtol(argv[1], NULL, 10);
1874 } else if (!strcasecmp(argv[0],"vm-max-threads") && argc == 2) {
1875 server.vm_max_threads = strtoll(argv[1], NULL, 10);
1876 } else {
1877 err = "Bad directive or wrong number of arguments"; goto loaderr;
1878 }
1879 for (j = 0; j < argc; j++)
1880 sdsfree(argv[j]);
1881 zfree(argv);
1882 sdsfree(line);
1883 }
1884 if (fp != stdin) fclose(fp);
1885 return;
1886
1887 loaderr:
1888 fprintf(stderr, "\n*** FATAL CONFIG FILE ERROR ***\n");
1889 fprintf(stderr, "Reading the configuration file, at line %d\n", linenum);
1890 fprintf(stderr, ">>> '%s'\n", line);
1891 fprintf(stderr, "%s\n", err);
1892 exit(1);
1893 }
1894
1895 static void freeClientArgv(redisClient *c) {
1896 int j;
1897
1898 for (j = 0; j < c->argc; j++)
1899 decrRefCount(c->argv[j]);
1900 for (j = 0; j < c->mbargc; j++)
1901 decrRefCount(c->mbargv[j]);
1902 c->argc = 0;
1903 c->mbargc = 0;
1904 }
1905
1906 static void freeClient(redisClient *c) {
1907 listNode *ln;
1908
1909 /* Note that if the client we are freeing is blocked into a blocking
1910 * call, we have to set querybuf to NULL *before* to call
1911 * unblockClientWaitingData() to avoid processInputBuffer() will get
1912 * called. Also it is important to remove the file events after
1913 * this, because this call adds the READABLE event. */
1914 sdsfree(c->querybuf);
1915 c->querybuf = NULL;
1916 if (c->flags & REDIS_BLOCKED)
1917 unblockClientWaitingData(c);
1918
1919 /* Unsubscribe from all the pubsub channels */
1920 pubsubUnsubscribeAllChannels(c,0);
1921 pubsubUnsubscribeAllPatterns(c,0);
1922 dictRelease(c->pubsub_channels);
1923 listRelease(c->pubsub_patterns);
1924 /* Obvious cleanup */
1925 aeDeleteFileEvent(server.el,c->fd,AE_READABLE);
1926 aeDeleteFileEvent(server.el,c->fd,AE_WRITABLE);
1927 listRelease(c->reply);
1928 freeClientArgv(c);
1929 close(c->fd);
1930 /* Remove from the list of clients */
1931 ln = listSearchKey(server.clients,c);
1932 redisAssert(ln != NULL);
1933 listDelNode(server.clients,ln);
1934 /* Remove from the list of clients waiting for swapped keys */
1935 if (c->flags & REDIS_IO_WAIT && listLength(c->io_keys) == 0) {
1936 ln = listSearchKey(server.io_ready_clients,c);
1937 if (ln) {
1938 listDelNode(server.io_ready_clients,ln);
1939 server.vm_blocked_clients--;
1940 }
1941 }
1942 while (server.vm_enabled && listLength(c->io_keys)) {
1943 ln = listFirst(c->io_keys);
1944 dontWaitForSwappedKey(c,ln->value);
1945 }
1946 listRelease(c->io_keys);
1947 /* Master/slave cleanup */
1948 if (c->flags & REDIS_SLAVE) {
1949 if (c->replstate == REDIS_REPL_SEND_BULK && c->repldbfd != -1)
1950 close(c->repldbfd);
1951 list *l = (c->flags & REDIS_MONITOR) ? server.monitors : server.slaves;
1952 ln = listSearchKey(l,c);
1953 redisAssert(ln != NULL);
1954 listDelNode(l,ln);
1955 }
1956 if (c->flags & REDIS_MASTER) {
1957 server.master = NULL;
1958 server.replstate = REDIS_REPL_CONNECT;
1959 }
1960 /* Release memory */
1961 zfree(c->argv);
1962 zfree(c->mbargv);
1963 freeClientMultiState(c);
1964 zfree(c);
1965 }
1966
1967 #define GLUEREPLY_UP_TO (1024)
1968 static void glueReplyBuffersIfNeeded(redisClient *c) {
1969 int copylen = 0;
1970 char buf[GLUEREPLY_UP_TO];
1971 listNode *ln;
1972 listIter li;
1973 robj *o;
1974
1975 listRewind(c->reply,&li);
1976 while((ln = listNext(&li))) {
1977 int objlen;
1978
1979 o = ln->value;
1980 objlen = sdslen(o->ptr);
1981 if (copylen + objlen <= GLUEREPLY_UP_TO) {
1982 memcpy(buf+copylen,o->ptr,objlen);
1983 copylen += objlen;
1984 listDelNode(c->reply,ln);
1985 } else {
1986 if (copylen == 0) return;
1987 break;
1988 }
1989 }
1990 /* Now the output buffer is empty, add the new single element */
1991 o = createObject(REDIS_STRING,sdsnewlen(buf,copylen));
1992 listAddNodeHead(c->reply,o);
1993 }
1994
1995 static void sendReplyToClient(aeEventLoop *el, int fd, void *privdata, int mask) {
1996 redisClient *c = privdata;
1997 int nwritten = 0, totwritten = 0, objlen;
1998 robj *o;
1999 REDIS_NOTUSED(el);
2000 REDIS_NOTUSED(mask);
2001
2002 /* Use writev() if we have enough buffers to send */
2003 if (!server.glueoutputbuf &&
2004 listLength(c->reply) > REDIS_WRITEV_THRESHOLD &&
2005 !(c->flags & REDIS_MASTER))
2006 {
2007 sendReplyToClientWritev(el, fd, privdata, mask);
2008 return;
2009 }
2010
2011 while(listLength(c->reply)) {
2012 if (server.glueoutputbuf && listLength(c->reply) > 1)
2013 glueReplyBuffersIfNeeded(c);
2014
2015 o = listNodeValue(listFirst(c->reply));
2016 objlen = sdslen(o->ptr);
2017
2018 if (objlen == 0) {
2019 listDelNode(c->reply,listFirst(c->reply));
2020 continue;
2021 }
2022
2023 if (c->flags & REDIS_MASTER) {
2024 /* Don't reply to a master */
2025 nwritten = objlen - c->sentlen;
2026 } else {
2027 nwritten = write(fd, ((char*)o->ptr)+c->sentlen, objlen - c->sentlen);
2028 if (nwritten <= 0) break;
2029 }
2030 c->sentlen += nwritten;
2031 totwritten += nwritten;
2032 /* If we fully sent the object on head go to the next one */
2033 if (c->sentlen == objlen) {
2034 listDelNode(c->reply,listFirst(c->reply));
2035 c->sentlen = 0;
2036 }
2037 /* Note that we avoid to send more thank REDIS_MAX_WRITE_PER_EVENT
2038 * bytes, in a single threaded server it's a good idea to serve
2039 * other clients as well, even if a very large request comes from
2040 * super fast link that is always able to accept data (in real world
2041 * scenario think about 'KEYS *' against the loopback interfae) */
2042 if (totwritten > REDIS_MAX_WRITE_PER_EVENT) break;
2043 }
2044 if (nwritten == -1) {
2045 if (errno == EAGAIN) {
2046 nwritten = 0;
2047 } else {
2048 redisLog(REDIS_VERBOSE,
2049 "Error writing to client: %s", strerror(errno));
2050 freeClient(c);
2051 return;
2052 }
2053 }
2054 if (totwritten > 0) c->lastinteraction = time(NULL);
2055 if (listLength(c->reply) == 0) {
2056 c->sentlen = 0;
2057 aeDeleteFileEvent(server.el,c->fd,AE_WRITABLE);
2058 }
2059 }
2060
2061 static void sendReplyToClientWritev(aeEventLoop *el, int fd, void *privdata, int mask)
2062 {
2063 redisClient *c = privdata;
2064 int nwritten = 0, totwritten = 0, objlen, willwrite;
2065 robj *o;
2066 struct iovec iov[REDIS_WRITEV_IOVEC_COUNT];
2067 int offset, ion = 0;
2068 REDIS_NOTUSED(el);
2069 REDIS_NOTUSED(mask);
2070
2071 listNode *node;
2072 while (listLength(c->reply)) {
2073 offset = c->sentlen;
2074 ion = 0;
2075 willwrite = 0;
2076
2077 /* fill-in the iov[] array */
2078 for(node = listFirst(c->reply); node; node = listNextNode(node)) {
2079 o = listNodeValue(node);
2080 objlen = sdslen(o->ptr);
2081
2082 if (totwritten + objlen - offset > REDIS_MAX_WRITE_PER_EVENT)
2083 break;
2084
2085 if(ion == REDIS_WRITEV_IOVEC_COUNT)
2086 break; /* no more iovecs */
2087
2088 iov[ion].iov_base = ((char*)o->ptr) + offset;
2089 iov[ion].iov_len = objlen - offset;
2090 willwrite += objlen - offset;
2091 offset = 0; /* just for the first item */
2092 ion++;
2093 }
2094
2095 if(willwrite == 0)
2096 break;
2097
2098 /* write all collected blocks at once */
2099 if((nwritten = writev(fd, iov, ion)) < 0) {
2100 if (errno != EAGAIN) {
2101 redisLog(REDIS_VERBOSE,
2102 "Error writing to client: %s", strerror(errno));
2103 freeClient(c);
2104 return;
2105 }
2106 break;
2107 }
2108
2109 totwritten += nwritten;
2110 offset = c->sentlen;
2111
2112 /* remove written robjs from c->reply */
2113 while (nwritten && listLength(c->reply)) {
2114 o = listNodeValue(listFirst(c->reply));
2115 objlen = sdslen(o->ptr);
2116
2117 if(nwritten >= objlen - offset) {
2118 listDelNode(c->reply, listFirst(c->reply));
2119 nwritten -= objlen - offset;
2120 c->sentlen = 0;
2121 } else {
2122 /* partial write */
2123 c->sentlen += nwritten;
2124 break;
2125 }
2126 offset = 0;
2127 }
2128 }
2129
2130 if (totwritten > 0)
2131 c->lastinteraction = time(NULL);
2132
2133 if (listLength(c->reply) == 0) {
2134 c->sentlen = 0;
2135 aeDeleteFileEvent(server.el,c->fd,AE_WRITABLE);
2136 }
2137 }
2138
2139 static struct redisCommand *lookupCommand(char *name) {
2140 int j = 0;
2141 while(cmdTable[j].name != NULL) {
2142 if (!strcasecmp(name,cmdTable[j].name)) return &cmdTable[j];
2143 j++;
2144 }
2145 return NULL;
2146 }
2147
2148 /* resetClient prepare the client to process the next command */
2149 static void resetClient(redisClient *c) {
2150 freeClientArgv(c);
2151 c->bulklen = -1;
2152 c->multibulk = 0;
2153 }
2154
2155 /* Call() is the core of Redis execution of a command */
2156 static void call(redisClient *c, struct redisCommand *cmd) {
2157 long long dirty;
2158
2159 dirty = server.dirty;
2160 cmd->proc(c);
2161 dirty = server.dirty-dirty;
2162
2163 if (server.appendonly && dirty)
2164 feedAppendOnlyFile(cmd,c->db->id,c->argv,c->argc);
2165 if ((dirty || cmd->flags & REDIS_CMD_FORCE_REPLICATION) &&
2166 listLength(server.slaves))
2167 replicationFeedSlaves(server.slaves,c->db->id,c->argv,c->argc);
2168 if (listLength(server.monitors))
2169 replicationFeedSlaves(server.monitors,c->db->id,c->argv,c->argc);
2170 server.stat_numcommands++;
2171 }
2172
2173 /* If this function gets called we already read a whole
2174 * command, argments are in the client argv/argc fields.
2175 * processCommand() execute the command or prepare the
2176 * server for a bulk read from the client.
2177 *
2178 * If 1 is returned the client is still alive and valid and
2179 * and other operations can be performed by the caller. Otherwise
2180 * if 0 is returned the client was destroied (i.e. after QUIT). */
2181 static int processCommand(redisClient *c) {
2182 struct redisCommand *cmd;
2183
2184 /* Free some memory if needed (maxmemory setting) */
2185 if (server.maxmemory) freeMemoryIfNeeded();
2186
2187 /* Handle the multi bulk command type. This is an alternative protocol
2188 * supported by Redis in order to receive commands that are composed of
2189 * multiple binary-safe "bulk" arguments. The latency of processing is
2190 * a bit higher but this allows things like multi-sets, so if this
2191 * protocol is used only for MSET and similar commands this is a big win. */
2192 if (c->multibulk == 0 && c->argc == 1 && ((char*)(c->argv[0]->ptr))[0] == '*') {
2193 c->multibulk = atoi(((char*)c->argv[0]->ptr)+1);
2194 if (c->multibulk <= 0) {
2195 resetClient(c);
2196 return 1;
2197 } else {
2198 decrRefCount(c->argv[c->argc-1]);
2199 c->argc--;
2200 return 1;
2201 }
2202 } else if (c->multibulk) {
2203 if (c->bulklen == -1) {
2204 if (((char*)c->argv[0]->ptr)[0] != '$') {
2205 addReplySds(c,sdsnew("-ERR multi bulk protocol error\r\n"));
2206 resetClient(c);
2207 return 1;
2208 } else {
2209 int bulklen = atoi(((char*)c->argv[0]->ptr)+1);
2210 decrRefCount(c->argv[0]);
2211 if (bulklen < 0 || bulklen > 1024*1024*1024) {
2212 c->argc--;
2213 addReplySds(c,sdsnew("-ERR invalid bulk write count\r\n"));
2214 resetClient(c);
2215 return 1;
2216 }
2217 c->argc--;
2218 c->bulklen = bulklen+2; /* add two bytes for CR+LF */
2219 return 1;
2220 }
2221 } else {
2222 c->mbargv = zrealloc(c->mbargv,(sizeof(robj*))*(c->mbargc+1));
2223 c->mbargv[c->mbargc] = c->argv[0];
2224 c->mbargc++;
2225 c->argc--;
2226 c->multibulk--;
2227 if (c->multibulk == 0) {
2228 robj **auxargv;
2229 int auxargc;
2230
2231 /* Here we need to swap the multi-bulk argc/argv with the
2232 * normal argc/argv of the client structure. */
2233 auxargv = c->argv;
2234 c->argv = c->mbargv;
2235 c->mbargv = auxargv;
2236
2237 auxargc = c->argc;
2238 c->argc = c->mbargc;
2239 c->mbargc = auxargc;
2240
2241 /* We need to set bulklen to something different than -1
2242 * in order for the code below to process the command without
2243 * to try to read the last argument of a bulk command as
2244 * a special argument. */
2245 c->bulklen = 0;
2246 /* continue below and process the command */
2247 } else {
2248 c->bulklen = -1;
2249 return 1;
2250 }
2251 }
2252 }
2253 /* -- end of multi bulk commands processing -- */
2254
2255 /* The QUIT command is handled as a special case. Normal command
2256 * procs are unable to close the client connection safely */
2257 if (!strcasecmp(c->argv[0]->ptr,"quit")) {
2258 freeClient(c);
2259 return 0;
2260 }
2261
2262 /* Now lookup the command and check ASAP about trivial error conditions
2263 * such wrong arity, bad command name and so forth. */
2264 cmd = lookupCommand(c->argv[0]->ptr);
2265 if (!cmd) {
2266 addReplySds(c,
2267 sdscatprintf(sdsempty(), "-ERR unknown command '%s'\r\n",
2268 (char*)c->argv[0]->ptr));
2269 resetClient(c);
2270 return 1;
2271 } else if ((cmd->arity > 0 && cmd->arity != c->argc) ||
2272 (c->argc < -cmd->arity)) {
2273 addReplySds(c,
2274 sdscatprintf(sdsempty(),
2275 "-ERR wrong number of arguments for '%s' command\r\n",
2276 cmd->name));
2277 resetClient(c);
2278 return 1;
2279 } else if (cmd->flags & REDIS_CMD_BULK && c->bulklen == -1) {
2280 /* This is a bulk command, we have to read the last argument yet. */
2281 int bulklen = atoi(c->argv[c->argc-1]->ptr);
2282
2283 decrRefCount(c->argv[c->argc-1]);
2284 if (bulklen < 0 || bulklen > 1024*1024*1024) {
2285 c->argc--;
2286 addReplySds(c,sdsnew("-ERR invalid bulk write count\r\n"));
2287 resetClient(c);
2288 return 1;
2289 }
2290 c->argc--;
2291 c->bulklen = bulklen+2; /* add two bytes for CR+LF */
2292 /* It is possible that the bulk read is already in the
2293 * buffer. Check this condition and handle it accordingly.
2294 * This is just a fast path, alternative to call processInputBuffer().
2295 * It's a good idea since the code is small and this condition
2296 * happens most of the times. */
2297 if ((signed)sdslen(c->querybuf) >= c->bulklen) {
2298 c->argv[c->argc] = createStringObject(c->querybuf,c->bulklen-2);
2299 c->argc++;
2300 c->querybuf = sdsrange(c->querybuf,c->bulklen,-1);
2301 } else {
2302 /* Otherwise return... there is to read the last argument
2303 * from the socket. */
2304 return 1;
2305 }
2306 }
2307 /* Let's try to encode the bulk object to save space. */
2308 if (cmd->flags & REDIS_CMD_BULK)
2309 c->argv[c->argc-1] = tryObjectEncoding(c->argv[c->argc-1]);
2310
2311 /* Check if the user is authenticated */
2312 if (server.requirepass && !c->authenticated && cmd->proc != authCommand) {
2313 addReplySds(c,sdsnew("-ERR operation not permitted\r\n"));
2314 resetClient(c);
2315 return 1;
2316 }
2317
2318 /* Handle the maxmemory directive */
2319 if (server.maxmemory && (cmd->flags & REDIS_CMD_DENYOOM) &&
2320 zmalloc_used_memory() > server.maxmemory)
2321 {
2322 addReplySds(c,sdsnew("-ERR command not allowed when used memory > 'maxmemory'\r\n"));
2323 resetClient(c);
2324 return 1;
2325 }
2326
2327 /* Only allow SUBSCRIBE and UNSUBSCRIBE in the context of Pub/Sub */
2328 if ((dictSize(c->pubsub_channels) > 0 || listLength(c->pubsub_patterns) > 0)
2329 &&
2330 cmd->proc != subscribeCommand && cmd->proc != unsubscribeCommand &&
2331 cmd->proc != psubscribeCommand && cmd->proc != punsubscribeCommand) {
2332 addReplySds(c,sdsnew("-ERR only (P)SUBSCRIBE / (P)UNSUBSCRIBE / QUIT allowed in this context\r\n"));
2333 resetClient(c);
2334 return 1;
2335 }
2336
2337 /* Exec the command */
2338 if (c->flags & REDIS_MULTI && cmd->proc != execCommand && cmd->proc != discardCommand) {
2339 queueMultiCommand(c,cmd);
2340 addReply(c,shared.queued);
2341 } else {
2342 if (server.vm_enabled && server.vm_max_threads > 0 &&
2343 blockClientOnSwappedKeys(cmd,c)) return 1;
2344 call(c,cmd);
2345 }
2346
2347 /* Prepare the client for the next command */
2348 resetClient(c);
2349 return 1;
2350 }
2351
2352 static void replicationFeedSlaves(list *slaves, int dictid, robj **argv, int argc) {
2353 listNode *ln;
2354 listIter li;
2355 int outc = 0, j;
2356 robj **outv;
2357 /* We need 1+(ARGS*3) objects since commands are using the new protocol
2358 * and we one 1 object for the first "*<count>\r\n" multibulk count, then
2359 * for every additional object we have "$<count>\r\n" + object + "\r\n". */
2360 robj *static_outv[REDIS_STATIC_ARGS*3+1];
2361 robj *lenobj;
2362
2363 if (argc <= REDIS_STATIC_ARGS) {
2364 outv = static_outv;
2365 } else {
2366 outv = zmalloc(sizeof(robj*)*(argc*3+1));
2367 }
2368
2369 lenobj = createObject(REDIS_STRING,
2370 sdscatprintf(sdsempty(), "*%d\r\n", argc));
2371 lenobj->refcount = 0;
2372 outv[outc++] = lenobj;
2373 for (j = 0; j < argc; j++) {
2374 lenobj = createObject(REDIS_STRING,
2375 sdscatprintf(sdsempty(),"$%lu\r\n",
2376 (unsigned long) stringObjectLen(argv[j])));
2377 lenobj->refcount = 0;
2378 outv[outc++] = lenobj;
2379 outv[outc++] = argv[j];
2380 outv[outc++] = shared.crlf;
2381 }
2382
2383 /* Increment all the refcounts at start and decrement at end in order to
2384 * be sure to free objects if there is no slave in a replication state
2385 * able to be feed with commands */
2386 for (j = 0; j < outc; j++) incrRefCount(outv[j]);
2387 listRewind(slaves,&li);
2388 while((ln = listNext(&li))) {
2389 redisClient *slave = ln->value;
2390
2391 /* Don't feed slaves that are still waiting for BGSAVE to start */
2392 if (slave->replstate == REDIS_REPL_WAIT_BGSAVE_START) continue;
2393
2394 /* Feed all the other slaves, MONITORs and so on */
2395 if (slave->slaveseldb != dictid) {
2396 robj *selectcmd;
2397
2398 switch(dictid) {
2399 case 0: selectcmd = shared.select0; break;
2400 case 1: selectcmd = shared.select1; break;
2401 case 2: selectcmd = shared.select2; break;
2402 case 3: selectcmd = shared.select3; break;
2403 case 4: selectcmd = shared.select4; break;
2404 case 5: selectcmd = shared.select5; break;
2405 case 6: selectcmd = shared.select6; break;
2406 case 7: selectcmd = shared.select7; break;
2407 case 8: selectcmd = shared.select8; break;
2408 case 9: selectcmd = shared.select9; break;
2409 default:
2410 selectcmd = createObject(REDIS_STRING,
2411 sdscatprintf(sdsempty(),"select %d\r\n",dictid));
2412 selectcmd->refcount = 0;
2413 break;
2414 }
2415 addReply(slave,selectcmd);
2416 slave->slaveseldb = dictid;
2417 }
2418 for (j = 0; j < outc; j++) addReply(slave,outv[j]);
2419 }
2420 for (j = 0; j < outc; j++) decrRefCount(outv[j]);
2421 if (outv != static_outv) zfree(outv);
2422 }
2423
2424 static void processInputBuffer(redisClient *c) {
2425 again:
2426 /* Before to process the input buffer, make sure the client is not
2427 * waitig for a blocking operation such as BLPOP. Note that the first
2428 * iteration the client is never blocked, otherwise the processInputBuffer
2429 * would not be called at all, but after the execution of the first commands
2430 * in the input buffer the client may be blocked, and the "goto again"
2431 * will try to reiterate. The following line will make it return asap. */
2432 if (c->flags & REDIS_BLOCKED || c->flags & REDIS_IO_WAIT) return;
2433 if (c->bulklen == -1) {
2434 /* Read the first line of the query */
2435 char *p = strchr(c->querybuf,'\n');
2436 size_t querylen;
2437
2438 if (p) {
2439 sds query, *argv;
2440 int argc, j;
2441
2442 query = c->querybuf;
2443 c->querybuf = sdsempty();
2444 querylen = 1+(p-(query));
2445 if (sdslen(query) > querylen) {
2446 /* leave data after the first line of the query in the buffer */
2447 c->querybuf = sdscatlen(c->querybuf,query+querylen,sdslen(query)-querylen);
2448 }
2449 *p = '\0'; /* remove "\n" */
2450 if (*(p-1) == '\r') *(p-1) = '\0'; /* and "\r" if any */
2451 sdsupdatelen(query);
2452
2453 /* Now we can split the query in arguments */
2454 argv = sdssplitlen(query,sdslen(query)," ",1,&argc);
2455 sdsfree(query);
2456
2457 if (c->argv) zfree(c->argv);
2458 c->argv = zmalloc(sizeof(robj*)*argc);
2459
2460 for (j = 0; j < argc; j++) {
2461 if (sdslen(argv[j])) {
2462 c->argv[c->argc] = createObject(REDIS_STRING,argv[j]);
2463 c->argc++;
2464 } else {
2465 sdsfree(argv[j]);
2466 }
2467 }
2468 zfree(argv);
2469 if (c->argc) {
2470 /* Execute the command. If the client is still valid
2471 * after processCommand() return and there is something
2472 * on the query buffer try to process the next command. */
2473 if (processCommand(c) && sdslen(c->querybuf)) goto again;
2474 } else {
2475 /* Nothing to process, argc == 0. Just process the query
2476 * buffer if it's not empty or return to the caller */
2477 if (sdslen(c->querybuf)) goto again;
2478 }
2479 return;
2480 } else if (sdslen(c->querybuf) >= REDIS_REQUEST_MAX_SIZE) {
2481 redisLog(REDIS_VERBOSE, "Client protocol error");
2482 freeClient(c);
2483 return;
2484 }
2485 } else {
2486 /* Bulk read handling. Note that if we are at this point
2487 the client already sent a command terminated with a newline,
2488 we are reading the bulk data that is actually the last
2489 argument of the command. */
2490 int qbl = sdslen(c->querybuf);
2491
2492 if (c->bulklen <= qbl) {
2493 /* Copy everything but the final CRLF as final argument */
2494 c->argv[c->argc] = createStringObject(c->querybuf,c->bulklen-2);
2495 c->argc++;
2496 c->querybuf = sdsrange(c->querybuf,c->bulklen,-1);
2497 /* Process the command. If the client is still valid after
2498 * the processing and there is more data in the buffer
2499 * try to parse it. */
2500 if (processCommand(c) && sdslen(c->querybuf)) goto again;
2501 return;
2502 }
2503 }
2504 }
2505
2506 static void readQueryFromClient(aeEventLoop *el, int fd, void *privdata, int mask) {
2507 redisClient *c = (redisClient*) privdata;
2508 char buf[REDIS_IOBUF_LEN];
2509 int nread;
2510 REDIS_NOTUSED(el);
2511 REDIS_NOTUSED(mask);
2512
2513 nread = read(fd, buf, REDIS_IOBUF_LEN);
2514 if (nread == -1) {
2515 if (errno == EAGAIN) {
2516 nread = 0;
2517 } else {
2518 redisLog(REDIS_VERBOSE, "Reading from client: %s",strerror(errno));
2519 freeClient(c);
2520 return;
2521 }
2522 } else if (nread == 0) {
2523 redisLog(REDIS_VERBOSE, "Client closed connection");
2524 freeClient(c);
2525 return;
2526 }
2527 if (nread) {
2528 c->querybuf = sdscatlen(c->querybuf, buf, nread);
2529 c->lastinteraction = time(NULL);
2530 } else {
2531 return;
2532 }
2533 processInputBuffer(c);
2534 }
2535
2536 static int selectDb(redisClient *c, int id) {
2537 if (id < 0 || id >= server.dbnum)
2538 return REDIS_ERR;
2539 c->db = &server.db[id];
2540 return REDIS_OK;
2541 }
2542
2543 static void *dupClientReplyValue(void *o) {
2544 incrRefCount((robj*)o);
2545 return o;
2546 }
2547
2548 static int listMatchObjects(void *a, void *b) {
2549 return compareStringObjects(a,b) == 0;
2550 }
2551
2552 static redisClient *createClient(int fd) {
2553 redisClient *c = zmalloc(sizeof(*c));
2554
2555 anetNonBlock(NULL,fd);
2556 anetTcpNoDelay(NULL,fd);
2557 if (!c) return NULL;
2558 selectDb(c,0);
2559 c->fd = fd;
2560 c->querybuf = sdsempty();
2561 c->argc = 0;
2562 c->argv = NULL;
2563 c->bulklen = -1;
2564 c->multibulk = 0;
2565 c->mbargc = 0;
2566 c->mbargv = NULL;
2567 c->sentlen = 0;
2568 c->flags = 0;
2569 c->lastinteraction = time(NULL);
2570 c->authenticated = 0;
2571 c->replstate = REDIS_REPL_NONE;
2572 c->reply = listCreate();
2573 listSetFreeMethod(c->reply,decrRefCount);
2574 listSetDupMethod(c->reply,dupClientReplyValue);
2575 c->blockingkeys = NULL;
2576 c->blockingkeysnum = 0;
2577 c->io_keys = listCreate();
2578 listSetFreeMethod(c->io_keys,decrRefCount);
2579 c->pubsub_channels = dictCreate(&setDictType,NULL);
2580 c->pubsub_patterns = listCreate();
2581 listSetFreeMethod(c->pubsub_patterns,decrRefCount);
2582 listSetMatchMethod(c->pubsub_patterns,listMatchObjects);
2583 if (aeCreateFileEvent(server.el, c->fd, AE_READABLE,
2584 readQueryFromClient, c) == AE_ERR) {
2585 freeClient(c);
2586 return NULL;
2587 }
2588 listAddNodeTail(server.clients,c);
2589 initClientMultiState(c);
2590 return c;
2591 }
2592
2593 static void addReply(redisClient *c, robj *obj) {
2594 if (listLength(c->reply) == 0 &&
2595 (c->replstate == REDIS_REPL_NONE ||
2596 c->replstate == REDIS_REPL_ONLINE) &&
2597 aeCreateFileEvent(server.el, c->fd, AE_WRITABLE,
2598 sendReplyToClient, c) == AE_ERR) return;
2599
2600 if (server.vm_enabled && obj->storage != REDIS_VM_MEMORY) {
2601 obj = dupStringObject(obj);
2602 obj->refcount = 0; /* getDecodedObject() will increment the refcount */
2603 }
2604 listAddNodeTail(c->reply,getDecodedObject(obj));
2605 }
2606
2607 static void addReplySds(redisClient *c, sds s) {
2608 robj *o = createObject(REDIS_STRING,s);
2609 addReply(c,o);
2610 decrRefCount(o);
2611 }
2612
2613 static void addReplyDouble(redisClient *c, double d) {
2614 char buf[128];
2615
2616 snprintf(buf,sizeof(buf),"%.17g",d);
2617 addReplySds(c,sdscatprintf(sdsempty(),"$%lu\r\n%s\r\n",
2618 (unsigned long) strlen(buf),buf));
2619 }
2620
2621 static void addReplyLong(redisClient *c, long l) {
2622 char buf[128];
2623 size_t len;
2624
2625 if (l == 0) {
2626 addReply(c,shared.czero);
2627 return;
2628 } else if (l == 1) {
2629 addReply(c,shared.cone);
2630 return;
2631 }
2632 len = snprintf(buf,sizeof(buf),":%ld\r\n",l);
2633 addReplySds(c,sdsnewlen(buf,len));
2634 }
2635
2636 static void addReplyLongLong(redisClient *c, long long ll) {
2637 char buf[128];
2638 size_t len;
2639
2640 if (ll == 0) {
2641 addReply(c,shared.czero);
2642 return;
2643 } else if (ll == 1) {
2644 addReply(c,shared.cone);
2645 return;
2646 }
2647 len = snprintf(buf,sizeof(buf),":%lld\r\n",ll);
2648 addReplySds(c,sdsnewlen(buf,len));
2649 }
2650
2651 static void addReplyUlong(redisClient *c, unsigned long ul) {
2652 char buf[128];
2653 size_t len;
2654
2655 if (ul == 0) {
2656 addReply(c,shared.czero);
2657 return;
2658 } else if (ul == 1) {
2659 addReply(c,shared.cone);
2660 return;
2661 }
2662 len = snprintf(buf,sizeof(buf),":%lu\r\n",ul);
2663 addReplySds(c,sdsnewlen(buf,len));
2664 }
2665
2666 static void addReplyBulkLen(redisClient *c, robj *obj) {
2667 size_t len;
2668
2669 if (obj->encoding == REDIS_ENCODING_RAW) {
2670 len = sdslen(obj->ptr);
2671 } else {
2672 long n = (long)obj->ptr;
2673
2674 /* Compute how many bytes will take this integer as a radix 10 string */
2675 len = 1;
2676 if (n < 0) {
2677 len++;
2678 n = -n;
2679 }
2680 while((n = n/10) != 0) {
2681 len++;
2682 }
2683 }
2684 addReplySds(c,sdscatprintf(sdsempty(),"$%lu\r\n",(unsigned long)len));
2685 }
2686
2687 static void addReplyBulk(redisClient *c, robj *obj) {
2688 addReplyBulkLen(c,obj);
2689 addReply(c,obj);
2690 addReply(c,shared.crlf);
2691 }
2692
2693 /* In the CONFIG command we need to add vanilla C string as bulk replies */
2694 static void addReplyBulkCString(redisClient *c, char *s) {
2695 if (s == NULL) {
2696 addReply(c,shared.nullbulk);
2697 } else {
2698 robj *o = createStringObject(s,strlen(s));
2699 addReplyBulk(c,o);
2700 decrRefCount(o);
2701 }
2702 }
2703
2704 static void acceptHandler(aeEventLoop *el, int fd, void *privdata, int mask) {
2705 int cport, cfd;
2706 char cip[128];
2707 redisClient *c;
2708 REDIS_NOTUSED(el);
2709 REDIS_NOTUSED(mask);
2710 REDIS_NOTUSED(privdata);
2711
2712 cfd = anetAccept(server.neterr, fd, cip, &cport);
2713 if (cfd == AE_ERR) {
2714 redisLog(REDIS_VERBOSE,"Accepting client connection: %s", server.neterr);
2715 return;
2716 }
2717 redisLog(REDIS_VERBOSE,"Accepted %s:%d", cip, cport);
2718 if ((c = createClient(cfd)) == NULL) {
2719 redisLog(REDIS_WARNING,"Error allocating resoures for the client");
2720 close(cfd); /* May be already closed, just ingore errors */
2721 return;
2722 }
2723 /* If maxclient directive is set and this is one client more... close the
2724 * connection. Note that we create the client instead to check before
2725 * for this condition, since now the socket is already set in nonblocking
2726 * mode and we can send an error for free using the Kernel I/O */
2727 if (server.maxclients && listLength(server.clients) > server.maxclients) {
2728 char *err = "-ERR max number of clients reached\r\n";
2729
2730 /* That's a best effort error message, don't check write errors */
2731 if (write(c->fd,err,strlen(err)) == -1) {
2732 /* Nothing to do, Just to avoid the warning... */
2733 }
2734 freeClient(c);
2735 return;
2736 }
2737 server.stat_numconnections++;
2738 }
2739
2740 /* ======================= Redis objects implementation ===================== */
2741
2742 static robj *createObject(int type, void *ptr) {
2743 robj *o;
2744
2745 if (server.vm_enabled) pthread_mutex_lock(&server.obj_freelist_mutex);
2746 if (listLength(server.objfreelist)) {
2747 listNode *head = listFirst(server.objfreelist);
2748 o = listNodeValue(head);
2749 listDelNode(server.objfreelist,head);
2750 if (server.vm_enabled) pthread_mutex_unlock(&server.obj_freelist_mutex);
2751 } else {
2752 if (server.vm_enabled) {
2753 pthread_mutex_unlock(&server.obj_freelist_mutex);
2754 o = zmalloc(sizeof(*o));
2755 } else {
2756 o = zmalloc(sizeof(*o)-sizeof(struct redisObjectVM));
2757 }
2758 }
2759 o->type = type;
2760 o->encoding = REDIS_ENCODING_RAW;
2761 o->ptr = ptr;
2762 o->refcount = 1;
2763 if (server.vm_enabled) {
2764 /* Note that this code may run in the context of an I/O thread
2765 * and accessing to server.unixtime in theory is an error
2766 * (no locks). But in practice this is safe, and even if we read
2767 * garbage Redis will not fail, as it's just a statistical info */
2768 o->vm.atime = server.unixtime;
2769 o->storage = REDIS_VM_MEMORY;
2770 }
2771 return o;
2772 }
2773
2774 static robj *createStringObject(char *ptr, size_t len) {
2775 return createObject(REDIS_STRING,sdsnewlen(ptr,len));
2776 }
2777
2778 static robj *createStringObjectFromLongLong(long long value) {
2779 robj *o;
2780 if (value >= 0 && value < REDIS_SHARED_INTEGERS) {
2781 incrRefCount(shared.integers[value]);
2782 o = shared.integers[value];
2783 } else {
2784 o = createObject(REDIS_STRING, NULL);
2785 if (value >= LONG_MIN && value <= LONG_MAX) {
2786 o->encoding = REDIS_ENCODING_INT;
2787 o->ptr = (void*)((long)value);
2788 } else {
2789 o->ptr = sdscatprintf(sdsempty(),"%lld",value);
2790 }
2791 }
2792 return o;
2793 }
2794
2795 static robj *dupStringObject(robj *o) {
2796 assert(o->encoding == REDIS_ENCODING_RAW);
2797 return createStringObject(o->ptr,sdslen(o->ptr));
2798 }
2799
2800 static robj *createListObject(void) {
2801 list *l = listCreate();
2802
2803 listSetFreeMethod(l,decrRefCount);
2804 return createObject(REDIS_LIST,l);
2805 }
2806
2807 static robj *createSetObject(void) {
2808 dict *d = dictCreate(&setDictType,NULL);
2809 return createObject(REDIS_SET,d);
2810 }
2811
2812 static robj *createHashObject(void) {
2813 /* All the Hashes start as zipmaps. Will be automatically converted
2814 * into hash tables if there are enough elements or big elements
2815 * inside. */
2816 unsigned char *zm = zipmapNew();
2817 robj *o = createObject(REDIS_HASH,zm);
2818 o->encoding = REDIS_ENCODING_ZIPMAP;
2819 return o;
2820 }
2821
2822 static robj *createZsetObject(void) {
2823 zset *zs = zmalloc(sizeof(*zs));
2824
2825 zs->dict = dictCreate(&zsetDictType,NULL);
2826 zs->zsl = zslCreate();
2827 return createObject(REDIS_ZSET,zs);
2828 }
2829
2830 static void freeStringObject(robj *o) {
2831 if (o->encoding == REDIS_ENCODING_RAW) {
2832 sdsfree(o->ptr);
2833 }
2834 }
2835
2836 static void freeListObject(robj *o) {
2837 listRelease((list*) o->ptr);
2838 }
2839
2840 static void freeSetObject(robj *o) {
2841 dictRelease((dict*) o->ptr);
2842 }
2843
2844 static void freeZsetObject(robj *o) {
2845 zset *zs = o->ptr;
2846
2847 dictRelease(zs->dict);
2848 zslFree(zs->zsl);
2849 zfree(zs);
2850 }
2851
2852 static void freeHashObject(robj *o) {
2853 switch (o->encoding) {
2854 case REDIS_ENCODING_HT:
2855 dictRelease((dict*) o->ptr);
2856 break;
2857 case REDIS_ENCODING_ZIPMAP:
2858 zfree(o->ptr);
2859 break;
2860 default:
2861 redisPanic("Unknown hash encoding type");
2862 break;
2863 }
2864 }
2865
2866 static void incrRefCount(robj *o) {
2867 o->refcount++;
2868 }
2869
2870 static void decrRefCount(void *obj) {
2871 robj *o = obj;
2872
2873 if (o->refcount <= 0) redisPanic("decrRefCount against refcount <= 0");
2874 /* Object is a key of a swapped out value, or in the process of being
2875 * loaded. */
2876 if (server.vm_enabled &&
2877 (o->storage == REDIS_VM_SWAPPED || o->storage == REDIS_VM_LOADING))
2878 {
2879 if (o->storage == REDIS_VM_LOADING) vmCancelThreadedIOJob(obj);
2880 redisAssert(o->type == REDIS_STRING);
2881 freeStringObject(o);
2882 vmMarkPagesFree(o->vm.page,o->vm.usedpages);
2883 pthread_mutex_lock(&server.obj_freelist_mutex);
2884 if (listLength(server.objfreelist) > REDIS_OBJFREELIST_MAX ||
2885 !listAddNodeHead(server.objfreelist,o))
2886 zfree(o);
2887 pthread_mutex_unlock(&server.obj_freelist_mutex);
2888 server.vm_stats_swapped_objects--;
2889 return;
2890 }
2891 /* Object is in memory, or in the process of being swapped out. */
2892 if (--(o->refcount) == 0) {
2893 if (server.vm_enabled && o->storage == REDIS_VM_SWAPPING)
2894 vmCancelThreadedIOJob(obj);
2895 switch(o->type) {
2896 case REDIS_STRING: freeStringObject(o); break;
2897 case REDIS_LIST: freeListObject(o); break;
2898 case REDIS_SET: freeSetObject(o); break;
2899 case REDIS_ZSET: freeZsetObject(o); break;
2900 case REDIS_HASH: freeHashObject(o); break;
2901 default: redisPanic("Unknown object type"); break;
2902 }
2903 if (server.vm_enabled) pthread_mutex_lock(&server.obj_freelist_mutex);
2904 if (listLength(server.objfreelist) > REDIS_OBJFREELIST_MAX ||
2905 !listAddNodeHead(server.objfreelist,o))
2906 zfree(o);
2907 if (server.vm_enabled) pthread_mutex_unlock(&server.obj_freelist_mutex);
2908 }
2909 }
2910
2911 static robj *lookupKey(redisDb *db, robj *key) {
2912 dictEntry *de = dictFind(db->dict,key);
2913 if (de) {
2914 robj *key = dictGetEntryKey(de);
2915 robj *val = dictGetEntryVal(de);
2916
2917 if (server.vm_enabled) {
2918 if (key->storage == REDIS_VM_MEMORY ||
2919 key->storage == REDIS_VM_SWAPPING)
2920 {
2921 /* If we were swapping the object out, stop it, this key
2922 * was requested. */
2923 if (key->storage == REDIS_VM_SWAPPING)
2924 vmCancelThreadedIOJob(key);
2925 /* Update the access time of the key for the aging algorithm. */
2926 key->vm.atime = server.unixtime;
2927 } else {
2928 int notify = (key->storage == REDIS_VM_LOADING);
2929
2930 /* Our value was swapped on disk. Bring it at home. */
2931 redisAssert(val == NULL);
2932 val = vmLoadObject(key);
2933 dictGetEntryVal(de) = val;
2934
2935 /* Clients blocked by the VM subsystem may be waiting for
2936 * this key... */
2937 if (notify) handleClientsBlockedOnSwappedKey(db,key);
2938 }
2939 }
2940 return val;
2941 } else {
2942 return NULL;
2943 }
2944 }
2945
2946 static robj *lookupKeyRead(redisDb *db, robj *key) {
2947 expireIfNeeded(db,key);
2948 return lookupKey(db,key);
2949 }
2950
2951 static robj *lookupKeyWrite(redisDb *db, robj *key) {
2952 deleteIfVolatile(db,key);
2953 return lookupKey(db,key);
2954 }
2955
2956 static robj *lookupKeyReadOrReply(redisClient *c, robj *key, robj *reply) {
2957 robj *o = lookupKeyRead(c->db, key);
2958 if (!o) addReply(c,reply);
2959 return o;
2960 }
2961
2962 static robj *lookupKeyWriteOrReply(redisClient *c, robj *key, robj *reply) {
2963 robj *o = lookupKeyWrite(c->db, key);
2964 if (!o) addReply(c,reply);
2965 return o;
2966 }
2967
2968 static int checkType(redisClient *c, robj *o, int type) {
2969 if (o->type != type) {
2970 addReply(c,shared.wrongtypeerr);
2971 return 1;
2972 }
2973 return 0;
2974 }
2975
2976 static int deleteKey(redisDb *db, robj *key) {
2977 int retval;
2978
2979 /* We need to protect key from destruction: after the first dictDelete()
2980 * it may happen that 'key' is no longer valid if we don't increment
2981 * it's count. This may happen when we get the object reference directly
2982 * from the hash table with dictRandomKey() or dict iterators */
2983 incrRefCount(key);
2984 if (dictSize(db->expires)) dictDelete(db->expires,key);
2985 retval = dictDelete(db->dict,key);
2986 decrRefCount(key);
2987
2988 return retval == DICT_OK;
2989 }
2990
2991 /* Check if the nul-terminated string 's' can be represented by a long
2992 * (that is, is a number that fits into long without any other space or
2993 * character before or after the digits).
2994 *
2995 * If so, the function returns REDIS_OK and *longval is set to the value
2996 * of the number. Otherwise REDIS_ERR is returned */
2997 static int isStringRepresentableAsLong(sds s, long *longval) {
2998 char buf[32], *endptr;
2999 long value;
3000 int slen;
3001
3002 value = strtol(s, &endptr, 10);
3003 if (endptr[0] != '\0') return REDIS_ERR;
3004 slen = snprintf(buf,32,"%ld",value);
3005
3006 /* If the number converted back into a string is not identical
3007 * then it's not possible to encode the string as integer */
3008 if (sdslen(s) != (unsigned)slen || memcmp(buf,s,slen)) return REDIS_ERR;
3009 if (longval) *longval = value;
3010 return REDIS_OK;
3011 }
3012
3013 /* Try to encode a string object in order to save space */
3014 static robj *tryObjectEncoding(robj *o) {
3015 long value;
3016 sds s = o->ptr;
3017
3018 if (o->encoding != REDIS_ENCODING_RAW)
3019 return o; /* Already encoded */
3020
3021 /* It's not safe to encode shared objects: shared objects can be shared
3022 * everywhere in the "object space" of Redis. Encoded objects can only
3023 * appear as "values" (and not, for instance, as keys) */
3024 if (o->refcount > 1) return o;
3025
3026 /* Currently we try to encode only strings */
3027 redisAssert(o->type == REDIS_STRING);
3028
3029 /* Check if we can represent this string as a long integer */
3030 if (isStringRepresentableAsLong(s,&value) == REDIS_ERR) return o;
3031
3032 /* Ok, this object can be encoded */
3033 if (value >= 0 && value < REDIS_SHARED_INTEGERS) {
3034 decrRefCount(o);
3035 incrRefCount(shared.integers[value]);
3036 return shared.integers[value];
3037 } else {
3038 o->encoding = REDIS_ENCODING_INT;
3039 sdsfree(o->ptr);
3040 o->ptr = (void*) value;
3041 return o;
3042 }
3043 }
3044
3045 /* Get a decoded version of an encoded object (returned as a new object).
3046 * If the object is already raw-encoded just increment the ref count. */
3047 static robj *getDecodedObject(robj *o) {
3048 robj *dec;
3049
3050 if (o->encoding == REDIS_ENCODING_RAW) {
3051 incrRefCount(o);
3052 return o;
3053 }
3054 if (o->type == REDIS_STRING && o->encoding == REDIS_ENCODING_INT) {
3055 char buf[32];
3056
3057 snprintf(buf,32,"%ld",(long)o->ptr);
3058 dec = createStringObject(buf,strlen(buf));
3059 return dec;
3060 } else {
3061 redisPanic("Unknown encoding type");
3062 }
3063 }
3064
3065 /* Compare two string objects via strcmp() or alike.
3066 * Note that the objects may be integer-encoded. In such a case we
3067 * use snprintf() to get a string representation of the numbers on the stack
3068 * and compare the strings, it's much faster than calling getDecodedObject().
3069 *
3070 * Important note: if objects are not integer encoded, but binary-safe strings,
3071 * sdscmp() from sds.c will apply memcmp() so this function ca be considered
3072 * binary safe. */
3073 static int compareStringObjects(robj *a, robj *b) {
3074 redisAssert(a->type == REDIS_STRING && b->type == REDIS_STRING);
3075 char bufa[128], bufb[128], *astr, *bstr;
3076 int bothsds = 1;
3077
3078 if (a == b) return 0;
3079 if (a->encoding != REDIS_ENCODING_RAW) {
3080 snprintf(bufa,sizeof(bufa),"%ld",(long) a->ptr);
3081 astr = bufa;
3082 bothsds = 0;
3083 } else {
3084 astr = a->ptr;
3085 }
3086 if (b->encoding != REDIS_ENCODING_RAW) {
3087 snprintf(bufb,sizeof(bufb),"%ld",(long) b->ptr);
3088 bstr = bufb;
3089 bothsds = 0;
3090 } else {
3091 bstr = b->ptr;
3092 }
3093 return bothsds ? sdscmp(astr,bstr) : strcmp(astr,bstr);
3094 }
3095
3096 static size_t stringObjectLen(robj *o) {
3097 redisAssert(o->type == REDIS_STRING);
3098 if (o->encoding == REDIS_ENCODING_RAW) {
3099 return sdslen(o->ptr);
3100 } else {
3101 char buf[32];
3102
3103 return snprintf(buf,32,"%ld",(long)o->ptr);
3104 }
3105 }
3106
3107 static int getDoubleFromObject(robj *o, double *target) {
3108 double value;
3109 char *eptr;
3110
3111 if (o == NULL) {
3112 value = 0;
3113 } else {
3114 redisAssert(o->type == REDIS_STRING);
3115 if (o->encoding == REDIS_ENCODING_RAW) {
3116 value = strtod(o->ptr, &eptr);
3117 if (eptr[0] != '\0') return REDIS_ERR;
3118 } else if (o->encoding == REDIS_ENCODING_INT) {
3119 value = (long)o->ptr;
3120 } else {
3121 redisAssert(1 != 1);
3122 }
3123 }
3124
3125 *target = value;
3126 return REDIS_OK;
3127 }
3128
3129 static int getDoubleFromObjectOrReply(redisClient *c, robj *o, double *target, const char *msg) {
3130 double value;
3131 if (getDoubleFromObject(o, &value) != REDIS_OK) {
3132 if (msg != NULL) {
3133 addReplySds(c, sdscatprintf(sdsempty(), "-ERR %s\r\n", msg));
3134 } else {
3135 addReplySds(c, sdsnew("-ERR value is not a double\r\n"));
3136 }
3137 return REDIS_ERR;
3138 }
3139
3140 *target = value;
3141 return REDIS_OK;
3142 }
3143
3144 static int getLongLongFromObject(robj *o, long long *target) {
3145 long long value;
3146 char *eptr;
3147
3148 if (o == NULL) {
3149 value = 0;
3150 } else {
3151 redisAssert(o->type == REDIS_STRING);
3152 if (o->encoding == REDIS_ENCODING_RAW) {
3153 value = strtoll(o->ptr, &eptr, 10);
3154 if (eptr[0] != '\0') return REDIS_ERR;
3155 } else if (o->encoding == REDIS_ENCODING_INT) {
3156 value = (long)o->ptr;
3157 } else {
3158 redisAssert(1 != 1);
3159 }
3160 }
3161
3162 *target = value;
3163 return REDIS_OK;
3164 }
3165
3166 static int getLongLongFromObjectOrReply(redisClient *c, robj *o, long long *target, const char *msg) {
3167 long long value;
3168 if (getLongLongFromObject(o, &value) != REDIS_OK) {
3169 if (msg != NULL) {
3170 addReplySds(c, sdscatprintf(sdsempty(), "-ERR %s\r\n", msg));
3171 } else {
3172 addReplySds(c, sdsnew("-ERR value is not an integer\r\n"));
3173 }
3174 return REDIS_ERR;
3175 }
3176
3177 *target = value;
3178 return REDIS_OK;
3179 }
3180
3181 static int getLongFromObjectOrReply(redisClient *c, robj *o, long *target, const char *msg) {
3182 long long value;
3183
3184 if (getLongLongFromObjectOrReply(c, o, &value, msg) != REDIS_OK) return REDIS_ERR;
3185 if (value < LONG_MIN || value > LONG_MAX) {
3186 if (msg != NULL) {
3187 addReplySds(c, sdscatprintf(sdsempty(), "-ERR %s\r\n", msg));
3188 } else {
3189 addReplySds(c, sdsnew("-ERR value is out of range\r\n"));
3190 }
3191 return REDIS_ERR;
3192 }
3193
3194 *target = value;
3195 return REDIS_OK;
3196 }
3197
3198 /*============================ RDB saving/loading =========================== */
3199
3200 static int rdbSaveType(FILE *fp, unsigned char type) {
3201 if (fwrite(&type,1,1,fp) == 0) return -1;
3202 return 0;
3203 }
3204
3205 static int rdbSaveTime(FILE *fp, time_t t) {
3206 int32_t t32 = (int32_t) t;
3207 if (fwrite(&t32,4,1,fp) == 0) return -1;
3208 return 0;
3209 }
3210
3211 /* check rdbLoadLen() comments for more info */
3212 static int rdbSaveLen(FILE *fp, uint32_t len) {
3213 unsigned char buf[2];
3214
3215 if (len < (1<<6)) {
3216 /* Save a 6 bit len */
3217 buf[0] = (len&0xFF)|(REDIS_RDB_6BITLEN<<6);
3218 if (fwrite(buf,1,1,fp) == 0) return -1;
3219 } else if (len < (1<<14)) {
3220 /* Save a 14 bit len */
3221 buf[0] = ((len>>8)&0xFF)|(REDIS_RDB_14BITLEN<<6);
3222 buf[1] = len&0xFF;
3223 if (fwrite(buf,2,1,fp) == 0) return -1;
3224 } else {
3225 /* Save a 32 bit len */
3226 buf[0] = (REDIS_RDB_32BITLEN<<6);
3227 if (fwrite(buf,1,1,fp) == 0) return -1;
3228 len = htonl(len);
3229 if (fwrite(&len,4,1,fp) == 0) return -1;
3230 }
3231 return 0;
3232 }
3233
3234 /* String objects in the form "2391" "-100" without any space and with a
3235 * range of values that can fit in an 8, 16 or 32 bit signed value can be
3236 * encoded as integers to save space */
3237 static int rdbTryIntegerEncoding(char *s, size_t len, unsigned char *enc) {
3238 long long value;
3239 char *endptr, buf[32];
3240
3241 /* Check if it's possible to encode this value as a number */
3242 value = strtoll(s, &endptr, 10);
3243 if (endptr[0] != '\0') return 0;
3244 snprintf(buf,32,"%lld",value);
3245
3246 /* If the number converted back into a string is not identical
3247 * then it's not possible to encode the string as integer */
3248 if (strlen(buf) != len || memcmp(buf,s,len)) return 0;
3249
3250 /* Finally check if it fits in our ranges */
3251 if (value >= -(1<<7) && value <= (1<<7)-1) {
3252 enc[0] = (REDIS_RDB_ENCVAL<<6)|REDIS_RDB_ENC_INT8;
3253 enc[1] = value&0xFF;
3254 return 2;
3255 } else if (value >= -(1<<15) && value <= (1<<15)-1) {
3256 enc[0] = (REDIS_RDB_ENCVAL<<6)|REDIS_RDB_ENC_INT16;
3257 enc[1] = value&0xFF;
3258 enc[2] = (value>>8)&0xFF;
3259 return 3;
3260 } else if (value >= -((long long)1<<31) && value <= ((long long)1<<31)-1) {
3261 enc[0] = (REDIS_RDB_ENCVAL<<6)|REDIS_RDB_ENC_INT32;
3262 enc[1] = value&0xFF;
3263 enc[2] = (value>>8)&0xFF;
3264 enc[3] = (value>>16)&0xFF;
3265 enc[4] = (value>>24)&0xFF;
3266 return 5;
3267 } else {
3268 return 0;
3269 }
3270 }
3271
3272 static int rdbSaveLzfStringObject(FILE *fp, unsigned char *s, size_t len) {
3273 size_t comprlen, outlen;
3274 unsigned char byte;
3275 void *out;
3276
3277 /* We require at least four bytes compression for this to be worth it */
3278 if (len <= 4) return 0;
3279 outlen = len-4;
3280 if ((out = zmalloc(outlen+1)) == NULL) return 0;
3281 comprlen = lzf_compress(s, len, out, outlen);
3282 if (comprlen == 0) {
3283 zfree(out);
3284 return 0;
3285 }
3286 /* Data compressed! Let's save it on disk */
3287 byte = (REDIS_RDB_ENCVAL<<6)|REDIS_RDB_ENC_LZF;
3288 if (fwrite(&byte,1,1,fp) == 0) goto writeerr;
3289 if (rdbSaveLen(fp,comprlen) == -1) goto writeerr;
3290 if (rdbSaveLen(fp,len) == -1) goto writeerr;
3291 if (fwrite(out,comprlen,1,fp) == 0) goto writeerr;
3292 zfree(out);
3293 return comprlen;
3294
3295 writeerr:
3296 zfree(out);
3297 return -1;
3298 }
3299
3300 /* Save a string objet as [len][data] on disk. If the object is a string
3301 * representation of an integer value we try to safe it in a special form */
3302 static int rdbSaveRawString(FILE *fp, unsigned char *s, size_t len) {
3303 int enclen;
3304
3305 /* Try integer encoding */
3306 if (len <= 11) {
3307 unsigned char buf[5];
3308 if ((enclen = rdbTryIntegerEncoding((char*)s,len,buf)) > 0) {
3309 if (fwrite(buf,enclen,1,fp) == 0) return -1;
3310 return 0;
3311 }
3312 }
3313
3314 /* Try LZF compression - under 20 bytes it's unable to compress even
3315 * aaaaaaaaaaaaaaaaaa so skip it */
3316 if (server.rdbcompression && len > 20) {
3317 int retval;
3318
3319 retval = rdbSaveLzfStringObject(fp,s,len);
3320 if (retval == -1) return -1;
3321 if (retval > 0) return 0;
3322 /* retval == 0 means data can't be compressed, save the old way */
3323 }
3324
3325 /* Store verbatim */
3326 if (rdbSaveLen(fp,len) == -1) return -1;
3327 if (len && fwrite(s,len,1,fp) == 0) return -1;
3328 return 0;
3329 }
3330
3331 /* Like rdbSaveStringObjectRaw() but handle encoded objects */
3332 static int rdbSaveStringObject(FILE *fp, robj *obj) {
3333 int retval;
3334
3335 /* Avoid incr/decr ref count business when possible.
3336 * This plays well with copy-on-write given that we are probably
3337 * in a child process (BGSAVE). Also this makes sure key objects
3338 * of swapped objects are not incRefCount-ed (an assert does not allow
3339 * this in order to avoid bugs) */
3340 if (obj->encoding != REDIS_ENCODING_RAW) {
3341 obj = getDecodedObject(obj);
3342 retval = rdbSaveRawString(fp,obj->ptr,sdslen(obj->ptr));
3343 decrRefCount(obj);
3344 } else {
3345 retval = rdbSaveRawString(fp,obj->ptr,sdslen(obj->ptr));
3346 }
3347 return retval;
3348 }
3349
3350 /* Save a double value. Doubles are saved as strings prefixed by an unsigned
3351 * 8 bit integer specifing the length of the representation.
3352 * This 8 bit integer has special values in order to specify the following
3353 * conditions:
3354 * 253: not a number
3355 * 254: + inf
3356 * 255: - inf
3357 */
3358 static int rdbSaveDoubleValue(FILE *fp, double val) {
3359 unsigned char buf[128];
3360 int len;
3361
3362 if (isnan(val)) {
3363 buf[0] = 253;
3364 len = 1;
3365 } else if (!isfinite(val)) {
3366 len = 1;
3367 buf[0] = (val < 0) ? 255 : 254;
3368 } else {
3369 snprintf((char*)buf+1,sizeof(buf)-1,"%.17g",val);
3370 buf[0] = strlen((char*)buf+1);
3371 len = buf[0]+1;
3372 }
3373 if (fwrite(buf,len,1,fp) == 0) return -1;
3374 return 0;
3375 }
3376
3377 /* Save a Redis object. */
3378 static int rdbSaveObject(FILE *fp, robj *o) {
3379 if (o->type == REDIS_STRING) {
3380 /* Save a string value */
3381 if (rdbSaveStringObject(fp,o) == -1) return -1;
3382 } else if (o->type == REDIS_LIST) {
3383 /* Save a list value */
3384 list *list = o->ptr;
3385 listIter li;
3386 listNode *ln;
3387
3388 if (rdbSaveLen(fp,listLength(list)) == -1) return -1;
3389 listRewind(list,&li);
3390 while((ln = listNext(&li))) {
3391 robj *eleobj = listNodeValue(ln);
3392
3393 if (rdbSaveStringObject(fp,eleobj) == -1) return -1;
3394 }
3395 } else if (o->type == REDIS_SET) {
3396 /* Save a set value */
3397 dict *set = o->ptr;
3398 dictIterator *di = dictGetIterator(set);
3399 dictEntry *de;
3400
3401 if (rdbSaveLen(fp,dictSize(set)) == -1) return -1;
3402 while((de = dictNext(di)) != NULL) {
3403 robj *eleobj = dictGetEntryKey(de);
3404
3405 if (rdbSaveStringObject(fp,eleobj) == -1) return -1;
3406 }
3407 dictReleaseIterator(di);
3408 } else if (o->type == REDIS_ZSET) {
3409 /* Save a set value */
3410 zset *zs = o->ptr;
3411 dictIterator *di = dictGetIterator(zs->dict);
3412 dictEntry *de;
3413
3414 if (rdbSaveLen(fp,dictSize(zs->dict)) == -1) return -1;
3415 while((de = dictNext(di)) != NULL) {
3416 robj *eleobj = dictGetEntryKey(de);
3417 double *score = dictGetEntryVal(de);
3418
3419 if (rdbSaveStringObject(fp,eleobj) == -1) return -1;
3420 if (rdbSaveDoubleValue(fp,*score) == -1) return -1;
3421 }
3422 dictReleaseIterator(di);
3423 } else if (o->type == REDIS_HASH) {
3424 /* Save a hash value */
3425 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
3426 unsigned char *p = zipmapRewind(o->ptr);
3427 unsigned int count = zipmapLen(o->ptr);
3428 unsigned char *key, *val;
3429 unsigned int klen, vlen;
3430
3431 if (rdbSaveLen(fp,count) == -1) return -1;
3432 while((p = zipmapNext(p,&key,&klen,&val,&vlen)) != NULL) {
3433 if (rdbSaveRawString(fp,key,klen) == -1) return -1;
3434 if (rdbSaveRawString(fp,val,vlen) == -1) return -1;
3435 }
3436 } else {
3437 dictIterator *di = dictGetIterator(o->ptr);
3438 dictEntry *de;
3439
3440 if (rdbSaveLen(fp,dictSize((dict*)o->ptr)) == -1) return -1;
3441 while((de = dictNext(di)) != NULL) {
3442 robj *key = dictGetEntryKey(de);
3443 robj *val = dictGetEntryVal(de);
3444
3445 if (rdbSaveStringObject(fp,key) == -1) return -1;
3446 if (rdbSaveStringObject(fp,val) == -1) return -1;
3447 }
3448 dictReleaseIterator(di);
3449 }
3450 } else {
3451 redisPanic("Unknown object type");
3452 }
3453 return 0;
3454 }
3455
3456 /* Return the length the object will have on disk if saved with
3457 * the rdbSaveObject() function. Currently we use a trick to get
3458 * this length with very little changes to the code. In the future
3459 * we could switch to a faster solution. */
3460 static off_t rdbSavedObjectLen(robj *o, FILE *fp) {
3461 if (fp == NULL) fp = server.devnull;
3462 rewind(fp);
3463 assert(rdbSaveObject(fp,o) != 1);
3464 return ftello(fp);
3465 }
3466
3467 /* Return the number of pages required to save this object in the swap file */
3468 static off_t rdbSavedObjectPages(robj *o, FILE *fp) {
3469 off_t bytes = rdbSavedObjectLen(o,fp);
3470
3471 return (bytes+(server.vm_page_size-1))/server.vm_page_size;
3472 }
3473
3474 /* Save the DB on disk. Return REDIS_ERR on error, REDIS_OK on success */
3475 static int rdbSave(char *filename) {
3476 dictIterator *di = NULL;
3477 dictEntry *de;
3478 FILE *fp;
3479 char tmpfile[256];
3480 int j;
3481 time_t now = time(NULL);
3482
3483 /* Wait for I/O therads to terminate, just in case this is a
3484 * foreground-saving, to avoid seeking the swap file descriptor at the
3485 * same time. */
3486 if (server.vm_enabled)
3487 waitEmptyIOJobsQueue();
3488
3489 snprintf(tmpfile,256,"temp-%d.rdb", (int) getpid());
3490 fp = fopen(tmpfile,"w");
3491 if (!fp) {
3492 redisLog(REDIS_WARNING, "Failed saving the DB: %s", strerror(errno));
3493 return REDIS_ERR;
3494 }
3495 if (fwrite("REDIS0001",9,1,fp) == 0) goto werr;
3496 for (j = 0; j < server.dbnum; j++) {
3497 redisDb *db = server.db+j;
3498 dict *d = db->dict;
3499 if (dictSize(d) == 0) continue;
3500 di = dictGetIterator(d);
3501 if (!di) {
3502 fclose(fp);
3503 return REDIS_ERR;
3504 }
3505
3506 /* Write the SELECT DB opcode */
3507 if (rdbSaveType(fp,REDIS_SELECTDB) == -1) goto werr;
3508 if (rdbSaveLen(fp,j) == -1) goto werr;
3509
3510 /* Iterate this DB writing every entry */
3511 while((de = dictNext(di)) != NULL) {
3512 robj *key = dictGetEntryKey(de);
3513 robj *o = dictGetEntryVal(de);
3514 time_t expiretime = getExpire(db,key);
3515
3516 /* Save the expire time */
3517 if (expiretime != -1) {
3518 /* If this key is already expired skip it */
3519 if (expiretime < now) continue;
3520 if (rdbSaveType(fp,REDIS_EXPIRETIME) == -1) goto werr;
3521 if (rdbSaveTime(fp,expiretime) == -1) goto werr;
3522 }
3523 /* Save the key and associated value. This requires special
3524 * handling if the value is swapped out. */
3525 if (!server.vm_enabled || key->storage == REDIS_VM_MEMORY ||
3526 key->storage == REDIS_VM_SWAPPING) {
3527 /* Save type, key, value */
3528 if (rdbSaveType(fp,o->type) == -1) goto werr;
3529 if (rdbSaveStringObject(fp,key) == -1) goto werr;
3530 if (rdbSaveObject(fp,o) == -1) goto werr;
3531 } else {
3532 /* REDIS_VM_SWAPPED or REDIS_VM_LOADING */
3533 robj *po;
3534 /* Get a preview of the object in memory */
3535 po = vmPreviewObject(key);
3536 /* Save type, key, value */
3537 if (rdbSaveType(fp,key->vtype) == -1) goto werr;
3538 if (rdbSaveStringObject(fp,key) == -1) goto werr;
3539 if (rdbSaveObject(fp,po) == -1) goto werr;
3540 /* Remove the loaded object from memory */
3541 decrRefCount(po);
3542 }
3543 }
3544 dictReleaseIterator(di);
3545 }
3546 /* EOF opcode */
3547 if (rdbSaveType(fp,REDIS_EOF) == -1) goto werr;
3548
3549 /* Make sure data will not remain on the OS's output buffers */
3550 fflush(fp);
3551 fsync(fileno(fp));
3552 fclose(fp);
3553
3554 /* Use RENAME to make sure the DB file is changed atomically only
3555 * if the generate DB file is ok. */
3556 if (rename(tmpfile,filename) == -1) {
3557 redisLog(REDIS_WARNING,"Error moving temp DB file on the final destination: %s", strerror(errno));
3558 unlink(tmpfile);
3559 return REDIS_ERR;
3560 }
3561 redisLog(REDIS_NOTICE,"DB saved on disk");
3562 server.dirty = 0;
3563 server.lastsave = time(NULL);
3564 return REDIS_OK;
3565
3566 werr:
3567 fclose(fp);
3568 unlink(tmpfile);
3569 redisLog(REDIS_WARNING,"Write error saving DB on disk: %s", strerror(errno));
3570 if (di) dictReleaseIterator(di);
3571 return REDIS_ERR;
3572 }
3573
3574 static int rdbSaveBackground(char *filename) {
3575 pid_t childpid;
3576
3577 if (server.bgsavechildpid != -1) return REDIS_ERR;
3578 if (server.vm_enabled) waitEmptyIOJobsQueue();
3579 if ((childpid = fork()) == 0) {
3580 /* Child */
3581 if (server.vm_enabled) vmReopenSwapFile();
3582 close(server.fd);
3583 if (rdbSave(filename) == REDIS_OK) {
3584 _exit(0);
3585 } else {
3586 _exit(1);
3587 }
3588 } else {
3589 /* Parent */
3590 if (childpid == -1) {
3591 redisLog(REDIS_WARNING,"Can't save in background: fork: %s",
3592 strerror(errno));
3593 return REDIS_ERR;
3594 }
3595 redisLog(REDIS_NOTICE,"Background saving started by pid %d",childpid);
3596 server.bgsavechildpid = childpid;
3597 updateDictResizePolicy();
3598 return REDIS_OK;
3599 }
3600 return REDIS_OK; /* unreached */
3601 }
3602
3603 static void rdbRemoveTempFile(pid_t childpid) {
3604 char tmpfile[256];
3605
3606 snprintf(tmpfile,256,"temp-%d.rdb", (int) childpid);
3607 unlink(tmpfile);
3608 }
3609
3610 static int rdbLoadType(FILE *fp) {
3611 unsigned char type;
3612 if (fread(&type,1,1,fp) == 0) return -1;
3613 return type;
3614 }
3615
3616 static time_t rdbLoadTime(FILE *fp) {
3617 int32_t t32;
3618 if (fread(&t32,4,1,fp) == 0) return -1;
3619 return (time_t) t32;
3620 }
3621
3622 /* Load an encoded length from the DB, see the REDIS_RDB_* defines on the top
3623 * of this file for a description of how this are stored on disk.
3624 *
3625 * isencoded is set to 1 if the readed length is not actually a length but
3626 * an "encoding type", check the above comments for more info */
3627 static uint32_t rdbLoadLen(FILE *fp, int *isencoded) {
3628 unsigned char buf[2];
3629 uint32_t len;
3630 int type;
3631
3632 if (isencoded) *isencoded = 0;
3633 if (fread(buf,1,1,fp) == 0) return REDIS_RDB_LENERR;
3634 type = (buf[0]&0xC0)>>6;
3635 if (type == REDIS_RDB_6BITLEN) {
3636 /* Read a 6 bit len */
3637 return buf[0]&0x3F;
3638 } else if (type == REDIS_RDB_ENCVAL) {
3639 /* Read a 6 bit len encoding type */
3640 if (isencoded) *isencoded = 1;
3641 return buf[0]&0x3F;
3642 } else if (type == REDIS_RDB_14BITLEN) {
3643 /* Read a 14 bit len */
3644 if (fread(buf+1,1,1,fp) == 0) return REDIS_RDB_LENERR;
3645 return ((buf[0]&0x3F)<<8)|buf[1];
3646 } else {
3647 /* Read a 32 bit len */
3648 if (fread(&len,4,1,fp) == 0) return REDIS_RDB_LENERR;
3649 return ntohl(len);
3650 }
3651 }
3652
3653 static robj *rdbLoadIntegerObject(FILE *fp, int enctype) {
3654 unsigned char enc[4];
3655 long long val;
3656
3657 if (enctype == REDIS_RDB_ENC_INT8) {
3658 if (fread(enc,1,1,fp) == 0) return NULL;
3659 val = (signed char)enc[0];
3660 } else if (enctype == REDIS_RDB_ENC_INT16) {
3661 uint16_t v;
3662 if (fread(enc,2,1,fp) == 0) return NULL;
3663 v = enc[0]|(enc[1]<<8);
3664 val = (int16_t)v;
3665 } else if (enctype == REDIS_RDB_ENC_INT32) {
3666 uint32_t v;
3667 if (fread(enc,4,1,fp) == 0) return NULL;
3668 v = enc[0]|(enc[1]<<8)|(enc[2]<<16)|(enc[3]<<24);
3669 val = (int32_t)v;
3670 } else {
3671 val = 0; /* anti-warning */
3672 redisPanic("Unknown RDB integer encoding type");
3673 }
3674 return createObject(REDIS_STRING,sdscatprintf(sdsempty(),"%lld",val));
3675 }
3676
3677 static robj *rdbLoadLzfStringObject(FILE*fp) {
3678 unsigned int len, clen;
3679 unsigned char *c = NULL;
3680 sds val = NULL;
3681
3682 if ((clen = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR) return NULL;
3683 if ((len = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR) return NULL;
3684 if ((c = zmalloc(clen)) == NULL) goto err;
3685 if ((val = sdsnewlen(NULL,len)) == NULL) goto err;
3686 if (fread(c,clen,1,fp) == 0) goto err;
3687 if (lzf_decompress(c,clen,val,len) == 0) goto err;
3688 zfree(c);
3689 return createObject(REDIS_STRING,val);
3690 err:
3691 zfree(c);
3692 sdsfree(val);
3693 return NULL;
3694 }
3695
3696 static robj *rdbLoadStringObject(FILE*fp) {
3697 int isencoded;
3698 uint32_t len;
3699 sds val;
3700
3701 len = rdbLoadLen(fp,&isencoded);
3702 if (isencoded) {
3703 switch(len) {
3704 case REDIS_RDB_ENC_INT8:
3705 case REDIS_RDB_ENC_INT16:
3706 case REDIS_RDB_ENC_INT32:
3707 return rdbLoadIntegerObject(fp,len);
3708 case REDIS_RDB_ENC_LZF:
3709 return rdbLoadLzfStringObject(fp);
3710 default:
3711 redisPanic("Unknown RDB encoding type");
3712 }
3713 }
3714
3715 if (len == REDIS_RDB_LENERR) return NULL;
3716 val = sdsnewlen(NULL,len);
3717 if (len && fread(val,len,1,fp) == 0) {
3718 sdsfree(val);
3719 return NULL;
3720 }
3721 return createObject(REDIS_STRING,val);
3722 }
3723
3724 /* For information about double serialization check rdbSaveDoubleValue() */
3725 static int rdbLoadDoubleValue(FILE *fp, double *val) {
3726 char buf[128];
3727 unsigned char len;
3728
3729 if (fread(&len,1,1,fp) == 0) return -1;
3730 switch(len) {
3731 case 255: *val = R_NegInf; return 0;
3732 case 254: *val = R_PosInf; return 0;
3733 case 253: *val = R_Nan; return 0;
3734 default:
3735 if (fread(buf,len,1,fp) == 0) return -1;
3736 buf[len] = '\0';
3737 sscanf(buf, "%lg", val);
3738 return 0;
3739 }
3740 }
3741
3742 /* Load a Redis object of the specified type from the specified file.
3743 * On success a newly allocated object is returned, otherwise NULL. */
3744 static robj *rdbLoadObject(int type, FILE *fp) {
3745 robj *o;
3746
3747 redisLog(REDIS_DEBUG,"LOADING OBJECT %d (at %d)\n",type,ftell(fp));
3748 if (type == REDIS_STRING) {
3749 /* Read string value */
3750 if ((o = rdbLoadStringObject(fp)) == NULL) return NULL;
3751 o = tryObjectEncoding(o);
3752 } else if (type == REDIS_LIST || type == REDIS_SET) {
3753 /* Read list/set value */
3754 uint32_t listlen;
3755
3756 if ((listlen = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR) return NULL;
3757 o = (type == REDIS_LIST) ? createListObject() : createSetObject();
3758 /* It's faster to expand the dict to the right size asap in order
3759 * to avoid rehashing */
3760 if (type == REDIS_SET && listlen > DICT_HT_INITIAL_SIZE)
3761 dictExpand(o->ptr,listlen);
3762 /* Load every single element of the list/set */
3763 while(listlen--) {
3764 robj *ele;
3765
3766 if ((ele = rdbLoadStringObject(fp)) == NULL) return NULL;
3767 ele = tryObjectEncoding(ele);
3768 if (type == REDIS_LIST) {
3769 listAddNodeTail((list*)o->ptr,ele);
3770 } else {
3771 dictAdd((dict*)o->ptr,ele,NULL);
3772 }
3773 }
3774 } else if (type == REDIS_ZSET) {
3775 /* Read list/set value */
3776 size_t zsetlen;
3777 zset *zs;
3778
3779 if ((zsetlen = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR) return NULL;
3780 o = createZsetObject();
3781 zs = o->ptr;
3782 /* Load every single element of the list/set */
3783 while(zsetlen--) {
3784 robj *ele;
3785 double *score = zmalloc(sizeof(double));
3786
3787 if ((ele = rdbLoadStringObject(fp)) == NULL) return NULL;
3788 ele = tryObjectEncoding(ele);
3789 if (rdbLoadDoubleValue(fp,score) == -1) return NULL;
3790 dictAdd(zs->dict,ele,score);
3791 zslInsert(zs->zsl,*score,ele);
3792 incrRefCount(ele); /* added to skiplist */
3793 }
3794 } else if (type == REDIS_HASH) {
3795 size_t hashlen;
3796
3797 if ((hashlen = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR) return NULL;
3798 o = createHashObject();
3799 /* Too many entries? Use an hash table. */
3800 if (hashlen > server.hash_max_zipmap_entries)
3801 convertToRealHash(o);
3802 /* Load every key/value, then set it into the zipmap or hash
3803 * table, as needed. */
3804 while(hashlen--) {
3805 robj *key, *val;
3806
3807 if ((key = rdbLoadStringObject(fp)) == NULL) return NULL;
3808 if ((val = rdbLoadStringObject(fp)) == NULL) return NULL;
3809 /* If we are using a zipmap and there are too big values
3810 * the object is converted to real hash table encoding. */
3811 if (o->encoding != REDIS_ENCODING_HT &&
3812 (sdslen(key->ptr) > server.hash_max_zipmap_value ||
3813 sdslen(val->ptr) > server.hash_max_zipmap_value))
3814 {
3815 convertToRealHash(o);
3816 }
3817
3818 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
3819 unsigned char *zm = o->ptr;
3820
3821 zm = zipmapSet(zm,key->ptr,sdslen(key->ptr),
3822 val->ptr,sdslen(val->ptr),NULL);
3823 o->ptr = zm;
3824 decrRefCount(key);
3825 decrRefCount(val);
3826 } else {
3827 key = tryObjectEncoding(key);
3828 val = tryObjectEncoding(val);
3829 dictAdd((dict*)o->ptr,key,val);
3830 }
3831 }
3832 } else {
3833 redisPanic("Unknown object type");
3834 }
3835 return o;
3836 }
3837
3838 static int rdbLoad(char *filename) {
3839 FILE *fp;
3840 robj *keyobj = NULL;
3841 uint32_t dbid;
3842 int type, retval, rdbver;
3843 dict *d = server.db[0].dict;
3844 redisDb *db = server.db+0;
3845 char buf[1024];
3846 time_t expiretime = -1, now = time(NULL);
3847 long long loadedkeys = 0;
3848
3849 fp = fopen(filename,"r");
3850 if (!fp) return REDIS_ERR;
3851 if (fread(buf,9,1,fp) == 0) goto eoferr;
3852 buf[9] = '\0';
3853 if (memcmp(buf,"REDIS",5) != 0) {
3854 fclose(fp);
3855 redisLog(REDIS_WARNING,"Wrong signature trying to load DB from file");
3856 return REDIS_ERR;
3857 }
3858 rdbver = atoi(buf+5);
3859 if (rdbver != 1) {
3860 fclose(fp);
3861 redisLog(REDIS_WARNING,"Can't handle RDB format version %d",rdbver);
3862 return REDIS_ERR;
3863 }
3864 while(1) {
3865 robj *o;
3866
3867 /* Read type. */
3868 if ((type = rdbLoadType(fp)) == -1) goto eoferr;
3869 if (type == REDIS_EXPIRETIME) {
3870 if ((expiretime = rdbLoadTime(fp)) == -1) goto eoferr;
3871 /* We read the time so we need to read the object type again */
3872 if ((type = rdbLoadType(fp)) == -1) goto eoferr;
3873 }
3874 if (type == REDIS_EOF) break;
3875 /* Handle SELECT DB opcode as a special case */
3876 if (type == REDIS_SELECTDB) {
3877 if ((dbid = rdbLoadLen(fp,NULL)) == REDIS_RDB_LENERR)
3878 goto eoferr;
3879 if (dbid >= (unsigned)server.dbnum) {
3880 redisLog(REDIS_WARNING,"FATAL: Data file was created with a Redis server configured to handle more than %d databases. Exiting\n", server.dbnum);
3881 exit(1);
3882 }
3883 db = server.db+dbid;
3884 d = db->dict;
3885 continue;
3886 }
3887 /* Read key */
3888 if ((keyobj = rdbLoadStringObject(fp)) == NULL) goto eoferr;
3889 /* Read value */
3890 if ((o = rdbLoadObject(type,fp)) == NULL) goto eoferr;
3891 /* Add the new object in the hash table */
3892 retval = dictAdd(d,keyobj,o);
3893 if (retval == DICT_ERR) {
3894 redisLog(REDIS_WARNING,"Loading DB, duplicated key (%s) found! Unrecoverable error, exiting now.", keyobj->ptr);
3895 exit(1);
3896 }
3897 /* Set the expire time if needed */
3898 if (expiretime != -1) {
3899 setExpire(db,keyobj,expiretime);
3900 /* Delete this key if already expired */
3901 if (expiretime < now) deleteKey(db,keyobj);
3902 expiretime = -1;
3903 }
3904 keyobj = o = NULL;
3905 /* Handle swapping while loading big datasets when VM is on */
3906 loadedkeys++;
3907 if (server.vm_enabled && (loadedkeys % 5000) == 0) {
3908 while (zmalloc_used_memory() > server.vm_max_memory) {
3909 if (vmSwapOneObjectBlocking() == REDIS_ERR) break;
3910 }
3911 }
3912 }
3913 fclose(fp);
3914 return REDIS_OK;
3915
3916 eoferr: /* unexpected end of file is handled here with a fatal exit */
3917 if (keyobj) decrRefCount(keyobj);
3918 redisLog(REDIS_WARNING,"Short read or OOM loading DB. Unrecoverable error, aborting now.");
3919 exit(1);
3920 return REDIS_ERR; /* Just to avoid warning */
3921 }
3922
3923 /*================================== Commands =============================== */
3924
3925 static void authCommand(redisClient *c) {
3926 if (!server.requirepass || !strcmp(c->argv[1]->ptr, server.requirepass)) {
3927 c->authenticated = 1;
3928 addReply(c,shared.ok);
3929 } else {
3930 c->authenticated = 0;
3931 addReplySds(c,sdscatprintf(sdsempty(),"-ERR invalid password\r\n"));
3932 }
3933 }
3934
3935 static void pingCommand(redisClient *c) {
3936 addReply(c,shared.pong);
3937 }
3938
3939 static void echoCommand(redisClient *c) {
3940 addReplyBulk(c,c->argv[1]);
3941 }
3942
3943 /*=================================== Strings =============================== */
3944
3945 static void setGenericCommand(redisClient *c, int nx) {
3946 int retval;
3947
3948 if (nx) deleteIfVolatile(c->db,c->argv[1]);
3949 retval = dictAdd(c->db->dict,c->argv[1],c->argv[2]);
3950 if (retval == DICT_ERR) {
3951 if (!nx) {
3952 /* If the key is about a swapped value, we want a new key object
3953 * to overwrite the old. So we delete the old key in the database.
3954 * This will also make sure that swap pages about the old object
3955 * will be marked as free. */
3956 if (server.vm_enabled && deleteIfSwapped(c->db,c->argv[1]))
3957 incrRefCount(c->argv[1]);
3958 dictReplace(c->db->dict,c->argv[1],c->argv[2]);
3959 incrRefCount(c->argv[2]);
3960 } else {
3961 addReply(c,shared.czero);
3962 return;
3963 }
3964 } else {
3965 incrRefCount(c->argv[1]);
3966 incrRefCount(c->argv[2]);
3967 }
3968 server.dirty++;
3969 removeExpire(c->db,c->argv[1]);
3970 addReply(c, nx ? shared.cone : shared.ok);
3971 }
3972
3973 static void setCommand(redisClient *c) {
3974 setGenericCommand(c,0);
3975 }
3976
3977 static void setnxCommand(redisClient *c) {
3978 setGenericCommand(c,1);
3979 }
3980
3981 static int getGenericCommand(redisClient *c) {
3982 robj *o;
3983
3984 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL)
3985 return REDIS_OK;
3986
3987 if (o->type != REDIS_STRING) {
3988 addReply(c,shared.wrongtypeerr);
3989 return REDIS_ERR;
3990 } else {
3991 addReplyBulk(c,o);
3992 return REDIS_OK;
3993 }
3994 }
3995
3996 static void getCommand(redisClient *c) {
3997 getGenericCommand(c);
3998 }
3999
4000 static void getsetCommand(redisClient *c) {
4001 if (getGenericCommand(c) == REDIS_ERR) return;
4002 if (dictAdd(c->db->dict,c->argv[1],c->argv[2]) == DICT_ERR) {
4003 dictReplace(c->db->dict,c->argv[1],c->argv[2]);
4004 } else {
4005 incrRefCount(c->argv[1]);
4006 }
4007 incrRefCount(c->argv[2]);
4008 server.dirty++;
4009 removeExpire(c->db,c->argv[1]);
4010 }
4011
4012 static void mgetCommand(redisClient *c) {
4013 int j;
4014
4015 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",c->argc-1));
4016 for (j = 1; j < c->argc; j++) {
4017 robj *o = lookupKeyRead(c->db,c->argv[j]);
4018 if (o == NULL) {
4019 addReply(c,shared.nullbulk);
4020 } else {
4021 if (o->type != REDIS_STRING) {
4022 addReply(c,shared.nullbulk);
4023 } else {
4024 addReplyBulk(c,o);
4025 }
4026 }
4027 }
4028 }
4029
4030 static void msetGenericCommand(redisClient *c, int nx) {
4031 int j, busykeys = 0;
4032
4033 if ((c->argc % 2) == 0) {
4034 addReplySds(c,sdsnew("-ERR wrong number of arguments for MSET\r\n"));
4035 return;
4036 }
4037 /* Handle the NX flag. The MSETNX semantic is to return zero and don't
4038 * set nothing at all if at least one already key exists. */
4039 if (nx) {
4040 for (j = 1; j < c->argc; j += 2) {
4041 if (lookupKeyWrite(c->db,c->argv[j]) != NULL) {
4042 busykeys++;
4043 }
4044 }
4045 }
4046 if (busykeys) {
4047 addReply(c, shared.czero);
4048 return;
4049 }
4050
4051 for (j = 1; j < c->argc; j += 2) {
4052 int retval;
4053
4054 c->argv[j+1] = tryObjectEncoding(c->argv[j+1]);
4055 retval = dictAdd(c->db->dict,c->argv[j],c->argv[j+1]);
4056 if (retval == DICT_ERR) {
4057 dictReplace(c->db->dict,c->argv[j],c->argv[j+1]);
4058 incrRefCount(c->argv[j+1]);
4059 } else {
4060 incrRefCount(c->argv[j]);
4061 incrRefCount(c->argv[j+1]);
4062 }
4063 removeExpire(c->db,c->argv[j]);
4064 }
4065 server.dirty += (c->argc-1)/2;
4066 addReply(c, nx ? shared.cone : shared.ok);
4067 }
4068
4069 static void msetCommand(redisClient *c) {
4070 msetGenericCommand(c,0);
4071 }
4072
4073 static void msetnxCommand(redisClient *c) {
4074 msetGenericCommand(c,1);
4075 }
4076
4077 static void incrDecrCommand(redisClient *c, long long incr) {
4078 long long value;
4079 int retval;
4080 robj *o;
4081
4082 o = lookupKeyWrite(c->db,c->argv[1]);
4083
4084 if (getLongLongFromObjectOrReply(c, o, &value, NULL) != REDIS_OK) return;
4085
4086 value += incr;
4087 o = createObject(REDIS_STRING,sdscatprintf(sdsempty(),"%lld",value));
4088 o = tryObjectEncoding(o);
4089 retval = dictAdd(c->db->dict,c->argv[1],o);
4090 if (retval == DICT_ERR) {
4091 dictReplace(c->db->dict,c->argv[1],o);
4092 removeExpire(c->db,c->argv[1]);
4093 } else {
4094 incrRefCount(c->argv[1]);
4095 }
4096 server.dirty++;
4097 addReply(c,shared.colon);
4098 addReply(c,o);
4099 addReply(c,shared.crlf);
4100 }
4101
4102 static void incrCommand(redisClient *c) {
4103 incrDecrCommand(c,1);
4104 }
4105
4106 static void decrCommand(redisClient *c) {
4107 incrDecrCommand(c,-1);
4108 }
4109
4110 static void incrbyCommand(redisClient *c) {
4111 long long incr;
4112
4113 if (getLongLongFromObjectOrReply(c, c->argv[2], &incr, NULL) != REDIS_OK) return;
4114 incrDecrCommand(c,incr);
4115 }
4116
4117 static void decrbyCommand(redisClient *c) {
4118 long long incr;
4119
4120 if (getLongLongFromObjectOrReply(c, c->argv[2], &incr, NULL) != REDIS_OK) return;
4121 incrDecrCommand(c,-incr);
4122 }
4123
4124 static void appendCommand(redisClient *c) {
4125 int retval;
4126 size_t totlen;
4127 robj *o;
4128
4129 o = lookupKeyWrite(c->db,c->argv[1]);
4130 if (o == NULL) {
4131 /* Create the key */
4132 retval = dictAdd(c->db->dict,c->argv[1],c->argv[2]);
4133 incrRefCount(c->argv[1]);
4134 incrRefCount(c->argv[2]);
4135 totlen = stringObjectLen(c->argv[2]);
4136 } else {
4137 dictEntry *de;
4138
4139 de = dictFind(c->db->dict,c->argv[1]);
4140 assert(de != NULL);
4141
4142 o = dictGetEntryVal(de);
4143 if (o->type != REDIS_STRING) {
4144 addReply(c,shared.wrongtypeerr);
4145 return;
4146 }
4147 /* If the object is specially encoded or shared we have to make
4148 * a copy */
4149 if (o->refcount != 1 || o->encoding != REDIS_ENCODING_RAW) {
4150 robj *decoded = getDecodedObject(o);
4151
4152 o = createStringObject(decoded->ptr, sdslen(decoded->ptr));
4153 decrRefCount(decoded);
4154 dictReplace(c->db->dict,c->argv[1],o);
4155 }
4156 /* APPEND! */
4157 if (c->argv[2]->encoding == REDIS_ENCODING_RAW) {
4158 o->ptr = sdscatlen(o->ptr,
4159 c->argv[2]->ptr, sdslen(c->argv[2]->ptr));
4160 } else {
4161 o->ptr = sdscatprintf(o->ptr, "%ld",
4162 (unsigned long) c->argv[2]->ptr);
4163 }
4164 totlen = sdslen(o->ptr);
4165 }
4166 server.dirty++;
4167 addReplySds(c,sdscatprintf(sdsempty(),":%lu\r\n",(unsigned long)totlen));
4168 }
4169
4170 static void substrCommand(redisClient *c) {
4171 robj *o;
4172 long start = atoi(c->argv[2]->ptr);
4173 long end = atoi(c->argv[3]->ptr);
4174 size_t rangelen, strlen;
4175 sds range;
4176
4177 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4178 checkType(c,o,REDIS_STRING)) return;
4179
4180 o = getDecodedObject(o);
4181 strlen = sdslen(o->ptr);
4182
4183 /* convert negative indexes */
4184 if (start < 0) start = strlen+start;
4185 if (end < 0) end = strlen+end;
4186 if (start < 0) start = 0;
4187 if (end < 0) end = 0;
4188
4189 /* indexes sanity checks */
4190 if (start > end || (size_t)start >= strlen) {
4191 /* Out of range start or start > end result in null reply */
4192 addReply(c,shared.nullbulk);
4193 decrRefCount(o);
4194 return;
4195 }
4196 if ((size_t)end >= strlen) end = strlen-1;
4197 rangelen = (end-start)+1;
4198
4199 /* Return the result */
4200 addReplySds(c,sdscatprintf(sdsempty(),"$%zu\r\n",rangelen));
4201 range = sdsnewlen((char*)o->ptr+start,rangelen);
4202 addReplySds(c,range);
4203 addReply(c,shared.crlf);
4204 decrRefCount(o);
4205 }
4206
4207 /* ========================= Type agnostic commands ========================= */
4208
4209 static void delCommand(redisClient *c) {
4210 int deleted = 0, j;
4211
4212 for (j = 1; j < c->argc; j++) {
4213 if (deleteKey(c->db,c->argv[j])) {
4214 server.dirty++;
4215 deleted++;
4216 }
4217 }
4218 addReplyLong(c,deleted);
4219 }
4220
4221 static void existsCommand(redisClient *c) {
4222 addReply(c,lookupKeyRead(c->db,c->argv[1]) ? shared.cone : shared.czero);
4223 }
4224
4225 static void selectCommand(redisClient *c) {
4226 int id = atoi(c->argv[1]->ptr);
4227
4228 if (selectDb(c,id) == REDIS_ERR) {
4229 addReplySds(c,sdsnew("-ERR invalid DB index\r\n"));
4230 } else {
4231 addReply(c,shared.ok);
4232 }
4233 }
4234
4235 static void randomkeyCommand(redisClient *c) {
4236 dictEntry *de;
4237
4238 while(1) {
4239 de = dictGetRandomKey(c->db->dict);
4240 if (!de || expireIfNeeded(c->db,dictGetEntryKey(de)) == 0) break;
4241 }
4242 if (de == NULL) {
4243 addReply(c,shared.plus);
4244 addReply(c,shared.crlf);
4245 } else {
4246 addReply(c,shared.plus);
4247 addReply(c,dictGetEntryKey(de));
4248 addReply(c,shared.crlf);
4249 }
4250 }
4251
4252 static void keysCommand(redisClient *c) {
4253 dictIterator *di;
4254 dictEntry *de;
4255 sds pattern = c->argv[1]->ptr;
4256 int plen = sdslen(pattern);
4257 unsigned long numkeys = 0;
4258 robj *lenobj = createObject(REDIS_STRING,NULL);
4259
4260 di = dictGetIterator(c->db->dict);
4261 addReply(c,lenobj);
4262 decrRefCount(lenobj);
4263 while((de = dictNext(di)) != NULL) {
4264 robj *keyobj = dictGetEntryKey(de);
4265
4266 sds key = keyobj->ptr;
4267 if ((pattern[0] == '*' && pattern[1] == '\0') ||
4268 stringmatchlen(pattern,plen,key,sdslen(key),0)) {
4269 if (expireIfNeeded(c->db,keyobj) == 0) {
4270 addReplyBulk(c,keyobj);
4271 numkeys++;
4272 }
4273 }
4274 }
4275 dictReleaseIterator(di);
4276 lenobj->ptr = sdscatprintf(sdsempty(),"*%lu\r\n",numkeys);
4277 }
4278
4279 static void dbsizeCommand(redisClient *c) {
4280 addReplySds(c,
4281 sdscatprintf(sdsempty(),":%lu\r\n",dictSize(c->db->dict)));
4282 }
4283
4284 static void lastsaveCommand(redisClient *c) {
4285 addReplySds(c,
4286 sdscatprintf(sdsempty(),":%lu\r\n",server.lastsave));
4287 }
4288
4289 static void typeCommand(redisClient *c) {
4290 robj *o;
4291 char *type;
4292
4293 o = lookupKeyRead(c->db,c->argv[1]);
4294 if (o == NULL) {
4295 type = "+none";
4296 } else {
4297 switch(o->type) {
4298 case REDIS_STRING: type = "+string"; break;
4299 case REDIS_LIST: type = "+list"; break;
4300 case REDIS_SET: type = "+set"; break;
4301 case REDIS_ZSET: type = "+zset"; break;
4302 case REDIS_HASH: type = "+hash"; break;
4303 default: type = "+unknown"; break;
4304 }
4305 }
4306 addReplySds(c,sdsnew(type));
4307 addReply(c,shared.crlf);
4308 }
4309
4310 static void saveCommand(redisClient *c) {
4311 if (server.bgsavechildpid != -1) {
4312 addReplySds(c,sdsnew("-ERR background save in progress\r\n"));
4313 return;
4314 }
4315 if (rdbSave(server.dbfilename) == REDIS_OK) {
4316 addReply(c,shared.ok);
4317 } else {
4318 addReply(c,shared.err);
4319 }
4320 }
4321
4322 static void bgsaveCommand(redisClient *c) {
4323 if (server.bgsavechildpid != -1) {
4324 addReplySds(c,sdsnew("-ERR background save already in progress\r\n"));
4325 return;
4326 }
4327 if (rdbSaveBackground(server.dbfilename) == REDIS_OK) {
4328 char *status = "+Background saving started\r\n";
4329 addReplySds(c,sdsnew(status));
4330 } else {
4331 addReply(c,shared.err);
4332 }
4333 }
4334
4335 static void shutdownCommand(redisClient *c) {
4336 redisLog(REDIS_WARNING,"User requested shutdown, saving DB...");
4337 /* Kill the saving child if there is a background saving in progress.
4338 We want to avoid race conditions, for instance our saving child may
4339 overwrite the synchronous saving did by SHUTDOWN. */
4340 if (server.bgsavechildpid != -1) {
4341 redisLog(REDIS_WARNING,"There is a live saving child. Killing it!");
4342 kill(server.bgsavechildpid,SIGKILL);
4343 rdbRemoveTempFile(server.bgsavechildpid);
4344 }
4345 if (server.appendonly) {
4346 /* Append only file: fsync() the AOF and exit */
4347 fsync(server.appendfd);
4348 if (server.vm_enabled) unlink(server.vm_swap_file);
4349 exit(0);
4350 } else {
4351 /* Snapshotting. Perform a SYNC SAVE and exit */
4352 if (rdbSave(server.dbfilename) == REDIS_OK) {
4353 if (server.daemonize)
4354 unlink(server.pidfile);
4355 redisLog(REDIS_WARNING,"%zu bytes used at exit",zmalloc_used_memory());
4356 redisLog(REDIS_WARNING,"Server exit now, bye bye...");
4357 if (server.vm_enabled) unlink(server.vm_swap_file);
4358 exit(0);
4359 } else {
4360 /* Ooops.. error saving! The best we can do is to continue
4361 * operating. Note that if there was a background saving process,
4362 * in the next cron() Redis will be notified that the background
4363 * saving aborted, handling special stuff like slaves pending for
4364 * synchronization... */
4365 redisLog(REDIS_WARNING,"Error trying to save the DB, can't exit");
4366 addReplySds(c,
4367 sdsnew("-ERR can't quit, problems saving the DB\r\n"));
4368 }
4369 }
4370 }
4371
4372 static void renameGenericCommand(redisClient *c, int nx) {
4373 robj *o;
4374
4375 /* To use the same key as src and dst is probably an error */
4376 if (sdscmp(c->argv[1]->ptr,c->argv[2]->ptr) == 0) {
4377 addReply(c,shared.sameobjecterr);
4378 return;
4379 }
4380
4381 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.nokeyerr)) == NULL)
4382 return;
4383
4384 incrRefCount(o);
4385 deleteIfVolatile(c->db,c->argv[2]);
4386 if (dictAdd(c->db->dict,c->argv[2],o) == DICT_ERR) {
4387 if (nx) {
4388 decrRefCount(o);
4389 addReply(c,shared.czero);
4390 return;
4391 }
4392 dictReplace(c->db->dict,c->argv[2],o);
4393 } else {
4394 incrRefCount(c->argv[2]);
4395 }
4396 deleteKey(c->db,c->argv[1]);
4397 server.dirty++;
4398 addReply(c,nx ? shared.cone : shared.ok);
4399 }
4400
4401 static void renameCommand(redisClient *c) {
4402 renameGenericCommand(c,0);
4403 }
4404
4405 static void renamenxCommand(redisClient *c) {
4406 renameGenericCommand(c,1);
4407 }
4408
4409 static void moveCommand(redisClient *c) {
4410 robj *o;
4411 redisDb *src, *dst;
4412 int srcid;
4413
4414 /* Obtain source and target DB pointers */
4415 src = c->db;
4416 srcid = c->db->id;
4417 if (selectDb(c,atoi(c->argv[2]->ptr)) == REDIS_ERR) {
4418 addReply(c,shared.outofrangeerr);
4419 return;
4420 }
4421 dst = c->db;
4422 selectDb(c,srcid); /* Back to the source DB */
4423
4424 /* If the user is moving using as target the same
4425 * DB as the source DB it is probably an error. */
4426 if (src == dst) {
4427 addReply(c,shared.sameobjecterr);
4428 return;
4429 }
4430
4431 /* Check if the element exists and get a reference */
4432 o = lookupKeyWrite(c->db,c->argv[1]);
4433 if (!o) {
4434 addReply(c,shared.czero);
4435 return;
4436 }
4437
4438 /* Try to add the element to the target DB */
4439 deleteIfVolatile(dst,c->argv[1]);
4440 if (dictAdd(dst->dict,c->argv[1],o) == DICT_ERR) {
4441 addReply(c,shared.czero);
4442 return;
4443 }
4444 incrRefCount(c->argv[1]);
4445 incrRefCount(o);
4446
4447 /* OK! key moved, free the entry in the source DB */
4448 deleteKey(src,c->argv[1]);
4449 server.dirty++;
4450 addReply(c,shared.cone);
4451 }
4452
4453 /* =================================== Lists ================================ */
4454 static void pushGenericCommand(redisClient *c, int where) {
4455 robj *lobj;
4456 list *list;
4457
4458 lobj = lookupKeyWrite(c->db,c->argv[1]);
4459 if (lobj == NULL) {
4460 if (handleClientsWaitingListPush(c,c->argv[1],c->argv[2])) {
4461 addReply(c,shared.cone);
4462 return;
4463 }
4464 lobj = createListObject();
4465 list = lobj->ptr;
4466 if (where == REDIS_HEAD) {
4467 listAddNodeHead(list,c->argv[2]);
4468 } else {
4469 listAddNodeTail(list,c->argv[2]);
4470 }
4471 dictAdd(c->db->dict,c->argv[1],lobj);
4472 incrRefCount(c->argv[1]);
4473 incrRefCount(c->argv[2]);
4474 } else {
4475 if (lobj->type != REDIS_LIST) {
4476 addReply(c,shared.wrongtypeerr);
4477 return;
4478 }
4479 if (handleClientsWaitingListPush(c,c->argv[1],c->argv[2])) {
4480 addReply(c,shared.cone);
4481 return;
4482 }
4483 list = lobj->ptr;
4484 if (where == REDIS_HEAD) {
4485 listAddNodeHead(list,c->argv[2]);
4486 } else {
4487 listAddNodeTail(list,c->argv[2]);
4488 }
4489 incrRefCount(c->argv[2]);
4490 }
4491 server.dirty++;
4492 addReplySds(c,sdscatprintf(sdsempty(),":%d\r\n",listLength(list)));
4493 }
4494
4495 static void lpushCommand(redisClient *c) {
4496 pushGenericCommand(c,REDIS_HEAD);
4497 }
4498
4499 static void rpushCommand(redisClient *c) {
4500 pushGenericCommand(c,REDIS_TAIL);
4501 }
4502
4503 static void llenCommand(redisClient *c) {
4504 robj *o;
4505 list *l;
4506
4507 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
4508 checkType(c,o,REDIS_LIST)) return;
4509
4510 l = o->ptr;
4511 addReplyUlong(c,listLength(l));
4512 }
4513
4514 static void lindexCommand(redisClient *c) {
4515 robj *o;
4516 int index = atoi(c->argv[2]->ptr);
4517 list *list;
4518 listNode *ln;
4519
4520 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4521 checkType(c,o,REDIS_LIST)) return;
4522 list = o->ptr;
4523
4524 ln = listIndex(list, index);
4525 if (ln == NULL) {
4526 addReply(c,shared.nullbulk);
4527 } else {
4528 robj *ele = listNodeValue(ln);
4529 addReplyBulk(c,ele);
4530 }
4531 }
4532
4533 static void lsetCommand(redisClient *c) {
4534 robj *o;
4535 int index = atoi(c->argv[2]->ptr);
4536 list *list;
4537 listNode *ln;
4538
4539 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.nokeyerr)) == NULL ||
4540 checkType(c,o,REDIS_LIST)) return;
4541 list = o->ptr;
4542
4543 ln = listIndex(list, index);
4544 if (ln == NULL) {
4545 addReply(c,shared.outofrangeerr);
4546 } else {
4547 robj *ele = listNodeValue(ln);
4548
4549 decrRefCount(ele);
4550 listNodeValue(ln) = c->argv[3];
4551 incrRefCount(c->argv[3]);
4552 addReply(c,shared.ok);
4553 server.dirty++;
4554 }
4555 }
4556
4557 static void popGenericCommand(redisClient *c, int where) {
4558 robj *o;
4559 list *list;
4560 listNode *ln;
4561
4562 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4563 checkType(c,o,REDIS_LIST)) return;
4564 list = o->ptr;
4565
4566 if (where == REDIS_HEAD)
4567 ln = listFirst(list);
4568 else
4569 ln = listLast(list);
4570
4571 if (ln == NULL) {
4572 addReply(c,shared.nullbulk);
4573 } else {
4574 robj *ele = listNodeValue(ln);
4575 addReplyBulk(c,ele);
4576 listDelNode(list,ln);
4577 if (listLength(list) == 0) deleteKey(c->db,c->argv[1]);
4578 server.dirty++;
4579 }
4580 }
4581
4582 static void lpopCommand(redisClient *c) {
4583 popGenericCommand(c,REDIS_HEAD);
4584 }
4585
4586 static void rpopCommand(redisClient *c) {
4587 popGenericCommand(c,REDIS_TAIL);
4588 }
4589
4590 static void lrangeCommand(redisClient *c) {
4591 robj *o;
4592 int start = atoi(c->argv[2]->ptr);
4593 int end = atoi(c->argv[3]->ptr);
4594 int llen;
4595 int rangelen, j;
4596 list *list;
4597 listNode *ln;
4598 robj *ele;
4599
4600 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.emptymultibulk)) == NULL
4601 || checkType(c,o,REDIS_LIST)) return;
4602 list = o->ptr;
4603 llen = listLength(list);
4604
4605 /* convert negative indexes */
4606 if (start < 0) start = llen+start;
4607 if (end < 0) end = llen+end;
4608 if (start < 0) start = 0;
4609 if (end < 0) end = 0;
4610
4611 /* indexes sanity checks */
4612 if (start > end || start >= llen) {
4613 /* Out of range start or start > end result in empty list */
4614 addReply(c,shared.emptymultibulk);
4615 return;
4616 }
4617 if (end >= llen) end = llen-1;
4618 rangelen = (end-start)+1;
4619
4620 /* Return the result in form of a multi-bulk reply */
4621 ln = listIndex(list, start);
4622 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",rangelen));
4623 for (j = 0; j < rangelen; j++) {
4624 ele = listNodeValue(ln);
4625 addReplyBulk(c,ele);
4626 ln = ln->next;
4627 }
4628 }
4629
4630 static void ltrimCommand(redisClient *c) {
4631 robj *o;
4632 int start = atoi(c->argv[2]->ptr);
4633 int end = atoi(c->argv[3]->ptr);
4634 int llen;
4635 int j, ltrim, rtrim;
4636 list *list;
4637 listNode *ln;
4638
4639 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.ok)) == NULL ||
4640 checkType(c,o,REDIS_LIST)) return;
4641 list = o->ptr;
4642 llen = listLength(list);
4643
4644 /* convert negative indexes */
4645 if (start < 0) start = llen+start;
4646 if (end < 0) end = llen+end;
4647 if (start < 0) start = 0;
4648 if (end < 0) end = 0;
4649
4650 /* indexes sanity checks */
4651 if (start > end || start >= llen) {
4652 /* Out of range start or start > end result in empty list */
4653 ltrim = llen;
4654 rtrim = 0;
4655 } else {
4656 if (end >= llen) end = llen-1;
4657 ltrim = start;
4658 rtrim = llen-end-1;
4659 }
4660
4661 /* Remove list elements to perform the trim */
4662 for (j = 0; j < ltrim; j++) {
4663 ln = listFirst(list);
4664 listDelNode(list,ln);
4665 }
4666 for (j = 0; j < rtrim; j++) {
4667 ln = listLast(list);
4668 listDelNode(list,ln);
4669 }
4670 if (listLength(list) == 0) deleteKey(c->db,c->argv[1]);
4671 server.dirty++;
4672 addReply(c,shared.ok);
4673 }
4674
4675 static void lremCommand(redisClient *c) {
4676 robj *o;
4677 list *list;
4678 listNode *ln, *next;
4679 int toremove = atoi(c->argv[2]->ptr);
4680 int removed = 0;
4681 int fromtail = 0;
4682
4683 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
4684 checkType(c,o,REDIS_LIST)) return;
4685 list = o->ptr;
4686
4687 if (toremove < 0) {
4688 toremove = -toremove;
4689 fromtail = 1;
4690 }
4691 ln = fromtail ? list->tail : list->head;
4692 while (ln) {
4693 robj *ele = listNodeValue(ln);
4694
4695 next = fromtail ? ln->prev : ln->next;
4696 if (compareStringObjects(ele,c->argv[3]) == 0) {
4697 listDelNode(list,ln);
4698 server.dirty++;
4699 removed++;
4700 if (toremove && removed == toremove) break;
4701 }
4702 ln = next;
4703 }
4704 if (listLength(list) == 0) deleteKey(c->db,c->argv[1]);
4705 addReplySds(c,sdscatprintf(sdsempty(),":%d\r\n",removed));
4706 }
4707
4708 /* This is the semantic of this command:
4709 * RPOPLPUSH srclist dstlist:
4710 * IF LLEN(srclist) > 0
4711 * element = RPOP srclist
4712 * LPUSH dstlist element
4713 * RETURN element
4714 * ELSE
4715 * RETURN nil
4716 * END
4717 * END
4718 *
4719 * The idea is to be able to get an element from a list in a reliable way
4720 * since the element is not just returned but pushed against another list
4721 * as well. This command was originally proposed by Ezra Zygmuntowicz.
4722 */
4723 static void rpoplpushcommand(redisClient *c) {
4724 robj *sobj;
4725 list *srclist;
4726 listNode *ln;
4727
4728 if ((sobj = lookupKeyWriteOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4729 checkType(c,sobj,REDIS_LIST)) return;
4730 srclist = sobj->ptr;
4731 ln = listLast(srclist);
4732
4733 if (ln == NULL) {
4734 addReply(c,shared.nullbulk);
4735 } else {
4736 robj *dobj = lookupKeyWrite(c->db,c->argv[2]);
4737 robj *ele = listNodeValue(ln);
4738 list *dstlist;
4739
4740 if (dobj && dobj->type != REDIS_LIST) {
4741 addReply(c,shared.wrongtypeerr);
4742 return;
4743 }
4744
4745 /* Add the element to the target list (unless it's directly
4746 * passed to some BLPOP-ing client */
4747 if (!handleClientsWaitingListPush(c,c->argv[2],ele)) {
4748 if (dobj == NULL) {
4749 /* Create the list if the key does not exist */
4750 dobj = createListObject();
4751 dictAdd(c->db->dict,c->argv[2],dobj);
4752 incrRefCount(c->argv[2]);
4753 }
4754 dstlist = dobj->ptr;
4755 listAddNodeHead(dstlist,ele);
4756 incrRefCount(ele);
4757 }
4758
4759 /* Send the element to the client as reply as well */
4760 addReplyBulk(c,ele);
4761
4762 /* Finally remove the element from the source list */
4763 listDelNode(srclist,ln);
4764 if (listLength(srclist) == 0) deleteKey(c->db,c->argv[1]);
4765 server.dirty++;
4766 }
4767 }
4768
4769 /* ==================================== Sets ================================ */
4770
4771 static void saddCommand(redisClient *c) {
4772 robj *set;
4773
4774 set = lookupKeyWrite(c->db,c->argv[1]);
4775 if (set == NULL) {
4776 set = createSetObject();
4777 dictAdd(c->db->dict,c->argv[1],set);
4778 incrRefCount(c->argv[1]);
4779 } else {
4780 if (set->type != REDIS_SET) {
4781 addReply(c,shared.wrongtypeerr);
4782 return;
4783 }
4784 }
4785 if (dictAdd(set->ptr,c->argv[2],NULL) == DICT_OK) {
4786 incrRefCount(c->argv[2]);
4787 server.dirty++;
4788 addReply(c,shared.cone);
4789 } else {
4790 addReply(c,shared.czero);
4791 }
4792 }
4793
4794 static void sremCommand(redisClient *c) {
4795 robj *set;
4796
4797 if ((set = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
4798 checkType(c,set,REDIS_SET)) return;
4799
4800 if (dictDelete(set->ptr,c->argv[2]) == DICT_OK) {
4801 server.dirty++;
4802 if (htNeedsResize(set->ptr)) dictResize(set->ptr);
4803 if (dictSize((dict*)set->ptr) == 0) deleteKey(c->db,c->argv[1]);
4804 addReply(c,shared.cone);
4805 } else {
4806 addReply(c,shared.czero);
4807 }
4808 }
4809
4810 static void smoveCommand(redisClient *c) {
4811 robj *srcset, *dstset;
4812
4813 srcset = lookupKeyWrite(c->db,c->argv[1]);
4814 dstset = lookupKeyWrite(c->db,c->argv[2]);
4815
4816 /* If the source key does not exist return 0, if it's of the wrong type
4817 * raise an error */
4818 if (srcset == NULL || srcset->type != REDIS_SET) {
4819 addReply(c, srcset ? shared.wrongtypeerr : shared.czero);
4820 return;
4821 }
4822 /* Error if the destination key is not a set as well */
4823 if (dstset && dstset->type != REDIS_SET) {
4824 addReply(c,shared.wrongtypeerr);
4825 return;
4826 }
4827 /* Remove the element from the source set */
4828 if (dictDelete(srcset->ptr,c->argv[3]) == DICT_ERR) {
4829 /* Key not found in the src set! return zero */
4830 addReply(c,shared.czero);
4831 return;
4832 }
4833 if (dictSize((dict*)srcset->ptr) == 0 && srcset != dstset)
4834 deleteKey(c->db,c->argv[1]);
4835 server.dirty++;
4836 /* Add the element to the destination set */
4837 if (!dstset) {
4838 dstset = createSetObject();
4839 dictAdd(c->db->dict,c->argv[2],dstset);
4840 incrRefCount(c->argv[2]);
4841 }
4842 if (dictAdd(dstset->ptr,c->argv[3],NULL) == DICT_OK)
4843 incrRefCount(c->argv[3]);
4844 addReply(c,shared.cone);
4845 }
4846
4847 static void sismemberCommand(redisClient *c) {
4848 robj *set;
4849
4850 if ((set = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
4851 checkType(c,set,REDIS_SET)) return;
4852
4853 if (dictFind(set->ptr,c->argv[2]))
4854 addReply(c,shared.cone);
4855 else
4856 addReply(c,shared.czero);
4857 }
4858
4859 static void scardCommand(redisClient *c) {
4860 robj *o;
4861 dict *s;
4862
4863 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
4864 checkType(c,o,REDIS_SET)) return;
4865
4866 s = o->ptr;
4867 addReplyUlong(c,dictSize(s));
4868 }
4869
4870 static void spopCommand(redisClient *c) {
4871 robj *set;
4872 dictEntry *de;
4873
4874 if ((set = lookupKeyWriteOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4875 checkType(c,set,REDIS_SET)) return;
4876
4877 de = dictGetRandomKey(set->ptr);
4878 if (de == NULL) {
4879 addReply(c,shared.nullbulk);
4880 } else {
4881 robj *ele = dictGetEntryKey(de);
4882
4883 addReplyBulk(c,ele);
4884 dictDelete(set->ptr,ele);
4885 if (htNeedsResize(set->ptr)) dictResize(set->ptr);
4886 if (dictSize((dict*)set->ptr) == 0) deleteKey(c->db,c->argv[1]);
4887 server.dirty++;
4888 }
4889 }
4890
4891 static void srandmemberCommand(redisClient *c) {
4892 robj *set;
4893 dictEntry *de;
4894
4895 if ((set = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
4896 checkType(c,set,REDIS_SET)) return;
4897
4898 de = dictGetRandomKey(set->ptr);
4899 if (de == NULL) {
4900 addReply(c,shared.nullbulk);
4901 } else {
4902 robj *ele = dictGetEntryKey(de);
4903
4904 addReplyBulk(c,ele);
4905 }
4906 }
4907
4908 static int qsortCompareSetsByCardinality(const void *s1, const void *s2) {
4909 dict **d1 = (void*) s1, **d2 = (void*) s2;
4910
4911 return dictSize(*d1)-dictSize(*d2);
4912 }
4913
4914 static void sinterGenericCommand(redisClient *c, robj **setskeys, unsigned long setsnum, robj *dstkey) {
4915 dict **dv = zmalloc(sizeof(dict*)*setsnum);
4916 dictIterator *di;
4917 dictEntry *de;
4918 robj *lenobj = NULL, *dstset = NULL;
4919 unsigned long j, cardinality = 0;
4920
4921 for (j = 0; j < setsnum; j++) {
4922 robj *setobj;
4923
4924 setobj = dstkey ?
4925 lookupKeyWrite(c->db,setskeys[j]) :
4926 lookupKeyRead(c->db,setskeys[j]);
4927 if (!setobj) {
4928 zfree(dv);
4929 if (dstkey) {
4930 if (deleteKey(c->db,dstkey))
4931 server.dirty++;
4932 addReply(c,shared.czero);
4933 } else {
4934 addReply(c,shared.emptymultibulk);
4935 }
4936 return;
4937 }
4938 if (setobj->type != REDIS_SET) {
4939 zfree(dv);
4940 addReply(c,shared.wrongtypeerr);
4941 return;
4942 }
4943 dv[j] = setobj->ptr;
4944 }
4945 /* Sort sets from the smallest to largest, this will improve our
4946 * algorithm's performace */
4947 qsort(dv,setsnum,sizeof(dict*),qsortCompareSetsByCardinality);
4948
4949 /* The first thing we should output is the total number of elements...
4950 * since this is a multi-bulk write, but at this stage we don't know
4951 * the intersection set size, so we use a trick, append an empty object
4952 * to the output list and save the pointer to later modify it with the
4953 * right length */
4954 if (!dstkey) {
4955 lenobj = createObject(REDIS_STRING,NULL);
4956 addReply(c,lenobj);
4957 decrRefCount(lenobj);
4958 } else {
4959 /* If we have a target key where to store the resulting set
4960 * create this key with an empty set inside */
4961 dstset = createSetObject();
4962 }
4963
4964 /* Iterate all the elements of the first (smallest) set, and test
4965 * the element against all the other sets, if at least one set does
4966 * not include the element it is discarded */
4967 di = dictGetIterator(dv[0]);
4968
4969 while((de = dictNext(di)) != NULL) {
4970 robj *ele;
4971
4972 for (j = 1; j < setsnum; j++)
4973 if (dictFind(dv[j],dictGetEntryKey(de)) == NULL) break;
4974 if (j != setsnum)
4975 continue; /* at least one set does not contain the member */
4976 ele = dictGetEntryKey(de);
4977 if (!dstkey) {
4978 addReplyBulk(c,ele);
4979 cardinality++;
4980 } else {
4981 dictAdd(dstset->ptr,ele,NULL);
4982 incrRefCount(ele);
4983 }
4984 }
4985 dictReleaseIterator(di);
4986
4987 if (dstkey) {
4988 /* Store the resulting set into the target, if the intersection
4989 * is not an empty set. */
4990 deleteKey(c->db,dstkey);
4991 if (dictSize((dict*)dstset->ptr) > 0) {
4992 dictAdd(c->db->dict,dstkey,dstset);
4993 incrRefCount(dstkey);
4994 addReplyLong(c,dictSize((dict*)dstset->ptr));
4995 } else {
4996 decrRefCount(dstset);
4997 addReply(c,shared.czero);
4998 }
4999 server.dirty++;
5000 } else {
5001 lenobj->ptr = sdscatprintf(sdsempty(),"*%lu\r\n",cardinality);
5002 }
5003 zfree(dv);
5004 }
5005
5006 static void sinterCommand(redisClient *c) {
5007 sinterGenericCommand(c,c->argv+1,c->argc-1,NULL);
5008 }
5009
5010 static void sinterstoreCommand(redisClient *c) {
5011 sinterGenericCommand(c,c->argv+2,c->argc-2,c->argv[1]);
5012 }
5013
5014 #define REDIS_OP_UNION 0
5015 #define REDIS_OP_DIFF 1
5016 #define REDIS_OP_INTER 2
5017
5018 static void sunionDiffGenericCommand(redisClient *c, robj **setskeys, int setsnum, robj *dstkey, int op) {
5019 dict **dv = zmalloc(sizeof(dict*)*setsnum);
5020 dictIterator *di;
5021 dictEntry *de;
5022 robj *dstset = NULL;
5023 int j, cardinality = 0;
5024
5025 for (j = 0; j < setsnum; j++) {
5026 robj *setobj;
5027
5028 setobj = dstkey ?
5029 lookupKeyWrite(c->db,setskeys[j]) :
5030 lookupKeyRead(c->db,setskeys[j]);
5031 if (!setobj) {
5032 dv[j] = NULL;
5033 continue;
5034 }
5035 if (setobj->type != REDIS_SET) {
5036 zfree(dv);
5037 addReply(c,shared.wrongtypeerr);
5038 return;
5039 }
5040 dv[j] = setobj->ptr;
5041 }
5042
5043 /* We need a temp set object to store our union. If the dstkey
5044 * is not NULL (that is, we are inside an SUNIONSTORE operation) then
5045 * this set object will be the resulting object to set into the target key*/
5046 dstset = createSetObject();
5047
5048 /* Iterate all the elements of all the sets, add every element a single
5049 * time to the result set */
5050 for (j = 0; j < setsnum; j++) {
5051 if (op == REDIS_OP_DIFF && j == 0 && !dv[j]) break; /* result set is empty */
5052 if (!dv[j]) continue; /* non existing keys are like empty sets */
5053
5054 di = dictGetIterator(dv[j]);
5055
5056 while((de = dictNext(di)) != NULL) {
5057 robj *ele;
5058
5059 /* dictAdd will not add the same element multiple times */
5060 ele = dictGetEntryKey(de);
5061 if (op == REDIS_OP_UNION || j == 0) {
5062 if (dictAdd(dstset->ptr,ele,NULL) == DICT_OK) {
5063 incrRefCount(ele);
5064 cardinality++;
5065 }
5066 } else if (op == REDIS_OP_DIFF) {
5067 if (dictDelete(dstset->ptr,ele) == DICT_OK) {
5068 cardinality--;
5069 }
5070 }
5071 }
5072 dictReleaseIterator(di);
5073
5074 /* result set is empty? Exit asap. */
5075 if (op == REDIS_OP_DIFF && cardinality == 0) break;
5076 }
5077
5078 /* Output the content of the resulting set, if not in STORE mode */
5079 if (!dstkey) {
5080 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",cardinality));
5081 di = dictGetIterator(dstset->ptr);
5082 while((de = dictNext(di)) != NULL) {
5083 robj *ele;
5084
5085 ele = dictGetEntryKey(de);
5086 addReplyBulk(c,ele);
5087 }
5088 dictReleaseIterator(di);
5089 decrRefCount(dstset);
5090 } else {
5091 /* If we have a target key where to store the resulting set
5092 * create this key with the result set inside */
5093 deleteKey(c->db,dstkey);
5094 if (dictSize((dict*)dstset->ptr) > 0) {
5095 dictAdd(c->db->dict,dstkey,dstset);
5096 incrRefCount(dstkey);
5097 addReplyLong(c,dictSize((dict*)dstset->ptr));
5098 } else {
5099 decrRefCount(dstset);
5100 addReply(c,shared.czero);
5101 }
5102 server.dirty++;
5103 }
5104 zfree(dv);
5105 }
5106
5107 static void sunionCommand(redisClient *c) {
5108 sunionDiffGenericCommand(c,c->argv+1,c->argc-1,NULL,REDIS_OP_UNION);
5109 }
5110
5111 static void sunionstoreCommand(redisClient *c) {
5112 sunionDiffGenericCommand(c,c->argv+2,c->argc-2,c->argv[1],REDIS_OP_UNION);
5113 }
5114
5115 static void sdiffCommand(redisClient *c) {
5116 sunionDiffGenericCommand(c,c->argv+1,c->argc-1,NULL,REDIS_OP_DIFF);
5117 }
5118
5119 static void sdiffstoreCommand(redisClient *c) {
5120 sunionDiffGenericCommand(c,c->argv+2,c->argc-2,c->argv[1],REDIS_OP_DIFF);
5121 }
5122
5123 /* ==================================== ZSets =============================== */
5124
5125 /* ZSETs are ordered sets using two data structures to hold the same elements
5126 * in order to get O(log(N)) INSERT and REMOVE operations into a sorted
5127 * data structure.
5128 *
5129 * The elements are added to an hash table mapping Redis objects to scores.
5130 * At the same time the elements are added to a skip list mapping scores
5131 * to Redis objects (so objects are sorted by scores in this "view"). */
5132
5133 /* This skiplist implementation is almost a C translation of the original
5134 * algorithm described by William Pugh in "Skip Lists: A Probabilistic
5135 * Alternative to Balanced Trees", modified in three ways:
5136 * a) this implementation allows for repeated values.
5137 * b) the comparison is not just by key (our 'score') but by satellite data.
5138 * c) there is a back pointer, so it's a doubly linked list with the back
5139 * pointers being only at "level 1". This allows to traverse the list
5140 * from tail to head, useful for ZREVRANGE. */
5141
5142 static zskiplistNode *zslCreateNode(int level, double score, robj *obj) {
5143 zskiplistNode *zn = zmalloc(sizeof(*zn));
5144
5145 zn->forward = zmalloc(sizeof(zskiplistNode*) * level);
5146 if (level > 0)
5147 zn->span = zmalloc(sizeof(unsigned int) * (level - 1));
5148 zn->score = score;
5149 zn->obj = obj;
5150 return zn;
5151 }
5152
5153 static zskiplist *zslCreate(void) {
5154 int j;
5155 zskiplist *zsl;
5156
5157 zsl = zmalloc(sizeof(*zsl));
5158 zsl->level = 1;
5159 zsl->length = 0;
5160 zsl->header = zslCreateNode(ZSKIPLIST_MAXLEVEL,0,NULL);
5161 for (j = 0; j < ZSKIPLIST_MAXLEVEL; j++) {
5162 zsl->header->forward[j] = NULL;
5163
5164 /* span has space for ZSKIPLIST_MAXLEVEL-1 elements */
5165 if (j < ZSKIPLIST_MAXLEVEL-1)
5166 zsl->header->span[j] = 0;
5167 }
5168 zsl->header->backward = NULL;
5169 zsl->tail = NULL;
5170 return zsl;
5171 }
5172
5173 static void zslFreeNode(zskiplistNode *node) {
5174 decrRefCount(node->obj);
5175 zfree(node->forward);
5176 zfree(node->span);
5177 zfree(node);
5178 }
5179
5180 static void zslFree(zskiplist *zsl) {
5181 zskiplistNode *node = zsl->header->forward[0], *next;
5182
5183 zfree(zsl->header->forward);
5184 zfree(zsl->header->span);
5185 zfree(zsl->header);
5186 while(node) {
5187 next = node->forward[0];
5188 zslFreeNode(node);
5189 node = next;
5190 }
5191 zfree(zsl);
5192 }
5193
5194 static int zslRandomLevel(void) {
5195 int level = 1;
5196 while ((random()&0xFFFF) < (ZSKIPLIST_P * 0xFFFF))
5197 level += 1;
5198 return (level<ZSKIPLIST_MAXLEVEL) ? level : ZSKIPLIST_MAXLEVEL;
5199 }
5200
5201 static void zslInsert(zskiplist *zsl, double score, robj *obj) {
5202 zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x;
5203 unsigned int rank[ZSKIPLIST_MAXLEVEL];
5204 int i, level;
5205
5206 x = zsl->header;
5207 for (i = zsl->level-1; i >= 0; i--) {
5208 /* store rank that is crossed to reach the insert position */
5209 rank[i] = i == (zsl->level-1) ? 0 : rank[i+1];
5210
5211 while (x->forward[i] &&
5212 (x->forward[i]->score < score ||
5213 (x->forward[i]->score == score &&
5214 compareStringObjects(x->forward[i]->obj,obj) < 0))) {
5215 rank[i] += i > 0 ? x->span[i-1] : 1;
5216 x = x->forward[i];
5217 }
5218 update[i] = x;
5219 }
5220 /* we assume the key is not already inside, since we allow duplicated
5221 * scores, and the re-insertion of score and redis object should never
5222 * happpen since the caller of zslInsert() should test in the hash table
5223 * if the element is already inside or not. */
5224 level = zslRandomLevel();
5225 if (level > zsl->level) {
5226 for (i = zsl->level; i < level; i++) {
5227 rank[i] = 0;
5228 update[i] = zsl->header;
5229 update[i]->span[i-1] = zsl->length;
5230 }
5231 zsl->level = level;
5232 }
5233 x = zslCreateNode(level,score,obj);
5234 for (i = 0; i < level; i++) {
5235 x->forward[i] = update[i]->forward[i];
5236 update[i]->forward[i] = x;
5237
5238 /* update span covered by update[i] as x is inserted here */
5239 if (i > 0) {
5240 x->span[i-1] = update[i]->span[i-1] - (rank[0] - rank[i]);
5241 update[i]->span[i-1] = (rank[0] - rank[i]) + 1;
5242 }
5243 }
5244
5245 /* increment span for untouched levels */
5246 for (i = level; i < zsl->level; i++) {
5247 update[i]->span[i-1]++;
5248 }
5249
5250 x->backward = (update[0] == zsl->header) ? NULL : update[0];
5251 if (x->forward[0])
5252 x->forward[0]->backward = x;
5253 else
5254 zsl->tail = x;
5255 zsl->length++;
5256 }
5257
5258 /* Internal function used by zslDelete, zslDeleteByScore and zslDeleteByRank */
5259 void zslDeleteNode(zskiplist *zsl, zskiplistNode *x, zskiplistNode **update) {
5260 int i;
5261 for (i = 0; i < zsl->level; i++) {
5262 if (update[i]->forward[i] == x) {
5263 if (i > 0) {
5264 update[i]->span[i-1] += x->span[i-1] - 1;
5265 }
5266 update[i]->forward[i] = x->forward[i];
5267 } else {
5268 /* invariant: i > 0, because update[0]->forward[0]
5269 * is always equal to x */
5270 update[i]->span[i-1] -= 1;
5271 }
5272 }
5273 if (x->forward[0]) {
5274 x->forward[0]->backward = x->backward;
5275 } else {
5276 zsl->tail = x->backward;
5277 }
5278 while(zsl->level > 1 && zsl->header->forward[zsl->level-1] == NULL)
5279 zsl->level--;
5280 zsl->length--;
5281 }
5282
5283 /* Delete an element with matching score/object from the skiplist. */
5284 static int zslDelete(zskiplist *zsl, double score, robj *obj) {
5285 zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x;
5286 int i;
5287
5288 x = zsl->header;
5289 for (i = zsl->level-1; i >= 0; i--) {
5290 while (x->forward[i] &&
5291 (x->forward[i]->score < score ||
5292 (x->forward[i]->score == score &&
5293 compareStringObjects(x->forward[i]->obj,obj) < 0)))
5294 x = x->forward[i];
5295 update[i] = x;
5296 }
5297 /* We may have multiple elements with the same score, what we need
5298 * is to find the element with both the right score and object. */
5299 x = x->forward[0];
5300 if (x && score == x->score && compareStringObjects(x->obj,obj) == 0) {
5301 zslDeleteNode(zsl, x, update);
5302 zslFreeNode(x);
5303 return 1;
5304 } else {
5305 return 0; /* not found */
5306 }
5307 return 0; /* not found */
5308 }
5309
5310 /* Delete all the elements with score between min and max from the skiplist.
5311 * Min and mx are inclusive, so a score >= min || score <= max is deleted.
5312 * Note that this function takes the reference to the hash table view of the
5313 * sorted set, in order to remove the elements from the hash table too. */
5314 static unsigned long zslDeleteRangeByScore(zskiplist *zsl, double min, double max, dict *dict) {
5315 zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x;
5316 unsigned long removed = 0;
5317 int i;
5318
5319 x = zsl->header;
5320 for (i = zsl->level-1; i >= 0; i--) {
5321 while (x->forward[i] && x->forward[i]->score < min)
5322 x = x->forward[i];
5323 update[i] = x;
5324 }
5325 /* We may have multiple elements with the same score, what we need
5326 * is to find the element with both the right score and object. */
5327 x = x->forward[0];
5328 while (x && x->score <= max) {
5329 zskiplistNode *next = x->forward[0];
5330 zslDeleteNode(zsl, x, update);
5331 dictDelete(dict,x->obj);
5332 zslFreeNode(x);
5333 removed++;
5334 x = next;
5335 }
5336 return removed; /* not found */
5337 }
5338
5339 /* Delete all the elements with rank between start and end from the skiplist.
5340 * Start and end are inclusive. Note that start and end need to be 1-based */
5341 static unsigned long zslDeleteRangeByRank(zskiplist *zsl, unsigned int start, unsigned int end, dict *dict) {
5342 zskiplistNode *update[ZSKIPLIST_MAXLEVEL], *x;
5343 unsigned long traversed = 0, removed = 0;
5344 int i;
5345
5346 x = zsl->header;
5347 for (i = zsl->level-1; i >= 0; i--) {
5348 while (x->forward[i] && (traversed + (i > 0 ? x->span[i-1] : 1)) < start) {
5349 traversed += i > 0 ? x->span[i-1] : 1;
5350 x = x->forward[i];
5351 }
5352 update[i] = x;
5353 }
5354
5355 traversed++;
5356 x = x->forward[0];
5357 while (x && traversed <= end) {
5358 zskiplistNode *next = x->forward[0];
5359 zslDeleteNode(zsl, x, update);
5360 dictDelete(dict,x->obj);
5361 zslFreeNode(x);
5362 removed++;
5363 traversed++;
5364 x = next;
5365 }
5366 return removed;
5367 }
5368
5369 /* Find the first node having a score equal or greater than the specified one.
5370 * Returns NULL if there is no match. */
5371 static zskiplistNode *zslFirstWithScore(zskiplist *zsl, double score) {
5372 zskiplistNode *x;
5373 int i;
5374
5375 x = zsl->header;
5376 for (i = zsl->level-1; i >= 0; i--) {
5377 while (x->forward[i] && x->forward[i]->score < score)
5378 x = x->forward[i];
5379 }
5380 /* We may have multiple elements with the same score, what we need
5381 * is to find the element with both the right score and object. */
5382 return x->forward[0];
5383 }
5384
5385 /* Find the rank for an element by both score and key.
5386 * Returns 0 when the element cannot be found, rank otherwise.
5387 * Note that the rank is 1-based due to the span of zsl->header to the
5388 * first element. */
5389 static unsigned long zslGetRank(zskiplist *zsl, double score, robj *o) {
5390 zskiplistNode *x;
5391 unsigned long rank = 0;
5392 int i;
5393
5394 x = zsl->header;
5395 for (i = zsl->level-1; i >= 0; i--) {
5396 while (x->forward[i] &&
5397 (x->forward[i]->score < score ||
5398 (x->forward[i]->score == score &&
5399 compareStringObjects(x->forward[i]->obj,o) <= 0))) {
5400 rank += i > 0 ? x->span[i-1] : 1;
5401 x = x->forward[i];
5402 }
5403
5404 /* x might be equal to zsl->header, so test if obj is non-NULL */
5405 if (x->obj && compareStringObjects(x->obj,o) == 0) {
5406 return rank;
5407 }
5408 }
5409 return 0;
5410 }
5411
5412 /* Finds an element by its rank. The rank argument needs to be 1-based. */
5413 zskiplistNode* zslGetElementByRank(zskiplist *zsl, unsigned long rank) {
5414 zskiplistNode *x;
5415 unsigned long traversed = 0;
5416 int i;
5417
5418 x = zsl->header;
5419 for (i = zsl->level-1; i >= 0; i--) {
5420 while (x->forward[i] && (traversed + (i>0 ? x->span[i-1] : 1)) <= rank)
5421 {
5422 traversed += i > 0 ? x->span[i-1] : 1;
5423 x = x->forward[i];
5424 }
5425 if (traversed == rank) {
5426 return x;
5427 }
5428 }
5429 return NULL;
5430 }
5431
5432 /* The actual Z-commands implementations */
5433
5434 /* This generic command implements both ZADD and ZINCRBY.
5435 * scoreval is the score if the operation is a ZADD (doincrement == 0) or
5436 * the increment if the operation is a ZINCRBY (doincrement == 1). */
5437 static void zaddGenericCommand(redisClient *c, robj *key, robj *ele, double scoreval, int doincrement) {
5438 robj *zsetobj;
5439 zset *zs;
5440 double *score;
5441
5442 zsetobj = lookupKeyWrite(c->db,key);
5443 if (zsetobj == NULL) {
5444 zsetobj = createZsetObject();
5445 dictAdd(c->db->dict,key,zsetobj);
5446 incrRefCount(key);
5447 } else {
5448 if (zsetobj->type != REDIS_ZSET) {
5449 addReply(c,shared.wrongtypeerr);
5450 return;
5451 }
5452 }
5453 zs = zsetobj->ptr;
5454
5455 /* Ok now since we implement both ZADD and ZINCRBY here the code
5456 * needs to handle the two different conditions. It's all about setting
5457 * '*score', that is, the new score to set, to the right value. */
5458 score = zmalloc(sizeof(double));
5459 if (doincrement) {
5460 dictEntry *de;
5461
5462 /* Read the old score. If the element was not present starts from 0 */
5463 de = dictFind(zs->dict,ele);
5464 if (de) {
5465 double *oldscore = dictGetEntryVal(de);
5466 *score = *oldscore + scoreval;
5467 } else {
5468 *score = scoreval;
5469 }
5470 } else {
5471 *score = scoreval;
5472 }
5473
5474 /* What follows is a simple remove and re-insert operation that is common
5475 * to both ZADD and ZINCRBY... */
5476 if (dictAdd(zs->dict,ele,score) == DICT_OK) {
5477 /* case 1: New element */
5478 incrRefCount(ele); /* added to hash */
5479 zslInsert(zs->zsl,*score,ele);
5480 incrRefCount(ele); /* added to skiplist */
5481 server.dirty++;
5482 if (doincrement)
5483 addReplyDouble(c,*score);
5484 else
5485 addReply(c,shared.cone);
5486 } else {
5487 dictEntry *de;
5488 double *oldscore;
5489
5490 /* case 2: Score update operation */
5491 de = dictFind(zs->dict,ele);
5492 redisAssert(de != NULL);
5493 oldscore = dictGetEntryVal(de);
5494 if (*score != *oldscore) {
5495 int deleted;
5496
5497 /* Remove and insert the element in the skip list with new score */
5498 deleted = zslDelete(zs->zsl,*oldscore,ele);
5499 redisAssert(deleted != 0);
5500 zslInsert(zs->zsl,*score,ele);
5501 incrRefCount(ele);
5502 /* Update the score in the hash table */
5503 dictReplace(zs->dict,ele,score);
5504 server.dirty++;
5505 } else {
5506 zfree(score);
5507 }
5508 if (doincrement)
5509 addReplyDouble(c,*score);
5510 else
5511 addReply(c,shared.czero);
5512 }
5513 }
5514
5515 static void zaddCommand(redisClient *c) {
5516 double scoreval;
5517
5518 if (getDoubleFromObjectOrReply(c, c->argv[2], &scoreval, NULL) != REDIS_OK) return;
5519 zaddGenericCommand(c,c->argv[1],c->argv[3],scoreval,0);
5520 }
5521
5522 static void zincrbyCommand(redisClient *c) {
5523 double scoreval;
5524
5525 if (getDoubleFromObjectOrReply(c, c->argv[2], &scoreval, NULL) != REDIS_OK) return;
5526 zaddGenericCommand(c,c->argv[1],c->argv[3],scoreval,1);
5527 }
5528
5529 static void zremCommand(redisClient *c) {
5530 robj *zsetobj;
5531 zset *zs;
5532 dictEntry *de;
5533 double *oldscore;
5534 int deleted;
5535
5536 if ((zsetobj = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
5537 checkType(c,zsetobj,REDIS_ZSET)) return;
5538
5539 zs = zsetobj->ptr;
5540 de = dictFind(zs->dict,c->argv[2]);
5541 if (de == NULL) {
5542 addReply(c,shared.czero);
5543 return;
5544 }
5545 /* Delete from the skiplist */
5546 oldscore = dictGetEntryVal(de);
5547 deleted = zslDelete(zs->zsl,*oldscore,c->argv[2]);
5548 redisAssert(deleted != 0);
5549
5550 /* Delete from the hash table */
5551 dictDelete(zs->dict,c->argv[2]);
5552 if (htNeedsResize(zs->dict)) dictResize(zs->dict);
5553 if (dictSize(zs->dict) == 0) deleteKey(c->db,c->argv[1]);
5554 server.dirty++;
5555 addReply(c,shared.cone);
5556 }
5557
5558 static void zremrangebyscoreCommand(redisClient *c) {
5559 double min;
5560 double max;
5561 long deleted;
5562 robj *zsetobj;
5563 zset *zs;
5564
5565 if ((getDoubleFromObjectOrReply(c, c->argv[2], &min, NULL) != REDIS_OK) ||
5566 (getDoubleFromObjectOrReply(c, c->argv[3], &max, NULL) != REDIS_OK)) return;
5567
5568 if ((zsetobj = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
5569 checkType(c,zsetobj,REDIS_ZSET)) return;
5570
5571 zs = zsetobj->ptr;
5572 deleted = zslDeleteRangeByScore(zs->zsl,min,max,zs->dict);
5573 if (htNeedsResize(zs->dict)) dictResize(zs->dict);
5574 if (dictSize(zs->dict) == 0) deleteKey(c->db,c->argv[1]);
5575 server.dirty += deleted;
5576 addReplyLong(c,deleted);
5577 }
5578
5579 static void zremrangebyrankCommand(redisClient *c) {
5580 long start;
5581 long end;
5582 int llen;
5583 long deleted;
5584 robj *zsetobj;
5585 zset *zs;
5586
5587 if ((getLongFromObjectOrReply(c, c->argv[2], &start, NULL) != REDIS_OK) ||
5588 (getLongFromObjectOrReply(c, c->argv[3], &end, NULL) != REDIS_OK)) return;
5589
5590 if ((zsetobj = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
5591 checkType(c,zsetobj,REDIS_ZSET)) return;
5592 zs = zsetobj->ptr;
5593 llen = zs->zsl->length;
5594
5595 /* convert negative indexes */
5596 if (start < 0) start = llen+start;
5597 if (end < 0) end = llen+end;
5598 if (start < 0) start = 0;
5599 if (end < 0) end = 0;
5600
5601 /* indexes sanity checks */
5602 if (start > end || start >= llen) {
5603 addReply(c,shared.czero);
5604 return;
5605 }
5606 if (end >= llen) end = llen-1;
5607
5608 /* increment start and end because zsl*Rank functions
5609 * use 1-based rank */
5610 deleted = zslDeleteRangeByRank(zs->zsl,start+1,end+1,zs->dict);
5611 if (htNeedsResize(zs->dict)) dictResize(zs->dict);
5612 if (dictSize(zs->dict) == 0) deleteKey(c->db,c->argv[1]);
5613 server.dirty += deleted;
5614 addReplyLong(c, deleted);
5615 }
5616
5617 typedef struct {
5618 dict *dict;
5619 double weight;
5620 } zsetopsrc;
5621
5622 static int qsortCompareZsetopsrcByCardinality(const void *s1, const void *s2) {
5623 zsetopsrc *d1 = (void*) s1, *d2 = (void*) s2;
5624 unsigned long size1, size2;
5625 size1 = d1->dict ? dictSize(d1->dict) : 0;
5626 size2 = d2->dict ? dictSize(d2->dict) : 0;
5627 return size1 - size2;
5628 }
5629
5630 #define REDIS_AGGR_SUM 1
5631 #define REDIS_AGGR_MIN 2
5632 #define REDIS_AGGR_MAX 3
5633
5634 inline static void zunionInterAggregate(double *target, double val, int aggregate) {
5635 if (aggregate == REDIS_AGGR_SUM) {
5636 *target = *target + val;
5637 } else if (aggregate == REDIS_AGGR_MIN) {
5638 *target = val < *target ? val : *target;
5639 } else if (aggregate == REDIS_AGGR_MAX) {
5640 *target = val > *target ? val : *target;
5641 } else {
5642 /* safety net */
5643 redisPanic("Unknown ZUNION/INTER aggregate type");
5644 }
5645 }
5646
5647 static void zunionInterGenericCommand(redisClient *c, robj *dstkey, int op) {
5648 int i, j, zsetnum;
5649 int aggregate = REDIS_AGGR_SUM;
5650 zsetopsrc *src;
5651 robj *dstobj;
5652 zset *dstzset;
5653 dictIterator *di;
5654 dictEntry *de;
5655
5656 /* expect zsetnum input keys to be given */
5657 zsetnum = atoi(c->argv[2]->ptr);
5658 if (zsetnum < 1) {
5659 addReplySds(c,sdsnew("-ERR at least 1 input key is needed for ZUNION/ZINTER\r\n"));
5660 return;
5661 }
5662
5663 /* test if the expected number of keys would overflow */
5664 if (3+zsetnum > c->argc) {
5665 addReply(c,shared.syntaxerr);
5666 return;
5667 }
5668
5669 /* read keys to be used for input */
5670 src = zmalloc(sizeof(zsetopsrc) * zsetnum);
5671 for (i = 0, j = 3; i < zsetnum; i++, j++) {
5672 robj *zsetobj = lookupKeyWrite(c->db,c->argv[j]);
5673 if (!zsetobj) {
5674 src[i].dict = NULL;
5675 } else {
5676 if (zsetobj->type != REDIS_ZSET) {
5677 zfree(src);
5678 addReply(c,shared.wrongtypeerr);
5679 return;
5680 }
5681 src[i].dict = ((zset*)zsetobj->ptr)->dict;
5682 }
5683
5684 /* default all weights to 1 */
5685 src[i].weight = 1.0;
5686 }
5687
5688 /* parse optional extra arguments */
5689 if (j < c->argc) {
5690 int remaining = c->argc - j;
5691
5692 while (remaining) {
5693 if (remaining >= (zsetnum + 1) && !strcasecmp(c->argv[j]->ptr,"weights")) {
5694 j++; remaining--;
5695 for (i = 0; i < zsetnum; i++, j++, remaining--) {
5696 if (getDoubleFromObjectOrReply(c, c->argv[j], &src[i].weight, NULL) != REDIS_OK)
5697 return;
5698 }
5699 } else if (remaining >= 2 && !strcasecmp(c->argv[j]->ptr,"aggregate")) {
5700 j++; remaining--;
5701 if (!strcasecmp(c->argv[j]->ptr,"sum")) {
5702 aggregate = REDIS_AGGR_SUM;
5703 } else if (!strcasecmp(c->argv[j]->ptr,"min")) {
5704 aggregate = REDIS_AGGR_MIN;
5705 } else if (!strcasecmp(c->argv[j]->ptr,"max")) {
5706 aggregate = REDIS_AGGR_MAX;
5707 } else {
5708 zfree(src);
5709 addReply(c,shared.syntaxerr);
5710 return;
5711 }
5712 j++; remaining--;
5713 } else {
5714 zfree(src);
5715 addReply(c,shared.syntaxerr);
5716 return;
5717 }
5718 }
5719 }
5720
5721 /* sort sets from the smallest to largest, this will improve our
5722 * algorithm's performance */
5723 qsort(src,zsetnum,sizeof(zsetopsrc), qsortCompareZsetopsrcByCardinality);
5724
5725 dstobj = createZsetObject();
5726 dstzset = dstobj->ptr;
5727
5728 if (op == REDIS_OP_INTER) {
5729 /* skip going over all entries if the smallest zset is NULL or empty */
5730 if (src[0].dict && dictSize(src[0].dict) > 0) {
5731 /* precondition: as src[0].dict is non-empty and the zsets are ordered
5732 * from small to large, all src[i > 0].dict are non-empty too */
5733 di = dictGetIterator(src[0].dict);
5734 while((de = dictNext(di)) != NULL) {
5735 double *score = zmalloc(sizeof(double)), value;
5736 *score = src[0].weight * (*(double*)dictGetEntryVal(de));
5737
5738 for (j = 1; j < zsetnum; j++) {
5739 dictEntry *other = dictFind(src[j].dict,dictGetEntryKey(de));
5740 if (other) {
5741 value = src[j].weight * (*(double*)dictGetEntryVal(other));
5742 zunionInterAggregate(score, value, aggregate);
5743 } else {
5744 break;
5745 }
5746 }
5747
5748 /* skip entry when not present in every source dict */
5749 if (j != zsetnum) {
5750 zfree(score);
5751 } else {
5752 robj *o = dictGetEntryKey(de);
5753 dictAdd(dstzset->dict,o,score);
5754 incrRefCount(o); /* added to dictionary */
5755 zslInsert(dstzset->zsl,*score,o);
5756 incrRefCount(o); /* added to skiplist */
5757 }
5758 }
5759 dictReleaseIterator(di);
5760 }
5761 } else if (op == REDIS_OP_UNION) {
5762 for (i = 0; i < zsetnum; i++) {
5763 if (!src[i].dict) continue;
5764
5765 di = dictGetIterator(src[i].dict);
5766 while((de = dictNext(di)) != NULL) {
5767 /* skip key when already processed */
5768 if (dictFind(dstzset->dict,dictGetEntryKey(de)) != NULL) continue;
5769
5770 double *score = zmalloc(sizeof(double)), value;
5771 *score = src[i].weight * (*(double*)dictGetEntryVal(de));
5772
5773 /* because the zsets are sorted by size, its only possible
5774 * for sets at larger indices to hold this entry */
5775 for (j = (i+1); j < zsetnum; j++) {
5776 dictEntry *other = dictFind(src[j].dict,dictGetEntryKey(de));
5777 if (other) {
5778 value = src[j].weight * (*(double*)dictGetEntryVal(other));
5779 zunionInterAggregate(score, value, aggregate);
5780 }
5781 }
5782
5783 robj *o = dictGetEntryKey(de);
5784 dictAdd(dstzset->dict,o,score);
5785 incrRefCount(o); /* added to dictionary */
5786 zslInsert(dstzset->zsl,*score,o);
5787 incrRefCount(o); /* added to skiplist */
5788 }
5789 dictReleaseIterator(di);
5790 }
5791 } else {
5792 /* unknown operator */
5793 redisAssert(op == REDIS_OP_INTER || op == REDIS_OP_UNION);
5794 }
5795
5796 deleteKey(c->db,dstkey);
5797 if (dstzset->zsl->length) {
5798 dictAdd(c->db->dict,dstkey,dstobj);
5799 incrRefCount(dstkey);
5800 addReplyLong(c, dstzset->zsl->length);
5801 server.dirty++;
5802 } else {
5803 decrRefCount(dstobj);
5804 addReply(c, shared.czero);
5805 }
5806 zfree(src);
5807 }
5808
5809 static void zunionCommand(redisClient *c) {
5810 zunionInterGenericCommand(c,c->argv[1], REDIS_OP_UNION);
5811 }
5812
5813 static void zinterCommand(redisClient *c) {
5814 zunionInterGenericCommand(c,c->argv[1], REDIS_OP_INTER);
5815 }
5816
5817 static void zrangeGenericCommand(redisClient *c, int reverse) {
5818 robj *o;
5819 long start;
5820 long end;
5821 int withscores = 0;
5822 int llen;
5823 int rangelen, j;
5824 zset *zsetobj;
5825 zskiplist *zsl;
5826 zskiplistNode *ln;
5827 robj *ele;
5828
5829 if ((getLongFromObjectOrReply(c, c->argv[2], &start, NULL) != REDIS_OK) ||
5830 (getLongFromObjectOrReply(c, c->argv[3], &end, NULL) != REDIS_OK)) return;
5831
5832 if (c->argc == 5 && !strcasecmp(c->argv[4]->ptr,"withscores")) {
5833 withscores = 1;
5834 } else if (c->argc >= 5) {
5835 addReply(c,shared.syntaxerr);
5836 return;
5837 }
5838
5839 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.emptymultibulk)) == NULL
5840 || checkType(c,o,REDIS_ZSET)) return;
5841 zsetobj = o->ptr;
5842 zsl = zsetobj->zsl;
5843 llen = zsl->length;
5844
5845 /* convert negative indexes */
5846 if (start < 0) start = llen+start;
5847 if (end < 0) end = llen+end;
5848 if (start < 0) start = 0;
5849 if (end < 0) end = 0;
5850
5851 /* indexes sanity checks */
5852 if (start > end || start >= llen) {
5853 /* Out of range start or start > end result in empty list */
5854 addReply(c,shared.emptymultibulk);
5855 return;
5856 }
5857 if (end >= llen) end = llen-1;
5858 rangelen = (end-start)+1;
5859
5860 /* check if starting point is trivial, before searching
5861 * the element in log(N) time */
5862 if (reverse) {
5863 ln = start == 0 ? zsl->tail : zslGetElementByRank(zsl, llen-start);
5864 } else {
5865 ln = start == 0 ?
5866 zsl->header->forward[0] : zslGetElementByRank(zsl, start+1);
5867 }
5868
5869 /* Return the result in form of a multi-bulk reply */
5870 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",
5871 withscores ? (rangelen*2) : rangelen));
5872 for (j = 0; j < rangelen; j++) {
5873 ele = ln->obj;
5874 addReplyBulk(c,ele);
5875 if (withscores)
5876 addReplyDouble(c,ln->score);
5877 ln = reverse ? ln->backward : ln->forward[0];
5878 }
5879 }
5880
5881 static void zrangeCommand(redisClient *c) {
5882 zrangeGenericCommand(c,0);
5883 }
5884
5885 static void zrevrangeCommand(redisClient *c) {
5886 zrangeGenericCommand(c,1);
5887 }
5888
5889 /* This command implements both ZRANGEBYSCORE and ZCOUNT.
5890 * If justcount is non-zero, just the count is returned. */
5891 static void genericZrangebyscoreCommand(redisClient *c, int justcount) {
5892 robj *o;
5893 double min, max;
5894 int minex = 0, maxex = 0; /* are min or max exclusive? */
5895 int offset = 0, limit = -1;
5896 int withscores = 0;
5897 int badsyntax = 0;
5898
5899 /* Parse the min-max interval. If one of the values is prefixed
5900 * by the "(" character, it's considered "open". For instance
5901 * ZRANGEBYSCORE zset (1.5 (2.5 will match min < x < max
5902 * ZRANGEBYSCORE zset 1.5 2.5 will instead match min <= x <= max */
5903 if (((char*)c->argv[2]->ptr)[0] == '(') {
5904 min = strtod((char*)c->argv[2]->ptr+1,NULL);
5905 minex = 1;
5906 } else {
5907 min = strtod(c->argv[2]->ptr,NULL);
5908 }
5909 if (((char*)c->argv[3]->ptr)[0] == '(') {
5910 max = strtod((char*)c->argv[3]->ptr+1,NULL);
5911 maxex = 1;
5912 } else {
5913 max = strtod(c->argv[3]->ptr,NULL);
5914 }
5915
5916 /* Parse "WITHSCORES": note that if the command was called with
5917 * the name ZCOUNT then we are sure that c->argc == 4, so we'll never
5918 * enter the following paths to parse WITHSCORES and LIMIT. */
5919 if (c->argc == 5 || c->argc == 8) {
5920 if (strcasecmp(c->argv[c->argc-1]->ptr,"withscores") == 0)
5921 withscores = 1;
5922 else
5923 badsyntax = 1;
5924 }
5925 if (c->argc != (4 + withscores) && c->argc != (7 + withscores))
5926 badsyntax = 1;
5927 if (badsyntax) {
5928 addReplySds(c,
5929 sdsnew("-ERR wrong number of arguments for ZRANGEBYSCORE\r\n"));
5930 return;
5931 }
5932
5933 /* Parse "LIMIT" */
5934 if (c->argc == (7 + withscores) && strcasecmp(c->argv[4]->ptr,"limit")) {
5935 addReply(c,shared.syntaxerr);
5936 return;
5937 } else if (c->argc == (7 + withscores)) {
5938 offset = atoi(c->argv[5]->ptr);
5939 limit = atoi(c->argv[6]->ptr);
5940 if (offset < 0) offset = 0;
5941 }
5942
5943 /* Ok, lookup the key and get the range */
5944 o = lookupKeyRead(c->db,c->argv[1]);
5945 if (o == NULL) {
5946 addReply(c,justcount ? shared.czero : shared.emptymultibulk);
5947 } else {
5948 if (o->type != REDIS_ZSET) {
5949 addReply(c,shared.wrongtypeerr);
5950 } else {
5951 zset *zsetobj = o->ptr;
5952 zskiplist *zsl = zsetobj->zsl;
5953 zskiplistNode *ln;
5954 robj *ele, *lenobj = NULL;
5955 unsigned long rangelen = 0;
5956
5957 /* Get the first node with the score >= min, or with
5958 * score > min if 'minex' is true. */
5959 ln = zslFirstWithScore(zsl,min);
5960 while (minex && ln && ln->score == min) ln = ln->forward[0];
5961
5962 if (ln == NULL) {
5963 /* No element matching the speciifed interval */
5964 addReply(c,justcount ? shared.czero : shared.emptymultibulk);
5965 return;
5966 }
5967
5968 /* We don't know in advance how many matching elements there
5969 * are in the list, so we push this object that will represent
5970 * the multi-bulk length in the output buffer, and will "fix"
5971 * it later */
5972 if (!justcount) {
5973 lenobj = createObject(REDIS_STRING,NULL);
5974 addReply(c,lenobj);
5975 decrRefCount(lenobj);
5976 }
5977
5978 while(ln && (maxex ? (ln->score < max) : (ln->score <= max))) {
5979 if (offset) {
5980 offset--;
5981 ln = ln->forward[0];
5982 continue;
5983 }
5984 if (limit == 0) break;
5985 if (!justcount) {
5986 ele = ln->obj;
5987 addReplyBulk(c,ele);
5988 if (withscores)
5989 addReplyDouble(c,ln->score);
5990 }
5991 ln = ln->forward[0];
5992 rangelen++;
5993 if (limit > 0) limit--;
5994 }
5995 if (justcount) {
5996 addReplyLong(c,(long)rangelen);
5997 } else {
5998 lenobj->ptr = sdscatprintf(sdsempty(),"*%lu\r\n",
5999 withscores ? (rangelen*2) : rangelen);
6000 }
6001 }
6002 }
6003 }
6004
6005 static void zrangebyscoreCommand(redisClient *c) {
6006 genericZrangebyscoreCommand(c,0);
6007 }
6008
6009 static void zcountCommand(redisClient *c) {
6010 genericZrangebyscoreCommand(c,1);
6011 }
6012
6013 static void zcardCommand(redisClient *c) {
6014 robj *o;
6015 zset *zs;
6016
6017 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
6018 checkType(c,o,REDIS_ZSET)) return;
6019
6020 zs = o->ptr;
6021 addReplyUlong(c,zs->zsl->length);
6022 }
6023
6024 static void zscoreCommand(redisClient *c) {
6025 robj *o;
6026 zset *zs;
6027 dictEntry *de;
6028
6029 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
6030 checkType(c,o,REDIS_ZSET)) return;
6031
6032 zs = o->ptr;
6033 de = dictFind(zs->dict,c->argv[2]);
6034 if (!de) {
6035 addReply(c,shared.nullbulk);
6036 } else {
6037 double *score = dictGetEntryVal(de);
6038
6039 addReplyDouble(c,*score);
6040 }
6041 }
6042
6043 static void zrankGenericCommand(redisClient *c, int reverse) {
6044 robj *o;
6045 zset *zs;
6046 zskiplist *zsl;
6047 dictEntry *de;
6048 unsigned long rank;
6049 double *score;
6050
6051 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
6052 checkType(c,o,REDIS_ZSET)) return;
6053
6054 zs = o->ptr;
6055 zsl = zs->zsl;
6056 de = dictFind(zs->dict,c->argv[2]);
6057 if (!de) {
6058 addReply(c,shared.nullbulk);
6059 return;
6060 }
6061
6062 score = dictGetEntryVal(de);
6063 rank = zslGetRank(zsl, *score, c->argv[2]);
6064 if (rank) {
6065 if (reverse) {
6066 addReplyLong(c, zsl->length - rank);
6067 } else {
6068 addReplyLong(c, rank-1);
6069 }
6070 } else {
6071 addReply(c,shared.nullbulk);
6072 }
6073 }
6074
6075 static void zrankCommand(redisClient *c) {
6076 zrankGenericCommand(c, 0);
6077 }
6078
6079 static void zrevrankCommand(redisClient *c) {
6080 zrankGenericCommand(c, 1);
6081 }
6082
6083 /* ========================= Hashes utility functions ======================= */
6084 #define REDIS_HASH_KEY 1
6085 #define REDIS_HASH_VALUE 2
6086
6087 /* Check the length of a number of objects to see if we need to convert a
6088 * zipmap to a real hash. Note that we only check string encoded objects
6089 * as their string length can be queried in constant time. */
6090 static void hashTryConversion(robj *subject, robj **argv, int start, int end) {
6091 int i;
6092 if (subject->encoding != REDIS_ENCODING_ZIPMAP) return;
6093
6094 for (i = start; i <= end; i++) {
6095 if (argv[i]->encoding == REDIS_ENCODING_RAW &&
6096 sdslen(argv[i]->ptr) > server.hash_max_zipmap_value)
6097 {
6098 convertToRealHash(subject);
6099 return;
6100 }
6101 }
6102 }
6103
6104 /* Encode given objects in-place when the hash uses a dict. */
6105 static void hashTryObjectEncoding(robj *subject, robj **o1, robj **o2) {
6106 if (subject->encoding == REDIS_ENCODING_HT) {
6107 if (o1) *o1 = tryObjectEncoding(*o1);
6108 if (o2) *o2 = tryObjectEncoding(*o2);
6109 }
6110 }
6111
6112 /* Get the value from a hash identified by key. Returns either a string
6113 * object or NULL if the value cannot be found. The refcount of the object
6114 * is always increased by 1 when the value was found. */
6115 static robj *hashGet(robj *o, robj *key) {
6116 robj *value = NULL;
6117 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
6118 unsigned char *v;
6119 unsigned int vlen;
6120 key = getDecodedObject(key);
6121 if (zipmapGet(o->ptr,key->ptr,sdslen(key->ptr),&v,&vlen)) {
6122 value = createStringObject((char*)v,vlen);
6123 }
6124 decrRefCount(key);
6125 } else {
6126 dictEntry *de = dictFind(o->ptr,key);
6127 if (de != NULL) {
6128 value = dictGetEntryVal(de);
6129 incrRefCount(value);
6130 }
6131 }
6132 return value;
6133 }
6134
6135 /* Test if the key exists in the given hash. Returns 1 if the key
6136 * exists and 0 when it doesn't. */
6137 static int hashExists(robj *o, robj *key) {
6138 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
6139 key = getDecodedObject(key);
6140 if (zipmapExists(o->ptr,key->ptr,sdslen(key->ptr))) {
6141 decrRefCount(key);
6142 return 1;
6143 }
6144 decrRefCount(key);
6145 } else {
6146 if (dictFind(o->ptr,key) != NULL) {
6147 return 1;
6148 }
6149 }
6150 return 0;
6151 }
6152
6153 /* Add an element, discard the old if the key already exists.
6154 * Return 0 on insert and 1 on update. */
6155 static int hashSet(robj *o, robj *key, robj *value) {
6156 int update = 0;
6157 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
6158 key = getDecodedObject(key);
6159 value = getDecodedObject(value);
6160 o->ptr = zipmapSet(o->ptr,
6161 key->ptr,sdslen(key->ptr),
6162 value->ptr,sdslen(value->ptr), &update);
6163 decrRefCount(key);
6164 decrRefCount(value);
6165
6166 /* Check if the zipmap needs to be upgraded to a real hash table */
6167 if (zipmapLen(o->ptr) > server.hash_max_zipmap_entries)
6168 convertToRealHash(o);
6169 } else {
6170 if (dictReplace(o->ptr,key,value)) {
6171 /* Insert */
6172 incrRefCount(key);
6173 } else {
6174 /* Update */
6175 update = 1;
6176 }
6177 incrRefCount(value);
6178 }
6179 return update;
6180 }
6181
6182 /* Delete an element from a hash.
6183 * Return 1 on deleted and 0 on not found. */
6184 static int hashDelete(robj *o, robj *key) {
6185 int deleted = 0;
6186 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
6187 key = getDecodedObject(key);
6188 o->ptr = zipmapDel(o->ptr,key->ptr,sdslen(key->ptr), &deleted);
6189 decrRefCount(key);
6190 } else {
6191 deleted = dictDelete((dict*)o->ptr,key) == DICT_OK;
6192 /* Always check if the dictionary needs a resize after a delete. */
6193 if (deleted && htNeedsResize(o->ptr)) dictResize(o->ptr);
6194 }
6195 return deleted;
6196 }
6197
6198 /* Return the number of elements in a hash. */
6199 static unsigned long hashLength(robj *o) {
6200 return (o->encoding == REDIS_ENCODING_ZIPMAP) ?
6201 zipmapLen((unsigned char*)o->ptr) : dictSize((dict*)o->ptr);
6202 }
6203
6204 /* Structure to hold hash iteration abstration. Note that iteration over
6205 * hashes involves both fields and values. Because it is possible that
6206 * not both are required, store pointers in the iterator to avoid
6207 * unnecessary memory allocation for fields/values. */
6208 typedef struct {
6209 int encoding;
6210 unsigned char *zi;
6211 unsigned char *zk, *zv;
6212 unsigned int zklen, zvlen;
6213
6214 dictIterator *di;
6215 dictEntry *de;
6216 } hashIterator;
6217
6218 static hashIterator *hashInitIterator(robj *subject) {
6219 hashIterator *hi = zmalloc(sizeof(hashIterator));
6220 hi->encoding = subject->encoding;
6221 if (hi->encoding == REDIS_ENCODING_ZIPMAP) {
6222 hi->zi = zipmapRewind(subject->ptr);
6223 } else if (hi->encoding == REDIS_ENCODING_HT) {
6224 hi->di = dictGetIterator(subject->ptr);
6225 } else {
6226 redisAssert(NULL);
6227 }
6228 return hi;
6229 }
6230
6231 static void hashReleaseIterator(hashIterator *hi) {
6232 if (hi->encoding == REDIS_ENCODING_HT) {
6233 dictReleaseIterator(hi->di);
6234 }
6235 zfree(hi);
6236 }
6237
6238 /* Move to the next entry in the hash. Return REDIS_OK when the next entry
6239 * could be found and REDIS_ERR when the iterator reaches the end. */
6240 static int hashNext(hashIterator *hi) {
6241 if (hi->encoding == REDIS_ENCODING_ZIPMAP) {
6242 if ((hi->zi = zipmapNext(hi->zi, &hi->zk, &hi->zklen,
6243 &hi->zv, &hi->zvlen)) == NULL) return REDIS_ERR;
6244 } else {
6245 if ((hi->de = dictNext(hi->di)) == NULL) return REDIS_ERR;
6246 }
6247 return REDIS_OK;
6248 }
6249
6250 /* Get key or value object at current iteration position.
6251 * This increases the refcount of the field object by 1. */
6252 static robj *hashCurrent(hashIterator *hi, int what) {
6253 robj *o;
6254 if (hi->encoding == REDIS_ENCODING_ZIPMAP) {
6255 if (what & REDIS_HASH_KEY) {
6256 o = createStringObject((char*)hi->zk,hi->zklen);
6257 } else {
6258 o = createStringObject((char*)hi->zv,hi->zvlen);
6259 }
6260 } else {
6261 if (what & REDIS_HASH_KEY) {
6262 o = dictGetEntryKey(hi->de);
6263 } else {
6264 o = dictGetEntryVal(hi->de);
6265 }
6266 incrRefCount(o);
6267 }
6268 return o;
6269 }
6270
6271 static robj *hashLookupWriteOrCreate(redisClient *c, robj *key) {
6272 robj *o = lookupKeyWrite(c->db,key);
6273 if (o == NULL) {
6274 o = createHashObject();
6275 dictAdd(c->db->dict,key,o);
6276 incrRefCount(key);
6277 } else {
6278 if (o->type != REDIS_HASH) {
6279 addReply(c,shared.wrongtypeerr);
6280 return NULL;
6281 }
6282 }
6283 return o;
6284 }
6285
6286 /* ============================= Hash commands ============================== */
6287 static void hsetCommand(redisClient *c) {
6288 int update;
6289 robj *o;
6290
6291 if ((o = hashLookupWriteOrCreate(c,c->argv[1])) == NULL) return;
6292 hashTryConversion(o,c->argv,2,3);
6293 hashTryObjectEncoding(o,&c->argv[2], &c->argv[3]);
6294 update = hashSet(o,c->argv[2],c->argv[3]);
6295 addReply(c, update ? shared.czero : shared.cone);
6296 server.dirty++;
6297 }
6298
6299 static void hsetnxCommand(redisClient *c) {
6300 robj *o;
6301 if ((o = hashLookupWriteOrCreate(c,c->argv[1])) == NULL) return;
6302 hashTryConversion(o,c->argv,2,3);
6303
6304 if (hashExists(o, c->argv[2])) {
6305 addReply(c, shared.czero);
6306 } else {
6307 hashTryObjectEncoding(o,&c->argv[2], &c->argv[3]);
6308 hashSet(o,c->argv[2],c->argv[3]);
6309 addReply(c, shared.cone);
6310 server.dirty++;
6311 }
6312 }
6313
6314 static void hmsetCommand(redisClient *c) {
6315 int i;
6316 robj *o;
6317
6318 if ((c->argc % 2) == 1) {
6319 addReplySds(c,sdsnew("-ERR wrong number of arguments for HMSET\r\n"));
6320 return;
6321 }
6322
6323 if ((o = hashLookupWriteOrCreate(c,c->argv[1])) == NULL) return;
6324 hashTryConversion(o,c->argv,2,c->argc-1);
6325 for (i = 2; i < c->argc; i += 2) {
6326 hashTryObjectEncoding(o,&c->argv[i], &c->argv[i+1]);
6327 hashSet(o,c->argv[i],c->argv[i+1]);
6328 }
6329 addReply(c, shared.ok);
6330 server.dirty++;
6331 }
6332
6333 static void hincrbyCommand(redisClient *c) {
6334 long long value, incr;
6335 robj *o, *current, *new;
6336
6337 if (getLongLongFromObjectOrReply(c,c->argv[3],&incr,NULL) != REDIS_OK) return;
6338 if ((o = hashLookupWriteOrCreate(c,c->argv[1])) == NULL) return;
6339 if ((current = hashGet(o,c->argv[2])) != NULL) {
6340 if (current->encoding == REDIS_ENCODING_RAW)
6341 value = strtoll(current->ptr,NULL,10);
6342 else if (current->encoding == REDIS_ENCODING_INT)
6343 value = (long)current->ptr;
6344 else
6345 redisAssert(1 != 1);
6346 decrRefCount(current);
6347 } else {
6348 value = 0;
6349 }
6350
6351 value += incr;
6352 new = createStringObjectFromLongLong(value);
6353 hashTryObjectEncoding(o,&c->argv[2],NULL);
6354 hashSet(o,c->argv[2],new);
6355 decrRefCount(new);
6356 addReplyLongLong(c,value);
6357 server.dirty++;
6358 }
6359
6360 static void hgetCommand(redisClient *c) {
6361 robj *o, *value;
6362 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.nullbulk)) == NULL ||
6363 checkType(c,o,REDIS_HASH)) return;
6364
6365 if ((value = hashGet(o,c->argv[2])) != NULL) {
6366 addReplyBulk(c,value);
6367 decrRefCount(value);
6368 } else {
6369 addReply(c,shared.nullbulk);
6370 }
6371 }
6372
6373 static void hmgetCommand(redisClient *c) {
6374 int i;
6375 robj *o, *value;
6376 o = lookupKeyRead(c->db,c->argv[1]);
6377 if (o != NULL && o->type != REDIS_HASH) {
6378 addReply(c,shared.wrongtypeerr);
6379 }
6380
6381 /* Note the check for o != NULL happens inside the loop. This is
6382 * done because objects that cannot be found are considered to be
6383 * an empty hash. The reply should then be a series of NULLs. */
6384 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",c->argc-2));
6385 for (i = 2; i < c->argc; i++) {
6386 if (o != NULL && (value = hashGet(o,c->argv[i])) != NULL) {
6387 addReplyBulk(c,value);
6388 decrRefCount(value);
6389 } else {
6390 addReply(c,shared.nullbulk);
6391 }
6392 }
6393 }
6394
6395 static void hdelCommand(redisClient *c) {
6396 robj *o;
6397 if ((o = lookupKeyWriteOrReply(c,c->argv[1],shared.czero)) == NULL ||
6398 checkType(c,o,REDIS_HASH)) return;
6399
6400 if (hashDelete(o,c->argv[2])) {
6401 if (hashLength(o) == 0) deleteKey(c->db,c->argv[1]);
6402 addReply(c,shared.cone);
6403 server.dirty++;
6404 } else {
6405 addReply(c,shared.czero);
6406 }
6407 }
6408
6409 static void hlenCommand(redisClient *c) {
6410 robj *o;
6411 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
6412 checkType(c,o,REDIS_HASH)) return;
6413
6414 addReplyUlong(c,hashLength(o));
6415 }
6416
6417 static void genericHgetallCommand(redisClient *c, int flags) {
6418 robj *o, *lenobj, *obj;
6419 unsigned long count = 0;
6420 hashIterator *hi;
6421
6422 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.emptymultibulk)) == NULL
6423 || checkType(c,o,REDIS_HASH)) return;
6424
6425 lenobj = createObject(REDIS_STRING,NULL);
6426 addReply(c,lenobj);
6427 decrRefCount(lenobj);
6428
6429 hi = hashInitIterator(o);
6430 while (hashNext(hi) != REDIS_ERR) {
6431 if (flags & REDIS_HASH_KEY) {
6432 obj = hashCurrent(hi,REDIS_HASH_KEY);
6433 addReplyBulk(c,obj);
6434 decrRefCount(obj);
6435 count++;
6436 }
6437 if (flags & REDIS_HASH_VALUE) {
6438 obj = hashCurrent(hi,REDIS_HASH_VALUE);
6439 addReplyBulk(c,obj);
6440 decrRefCount(obj);
6441 count++;
6442 }
6443 }
6444 hashReleaseIterator(hi);
6445
6446 lenobj->ptr = sdscatprintf(sdsempty(),"*%lu\r\n",count);
6447 }
6448
6449 static void hkeysCommand(redisClient *c) {
6450 genericHgetallCommand(c,REDIS_HASH_KEY);
6451 }
6452
6453 static void hvalsCommand(redisClient *c) {
6454 genericHgetallCommand(c,REDIS_HASH_VALUE);
6455 }
6456
6457 static void hgetallCommand(redisClient *c) {
6458 genericHgetallCommand(c,REDIS_HASH_KEY|REDIS_HASH_VALUE);
6459 }
6460
6461 static void hexistsCommand(redisClient *c) {
6462 robj *o;
6463 if ((o = lookupKeyReadOrReply(c,c->argv[1],shared.czero)) == NULL ||
6464 checkType(c,o,REDIS_HASH)) return;
6465
6466 addReply(c, hashExists(o,c->argv[2]) ? shared.cone : shared.czero);
6467 }
6468
6469 static void convertToRealHash(robj *o) {
6470 unsigned char *key, *val, *p, *zm = o->ptr;
6471 unsigned int klen, vlen;
6472 dict *dict = dictCreate(&hashDictType,NULL);
6473
6474 assert(o->type == REDIS_HASH && o->encoding != REDIS_ENCODING_HT);
6475 p = zipmapRewind(zm);
6476 while((p = zipmapNext(p,&key,&klen,&val,&vlen)) != NULL) {
6477 robj *keyobj, *valobj;
6478
6479 keyobj = createStringObject((char*)key,klen);
6480 valobj = createStringObject((char*)val,vlen);
6481 keyobj = tryObjectEncoding(keyobj);
6482 valobj = tryObjectEncoding(valobj);
6483 dictAdd(dict,keyobj,valobj);
6484 }
6485 o->encoding = REDIS_ENCODING_HT;
6486 o->ptr = dict;
6487 zfree(zm);
6488 }
6489
6490 /* ========================= Non type-specific commands ==================== */
6491
6492 static void flushdbCommand(redisClient *c) {
6493 server.dirty += dictSize(c->db->dict);
6494 dictEmpty(c->db->dict);
6495 dictEmpty(c->db->expires);
6496 addReply(c,shared.ok);
6497 }
6498
6499 static void flushallCommand(redisClient *c) {
6500 server.dirty += emptyDb();
6501 addReply(c,shared.ok);
6502 if (server.bgsavechildpid != -1) {
6503 kill(server.bgsavechildpid,SIGKILL);
6504 rdbRemoveTempFile(server.bgsavechildpid);
6505 }
6506 rdbSave(server.dbfilename);
6507 server.dirty++;
6508 }
6509
6510 static redisSortOperation *createSortOperation(int type, robj *pattern) {
6511 redisSortOperation *so = zmalloc(sizeof(*so));
6512 so->type = type;
6513 so->pattern = pattern;
6514 return so;
6515 }
6516
6517 /* Return the value associated to the key with a name obtained
6518 * substituting the first occurence of '*' in 'pattern' with 'subst'.
6519 * The returned object will always have its refcount increased by 1
6520 * when it is non-NULL. */
6521 static robj *lookupKeyByPattern(redisDb *db, robj *pattern, robj *subst) {
6522 char *p, *f;
6523 sds spat, ssub;
6524 robj keyobj, fieldobj, *o;
6525 int prefixlen, sublen, postfixlen, fieldlen;
6526 /* Expoit the internal sds representation to create a sds string allocated on the stack in order to make this function faster */
6527 struct {
6528 long len;
6529 long free;
6530 char buf[REDIS_SORTKEY_MAX+1];
6531 } keyname, fieldname;
6532
6533 /* If the pattern is "#" return the substitution object itself in order
6534 * to implement the "SORT ... GET #" feature. */
6535 spat = pattern->ptr;
6536 if (spat[0] == '#' && spat[1] == '\0') {
6537 incrRefCount(subst);
6538 return subst;
6539 }
6540
6541 /* The substitution object may be specially encoded. If so we create
6542 * a decoded object on the fly. Otherwise getDecodedObject will just
6543 * increment the ref count, that we'll decrement later. */
6544 subst = getDecodedObject(subst);
6545
6546 ssub = subst->ptr;
6547 if (sdslen(spat)+sdslen(ssub)-1 > REDIS_SORTKEY_MAX) return NULL;
6548 p = strchr(spat,'*');
6549 if (!p) {
6550 decrRefCount(subst);
6551 return NULL;
6552 }
6553
6554 /* Find out if we're dealing with a hash dereference. */
6555 if ((f = strstr(p+1, "->")) != NULL) {
6556 fieldlen = sdslen(spat)-(f-spat);
6557 /* this also copies \0 character */
6558 memcpy(fieldname.buf,f+2,fieldlen-1);
6559 fieldname.len = fieldlen-2;
6560 } else {
6561 fieldlen = 0;
6562 }
6563
6564 prefixlen = p-spat;
6565 sublen = sdslen(ssub);
6566 postfixlen = sdslen(spat)-(prefixlen+1)-fieldlen;
6567 memcpy(keyname.buf,spat,prefixlen);
6568 memcpy(keyname.buf+prefixlen,ssub,sublen);
6569 memcpy(keyname.buf+prefixlen+sublen,p+1,postfixlen);
6570 keyname.buf[prefixlen+sublen+postfixlen] = '\0';
6571 keyname.len = prefixlen+sublen+postfixlen;
6572 decrRefCount(subst);
6573
6574 /* Lookup substituted key */
6575 initStaticStringObject(keyobj,((char*)&keyname)+(sizeof(long)*2));
6576 o = lookupKeyRead(db,&keyobj);
6577 if (o == NULL) return NULL;
6578
6579 if (fieldlen > 0) {
6580 if (o->type != REDIS_HASH || fieldname.len < 1) return NULL;
6581
6582 /* Retrieve value from hash by the field name. This operation
6583 * already increases the refcount of the returned object. */
6584 initStaticStringObject(fieldobj,((char*)&fieldname)+(sizeof(long)*2));
6585 o = hashGet(o, &fieldobj);
6586 } else {
6587 if (o->type != REDIS_STRING) return NULL;
6588
6589 /* Every object that this function returns needs to have its refcount
6590 * increased. sortCommand decreases it again. */
6591 incrRefCount(o);
6592 }
6593
6594 return o;
6595 }
6596
6597 /* sortCompare() is used by qsort in sortCommand(). Given that qsort_r with
6598 * the additional parameter is not standard but a BSD-specific we have to
6599 * pass sorting parameters via the global 'server' structure */
6600 static int sortCompare(const void *s1, const void *s2) {
6601 const redisSortObject *so1 = s1, *so2 = s2;
6602 int cmp;
6603
6604 if (!server.sort_alpha) {
6605 /* Numeric sorting. Here it's trivial as we precomputed scores */
6606 if (so1->u.score > so2->u.score) {
6607 cmp = 1;
6608 } else if (so1->u.score < so2->u.score) {
6609 cmp = -1;
6610 } else {
6611 cmp = 0;
6612 }
6613 } else {
6614 /* Alphanumeric sorting */
6615 if (server.sort_bypattern) {
6616 if (!so1->u.cmpobj || !so2->u.cmpobj) {
6617 /* At least one compare object is NULL */
6618 if (so1->u.cmpobj == so2->u.cmpobj)
6619 cmp = 0;
6620 else if (so1->u.cmpobj == NULL)
6621 cmp = -1;
6622 else
6623 cmp = 1;
6624 } else {
6625 /* We have both the objects, use strcoll */
6626 cmp = strcoll(so1->u.cmpobj->ptr,so2->u.cmpobj->ptr);
6627 }
6628 } else {
6629 /* Compare elements directly. */
6630 cmp = compareStringObjects(so1->obj,so2->obj);
6631 }
6632 }
6633 return server.sort_desc ? -cmp : cmp;
6634 }
6635
6636 /* The SORT command is the most complex command in Redis. Warning: this code
6637 * is optimized for speed and a bit less for readability */
6638 static void sortCommand(redisClient *c) {
6639 list *operations;
6640 int outputlen = 0;
6641 int desc = 0, alpha = 0;
6642 int limit_start = 0, limit_count = -1, start, end;
6643 int j, dontsort = 0, vectorlen;
6644 int getop = 0; /* GET operation counter */
6645 robj *sortval, *sortby = NULL, *storekey = NULL;
6646 redisSortObject *vector; /* Resulting vector to sort */
6647
6648 /* Lookup the key to sort. It must be of the right types */
6649 sortval = lookupKeyRead(c->db,c->argv[1]);
6650 if (sortval == NULL) {
6651 addReply(c,shared.emptymultibulk);
6652 return;
6653 }
6654 if (sortval->type != REDIS_SET && sortval->type != REDIS_LIST &&
6655 sortval->type != REDIS_ZSET)
6656 {
6657 addReply(c,shared.wrongtypeerr);
6658 return;
6659 }
6660
6661 /* Create a list of operations to perform for every sorted element.
6662 * Operations can be GET/DEL/INCR/DECR */
6663 operations = listCreate();
6664 listSetFreeMethod(operations,zfree);
6665 j = 2;
6666
6667 /* Now we need to protect sortval incrementing its count, in the future
6668 * SORT may have options able to overwrite/delete keys during the sorting
6669 * and the sorted key itself may get destroied */
6670 incrRefCount(sortval);
6671
6672 /* The SORT command has an SQL-alike syntax, parse it */
6673 while(j < c->argc) {
6674 int leftargs = c->argc-j-1;
6675 if (!strcasecmp(c->argv[j]->ptr,"asc")) {
6676 desc = 0;
6677 } else if (!strcasecmp(c->argv[j]->ptr,"desc")) {
6678 desc = 1;
6679 } else if (!strcasecmp(c->argv[j]->ptr,"alpha")) {
6680 alpha = 1;
6681 } else if (!strcasecmp(c->argv[j]->ptr,"limit") && leftargs >= 2) {
6682 limit_start = atoi(c->argv[j+1]->ptr);
6683 limit_count = atoi(c->argv[j+2]->ptr);
6684 j+=2;
6685 } else if (!strcasecmp(c->argv[j]->ptr,"store") && leftargs >= 1) {
6686 storekey = c->argv[j+1];
6687 j++;
6688 } else if (!strcasecmp(c->argv[j]->ptr,"by") && leftargs >= 1) {
6689 sortby = c->argv[j+1];
6690 /* If the BY pattern does not contain '*', i.e. it is constant,
6691 * we don't need to sort nor to lookup the weight keys. */
6692 if (strchr(c->argv[j+1]->ptr,'*') == NULL) dontsort = 1;
6693 j++;
6694 } else if (!strcasecmp(c->argv[j]->ptr,"get") && leftargs >= 1) {
6695 listAddNodeTail(operations,createSortOperation(
6696 REDIS_SORT_GET,c->argv[j+1]));
6697 getop++;
6698 j++;
6699 } else {
6700 decrRefCount(sortval);
6701 listRelease(operations);
6702 addReply(c,shared.syntaxerr);
6703 return;
6704 }
6705 j++;
6706 }
6707
6708 /* Load the sorting vector with all the objects to sort */
6709 switch(sortval->type) {
6710 case REDIS_LIST: vectorlen = listLength((list*)sortval->ptr); break;
6711 case REDIS_SET: vectorlen = dictSize((dict*)sortval->ptr); break;
6712 case REDIS_ZSET: vectorlen = dictSize(((zset*)sortval->ptr)->dict); break;
6713 default: vectorlen = 0; redisPanic("Bad SORT type"); /* Avoid GCC warning */
6714 }
6715 vector = zmalloc(sizeof(redisSortObject)*vectorlen);
6716 j = 0;
6717
6718 if (sortval->type == REDIS_LIST) {
6719 list *list = sortval->ptr;
6720 listNode *ln;
6721 listIter li;
6722
6723 listRewind(list,&li);
6724 while((ln = listNext(&li))) {
6725 robj *ele = ln->value;
6726 vector[j].obj = ele;
6727 vector[j].u.score = 0;
6728 vector[j].u.cmpobj = NULL;
6729 j++;
6730 }
6731 } else {
6732 dict *set;
6733 dictIterator *di;
6734 dictEntry *setele;
6735
6736 if (sortval->type == REDIS_SET) {
6737 set = sortval->ptr;
6738 } else {
6739 zset *zs = sortval->ptr;
6740 set = zs->dict;
6741 }
6742
6743 di = dictGetIterator(set);
6744 while((setele = dictNext(di)) != NULL) {
6745 vector[j].obj = dictGetEntryKey(setele);
6746 vector[j].u.score = 0;
6747 vector[j].u.cmpobj = NULL;
6748 j++;
6749 }
6750 dictReleaseIterator(di);
6751 }
6752 redisAssert(j == vectorlen);
6753
6754 /* Now it's time to load the right scores in the sorting vector */
6755 if (dontsort == 0) {
6756 for (j = 0; j < vectorlen; j++) {
6757 robj *byval;
6758 if (sortby) {
6759 /* lookup value to sort by */
6760 byval = lookupKeyByPattern(c->db,sortby,vector[j].obj);
6761 if (!byval) continue;
6762 } else {
6763 /* use object itself to sort by */
6764 byval = vector[j].obj;
6765 }
6766
6767 if (alpha) {
6768 if (sortby) vector[j].u.cmpobj = getDecodedObject(byval);
6769 } else {
6770 if (byval->encoding == REDIS_ENCODING_RAW) {
6771 vector[j].u.score = strtod(byval->ptr,NULL);
6772 } else if (byval->encoding == REDIS_ENCODING_INT) {
6773 /* Don't need to decode the object if it's
6774 * integer-encoded (the only encoding supported) so
6775 * far. We can just cast it */
6776 vector[j].u.score = (long)byval->ptr;
6777 } else {
6778 redisAssert(1 != 1);
6779 }
6780 }
6781
6782 /* when the object was retrieved using lookupKeyByPattern,
6783 * its refcount needs to be decreased. */
6784 if (sortby) {
6785 decrRefCount(byval);
6786 }
6787 }
6788 }
6789
6790 /* We are ready to sort the vector... perform a bit of sanity check
6791 * on the LIMIT option too. We'll use a partial version of quicksort. */
6792 start = (limit_start < 0) ? 0 : limit_start;
6793 end = (limit_count < 0) ? vectorlen-1 : start+limit_count-1;
6794 if (start >= vectorlen) {
6795 start = vectorlen-1;
6796 end = vectorlen-2;
6797 }
6798 if (end >= vectorlen) end = vectorlen-1;
6799
6800 if (dontsort == 0) {
6801 server.sort_desc = desc;
6802 server.sort_alpha = alpha;
6803 server.sort_bypattern = sortby ? 1 : 0;
6804 if (sortby && (start != 0 || end != vectorlen-1))
6805 pqsort(vector,vectorlen,sizeof(redisSortObject),sortCompare, start,end);
6806 else
6807 qsort(vector,vectorlen,sizeof(redisSortObject),sortCompare);
6808 }
6809
6810 /* Send command output to the output buffer, performing the specified
6811 * GET/DEL/INCR/DECR operations if any. */
6812 outputlen = getop ? getop*(end-start+1) : end-start+1;
6813 if (storekey == NULL) {
6814 /* STORE option not specified, sent the sorting result to client */
6815 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",outputlen));
6816 for (j = start; j <= end; j++) {
6817 listNode *ln;
6818 listIter li;
6819
6820 if (!getop) addReplyBulk(c,vector[j].obj);
6821 listRewind(operations,&li);
6822 while((ln = listNext(&li))) {
6823 redisSortOperation *sop = ln->value;
6824 robj *val = lookupKeyByPattern(c->db,sop->pattern,
6825 vector[j].obj);
6826
6827 if (sop->type == REDIS_SORT_GET) {
6828 if (!val) {
6829 addReply(c,shared.nullbulk);
6830 } else {
6831 addReplyBulk(c,val);
6832 decrRefCount(val);
6833 }
6834 } else {
6835 redisAssert(sop->type == REDIS_SORT_GET); /* always fails */
6836 }
6837 }
6838 }
6839 } else {
6840 robj *listObject = createListObject();
6841 list *listPtr = (list*) listObject->ptr;
6842
6843 /* STORE option specified, set the sorting result as a List object */
6844 for (j = start; j <= end; j++) {
6845 listNode *ln;
6846 listIter li;
6847
6848 if (!getop) {
6849 listAddNodeTail(listPtr,vector[j].obj);
6850 incrRefCount(vector[j].obj);
6851 }
6852 listRewind(operations,&li);
6853 while((ln = listNext(&li))) {
6854 redisSortOperation *sop = ln->value;
6855 robj *val = lookupKeyByPattern(c->db,sop->pattern,
6856 vector[j].obj);
6857
6858 if (sop->type == REDIS_SORT_GET) {
6859 if (!val) {
6860 listAddNodeTail(listPtr,createStringObject("",0));
6861 } else {
6862 /* We should do a incrRefCount on val because it is
6863 * added to the list, but also a decrRefCount because
6864 * it is returned by lookupKeyByPattern. This results
6865 * in doing nothing at all. */
6866 listAddNodeTail(listPtr,val);
6867 }
6868 } else {
6869 redisAssert(sop->type == REDIS_SORT_GET); /* always fails */
6870 }
6871 }
6872 }
6873 if (dictReplace(c->db->dict,storekey,listObject)) {
6874 incrRefCount(storekey);
6875 }
6876 /* Note: we add 1 because the DB is dirty anyway since even if the
6877 * SORT result is empty a new key is set and maybe the old content
6878 * replaced. */
6879 server.dirty += 1+outputlen;
6880 addReplySds(c,sdscatprintf(sdsempty(),":%d\r\n",outputlen));
6881 }
6882
6883 /* Cleanup */
6884 decrRefCount(sortval);
6885 listRelease(operations);
6886 for (j = 0; j < vectorlen; j++) {
6887 if (alpha && vector[j].u.cmpobj)
6888 decrRefCount(vector[j].u.cmpobj);
6889 }
6890 zfree(vector);
6891 }
6892
6893 /* Convert an amount of bytes into a human readable string in the form
6894 * of 100B, 2G, 100M, 4K, and so forth. */
6895 static void bytesToHuman(char *s, unsigned long long n) {
6896 double d;
6897
6898 if (n < 1024) {
6899 /* Bytes */
6900 sprintf(s,"%lluB",n);
6901 return;
6902 } else if (n < (1024*1024)) {
6903 d = (double)n/(1024);
6904 sprintf(s,"%.2fK",d);
6905 } else if (n < (1024LL*1024*1024)) {
6906 d = (double)n/(1024*1024);
6907 sprintf(s,"%.2fM",d);
6908 } else if (n < (1024LL*1024*1024*1024)) {
6909 d = (double)n/(1024LL*1024*1024);
6910 sprintf(s,"%.2fG",d);
6911 }
6912 }
6913
6914 /* Create the string returned by the INFO command. This is decoupled
6915 * by the INFO command itself as we need to report the same information
6916 * on memory corruption problems. */
6917 static sds genRedisInfoString(void) {
6918 sds info;
6919 time_t uptime = time(NULL)-server.stat_starttime;
6920 int j;
6921 char hmem[64];
6922
6923 bytesToHuman(hmem,zmalloc_used_memory());
6924 info = sdscatprintf(sdsempty(),
6925 "redis_version:%s\r\n"
6926 "arch_bits:%s\r\n"
6927 "multiplexing_api:%s\r\n"
6928 "process_id:%ld\r\n"
6929 "uptime_in_seconds:%ld\r\n"
6930 "uptime_in_days:%ld\r\n"
6931 "connected_clients:%d\r\n"
6932 "connected_slaves:%d\r\n"
6933 "blocked_clients:%d\r\n"
6934 "used_memory:%zu\r\n"
6935 "used_memory_human:%s\r\n"
6936 "changes_since_last_save:%lld\r\n"
6937 "bgsave_in_progress:%d\r\n"
6938 "last_save_time:%ld\r\n"
6939 "bgrewriteaof_in_progress:%d\r\n"
6940 "total_connections_received:%lld\r\n"
6941 "total_commands_processed:%lld\r\n"
6942 "expired_keys:%lld\r\n"
6943 "hash_max_zipmap_entries:%ld\r\n"
6944 "hash_max_zipmap_value:%ld\r\n"
6945 "pubsub_channels:%ld\r\n"
6946 "pubsub_patterns:%u\r\n"
6947 "vm_enabled:%d\r\n"
6948 "role:%s\r\n"
6949 ,REDIS_VERSION,
6950 (sizeof(long) == 8) ? "64" : "32",
6951 aeGetApiName(),
6952 (long) getpid(),
6953 uptime,
6954 uptime/(3600*24),
6955 listLength(server.clients)-listLength(server.slaves),
6956 listLength(server.slaves),
6957 server.blpop_blocked_clients,
6958 zmalloc_used_memory(),
6959 hmem,
6960 server.dirty,
6961 server.bgsavechildpid != -1,
6962 server.lastsave,
6963 server.bgrewritechildpid != -1,
6964 server.stat_numconnections,
6965 server.stat_numcommands,
6966 server.stat_expiredkeys,
6967 server.hash_max_zipmap_entries,
6968 server.hash_max_zipmap_value,
6969 dictSize(server.pubsub_channels),
6970 listLength(server.pubsub_patterns),
6971 server.vm_enabled != 0,
6972 server.masterhost == NULL ? "master" : "slave"
6973 );
6974 if (server.masterhost) {
6975 info = sdscatprintf(info,
6976 "master_host:%s\r\n"
6977 "master_port:%d\r\n"
6978 "master_link_status:%s\r\n"
6979 "master_last_io_seconds_ago:%d\r\n"
6980 ,server.masterhost,
6981 server.masterport,
6982 (server.replstate == REDIS_REPL_CONNECTED) ?
6983 "up" : "down",
6984 server.master ? ((int)(time(NULL)-server.master->lastinteraction)) : -1
6985 );
6986 }
6987 if (server.vm_enabled) {
6988 lockThreadedIO();
6989 info = sdscatprintf(info,
6990 "vm_conf_max_memory:%llu\r\n"
6991 "vm_conf_page_size:%llu\r\n"
6992 "vm_conf_pages:%llu\r\n"
6993 "vm_stats_used_pages:%llu\r\n"
6994 "vm_stats_swapped_objects:%llu\r\n"
6995 "vm_stats_swappin_count:%llu\r\n"
6996 "vm_stats_swappout_count:%llu\r\n"
6997 "vm_stats_io_newjobs_len:%lu\r\n"
6998 "vm_stats_io_processing_len:%lu\r\n"
6999 "vm_stats_io_processed_len:%lu\r\n"
7000 "vm_stats_io_active_threads:%lu\r\n"
7001 "vm_stats_blocked_clients:%lu\r\n"
7002 ,(unsigned long long) server.vm_max_memory,
7003 (unsigned long long) server.vm_page_size,
7004 (unsigned long long) server.vm_pages,
7005 (unsigned long long) server.vm_stats_used_pages,
7006 (unsigned long long) server.vm_stats_swapped_objects,
7007 (unsigned long long) server.vm_stats_swapins,
7008 (unsigned long long) server.vm_stats_swapouts,
7009 (unsigned long) listLength(server.io_newjobs),
7010 (unsigned long) listLength(server.io_processing),
7011 (unsigned long) listLength(server.io_processed),
7012 (unsigned long) server.io_active_threads,
7013 (unsigned long) server.vm_blocked_clients
7014 );
7015 unlockThreadedIO();
7016 }
7017 for (j = 0; j < server.dbnum; j++) {
7018 long long keys, vkeys;
7019
7020 keys = dictSize(server.db[j].dict);
7021 vkeys = dictSize(server.db[j].expires);
7022 if (keys || vkeys) {
7023 info = sdscatprintf(info, "db%d:keys=%lld,expires=%lld\r\n",
7024 j, keys, vkeys);
7025 }
7026 }
7027 return info;
7028 }
7029
7030 static void infoCommand(redisClient *c) {
7031 sds info = genRedisInfoString();
7032 addReplySds(c,sdscatprintf(sdsempty(),"$%lu\r\n",
7033 (unsigned long)sdslen(info)));
7034 addReplySds(c,info);
7035 addReply(c,shared.crlf);
7036 }
7037
7038 static void monitorCommand(redisClient *c) {
7039 /* ignore MONITOR if aleady slave or in monitor mode */
7040 if (c->flags & REDIS_SLAVE) return;
7041
7042 c->flags |= (REDIS_SLAVE|REDIS_MONITOR);
7043 c->slaveseldb = 0;
7044 listAddNodeTail(server.monitors,c);
7045 addReply(c,shared.ok);
7046 }
7047
7048 /* ================================= Expire ================================= */
7049 static int removeExpire(redisDb *db, robj *key) {
7050 if (dictDelete(db->expires,key) == DICT_OK) {
7051 return 1;
7052 } else {
7053 return 0;
7054 }
7055 }
7056
7057 static int setExpire(redisDb *db, robj *key, time_t when) {
7058 if (dictAdd(db->expires,key,(void*)when) == DICT_ERR) {
7059 return 0;
7060 } else {
7061 incrRefCount(key);
7062 return 1;
7063 }
7064 }
7065
7066 /* Return the expire time of the specified key, or -1 if no expire
7067 * is associated with this key (i.e. the key is non volatile) */
7068 static time_t getExpire(redisDb *db, robj *key) {
7069 dictEntry *de;
7070
7071 /* No expire? return ASAP */
7072 if (dictSize(db->expires) == 0 ||
7073 (de = dictFind(db->expires,key)) == NULL) return -1;
7074
7075 return (time_t) dictGetEntryVal(de);
7076 }
7077
7078 static int expireIfNeeded(redisDb *db, robj *key) {
7079 time_t when;
7080 dictEntry *de;
7081
7082 /* No expire? return ASAP */
7083 if (dictSize(db->expires) == 0 ||
7084 (de = dictFind(db->expires,key)) == NULL) return 0;
7085
7086 /* Lookup the expire */
7087 when = (time_t) dictGetEntryVal(de);
7088 if (time(NULL) <= when) return 0;
7089
7090 /* Delete the key */
7091 dictDelete(db->expires,key);
7092 server.stat_expiredkeys++;
7093 return dictDelete(db->dict,key) == DICT_OK;
7094 }
7095
7096 static int deleteIfVolatile(redisDb *db, robj *key) {
7097 dictEntry *de;
7098
7099 /* No expire? return ASAP */
7100 if (dictSize(db->expires) == 0 ||
7101 (de = dictFind(db->expires,key)) == NULL) return 0;
7102
7103 /* Delete the key */
7104 server.dirty++;
7105 server.stat_expiredkeys++;
7106 dictDelete(db->expires,key);
7107 return dictDelete(db->dict,key) == DICT_OK;
7108 }
7109
7110 static void expireGenericCommand(redisClient *c, robj *key, robj *param, long offset) {
7111 dictEntry *de;
7112 time_t seconds;
7113
7114 if (getLongFromObjectOrReply(c, param, &seconds, NULL) != REDIS_OK) return;
7115
7116 seconds -= offset;
7117
7118 de = dictFind(c->db->dict,key);
7119 if (de == NULL) {
7120 addReply(c,shared.czero);
7121 return;
7122 }
7123 if (seconds <= 0) {
7124 if (deleteKey(c->db,key)) server.dirty++;
7125 addReply(c, shared.cone);
7126 return;
7127 } else {
7128 time_t when = time(NULL)+seconds;
7129 if (setExpire(c->db,key,when)) {
7130 addReply(c,shared.cone);
7131 server.dirty++;
7132 } else {
7133 addReply(c,shared.czero);
7134 }
7135 return;
7136 }
7137 }
7138
7139 static void expireCommand(redisClient *c) {
7140 expireGenericCommand(c,c->argv[1],c->argv[2],0);
7141 }
7142
7143 static void expireatCommand(redisClient *c) {
7144 expireGenericCommand(c,c->argv[1],c->argv[2],time(NULL));
7145 }
7146
7147 static void ttlCommand(redisClient *c) {
7148 time_t expire;
7149 int ttl = -1;
7150
7151 expire = getExpire(c->db,c->argv[1]);
7152 if (expire != -1) {
7153 ttl = (int) (expire-time(NULL));
7154 if (ttl < 0) ttl = -1;
7155 }
7156 addReplySds(c,sdscatprintf(sdsempty(),":%d\r\n",ttl));
7157 }
7158
7159 /* ================================ MULTI/EXEC ============================== */
7160
7161 /* Client state initialization for MULTI/EXEC */
7162 static void initClientMultiState(redisClient *c) {
7163 c->mstate.commands = NULL;
7164 c->mstate.count = 0;
7165 }
7166
7167 /* Release all the resources associated with MULTI/EXEC state */
7168 static void freeClientMultiState(redisClient *c) {
7169 int j;
7170
7171 for (j = 0; j < c->mstate.count; j++) {
7172 int i;
7173 multiCmd *mc = c->mstate.commands+j;
7174
7175 for (i = 0; i < mc->argc; i++)
7176 decrRefCount(mc->argv[i]);
7177 zfree(mc->argv);
7178 }
7179 zfree(c->mstate.commands);
7180 }
7181
7182 /* Add a new command into the MULTI commands queue */
7183 static void queueMultiCommand(redisClient *c, struct redisCommand *cmd) {
7184 multiCmd *mc;
7185 int j;
7186
7187 c->mstate.commands = zrealloc(c->mstate.commands,
7188 sizeof(multiCmd)*(c->mstate.count+1));
7189 mc = c->mstate.commands+c->mstate.count;
7190 mc->cmd = cmd;
7191 mc->argc = c->argc;
7192 mc->argv = zmalloc(sizeof(robj*)*c->argc);
7193 memcpy(mc->argv,c->argv,sizeof(robj*)*c->argc);
7194 for (j = 0; j < c->argc; j++)
7195 incrRefCount(mc->argv[j]);
7196 c->mstate.count++;
7197 }
7198
7199 static void multiCommand(redisClient *c) {
7200 c->flags |= REDIS_MULTI;
7201 addReply(c,shared.ok);
7202 }
7203
7204 static void discardCommand(redisClient *c) {
7205 if (!(c->flags & REDIS_MULTI)) {
7206 addReplySds(c,sdsnew("-ERR DISCARD without MULTI\r\n"));
7207 return;
7208 }
7209
7210 freeClientMultiState(c);
7211 initClientMultiState(c);
7212 c->flags &= (~REDIS_MULTI);
7213 addReply(c,shared.ok);
7214 }
7215
7216 /* Send a MULTI command to all the slaves and AOF file. Check the execCommand
7217 * implememntation for more information. */
7218 static void execCommandReplicateMulti(redisClient *c) {
7219 struct redisCommand *cmd;
7220 robj *multistring = createStringObject("MULTI",5);
7221
7222 cmd = lookupCommand("multi");
7223 if (server.appendonly)
7224 feedAppendOnlyFile(cmd,c->db->id,&multistring,1);
7225 if (listLength(server.slaves))
7226 replicationFeedSlaves(server.slaves,c->db->id,&multistring,1);
7227 decrRefCount(multistring);
7228 }
7229
7230 static void execCommand(redisClient *c) {
7231 int j;
7232 robj **orig_argv;
7233 int orig_argc;
7234
7235 if (!(c->flags & REDIS_MULTI)) {
7236 addReplySds(c,sdsnew("-ERR EXEC without MULTI\r\n"));
7237 return;
7238 }
7239
7240 /* Replicate a MULTI request now that we are sure the block is executed.
7241 * This way we'll deliver the MULTI/..../EXEC block as a whole and
7242 * both the AOF and the replication link will have the same consistency
7243 * and atomicity guarantees. */
7244 execCommandReplicateMulti(c);
7245
7246 /* Exec all the queued commands */
7247 orig_argv = c->argv;
7248 orig_argc = c->argc;
7249 addReplySds(c,sdscatprintf(sdsempty(),"*%d\r\n",c->mstate.count));
7250 for (j = 0; j < c->mstate.count; j++) {
7251 c->argc = c->mstate.commands[j].argc;
7252 c->argv = c->mstate.commands[j].argv;
7253 call(c,c->mstate.commands[j].cmd);
7254 }
7255 c->argv = orig_argv;
7256 c->argc = orig_argc;
7257 freeClientMultiState(c);
7258 initClientMultiState(c);
7259 c->flags &= (~REDIS_MULTI);
7260 /* Make sure the EXEC command is always replicated / AOF, since we
7261 * always send the MULTI command (we can't know beforehand if the
7262 * next operations will contain at least a modification to the DB). */
7263 server.dirty++;
7264 }
7265
7266 /* =========================== Blocking Operations ========================= */
7267
7268 /* Currently Redis blocking operations support is limited to list POP ops,
7269 * so the current implementation is not fully generic, but it is also not
7270 * completely specific so it will not require a rewrite to support new
7271 * kind of blocking operations in the future.
7272 *
7273 * Still it's important to note that list blocking operations can be already
7274 * used as a notification mechanism in order to implement other blocking
7275 * operations at application level, so there must be a very strong evidence
7276 * of usefulness and generality before new blocking operations are implemented.
7277 *
7278 * This is how the current blocking POP works, we use BLPOP as example:
7279 * - If the user calls BLPOP and the key exists and contains a non empty list
7280 * then LPOP is called instead. So BLPOP is semantically the same as LPOP
7281 * if there is not to block.
7282 * - If instead BLPOP is called and the key does not exists or the list is
7283 * empty we need to block. In order to do so we remove the notification for
7284 * new data to read in the client socket (so that we'll not serve new
7285 * requests if the blocking request is not served). Also we put the client
7286 * in a dictionary (db->blockingkeys) mapping keys to a list of clients
7287 * blocking for this keys.
7288 * - If a PUSH operation against a key with blocked clients waiting is
7289 * performed, we serve the first in the list: basically instead to push
7290 * the new element inside the list we return it to the (first / oldest)
7291 * blocking client, unblock the client, and remove it form the list.
7292 *
7293 * The above comment and the source code should be enough in order to understand
7294 * the implementation and modify / fix it later.
7295 */
7296
7297 /* Set a client in blocking mode for the specified key, with the specified
7298 * timeout */
7299 static void blockForKeys(redisClient *c, robj **keys, int numkeys, time_t timeout) {
7300 dictEntry *de;
7301 list *l;
7302 int j;
7303
7304 c->blockingkeys = zmalloc(sizeof(robj*)*numkeys);
7305 c->blockingkeysnum = numkeys;
7306 c->blockingto = timeout;
7307 for (j = 0; j < numkeys; j++) {
7308 /* Add the key in the client structure, to map clients -> keys */
7309 c->blockingkeys[j] = keys[j];
7310 incrRefCount(keys[j]);
7311
7312 /* And in the other "side", to map keys -> clients */
7313 de = dictFind(c->db->blockingkeys,keys[j]);
7314 if (de == NULL) {
7315 int retval;
7316
7317 /* For every key we take a list of clients blocked for it */
7318 l = listCreate();
7319 retval = dictAdd(c->db->blockingkeys,keys[j],l);
7320 incrRefCount(keys[j]);
7321 assert(retval == DICT_OK);
7322 } else {
7323 l = dictGetEntryVal(de);
7324 }
7325 listAddNodeTail(l,c);
7326 }
7327 /* Mark the client as a blocked client */
7328 c->flags |= REDIS_BLOCKED;
7329 server.blpop_blocked_clients++;
7330 }
7331
7332 /* Unblock a client that's waiting in a blocking operation such as BLPOP */
7333 static void unblockClientWaitingData(redisClient *c) {
7334 dictEntry *de;
7335 list *l;
7336 int j;
7337
7338 assert(c->blockingkeys != NULL);
7339 /* The client may wait for multiple keys, so unblock it for every key. */
7340 for (j = 0; j < c->blockingkeysnum; j++) {
7341 /* Remove this client from the list of clients waiting for this key. */
7342 de = dictFind(c->db->blockingkeys,c->blockingkeys[j]);
7343 assert(de != NULL);
7344 l = dictGetEntryVal(de);
7345 listDelNode(l,listSearchKey(l,c));
7346 /* If the list is empty we need to remove it to avoid wasting memory */
7347 if (listLength(l) == 0)
7348 dictDelete(c->db->blockingkeys,c->blockingkeys[j]);
7349 decrRefCount(c->blockingkeys[j]);
7350 }
7351 /* Cleanup the client structure */
7352 zfree(c->blockingkeys);
7353 c->blockingkeys = NULL;
7354 c->flags &= (~REDIS_BLOCKED);
7355 server.blpop_blocked_clients--;
7356 /* We want to process data if there is some command waiting
7357 * in the input buffer. Note that this is safe even if
7358 * unblockClientWaitingData() gets called from freeClient() because
7359 * freeClient() will be smart enough to call this function
7360 * *after* c->querybuf was set to NULL. */
7361 if (c->querybuf && sdslen(c->querybuf) > 0) processInputBuffer(c);
7362 }
7363
7364 /* This should be called from any function PUSHing into lists.
7365 * 'c' is the "pushing client", 'key' is the key it is pushing data against,
7366 * 'ele' is the element pushed.
7367 *
7368 * If the function returns 0 there was no client waiting for a list push
7369 * against this key.
7370 *
7371 * If the function returns 1 there was a client waiting for a list push
7372 * against this key, the element was passed to this client thus it's not
7373 * needed to actually add it to the list and the caller should return asap. */
7374 static int handleClientsWaitingListPush(redisClient *c, robj *key, robj *ele) {
7375 struct dictEntry *de;
7376 redisClient *receiver;
7377 list *l;
7378 listNode *ln;
7379
7380 de = dictFind(c->db->blockingkeys,key);
7381 if (de == NULL) return 0;
7382 l = dictGetEntryVal(de);
7383 ln = listFirst(l);
7384 assert(ln != NULL);
7385 receiver = ln->value;
7386
7387 addReplySds(receiver,sdsnew("*2\r\n"));
7388 addReplyBulk(receiver,key);
7389 addReplyBulk(receiver,ele);
7390 unblockClientWaitingData(receiver);
7391 return 1;
7392 }
7393
7394 /* Blocking RPOP/LPOP */
7395 static void blockingPopGenericCommand(redisClient *c, int where) {
7396 robj *o;
7397 time_t timeout;
7398 int j;
7399
7400 for (j = 1; j < c->argc-1; j++) {
7401 o = lookupKeyWrite(c->db,c->argv[j]);
7402 if (o != NULL) {
7403 if (o->type != REDIS_LIST) {
7404 addReply(c,shared.wrongtypeerr);
7405 return;
7406 } else {
7407 list *list = o->ptr;
7408 if (listLength(list) != 0) {
7409 /* If the list contains elements fall back to the usual
7410 * non-blocking POP operation */
7411 robj *argv[2], **orig_argv;
7412 int orig_argc;
7413
7414 /* We need to alter the command arguments before to call
7415 * popGenericCommand() as the command takes a single key. */
7416 orig_argv = c->argv;
7417 orig_argc = c->argc;
7418 argv[1] = c->argv[j];
7419 c->argv = argv;
7420 c->argc = 2;
7421
7422 /* Also the return value is different, we need to output
7423 * the multi bulk reply header and the key name. The
7424 * "real" command will add the last element (the value)
7425 * for us. If this souds like an hack to you it's just
7426 * because it is... */
7427 addReplySds(c,sdsnew("*2\r\n"));
7428 addReplyBulk(c,argv[1]);
7429 popGenericCommand(c,where);
7430
7431 /* Fix the client structure with the original stuff */
7432 c->argv = orig_argv;
7433 c->argc = orig_argc;
7434 return;
7435 }
7436 }
7437 }
7438 }
7439 /* If the list is empty or the key does not exists we must block */
7440 timeout = strtol(c->argv[c->argc-1]->ptr,NULL,10);
7441 if (timeout > 0) timeout += time(NULL);
7442 blockForKeys(c,c->argv+1,c->argc-2,timeout);
7443 }
7444
7445 static void blpopCommand(redisClient *c) {
7446 blockingPopGenericCommand(c,REDIS_HEAD);
7447 }
7448
7449 static void brpopCommand(redisClient *c) {
7450 blockingPopGenericCommand(c,REDIS_TAIL);
7451 }
7452
7453 /* =============================== Replication ============================= */
7454
7455 static int syncWrite(int fd, char *ptr, ssize_t size, int timeout) {
7456 ssize_t nwritten, ret = size;
7457 time_t start = time(NULL);
7458
7459 timeout++;
7460 while(size) {
7461 if (aeWait(fd,AE_WRITABLE,1000) & AE_WRITABLE) {
7462 nwritten = write(fd,ptr,size);
7463 if (nwritten == -1) return -1;
7464 ptr += nwritten;
7465 size -= nwritten;
7466 }
7467 if ((time(NULL)-start) > timeout) {
7468 errno = ETIMEDOUT;
7469 return -1;
7470 }
7471 }
7472 return ret;
7473 }
7474
7475 static int syncRead(int fd, char *ptr, ssize_t size, int timeout) {
7476 ssize_t nread, totread = 0;
7477 time_t start = time(NULL);
7478
7479 timeout++;
7480 while(size) {
7481 if (aeWait(fd,AE_READABLE,1000) & AE_READABLE) {
7482 nread = read(fd,ptr,size);
7483 if (nread == -1) return -1;
7484 ptr += nread;
7485 size -= nread;
7486 totread += nread;
7487 }
7488 if ((time(NULL)-start) > timeout) {
7489 errno = ETIMEDOUT;
7490 return -1;
7491 }
7492 }
7493 return totread;
7494 }
7495
7496 static int syncReadLine(int fd, char *ptr, ssize_t size, int timeout) {
7497 ssize_t nread = 0;
7498
7499 size--;
7500 while(size) {
7501 char c;
7502
7503 if (syncRead(fd,&c,1,timeout) == -1) return -1;
7504 if (c == '\n') {
7505 *ptr = '\0';
7506 if (nread && *(ptr-1) == '\r') *(ptr-1) = '\0';
7507 return nread;
7508 } else {
7509 *ptr++ = c;
7510 *ptr = '\0';
7511 nread++;
7512 }
7513 }
7514 return nread;
7515 }
7516
7517 static void syncCommand(redisClient *c) {
7518 /* ignore SYNC if aleady slave or in monitor mode */
7519 if (c->flags & REDIS_SLAVE) return;
7520
7521 /* SYNC can't be issued when the server has pending data to send to
7522 * the client about already issued commands. We need a fresh reply
7523 * buffer registering the differences between the BGSAVE and the current
7524 * dataset, so that we can copy to other slaves if needed. */
7525 if (listLength(c->reply) != 0) {
7526 addReplySds(c,sdsnew("-ERR SYNC is invalid with pending input\r\n"));
7527 return;
7528 }
7529
7530 redisLog(REDIS_NOTICE,"Slave ask for synchronization");
7531 /* Here we need to check if there is a background saving operation
7532 * in progress, or if it is required to start one */
7533 if (server.bgsavechildpid != -1) {
7534 /* Ok a background save is in progress. Let's check if it is a good
7535 * one for replication, i.e. if there is another slave that is
7536 * registering differences since the server forked to save */
7537 redisClient *slave;
7538 listNode *ln;
7539 listIter li;
7540
7541 listRewind(server.slaves,&li);
7542 while((ln = listNext(&li))) {
7543 slave = ln->value;
7544 if (slave->replstate == REDIS_REPL_WAIT_BGSAVE_END) break;
7545 }
7546 if (ln) {
7547 /* Perfect, the server is already registering differences for
7548 * another slave. Set the right state, and copy the buffer. */
7549 listRelease(c->reply);
7550 c->reply = listDup(slave->reply);
7551 c->replstate = REDIS_REPL_WAIT_BGSAVE_END;
7552 redisLog(REDIS_NOTICE,"Waiting for end of BGSAVE for SYNC");
7553 } else {
7554 /* No way, we need to wait for the next BGSAVE in order to
7555 * register differences */
7556 c->replstate = REDIS_REPL_WAIT_BGSAVE_START;
7557 redisLog(REDIS_NOTICE,"Waiting for next BGSAVE for SYNC");
7558 }
7559 } else {
7560 /* Ok we don't have a BGSAVE in progress, let's start one */
7561 redisLog(REDIS_NOTICE,"Starting BGSAVE for SYNC");
7562 if (rdbSaveBackground(server.dbfilename) != REDIS_OK) {
7563 redisLog(REDIS_NOTICE,"Replication failed, can't BGSAVE");
7564 addReplySds(c,sdsnew("-ERR Unalbe to perform background save\r\n"));
7565 return;
7566 }
7567 c->replstate = REDIS_REPL_WAIT_BGSAVE_END;
7568 }
7569 c->repldbfd = -1;
7570 c->flags |= REDIS_SLAVE;
7571 c->slaveseldb = 0;
7572 listAddNodeTail(server.slaves,c);
7573 return;
7574 }
7575
7576 static void sendBulkToSlave(aeEventLoop *el, int fd, void *privdata, int mask) {
7577 redisClient *slave = privdata;
7578 REDIS_NOTUSED(el);
7579 REDIS_NOTUSED(mask);
7580 char buf[REDIS_IOBUF_LEN];
7581 ssize_t nwritten, buflen;
7582
7583 if (slave->repldboff == 0) {
7584 /* Write the bulk write count before to transfer the DB. In theory here
7585 * we don't know how much room there is in the output buffer of the
7586 * socket, but in pratice SO_SNDLOWAT (the minimum count for output
7587 * operations) will never be smaller than the few bytes we need. */
7588 sds bulkcount;
7589
7590 bulkcount = sdscatprintf(sdsempty(),"$%lld\r\n",(unsigned long long)
7591 slave->repldbsize);
7592 if (write(fd,bulkcount,sdslen(bulkcount)) != (signed)sdslen(bulkcount))
7593 {
7594 sdsfree(bulkcount);
7595 freeClient(slave);
7596 return;
7597 }
7598 sdsfree(bulkcount);
7599 }
7600 lseek(slave->repldbfd,slave->repldboff,SEEK_SET);
7601 buflen = read(slave->repldbfd,buf,REDIS_IOBUF_LEN);
7602 if (buflen <= 0) {
7603 redisLog(REDIS_WARNING,"Read error sending DB to slave: %s",
7604 (buflen == 0) ? "premature EOF" : strerror(errno));
7605 freeClient(slave);
7606 return;
7607 }
7608 if ((nwritten = write(fd,buf,buflen)) == -1) {
7609 redisLog(REDIS_VERBOSE,"Write error sending DB to slave: %s",
7610 strerror(errno));
7611 freeClient(slave);
7612 return;
7613 }
7614 slave->repldboff += nwritten;
7615 if (slave->repldboff == slave->repldbsize) {
7616 close(slave->repldbfd);
7617 slave->repldbfd = -1;
7618 aeDeleteFileEvent(server.el,slave->fd,AE_WRITABLE);
7619 slave->replstate = REDIS_REPL_ONLINE;
7620 if (aeCreateFileEvent(server.el, slave->fd, AE_WRITABLE,
7621 sendReplyToClient, slave) == AE_ERR) {
7622 freeClient(slave);
7623 return;
7624 }
7625 addReplySds(slave,sdsempty());
7626 redisLog(REDIS_NOTICE,"Synchronization with slave succeeded");
7627 }
7628 }
7629
7630 /* This function is called at the end of every backgrond saving.
7631 * The argument bgsaveerr is REDIS_OK if the background saving succeeded
7632 * otherwise REDIS_ERR is passed to the function.
7633 *
7634 * The goal of this function is to handle slaves waiting for a successful
7635 * background saving in order to perform non-blocking synchronization. */
7636 static void updateSlavesWaitingBgsave(int bgsaveerr) {
7637 listNode *ln;
7638 int startbgsave = 0;
7639 listIter li;
7640
7641 listRewind(server.slaves,&li);
7642 while((ln = listNext(&li))) {
7643 redisClient *slave = ln->value;
7644
7645 if (slave->replstate == REDIS_REPL_WAIT_BGSAVE_START) {
7646 startbgsave = 1;
7647 slave->replstate = REDIS_REPL_WAIT_BGSAVE_END;
7648 } else if (slave->replstate == REDIS_REPL_WAIT_BGSAVE_END) {
7649 struct redis_stat buf;
7650
7651 if (bgsaveerr != REDIS_OK) {
7652 freeClient(slave);
7653 redisLog(REDIS_WARNING,"SYNC failed. BGSAVE child returned an error");
7654 continue;
7655 }
7656 if ((slave->repldbfd = open(server.dbfilename,O_RDONLY)) == -1 ||
7657 redis_fstat(slave->repldbfd,&buf) == -1) {
7658 freeClient(slave);
7659 redisLog(REDIS_WARNING,"SYNC failed. Can't open/stat DB after BGSAVE: %s", strerror(errno));
7660 continue;
7661 }
7662 slave->repldboff = 0;
7663 slave->repldbsize = buf.st_size;
7664 slave->replstate = REDIS_REPL_SEND_BULK;
7665 aeDeleteFileEvent(server.el,slave->fd,AE_WRITABLE);
7666 if (aeCreateFileEvent(server.el, slave->fd, AE_WRITABLE, sendBulkToSlave, slave) == AE_ERR) {
7667 freeClient(slave);
7668 continue;
7669 }
7670 }
7671 }
7672 if (startbgsave) {
7673 if (rdbSaveBackground(server.dbfilename) != REDIS_OK) {
7674 listIter li;
7675
7676 listRewind(server.slaves,&li);
7677 redisLog(REDIS_WARNING,"SYNC failed. BGSAVE failed");
7678 while((ln = listNext(&li))) {
7679 redisClient *slave = ln->value;
7680
7681 if (slave->replstate == REDIS_REPL_WAIT_BGSAVE_START)
7682 freeClient(slave);
7683 }
7684 }
7685 }
7686 }
7687
7688 static int syncWithMaster(void) {
7689 char buf[1024], tmpfile[256], authcmd[1024];
7690 long dumpsize;
7691 int fd = anetTcpConnect(NULL,server.masterhost,server.masterport);
7692 int dfd, maxtries = 5;
7693
7694 if (fd == -1) {
7695 redisLog(REDIS_WARNING,"Unable to connect to MASTER: %s",
7696 strerror(errno));
7697 return REDIS_ERR;
7698 }
7699
7700 /* AUTH with the master if required. */
7701 if(server.masterauth) {
7702 snprintf(authcmd, 1024, "AUTH %s\r\n", server.masterauth);
7703 if (syncWrite(fd, authcmd, strlen(server.masterauth)+7, 5) == -1) {
7704 close(fd);
7705 redisLog(REDIS_WARNING,"Unable to AUTH to MASTER: %s",
7706 strerror(errno));
7707 return REDIS_ERR;
7708 }
7709 /* Read the AUTH result. */
7710 if (syncReadLine(fd,buf,1024,3600) == -1) {
7711 close(fd);
7712 redisLog(REDIS_WARNING,"I/O error reading auth result from MASTER: %s",
7713 strerror(errno));
7714 return REDIS_ERR;
7715 }
7716 if (buf[0] != '+') {
7717 close(fd);
7718 redisLog(REDIS_WARNING,"Cannot AUTH to MASTER, is the masterauth password correct?");
7719 return REDIS_ERR;
7720 }
7721 }
7722
7723 /* Issue the SYNC command */
7724 if (syncWrite(fd,"SYNC \r\n",7,5) == -1) {
7725 close(fd);
7726 redisLog(REDIS_WARNING,"I/O error writing to MASTER: %s",
7727 strerror(errno));
7728 return REDIS_ERR;
7729 }
7730 /* Read the bulk write count */
7731 if (syncReadLine(fd,buf,1024,3600) == -1) {
7732 close(fd);
7733 redisLog(REDIS_WARNING,"I/O error reading bulk count from MASTER: %s",
7734 strerror(errno));
7735 return REDIS_ERR;
7736 }
7737 if (buf[0] != '$') {
7738 close(fd);
7739 redisLog(REDIS_WARNING,"Bad protocol from MASTER, the first byte is not '$', are you sure the host and port are right?");
7740 return REDIS_ERR;
7741 }
7742 dumpsize = strtol(buf+1,NULL,10);
7743 redisLog(REDIS_NOTICE,"Receiving %ld bytes data dump from MASTER",dumpsize);
7744 /* Read the bulk write data on a temp file */
7745 while(maxtries--) {
7746 snprintf(tmpfile,256,
7747 "temp-%d.%ld.rdb",(int)time(NULL),(long int)getpid());
7748 dfd = open(tmpfile,O_CREAT|O_WRONLY|O_EXCL,0644);
7749 if (dfd != -1) break;
7750 sleep(1);
7751 }
7752 if (dfd == -1) {
7753 close(fd);
7754 redisLog(REDIS_WARNING,"Opening the temp file needed for MASTER <-> SLAVE synchronization: %s",strerror(errno));
7755 return REDIS_ERR;
7756 }
7757 while(dumpsize) {
7758 int nread, nwritten;
7759
7760 nread = read(fd,buf,(dumpsize < 1024)?dumpsize:1024);
7761 if (nread == -1) {
7762 redisLog(REDIS_WARNING,"I/O error trying to sync with MASTER: %s",
7763 strerror(errno));
7764 close(fd);
7765 close(dfd);
7766 return REDIS_ERR;
7767 }
7768 nwritten = write(dfd,buf,nread);
7769 if (nwritten == -1) {
7770 redisLog(REDIS_WARNING,"Write error writing to the DB dump file needed for MASTER <-> SLAVE synchrnonization: %s", strerror(errno));
7771 close(fd);
7772 close(dfd);
7773 return REDIS_ERR;
7774 }
7775 dumpsize -= nread;
7776 }
7777 close(dfd);
7778 if (rename(tmpfile,server.dbfilename) == -1) {
7779 redisLog(REDIS_WARNING,"Failed trying to rename the temp DB into dump.rdb in MASTER <-> SLAVE synchronization: %s", strerror(errno));
7780 unlink(tmpfile);
7781 close(fd);
7782 return REDIS_ERR;
7783 }
7784 emptyDb();
7785 if (rdbLoad(server.dbfilename) != REDIS_OK) {
7786 redisLog(REDIS_WARNING,"Failed trying to load the MASTER synchronization DB from disk");
7787 close(fd);
7788 return REDIS_ERR;
7789 }
7790 server.master = createClient(fd);
7791 server.master->flags |= REDIS_MASTER;
7792 server.master->authenticated = 1;
7793 server.replstate = REDIS_REPL_CONNECTED;
7794 return REDIS_OK;
7795 }
7796
7797 static void slaveofCommand(redisClient *c) {
7798 if (!strcasecmp(c->argv[1]->ptr,"no") &&
7799 !strcasecmp(c->argv[2]->ptr,"one")) {
7800 if (server.masterhost) {
7801 sdsfree(server.masterhost);
7802 server.masterhost = NULL;
7803 if (server.master) freeClient(server.master);
7804 server.replstate = REDIS_REPL_NONE;
7805 redisLog(REDIS_NOTICE,"MASTER MODE enabled (user request)");
7806 }
7807 } else {
7808 sdsfree(server.masterhost);
7809 server.masterhost = sdsdup(c->argv[1]->ptr);
7810 server.masterport = atoi(c->argv[2]->ptr);
7811 if (server.master) freeClient(server.master);
7812 server.replstate = REDIS_REPL_CONNECT;
7813 redisLog(REDIS_NOTICE,"SLAVE OF %s:%d enabled (user request)",
7814 server.masterhost, server.masterport);
7815 }
7816 addReply(c,shared.ok);
7817 }
7818
7819 /* ============================ Maxmemory directive ======================== */
7820
7821 /* Try to free one object form the pre-allocated objects free list.
7822 * This is useful under low mem conditions as by default we take 1 million
7823 * free objects allocated. On success REDIS_OK is returned, otherwise
7824 * REDIS_ERR. */
7825 static int tryFreeOneObjectFromFreelist(void) {
7826 robj *o;
7827
7828 if (server.vm_enabled) pthread_mutex_lock(&server.obj_freelist_mutex);
7829 if (listLength(server.objfreelist)) {
7830 listNode *head = listFirst(server.objfreelist);
7831 o = listNodeValue(head);
7832 listDelNode(server.objfreelist,head);
7833 if (server.vm_enabled) pthread_mutex_unlock(&server.obj_freelist_mutex);
7834 zfree(o);
7835 return REDIS_OK;
7836 } else {
7837 if (server.vm_enabled) pthread_mutex_unlock(&server.obj_freelist_mutex);
7838 return REDIS_ERR;
7839 }
7840 }
7841
7842 /* This function gets called when 'maxmemory' is set on the config file to limit
7843 * the max memory used by the server, and we are out of memory.
7844 * This function will try to, in order:
7845 *
7846 * - Free objects from the free list
7847 * - Try to remove keys with an EXPIRE set
7848 *
7849 * It is not possible to free enough memory to reach used-memory < maxmemory
7850 * the server will start refusing commands that will enlarge even more the
7851 * memory usage.
7852 */
7853 static void freeMemoryIfNeeded(void) {
7854 while (server.maxmemory && zmalloc_used_memory() > server.maxmemory) {
7855 int j, k, freed = 0;
7856
7857 if (tryFreeOneObjectFromFreelist() == REDIS_OK) continue;
7858 for (j = 0; j < server.dbnum; j++) {
7859 int minttl = -1;
7860 robj *minkey = NULL;
7861 struct dictEntry *de;
7862
7863 if (dictSize(server.db[j].expires)) {
7864 freed = 1;
7865 /* From a sample of three keys drop the one nearest to
7866 * the natural expire */
7867 for (k = 0; k < 3; k++) {
7868 time_t t;
7869
7870 de = dictGetRandomKey(server.db[j].expires);
7871 t = (time_t) dictGetEntryVal(de);
7872 if (minttl == -1 || t < minttl) {
7873 minkey = dictGetEntryKey(de);
7874 minttl = t;
7875 }
7876 }
7877 deleteKey(server.db+j,minkey);
7878 }
7879 }
7880 if (!freed) return; /* nothing to free... */
7881 }
7882 }
7883
7884 /* ============================== Append Only file ========================== */
7885
7886 static void feedAppendOnlyFile(struct redisCommand *cmd, int dictid, robj **argv, int argc) {
7887 sds buf = sdsempty();
7888 int j;
7889 ssize_t nwritten;
7890 time_t now;
7891 robj *tmpargv[3];
7892
7893 /* The DB this command was targetting is not the same as the last command
7894 * we appendend. To issue a SELECT command is needed. */
7895 if (dictid != server.appendseldb) {
7896 char seldb[64];
7897
7898 snprintf(seldb,sizeof(seldb),"%d",dictid);
7899 buf = sdscatprintf(buf,"*2\r\n$6\r\nSELECT\r\n$%lu\r\n%s\r\n",
7900 (unsigned long)strlen(seldb),seldb);
7901 server.appendseldb = dictid;
7902 }
7903
7904 /* "Fix" the argv vector if the command is EXPIRE. We want to translate
7905 * EXPIREs into EXPIREATs calls */
7906 if (cmd->proc == expireCommand) {
7907 long when;
7908
7909 tmpargv[0] = createStringObject("EXPIREAT",8);
7910 tmpargv[1] = argv[1];
7911 incrRefCount(argv[1]);
7912 when = time(NULL)+strtol(argv[2]->ptr,NULL,10);
7913 tmpargv[2] = createObject(REDIS_STRING,
7914 sdscatprintf(sdsempty(),"%ld",when));
7915 argv = tmpargv;
7916 }
7917
7918 /* Append the actual command */
7919 buf = sdscatprintf(buf,"*%d\r\n",argc);
7920 for (j = 0; j < argc; j++) {
7921 robj *o = argv[j];
7922
7923 o = getDecodedObject(o);
7924 buf = sdscatprintf(buf,"$%lu\r\n",(unsigned long)sdslen(o->ptr));
7925 buf = sdscatlen(buf,o->ptr,sdslen(o->ptr));
7926 buf = sdscatlen(buf,"\r\n",2);
7927 decrRefCount(o);
7928 }
7929
7930 /* Free the objects from the modified argv for EXPIREAT */
7931 if (cmd->proc == expireCommand) {
7932 for (j = 0; j < 3; j++)
7933 decrRefCount(argv[j]);
7934 }
7935
7936 /* We want to perform a single write. This should be guaranteed atomic
7937 * at least if the filesystem we are writing is a real physical one.
7938 * While this will save us against the server being killed I don't think
7939 * there is much to do about the whole server stopping for power problems
7940 * or alike */
7941 nwritten = write(server.appendfd,buf,sdslen(buf));
7942 if (nwritten != (signed)sdslen(buf)) {
7943 /* Ooops, we are in troubles. The best thing to do for now is
7944 * to simply exit instead to give the illusion that everything is
7945 * working as expected. */
7946 if (nwritten == -1) {
7947 redisLog(REDIS_WARNING,"Exiting on error writing to the append-only file: %s",strerror(errno));
7948 } else {
7949 redisLog(REDIS_WARNING,"Exiting on short write while writing to the append-only file: %s",strerror(errno));
7950 }
7951 exit(1);
7952 }
7953 /* If a background append only file rewriting is in progress we want to
7954 * accumulate the differences between the child DB and the current one
7955 * in a buffer, so that when the child process will do its work we
7956 * can append the differences to the new append only file. */
7957 if (server.bgrewritechildpid != -1)
7958 server.bgrewritebuf = sdscatlen(server.bgrewritebuf,buf,sdslen(buf));
7959
7960 sdsfree(buf);
7961 now = time(NULL);
7962 if (server.appendfsync == APPENDFSYNC_ALWAYS ||
7963 (server.appendfsync == APPENDFSYNC_EVERYSEC &&
7964 now-server.lastfsync > 1))
7965 {
7966 fsync(server.appendfd); /* Let's try to get this data on the disk */
7967 server.lastfsync = now;
7968 }
7969 }
7970
7971 /* In Redis commands are always executed in the context of a client, so in
7972 * order to load the append only file we need to create a fake client. */
7973 static struct redisClient *createFakeClient(void) {
7974 struct redisClient *c = zmalloc(sizeof(*c));
7975
7976 selectDb(c,0);
7977 c->fd = -1;
7978 c->querybuf = sdsempty();
7979 c->argc = 0;
7980 c->argv = NULL;
7981 c->flags = 0;
7982 /* We set the fake client as a slave waiting for the synchronization
7983 * so that Redis will not try to send replies to this client. */
7984 c->replstate = REDIS_REPL_WAIT_BGSAVE_START;
7985 c->reply = listCreate();
7986 listSetFreeMethod(c->reply,decrRefCount);
7987 listSetDupMethod(c->reply,dupClientReplyValue);
7988 return c;
7989 }
7990
7991 static void freeFakeClient(struct redisClient *c) {
7992 sdsfree(c->querybuf);
7993 listRelease(c->reply);
7994 zfree(c);
7995 }
7996
7997 /* Replay the append log file. On error REDIS_OK is returned. On non fatal
7998 * error (the append only file is zero-length) REDIS_ERR is returned. On
7999 * fatal error an error message is logged and the program exists. */
8000 int loadAppendOnlyFile(char *filename) {
8001 struct redisClient *fakeClient;
8002 FILE *fp = fopen(filename,"r");
8003 struct redis_stat sb;
8004 unsigned long long loadedkeys = 0;
8005
8006 if (redis_fstat(fileno(fp),&sb) != -1 && sb.st_size == 0)
8007 return REDIS_ERR;
8008
8009 if (fp == NULL) {
8010 redisLog(REDIS_WARNING,"Fatal error: can't open the append log file for reading: %s",strerror(errno));
8011 exit(1);
8012 }
8013
8014 fakeClient = createFakeClient();
8015 while(1) {
8016 int argc, j;
8017 unsigned long len;
8018 robj **argv;
8019 char buf[128];
8020 sds argsds;
8021 struct redisCommand *cmd;
8022
8023 if (fgets(buf,sizeof(buf),fp) == NULL) {
8024 if (feof(fp))
8025 break;
8026 else
8027 goto readerr;
8028 }
8029 if (buf[0] != '*') goto fmterr;
8030 argc = atoi(buf+1);
8031 argv = zmalloc(sizeof(robj*)*argc);
8032 for (j = 0; j < argc; j++) {
8033 if (fgets(buf,sizeof(buf),fp) == NULL) goto readerr;
8034 if (buf[0] != '$') goto fmterr;
8035 len = strtol(buf+1,NULL,10);
8036 argsds = sdsnewlen(NULL,len);
8037 if (len && fread(argsds,len,1,fp) == 0) goto fmterr;
8038 argv[j] = createObject(REDIS_STRING,argsds);
8039 if (fread(buf,2,1,fp) == 0) goto fmterr; /* discard CRLF */
8040 }
8041
8042 /* Command lookup */
8043 cmd = lookupCommand(argv[0]->ptr);
8044 if (!cmd) {
8045 redisLog(REDIS_WARNING,"Unknown command '%s' reading the append only file", argv[0]->ptr);
8046 exit(1);
8047 }
8048 /* Try object encoding */
8049 if (cmd->flags & REDIS_CMD_BULK)
8050 argv[argc-1] = tryObjectEncoding(argv[argc-1]);
8051 /* Run the command in the context of a fake client */
8052 fakeClient->argc = argc;
8053 fakeClient->argv = argv;
8054 cmd->proc(fakeClient);
8055 /* Discard the reply objects list from the fake client */
8056 while(listLength(fakeClient->reply))
8057 listDelNode(fakeClient->reply,listFirst(fakeClient->reply));
8058 /* Clean up, ready for the next command */
8059 for (j = 0; j < argc; j++) decrRefCount(argv[j]);
8060 zfree(argv);
8061 /* Handle swapping while loading big datasets when VM is on */
8062 loadedkeys++;
8063 if (server.vm_enabled && (loadedkeys % 5000) == 0) {
8064 while (zmalloc_used_memory() > server.vm_max_memory) {
8065 if (vmSwapOneObjectBlocking() == REDIS_ERR) break;
8066 }
8067 }
8068 }
8069 fclose(fp);
8070 freeFakeClient(fakeClient);
8071 return REDIS_OK;
8072
8073 readerr:
8074 if (feof(fp)) {
8075 redisLog(REDIS_WARNING,"Unexpected end of file reading the append only file");
8076 } else {
8077 redisLog(REDIS_WARNING,"Unrecoverable error reading the append only file: %s", strerror(errno));
8078 }
8079 exit(1);
8080 fmterr:
8081 redisLog(REDIS_WARNING,"Bad file format reading the append only file");
8082 exit(1);
8083 }
8084
8085 /* Write an object into a file in the bulk format $<count>\r\n<payload>\r\n */
8086 static int fwriteBulkObject(FILE *fp, robj *obj) {
8087 char buf[128];
8088 int decrrc = 0;
8089
8090 /* Avoid the incr/decr ref count business if possible to help
8091 * copy-on-write (we are often in a child process when this function
8092 * is called).
8093 * Also makes sure that key objects don't get incrRefCount-ed when VM
8094 * is enabled */
8095 if (obj->encoding != REDIS_ENCODING_RAW) {
8096 obj = getDecodedObject(obj);
8097 decrrc = 1;
8098 }
8099 snprintf(buf,sizeof(buf),"$%ld\r\n",(long)sdslen(obj->ptr));
8100 if (fwrite(buf,strlen(buf),1,fp) == 0) goto err;
8101 if (sdslen(obj->ptr) && fwrite(obj->ptr,sdslen(obj->ptr),1,fp) == 0)
8102 goto err;
8103 if (fwrite("\r\n",2,1,fp) == 0) goto err;
8104 if (decrrc) decrRefCount(obj);
8105 return 1;
8106 err:
8107 if (decrrc) decrRefCount(obj);
8108 return 0;
8109 }
8110
8111 /* Write binary-safe string into a file in the bulkformat
8112 * $<count>\r\n<payload>\r\n */
8113 static int fwriteBulkString(FILE *fp, char *s, unsigned long len) {
8114 char buf[128];
8115
8116 snprintf(buf,sizeof(buf),"$%ld\r\n",(unsigned long)len);
8117 if (fwrite(buf,strlen(buf),1,fp) == 0) return 0;
8118 if (len && fwrite(s,len,1,fp) == 0) return 0;
8119 if (fwrite("\r\n",2,1,fp) == 0) return 0;
8120 return 1;
8121 }
8122
8123 /* Write a double value in bulk format $<count>\r\n<payload>\r\n */
8124 static int fwriteBulkDouble(FILE *fp, double d) {
8125 char buf[128], dbuf[128];
8126
8127 snprintf(dbuf,sizeof(dbuf),"%.17g\r\n",d);
8128 snprintf(buf,sizeof(buf),"$%lu\r\n",(unsigned long)strlen(dbuf)-2);
8129 if (fwrite(buf,strlen(buf),1,fp) == 0) return 0;
8130 if (fwrite(dbuf,strlen(dbuf),1,fp) == 0) return 0;
8131 return 1;
8132 }
8133
8134 /* Write a long value in bulk format $<count>\r\n<payload>\r\n */
8135 static int fwriteBulkLong(FILE *fp, long l) {
8136 char buf[128], lbuf[128];
8137
8138 snprintf(lbuf,sizeof(lbuf),"%ld\r\n",l);
8139 snprintf(buf,sizeof(buf),"$%lu\r\n",(unsigned long)strlen(lbuf)-2);
8140 if (fwrite(buf,strlen(buf),1,fp) == 0) return 0;
8141 if (fwrite(lbuf,strlen(lbuf),1,fp) == 0) return 0;
8142 return 1;
8143 }
8144
8145 /* Write a sequence of commands able to fully rebuild the dataset into
8146 * "filename". Used both by REWRITEAOF and BGREWRITEAOF. */
8147 static int rewriteAppendOnlyFile(char *filename) {
8148 dictIterator *di = NULL;
8149 dictEntry *de;
8150 FILE *fp;
8151 char tmpfile[256];
8152 int j;
8153 time_t now = time(NULL);
8154
8155 /* Note that we have to use a different temp name here compared to the
8156 * one used by rewriteAppendOnlyFileBackground() function. */
8157 snprintf(tmpfile,256,"temp-rewriteaof-%d.aof", (int) getpid());
8158 fp = fopen(tmpfile,"w");
8159 if (!fp) {
8160 redisLog(REDIS_WARNING, "Failed rewriting the append only file: %s", strerror(errno));
8161 return REDIS_ERR;
8162 }
8163 for (j = 0; j < server.dbnum; j++) {
8164 char selectcmd[] = "*2\r\n$6\r\nSELECT\r\n";
8165 redisDb *db = server.db+j;
8166 dict *d = db->dict;
8167 if (dictSize(d) == 0) continue;
8168 di = dictGetIterator(d);
8169 if (!di) {
8170 fclose(fp);
8171 return REDIS_ERR;
8172 }
8173
8174 /* SELECT the new DB */
8175 if (fwrite(selectcmd,sizeof(selectcmd)-1,1,fp) == 0) goto werr;
8176 if (fwriteBulkLong(fp,j) == 0) goto werr;
8177
8178 /* Iterate this DB writing every entry */
8179 while((de = dictNext(di)) != NULL) {
8180 robj *key, *o;
8181 time_t expiretime;
8182 int swapped;
8183
8184 key = dictGetEntryKey(de);
8185 /* If the value for this key is swapped, load a preview in memory.
8186 * We use a "swapped" flag to remember if we need to free the
8187 * value object instead to just increment the ref count anyway
8188 * in order to avoid copy-on-write of pages if we are forked() */
8189 if (!server.vm_enabled || key->storage == REDIS_VM_MEMORY ||
8190 key->storage == REDIS_VM_SWAPPING) {
8191 o = dictGetEntryVal(de);
8192 swapped = 0;
8193 } else {
8194 o = vmPreviewObject(key);
8195 swapped = 1;
8196 }
8197 expiretime = getExpire(db,key);
8198
8199 /* Save the key and associated value */
8200 if (o->type == REDIS_STRING) {
8201 /* Emit a SET command */
8202 char cmd[]="*3\r\n$3\r\nSET\r\n";
8203 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8204 /* Key and value */
8205 if (fwriteBulkObject(fp,key) == 0) goto werr;
8206 if (fwriteBulkObject(fp,o) == 0) goto werr;
8207 } else if (o->type == REDIS_LIST) {
8208 /* Emit the RPUSHes needed to rebuild the list */
8209 list *list = o->ptr;
8210 listNode *ln;
8211 listIter li;
8212
8213 listRewind(list,&li);
8214 while((ln = listNext(&li))) {
8215 char cmd[]="*3\r\n$5\r\nRPUSH\r\n";
8216 robj *eleobj = listNodeValue(ln);
8217
8218 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8219 if (fwriteBulkObject(fp,key) == 0) goto werr;
8220 if (fwriteBulkObject(fp,eleobj) == 0) goto werr;
8221 }
8222 } else if (o->type == REDIS_SET) {
8223 /* Emit the SADDs needed to rebuild the set */
8224 dict *set = o->ptr;
8225 dictIterator *di = dictGetIterator(set);
8226 dictEntry *de;
8227
8228 while((de = dictNext(di)) != NULL) {
8229 char cmd[]="*3\r\n$4\r\nSADD\r\n";
8230 robj *eleobj = dictGetEntryKey(de);
8231
8232 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8233 if (fwriteBulkObject(fp,key) == 0) goto werr;
8234 if (fwriteBulkObject(fp,eleobj) == 0) goto werr;
8235 }
8236 dictReleaseIterator(di);
8237 } else if (o->type == REDIS_ZSET) {
8238 /* Emit the ZADDs needed to rebuild the sorted set */
8239 zset *zs = o->ptr;
8240 dictIterator *di = dictGetIterator(zs->dict);
8241 dictEntry *de;
8242
8243 while((de = dictNext(di)) != NULL) {
8244 char cmd[]="*4\r\n$4\r\nZADD\r\n";
8245 robj *eleobj = dictGetEntryKey(de);
8246 double *score = dictGetEntryVal(de);
8247
8248 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8249 if (fwriteBulkObject(fp,key) == 0) goto werr;
8250 if (fwriteBulkDouble(fp,*score) == 0) goto werr;
8251 if (fwriteBulkObject(fp,eleobj) == 0) goto werr;
8252 }
8253 dictReleaseIterator(di);
8254 } else if (o->type == REDIS_HASH) {
8255 char cmd[]="*4\r\n$4\r\nHSET\r\n";
8256
8257 /* Emit the HSETs needed to rebuild the hash */
8258 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
8259 unsigned char *p = zipmapRewind(o->ptr);
8260 unsigned char *field, *val;
8261 unsigned int flen, vlen;
8262
8263 while((p = zipmapNext(p,&field,&flen,&val,&vlen)) != NULL) {
8264 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8265 if (fwriteBulkObject(fp,key) == 0) goto werr;
8266 if (fwriteBulkString(fp,(char*)field,flen) == -1)
8267 return -1;
8268 if (fwriteBulkString(fp,(char*)val,vlen) == -1)
8269 return -1;
8270 }
8271 } else {
8272 dictIterator *di = dictGetIterator(o->ptr);
8273 dictEntry *de;
8274
8275 while((de = dictNext(di)) != NULL) {
8276 robj *field = dictGetEntryKey(de);
8277 robj *val = dictGetEntryVal(de);
8278
8279 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8280 if (fwriteBulkObject(fp,key) == 0) goto werr;
8281 if (fwriteBulkObject(fp,field) == -1) return -1;
8282 if (fwriteBulkObject(fp,val) == -1) return -1;
8283 }
8284 dictReleaseIterator(di);
8285 }
8286 } else {
8287 redisPanic("Unknown object type");
8288 }
8289 /* Save the expire time */
8290 if (expiretime != -1) {
8291 char cmd[]="*3\r\n$8\r\nEXPIREAT\r\n";
8292 /* If this key is already expired skip it */
8293 if (expiretime < now) continue;
8294 if (fwrite(cmd,sizeof(cmd)-1,1,fp) == 0) goto werr;
8295 if (fwriteBulkObject(fp,key) == 0) goto werr;
8296 if (fwriteBulkLong(fp,expiretime) == 0) goto werr;
8297 }
8298 if (swapped) decrRefCount(o);
8299 }
8300 dictReleaseIterator(di);
8301 }
8302
8303 /* Make sure data will not remain on the OS's output buffers */
8304 fflush(fp);
8305 fsync(fileno(fp));
8306 fclose(fp);
8307
8308 /* Use RENAME to make sure the DB file is changed atomically only
8309 * if the generate DB file is ok. */
8310 if (rename(tmpfile,filename) == -1) {
8311 redisLog(REDIS_WARNING,"Error moving temp append only file on the final destination: %s", strerror(errno));
8312 unlink(tmpfile);
8313 return REDIS_ERR;
8314 }
8315 redisLog(REDIS_NOTICE,"SYNC append only file rewrite performed");
8316 return REDIS_OK;
8317
8318 werr:
8319 fclose(fp);
8320 unlink(tmpfile);
8321 redisLog(REDIS_WARNING,"Write error writing append only file on disk: %s", strerror(errno));
8322 if (di) dictReleaseIterator(di);
8323 return REDIS_ERR;
8324 }
8325
8326 /* This is how rewriting of the append only file in background works:
8327 *
8328 * 1) The user calls BGREWRITEAOF
8329 * 2) Redis calls this function, that forks():
8330 * 2a) the child rewrite the append only file in a temp file.
8331 * 2b) the parent accumulates differences in server.bgrewritebuf.
8332 * 3) When the child finished '2a' exists.
8333 * 4) The parent will trap the exit code, if it's OK, will append the
8334 * data accumulated into server.bgrewritebuf into the temp file, and
8335 * finally will rename(2) the temp file in the actual file name.
8336 * The the new file is reopened as the new append only file. Profit!
8337 */
8338 static int rewriteAppendOnlyFileBackground(void) {
8339 pid_t childpid;
8340
8341 if (server.bgrewritechildpid != -1) return REDIS_ERR;
8342 if (server.vm_enabled) waitEmptyIOJobsQueue();
8343 if ((childpid = fork()) == 0) {
8344 /* Child */
8345 char tmpfile[256];
8346
8347 if (server.vm_enabled) vmReopenSwapFile();
8348 close(server.fd);
8349 snprintf(tmpfile,256,"temp-rewriteaof-bg-%d.aof", (int) getpid());
8350 if (rewriteAppendOnlyFile(tmpfile) == REDIS_OK) {
8351 _exit(0);
8352 } else {
8353 _exit(1);
8354 }
8355 } else {
8356 /* Parent */
8357 if (childpid == -1) {
8358 redisLog(REDIS_WARNING,
8359 "Can't rewrite append only file in background: fork: %s",
8360 strerror(errno));
8361 return REDIS_ERR;
8362 }
8363 redisLog(REDIS_NOTICE,
8364 "Background append only file rewriting started by pid %d",childpid);
8365 server.bgrewritechildpid = childpid;
8366 updateDictResizePolicy();
8367 /* We set appendseldb to -1 in order to force the next call to the
8368 * feedAppendOnlyFile() to issue a SELECT command, so the differences
8369 * accumulated by the parent into server.bgrewritebuf will start
8370 * with a SELECT statement and it will be safe to merge. */
8371 server.appendseldb = -1;
8372 return REDIS_OK;
8373 }
8374 return REDIS_OK; /* unreached */
8375 }
8376
8377 static void bgrewriteaofCommand(redisClient *c) {
8378 if (server.bgrewritechildpid != -1) {
8379 addReplySds(c,sdsnew("-ERR background append only file rewriting already in progress\r\n"));
8380 return;
8381 }
8382 if (rewriteAppendOnlyFileBackground() == REDIS_OK) {
8383 char *status = "+Background append only file rewriting started\r\n";
8384 addReplySds(c,sdsnew(status));
8385 } else {
8386 addReply(c,shared.err);
8387 }
8388 }
8389
8390 static void aofRemoveTempFile(pid_t childpid) {
8391 char tmpfile[256];
8392
8393 snprintf(tmpfile,256,"temp-rewriteaof-bg-%d.aof", (int) childpid);
8394 unlink(tmpfile);
8395 }
8396
8397 /* Virtual Memory is composed mainly of two subsystems:
8398 * - Blocking Virutal Memory
8399 * - Threaded Virtual Memory I/O
8400 * The two parts are not fully decoupled, but functions are split among two
8401 * different sections of the source code (delimited by comments) in order to
8402 * make more clear what functionality is about the blocking VM and what about
8403 * the threaded (not blocking) VM.
8404 *
8405 * Redis VM design:
8406 *
8407 * Redis VM is a blocking VM (one that blocks reading swapped values from
8408 * disk into memory when a value swapped out is needed in memory) that is made
8409 * unblocking by trying to examine the command argument vector in order to
8410 * load in background values that will likely be needed in order to exec
8411 * the command. The command is executed only once all the relevant keys
8412 * are loaded into memory.
8413 *
8414 * This basically is almost as simple of a blocking VM, but almost as parallel
8415 * as a fully non-blocking VM.
8416 */
8417
8418 /* =================== Virtual Memory - Blocking Side ====================== */
8419
8420 /* substitute the first occurrence of '%p' with the process pid in the
8421 * swap file name. */
8422 static void expandVmSwapFilename(void) {
8423 char *p = strstr(server.vm_swap_file,"%p");
8424 sds new;
8425
8426 if (!p) return;
8427 new = sdsempty();
8428 *p = '\0';
8429 new = sdscat(new,server.vm_swap_file);
8430 new = sdscatprintf(new,"%ld",(long) getpid());
8431 new = sdscat(new,p+2);
8432 zfree(server.vm_swap_file);
8433 server.vm_swap_file = new;
8434 }
8435
8436 static void vmInit(void) {
8437 off_t totsize;
8438 int pipefds[2];
8439 size_t stacksize;
8440
8441 if (server.vm_max_threads != 0)
8442 zmalloc_enable_thread_safeness(); /* we need thread safe zmalloc() */
8443
8444 expandVmSwapFilename();
8445 redisLog(REDIS_NOTICE,"Using '%s' as swap file",server.vm_swap_file);
8446 if ((server.vm_fp = fopen(server.vm_swap_file,"r+b")) == NULL) {
8447 server.vm_fp = fopen(server.vm_swap_file,"w+b");
8448 }
8449 if (server.vm_fp == NULL) {
8450 redisLog(REDIS_WARNING,
8451 "Impossible to open the swap file: %s. Exiting.",
8452 strerror(errno));
8453 exit(1);
8454 }
8455 server.vm_fd = fileno(server.vm_fp);
8456 server.vm_next_page = 0;
8457 server.vm_near_pages = 0;
8458 server.vm_stats_used_pages = 0;
8459 server.vm_stats_swapped_objects = 0;
8460 server.vm_stats_swapouts = 0;
8461 server.vm_stats_swapins = 0;
8462 totsize = server.vm_pages*server.vm_page_size;
8463 redisLog(REDIS_NOTICE,"Allocating %lld bytes of swap file",totsize);
8464 if (ftruncate(server.vm_fd,totsize) == -1) {
8465 redisLog(REDIS_WARNING,"Can't ftruncate swap file: %s. Exiting.",
8466 strerror(errno));
8467 exit(1);
8468 } else {
8469 redisLog(REDIS_NOTICE,"Swap file allocated with success");
8470 }
8471 server.vm_bitmap = zmalloc((server.vm_pages+7)/8);
8472 redisLog(REDIS_VERBOSE,"Allocated %lld bytes page table for %lld pages",
8473 (long long) (server.vm_pages+7)/8, server.vm_pages);
8474 memset(server.vm_bitmap,0,(server.vm_pages+7)/8);
8475
8476 /* Initialize threaded I/O (used by Virtual Memory) */
8477 server.io_newjobs = listCreate();
8478 server.io_processing = listCreate();
8479 server.io_processed = listCreate();
8480 server.io_ready_clients = listCreate();
8481 pthread_mutex_init(&server.io_mutex,NULL);
8482 pthread_mutex_init(&server.obj_freelist_mutex,NULL);
8483 pthread_mutex_init(&server.io_swapfile_mutex,NULL);
8484 server.io_active_threads = 0;
8485 if (pipe(pipefds) == -1) {
8486 redisLog(REDIS_WARNING,"Unable to intialized VM: pipe(2): %s. Exiting."
8487 ,strerror(errno));
8488 exit(1);
8489 }
8490 server.io_ready_pipe_read = pipefds[0];
8491 server.io_ready_pipe_write = pipefds[1];
8492 redisAssert(anetNonBlock(NULL,server.io_ready_pipe_read) != ANET_ERR);
8493 /* LZF requires a lot of stack */
8494 pthread_attr_init(&server.io_threads_attr);
8495 pthread_attr_getstacksize(&server.io_threads_attr, &stacksize);
8496 while (stacksize < REDIS_THREAD_STACK_SIZE) stacksize *= 2;
8497 pthread_attr_setstacksize(&server.io_threads_attr, stacksize);
8498 /* Listen for events in the threaded I/O pipe */
8499 if (aeCreateFileEvent(server.el, server.io_ready_pipe_read, AE_READABLE,
8500 vmThreadedIOCompletedJob, NULL) == AE_ERR)
8501 oom("creating file event");
8502 }
8503
8504 /* Mark the page as used */
8505 static void vmMarkPageUsed(off_t page) {
8506 off_t byte = page/8;
8507 int bit = page&7;
8508 redisAssert(vmFreePage(page) == 1);
8509 server.vm_bitmap[byte] |= 1<<bit;
8510 }
8511
8512 /* Mark N contiguous pages as used, with 'page' being the first. */
8513 static void vmMarkPagesUsed(off_t page, off_t count) {
8514 off_t j;
8515
8516 for (j = 0; j < count; j++)
8517 vmMarkPageUsed(page+j);
8518 server.vm_stats_used_pages += count;
8519 redisLog(REDIS_DEBUG,"Mark USED pages: %lld pages at %lld\n",
8520 (long long)count, (long long)page);
8521 }
8522
8523 /* Mark the page as free */
8524 static void vmMarkPageFree(off_t page) {
8525 off_t byte = page/8;
8526 int bit = page&7;
8527 redisAssert(vmFreePage(page) == 0);
8528 server.vm_bitmap[byte] &= ~(1<<bit);
8529 }
8530
8531 /* Mark N contiguous pages as free, with 'page' being the first. */
8532 static void vmMarkPagesFree(off_t page, off_t count) {
8533 off_t j;
8534
8535 for (j = 0; j < count; j++)
8536 vmMarkPageFree(page+j);
8537 server.vm_stats_used_pages -= count;
8538 redisLog(REDIS_DEBUG,"Mark FREE pages: %lld pages at %lld\n",
8539 (long long)count, (long long)page);
8540 }
8541
8542 /* Test if the page is free */
8543 static int vmFreePage(off_t page) {
8544 off_t byte = page/8;
8545 int bit = page&7;
8546 return (server.vm_bitmap[byte] & (1<<bit)) == 0;
8547 }
8548
8549 /* Find N contiguous free pages storing the first page of the cluster in *first.
8550 * Returns REDIS_OK if it was able to find N contiguous pages, otherwise
8551 * REDIS_ERR is returned.
8552 *
8553 * This function uses a simple algorithm: we try to allocate
8554 * REDIS_VM_MAX_NEAR_PAGES sequentially, when we reach this limit we start
8555 * again from the start of the swap file searching for free spaces.
8556 *
8557 * If it looks pretty clear that there are no free pages near our offset
8558 * we try to find less populated places doing a forward jump of
8559 * REDIS_VM_MAX_RANDOM_JUMP, then we start scanning again a few pages
8560 * without hurry, and then we jump again and so forth...
8561 *
8562 * This function can be improved using a free list to avoid to guess
8563 * too much, since we could collect data about freed pages.
8564 *
8565 * note: I implemented this function just after watching an episode of
8566 * Battlestar Galactica, where the hybrid was continuing to say "JUMP!"
8567 */
8568 static int vmFindContiguousPages(off_t *first, off_t n) {
8569 off_t base, offset = 0, since_jump = 0, numfree = 0;
8570
8571 if (server.vm_near_pages == REDIS_VM_MAX_NEAR_PAGES) {
8572 server.vm_near_pages = 0;
8573 server.vm_next_page = 0;
8574 }
8575 server.vm_near_pages++; /* Yet another try for pages near to the old ones */
8576 base = server.vm_next_page;
8577
8578 while(offset < server.vm_pages) {
8579 off_t this = base+offset;
8580
8581 /* If we overflow, restart from page zero */
8582 if (this >= server.vm_pages) {
8583 this -= server.vm_pages;
8584 if (this == 0) {
8585 /* Just overflowed, what we found on tail is no longer
8586 * interesting, as it's no longer contiguous. */
8587 numfree = 0;
8588 }
8589 }
8590 if (vmFreePage(this)) {
8591 /* This is a free page */
8592 numfree++;
8593 /* Already got N free pages? Return to the caller, with success */
8594 if (numfree == n) {
8595 *first = this-(n-1);
8596 server.vm_next_page = this+1;
8597 redisLog(REDIS_DEBUG, "FOUND CONTIGUOUS PAGES: %lld pages at %lld\n", (long long) n, (long long) *first);
8598 return REDIS_OK;
8599 }
8600 } else {
8601 /* The current one is not a free page */
8602 numfree = 0;
8603 }
8604
8605 /* Fast-forward if the current page is not free and we already
8606 * searched enough near this place. */
8607 since_jump++;
8608 if (!numfree && since_jump >= REDIS_VM_MAX_RANDOM_JUMP/4) {
8609 offset += random() % REDIS_VM_MAX_RANDOM_JUMP;
8610 since_jump = 0;
8611 /* Note that even if we rewind after the jump, we are don't need
8612 * to make sure numfree is set to zero as we only jump *if* it
8613 * is set to zero. */
8614 } else {
8615 /* Otherwise just check the next page */
8616 offset++;
8617 }
8618 }
8619 return REDIS_ERR;
8620 }
8621
8622 /* Write the specified object at the specified page of the swap file */
8623 static int vmWriteObjectOnSwap(robj *o, off_t page) {
8624 if (server.vm_enabled) pthread_mutex_lock(&server.io_swapfile_mutex);
8625 if (fseeko(server.vm_fp,page*server.vm_page_size,SEEK_SET) == -1) {
8626 if (server.vm_enabled) pthread_mutex_unlock(&server.io_swapfile_mutex);
8627 redisLog(REDIS_WARNING,
8628 "Critical VM problem in vmWriteObjectOnSwap(): can't seek: %s",
8629 strerror(errno));
8630 return REDIS_ERR;
8631 }
8632 rdbSaveObject(server.vm_fp,o);
8633 fflush(server.vm_fp);
8634 if (server.vm_enabled) pthread_mutex_unlock(&server.io_swapfile_mutex);
8635 return REDIS_OK;
8636 }
8637
8638 /* Swap the 'val' object relative to 'key' into disk. Store all the information
8639 * needed to later retrieve the object into the key object.
8640 * If we can't find enough contiguous empty pages to swap the object on disk
8641 * REDIS_ERR is returned. */
8642 static int vmSwapObjectBlocking(robj *key, robj *val) {
8643 off_t pages = rdbSavedObjectPages(val,NULL);
8644 off_t page;
8645
8646 assert(key->storage == REDIS_VM_MEMORY);
8647 assert(key->refcount == 1);
8648 if (vmFindContiguousPages(&page,pages) == REDIS_ERR) return REDIS_ERR;
8649 if (vmWriteObjectOnSwap(val,page) == REDIS_ERR) return REDIS_ERR;
8650 key->vm.page = page;
8651 key->vm.usedpages = pages;
8652 key->storage = REDIS_VM_SWAPPED;
8653 key->vtype = val->type;
8654 decrRefCount(val); /* Deallocate the object from memory. */
8655 vmMarkPagesUsed(page,pages);
8656 redisLog(REDIS_DEBUG,"VM: object %s swapped out at %lld (%lld pages)",
8657 (unsigned char*) key->ptr,
8658 (unsigned long long) page, (unsigned long long) pages);
8659 server.vm_stats_swapped_objects++;
8660 server.vm_stats_swapouts++;
8661 return REDIS_OK;
8662 }
8663
8664 static robj *vmReadObjectFromSwap(off_t page, int type) {
8665 robj *o;
8666
8667 if (server.vm_enabled) pthread_mutex_lock(&server.io_swapfile_mutex);
8668 if (fseeko(server.vm_fp,page*server.vm_page_size,SEEK_SET) == -1) {
8669 redisLog(REDIS_WARNING,
8670 "Unrecoverable VM problem in vmReadObjectFromSwap(): can't seek: %s",
8671 strerror(errno));
8672 _exit(1);
8673 }
8674 o = rdbLoadObject(type,server.vm_fp);
8675 if (o == NULL) {
8676 redisLog(REDIS_WARNING, "Unrecoverable VM problem in vmReadObjectFromSwap(): can't load object from swap file: %s", strerror(errno));
8677 _exit(1);
8678 }
8679 if (server.vm_enabled) pthread_mutex_unlock(&server.io_swapfile_mutex);
8680 return o;
8681 }
8682
8683 /* Load the value object relative to the 'key' object from swap to memory.
8684 * The newly allocated object is returned.
8685 *
8686 * If preview is true the unserialized object is returned to the caller but
8687 * no changes are made to the key object, nor the pages are marked as freed */
8688 static robj *vmGenericLoadObject(robj *key, int preview) {
8689 robj *val;
8690
8691 redisAssert(key->storage == REDIS_VM_SWAPPED || key->storage == REDIS_VM_LOADING);
8692 val = vmReadObjectFromSwap(key->vm.page,key->vtype);
8693 if (!preview) {
8694 key->storage = REDIS_VM_MEMORY;
8695 key->vm.atime = server.unixtime;
8696 vmMarkPagesFree(key->vm.page,key->vm.usedpages);
8697 redisLog(REDIS_DEBUG, "VM: object %s loaded from disk",
8698 (unsigned char*) key->ptr);
8699 server.vm_stats_swapped_objects--;
8700 } else {
8701 redisLog(REDIS_DEBUG, "VM: object %s previewed from disk",
8702 (unsigned char*) key->ptr);
8703 }
8704 server.vm_stats_swapins++;
8705 return val;
8706 }
8707
8708 /* Plain object loading, from swap to memory */
8709 static robj *vmLoadObject(robj *key) {
8710 /* If we are loading the object in background, stop it, we
8711 * need to load this object synchronously ASAP. */
8712 if (key->storage == REDIS_VM_LOADING)
8713 vmCancelThreadedIOJob(key);
8714 return vmGenericLoadObject(key,0);
8715 }
8716
8717 /* Just load the value on disk, without to modify the key.
8718 * This is useful when we want to perform some operation on the value
8719 * without to really bring it from swap to memory, like while saving the
8720 * dataset or rewriting the append only log. */
8721 static robj *vmPreviewObject(robj *key) {
8722 return vmGenericLoadObject(key,1);
8723 }
8724
8725 /* How a good candidate is this object for swapping?
8726 * The better candidate it is, the greater the returned value.
8727 *
8728 * Currently we try to perform a fast estimation of the object size in
8729 * memory, and combine it with aging informations.
8730 *
8731 * Basically swappability = idle-time * log(estimated size)
8732 *
8733 * Bigger objects are preferred over smaller objects, but not
8734 * proportionally, this is why we use the logarithm. This algorithm is
8735 * just a first try and will probably be tuned later. */
8736 static double computeObjectSwappability(robj *o) {
8737 time_t age = server.unixtime - o->vm.atime;
8738 long asize = 0;
8739 list *l;
8740 dict *d;
8741 struct dictEntry *de;
8742 int z;
8743
8744 if (age <= 0) return 0;
8745 switch(o->type) {
8746 case REDIS_STRING:
8747 if (o->encoding != REDIS_ENCODING_RAW) {
8748 asize = sizeof(*o);
8749 } else {
8750 asize = sdslen(o->ptr)+sizeof(*o)+sizeof(long)*2;
8751 }
8752 break;
8753 case REDIS_LIST:
8754 l = o->ptr;
8755 listNode *ln = listFirst(l);
8756
8757 asize = sizeof(list);
8758 if (ln) {
8759 robj *ele = ln->value;
8760 long elesize;
8761
8762 elesize = (ele->encoding == REDIS_ENCODING_RAW) ?
8763 (sizeof(*o)+sdslen(ele->ptr)) :
8764 sizeof(*o);
8765 asize += (sizeof(listNode)+elesize)*listLength(l);
8766 }
8767 break;
8768 case REDIS_SET:
8769 case REDIS_ZSET:
8770 z = (o->type == REDIS_ZSET);
8771 d = z ? ((zset*)o->ptr)->dict : o->ptr;
8772
8773 asize = sizeof(dict)+(sizeof(struct dictEntry*)*dictSlots(d));
8774 if (z) asize += sizeof(zset)-sizeof(dict);
8775 if (dictSize(d)) {
8776 long elesize;
8777 robj *ele;
8778
8779 de = dictGetRandomKey(d);
8780 ele = dictGetEntryKey(de);
8781 elesize = (ele->encoding == REDIS_ENCODING_RAW) ?
8782 (sizeof(*o)+sdslen(ele->ptr)) :
8783 sizeof(*o);
8784 asize += (sizeof(struct dictEntry)+elesize)*dictSize(d);
8785 if (z) asize += sizeof(zskiplistNode)*dictSize(d);
8786 }
8787 break;
8788 case REDIS_HASH:
8789 if (o->encoding == REDIS_ENCODING_ZIPMAP) {
8790 unsigned char *p = zipmapRewind((unsigned char*)o->ptr);
8791 unsigned int len = zipmapLen((unsigned char*)o->ptr);
8792 unsigned int klen, vlen;
8793 unsigned char *key, *val;
8794
8795 if ((p = zipmapNext(p,&key,&klen,&val,&vlen)) == NULL) {
8796 klen = 0;
8797 vlen = 0;
8798 }
8799 asize = len*(klen+vlen+3);
8800 } else if (o->encoding == REDIS_ENCODING_HT) {
8801 d = o->ptr;
8802 asize = sizeof(dict)+(sizeof(struct dictEntry*)*dictSlots(d));
8803 if (dictSize(d)) {
8804 long elesize;
8805 robj *ele;
8806
8807 de = dictGetRandomKey(d);
8808 ele = dictGetEntryKey(de);
8809 elesize = (ele->encoding == REDIS_ENCODING_RAW) ?
8810 (sizeof(*o)+sdslen(ele->ptr)) :
8811 sizeof(*o);
8812 ele = dictGetEntryVal(de);
8813 elesize = (ele->encoding == REDIS_ENCODING_RAW) ?
8814 (sizeof(*o)+sdslen(ele->ptr)) :
8815 sizeof(*o);
8816 asize += (sizeof(struct dictEntry)+elesize)*dictSize(d);
8817 }
8818 }
8819 break;
8820 }
8821 return (double)age*log(1+asize);
8822 }
8823
8824 /* Try to swap an object that's a good candidate for swapping.
8825 * Returns REDIS_OK if the object was swapped, REDIS_ERR if it's not possible
8826 * to swap any object at all.
8827 *
8828 * If 'usethreaded' is true, Redis will try to swap the object in background
8829 * using I/O threads. */
8830 static int vmSwapOneObject(int usethreads) {
8831 int j, i;
8832 struct dictEntry *best = NULL;
8833 double best_swappability = 0;
8834 redisDb *best_db = NULL;
8835 robj *key, *val;
8836
8837 for (j = 0; j < server.dbnum; j++) {
8838 redisDb *db = server.db+j;
8839 /* Why maxtries is set to 100?
8840 * Because this way (usually) we'll find 1 object even if just 1% - 2%
8841 * are swappable objects */
8842 int maxtries = 100;
8843
8844 if (dictSize(db->dict) == 0) continue;
8845 for (i = 0; i < 5; i++) {
8846 dictEntry *de;
8847 double swappability;
8848
8849 if (maxtries) maxtries--;
8850 de = dictGetRandomKey(db->dict);
8851 key = dictGetEntryKey(de);
8852 val = dictGetEntryVal(de);
8853 /* Only swap objects that are currently in memory.
8854 *
8855 * Also don't swap shared objects if threaded VM is on, as we
8856 * try to ensure that the main thread does not touch the
8857 * object while the I/O thread is using it, but we can't
8858 * control other keys without adding additional mutex. */
8859 if (key->storage != REDIS_VM_MEMORY ||
8860 (server.vm_max_threads != 0 && val->refcount != 1)) {
8861 if (maxtries) i--; /* don't count this try */
8862 continue;
8863 }
8864 swappability = computeObjectSwappability(val);
8865 if (!best || swappability > best_swappability) {
8866 best = de;
8867 best_swappability = swappability;
8868 best_db = db;
8869 }
8870 }
8871 }
8872 if (best == NULL) return REDIS_ERR;
8873 key = dictGetEntryKey(best);
8874 val = dictGetEntryVal(best);
8875
8876 redisLog(REDIS_DEBUG,"Key with best swappability: %s, %f",
8877 key->ptr, best_swappability);
8878
8879 /* Unshare the key if needed */
8880 if (key->refcount > 1) {
8881 robj *newkey = dupStringObject(key);
8882 decrRefCount(key);
8883 key = dictGetEntryKey(best) = newkey;
8884 }
8885 /* Swap it */
8886 if (usethreads) {
8887 vmSwapObjectThreaded(key,val,best_db);
8888 return REDIS_OK;
8889 } else {
8890 if (vmSwapObjectBlocking(key,val) == REDIS_OK) {
8891 dictGetEntryVal(best) = NULL;
8892 return REDIS_OK;
8893 } else {
8894 return REDIS_ERR;
8895 }
8896 }
8897 }
8898
8899 static int vmSwapOneObjectBlocking() {
8900 return vmSwapOneObject(0);
8901 }
8902
8903 static int vmSwapOneObjectThreaded() {
8904 return vmSwapOneObject(1);
8905 }
8906
8907 /* Return true if it's safe to swap out objects in a given moment.
8908 * Basically we don't want to swap objects out while there is a BGSAVE
8909 * or a BGAEOREWRITE running in backgroud. */
8910 static int vmCanSwapOut(void) {
8911 return (server.bgsavechildpid == -1 && server.bgrewritechildpid == -1);
8912 }
8913
8914 /* Delete a key if swapped. Returns 1 if the key was found, was swapped
8915 * and was deleted. Otherwise 0 is returned. */
8916 static int deleteIfSwapped(redisDb *db, robj *key) {
8917 dictEntry *de;
8918 robj *foundkey;
8919
8920 if ((de = dictFind(db->dict,key)) == NULL) return 0;
8921 foundkey = dictGetEntryKey(de);
8922 if (foundkey->storage == REDIS_VM_MEMORY) return 0;
8923 deleteKey(db,key);
8924 return 1;
8925 }
8926
8927 /* =================== Virtual Memory - Threaded I/O ======================= */
8928
8929 static void freeIOJob(iojob *j) {
8930 if ((j->type == REDIS_IOJOB_PREPARE_SWAP ||
8931 j->type == REDIS_IOJOB_DO_SWAP ||
8932 j->type == REDIS_IOJOB_LOAD) && j->val != NULL)
8933 decrRefCount(j->val);
8934 /* We don't decrRefCount the j->key field as we did't incremented
8935 * the count creating IO Jobs. This is because the key field here is
8936 * just used as an indentifier and if a key is removed the Job should
8937 * never be touched again. */
8938 zfree(j);
8939 }
8940
8941 /* Every time a thread finished a Job, it writes a byte into the write side
8942 * of an unix pipe in order to "awake" the main thread, and this function
8943 * is called. */
8944 static void vmThreadedIOCompletedJob(aeEventLoop *el, int fd, void *privdata,
8945 int mask)
8946 {
8947 char buf[1];
8948 int retval, processed = 0, toprocess = -1, trytoswap = 1;
8949 REDIS_NOTUSED(el);
8950 REDIS_NOTUSED(mask);
8951 REDIS_NOTUSED(privdata);
8952
8953 /* For every byte we read in the read side of the pipe, there is one
8954 * I/O job completed to process. */
8955 while((retval = read(fd,buf,1)) == 1) {
8956 iojob *j;
8957 listNode *ln;
8958 robj *key;
8959 struct dictEntry *de;
8960
8961 redisLog(REDIS_DEBUG,"Processing I/O completed job");
8962
8963 /* Get the processed element (the oldest one) */
8964 lockThreadedIO();
8965 assert(listLength(server.io_processed) != 0);
8966 if (toprocess == -1) {
8967 toprocess = (listLength(server.io_processed)*REDIS_MAX_COMPLETED_JOBS_PROCESSED)/100;
8968 if (toprocess <= 0) toprocess = 1;
8969 }
8970 ln = listFirst(server.io_processed);
8971 j = ln->value;
8972 listDelNode(server.io_processed,ln);
8973 unlockThreadedIO();
8974 /* If this job is marked as canceled, just ignore it */
8975 if (j->canceled) {
8976 freeIOJob(j);
8977 continue;
8978 }
8979 /* Post process it in the main thread, as there are things we
8980 * can do just here to avoid race conditions and/or invasive locks */
8981 redisLog(REDIS_DEBUG,"Job %p type: %d, key at %p (%s) refcount: %d\n", (void*) j, j->type, (void*)j->key, (char*)j->key->ptr, j->key->refcount);
8982 de = dictFind(j->db->dict,j->key);
8983 assert(de != NULL);
8984 key = dictGetEntryKey(de);
8985 if (j->type == REDIS_IOJOB_LOAD) {
8986 redisDb *db;
8987
8988 /* Key loaded, bring it at home */
8989 key->storage = REDIS_VM_MEMORY;
8990 key->vm.atime = server.unixtime;
8991 vmMarkPagesFree(key->vm.page,key->vm.usedpages);
8992 redisLog(REDIS_DEBUG, "VM: object %s loaded from disk (threaded)",
8993 (unsigned char*) key->ptr);
8994 server.vm_stats_swapped_objects--;
8995 server.vm_stats_swapins++;
8996 dictGetEntryVal(de) = j->val;
8997 incrRefCount(j->val);
8998 db = j->db;
8999 freeIOJob(j);
9000 /* Handle clients waiting for this key to be loaded. */
9001 handleClientsBlockedOnSwappedKey(db,key);
9002 } else if (j->type == REDIS_IOJOB_PREPARE_SWAP) {
9003 /* Now we know the amount of pages required to swap this object.
9004 * Let's find some space for it, and queue this task again
9005 * rebranded as REDIS_IOJOB_DO_SWAP. */
9006 if (!vmCanSwapOut() ||
9007 vmFindContiguousPages(&j->page,j->pages) == REDIS_ERR)
9008 {
9009 /* Ooops... no space or we can't swap as there is
9010 * a fork()ed Redis trying to save stuff on disk. */
9011 freeIOJob(j);
9012 key->storage = REDIS_VM_MEMORY; /* undo operation */
9013 } else {
9014 /* Note that we need to mark this pages as used now,
9015 * if the job will be canceled, we'll mark them as freed
9016 * again. */
9017 vmMarkPagesUsed(j->page,j->pages);
9018 j->type = REDIS_IOJOB_DO_SWAP;
9019 lockThreadedIO();
9020 queueIOJob(j);
9021 unlockThreadedIO();
9022 }
9023 } else if (j->type == REDIS_IOJOB_DO_SWAP) {
9024 robj *val;
9025
9026 /* Key swapped. We can finally free some memory. */
9027 if (key->storage != REDIS_VM_SWAPPING) {
9028 printf("key->storage: %d\n",key->storage);
9029 printf("key->name: %s\n",(char*)key->ptr);
9030 printf("key->refcount: %d\n",key->refcount);
9031 printf("val: %p\n",(void*)j->val);
9032 printf("val->type: %d\n",j->val->type);
9033 printf("val->ptr: %s\n",(char*)j->val->ptr);
9034 }
9035 redisAssert(key->storage == REDIS_VM_SWAPPING);
9036 val = dictGetEntryVal(de);
9037 key->vm.page = j->page;
9038 key->vm.usedpages = j->pages;
9039 key->storage = REDIS_VM_SWAPPED;
9040 key->vtype = j->val->type;
9041 decrRefCount(val); /* Deallocate the object from memory. */
9042 dictGetEntryVal(de) = NULL;
9043 redisLog(REDIS_DEBUG,
9044 "VM: object %s swapped out at %lld (%lld pages) (threaded)",
9045 (unsigned char*) key->ptr,
9046 (unsigned long long) j->page, (unsigned long long) j->pages);
9047 server.vm_stats_swapped_objects++;
9048 server.vm_stats_swapouts++;
9049 freeIOJob(j);
9050 /* Put a few more swap requests in queue if we are still
9051 * out of memory */
9052 if (trytoswap && vmCanSwapOut() &&
9053 zmalloc_used_memory() > server.vm_max_memory)
9054 {
9055 int more = 1;
9056 while(more) {
9057 lockThreadedIO();
9058 more = listLength(server.io_newjobs) <
9059 (unsigned) server.vm_max_threads;
9060 unlockThreadedIO();
9061 /* Don't waste CPU time if swappable objects are rare. */
9062 if (vmSwapOneObjectThreaded() == REDIS_ERR) {
9063 trytoswap = 0;
9064 break;
9065 }
9066 }
9067 }
9068 }
9069 processed++;
9070 if (processed == toprocess) return;
9071 }
9072 if (retval < 0 && errno != EAGAIN) {
9073 redisLog(REDIS_WARNING,
9074 "WARNING: read(2) error in vmThreadedIOCompletedJob() %s",
9075 strerror(errno));
9076 }
9077 }
9078
9079 static void lockThreadedIO(void) {
9080 pthread_mutex_lock(&server.io_mutex);
9081 }
9082
9083 static void unlockThreadedIO(void) {
9084 pthread_mutex_unlock(&server.io_mutex);
9085 }
9086
9087 /* Remove the specified object from the threaded I/O queue if still not
9088 * processed, otherwise make sure to flag it as canceled. */
9089 static void vmCancelThreadedIOJob(robj *o) {
9090 list *lists[3] = {
9091 server.io_newjobs, /* 0 */
9092 server.io_processing, /* 1 */
9093 server.io_processed /* 2 */
9094 };
9095 int i;
9096
9097 assert(o->storage == REDIS_VM_LOADING || o->storage == REDIS_VM_SWAPPING);
9098 again:
9099 lockThreadedIO();
9100 /* Search for a matching key in one of the queues */
9101 for (i = 0; i < 3; i++) {
9102 listNode *ln;
9103 listIter li;
9104
9105 listRewind(lists[i],&li);
9106 while ((ln = listNext(&li)) != NULL) {
9107 iojob *job = ln->value;
9108
9109 if (job->canceled) continue; /* Skip this, already canceled. */
9110 if (job->key == o) {
9111 redisLog(REDIS_DEBUG,"*** CANCELED %p (%s) (type %d) (LIST ID %d)\n",
9112 (void*)job, (char*)o->ptr, job->type, i);
9113 /* Mark the pages as free since the swap didn't happened
9114 * or happened but is now discarded. */
9115 if (i != 1 && job->type == REDIS_IOJOB_DO_SWAP)
9116 vmMarkPagesFree(job->page,job->pages);
9117 /* Cancel the job. It depends on the list the job is
9118 * living in. */
9119 switch(i) {
9120 case 0: /* io_newjobs */
9121 /* If the job was yet not processed the best thing to do
9122 * is to remove it from the queue at all */
9123 freeIOJob(job);
9124 listDelNode(lists[i],ln);
9125 break;
9126 case 1: /* io_processing */
9127 /* Oh Shi- the thread is messing with the Job:
9128 *
9129 * Probably it's accessing the object if this is a
9130 * PREPARE_SWAP or DO_SWAP job.
9131 * If it's a LOAD job it may be reading from disk and
9132 * if we don't wait for the job to terminate before to
9133 * cancel it, maybe in a few microseconds data can be
9134 * corrupted in this pages. So the short story is:
9135 *
9136 * Better to wait for the job to move into the
9137 * next queue (processed)... */
9138
9139 /* We try again and again until the job is completed. */
9140 unlockThreadedIO();
9141 /* But let's wait some time for the I/O thread
9142 * to finish with this job. After all this condition
9143 * should be very rare. */
9144 usleep(1);
9145 goto again;
9146 case 2: /* io_processed */
9147 /* The job was already processed, that's easy...
9148 * just mark it as canceled so that we'll ignore it
9149 * when processing completed jobs. */
9150 job->canceled = 1;
9151 break;
9152 }
9153 /* Finally we have to adjust the storage type of the object
9154 * in order to "UNDO" the operaiton. */
9155 if (o->storage == REDIS_VM_LOADING)
9156 o->storage = REDIS_VM_SWAPPED;
9157 else if (o->storage == REDIS_VM_SWAPPING)
9158 o->storage = REDIS_VM_MEMORY;
9159 unlockThreadedIO();
9160 return;
9161 }
9162 }
9163 }
9164 unlockThreadedIO();
9165 assert(1 != 1); /* We should never reach this */
9166 }
9167
9168 static void *IOThreadEntryPoint(void *arg) {
9169 iojob *j;
9170 listNode *ln;
9171 REDIS_NOTUSED(arg);
9172
9173 pthread_detach(pthread_self());
9174 while(1) {
9175 /* Get a new job to process */
9176 lockThreadedIO();
9177 if (listLength(server.io_newjobs) == 0) {
9178 /* No new jobs in queue, exit. */
9179 redisLog(REDIS_DEBUG,"Thread %ld exiting, nothing to do",
9180 (long) pthread_self());
9181 server.io_active_threads--;
9182 unlockThreadedIO();
9183 return NULL;
9184 }
9185 ln = listFirst(server.io_newjobs);
9186 j = ln->value;
9187 listDelNode(server.io_newjobs,ln);
9188 /* Add the job in the processing queue */
9189 j->thread = pthread_self();
9190 listAddNodeTail(server.io_processing,j);
9191 ln = listLast(server.io_processing); /* We use ln later to remove it */
9192 unlockThreadedIO();
9193 redisLog(REDIS_DEBUG,"Thread %ld got a new job (type %d): %p about key '%s'",
9194 (long) pthread_self(), j->type, (void*)j, (char*)j->key->ptr);
9195
9196 /* Process the Job */
9197 if (j->type == REDIS_IOJOB_LOAD) {
9198 j->val = vmReadObjectFromSwap(j->page,j->key->vtype);
9199 } else if (j->type == REDIS_IOJOB_PREPARE_SWAP) {
9200 FILE *fp = fopen("/dev/null","w+");
9201 j->pages = rdbSavedObjectPages(j->val,fp);
9202 fclose(fp);
9203 } else if (j->type == REDIS_IOJOB_DO_SWAP) {
9204 if (vmWriteObjectOnSwap(j->val,j->page) == REDIS_ERR)
9205 j->canceled = 1;
9206 }
9207
9208 /* Done: insert the job into the processed queue */
9209 redisLog(REDIS_DEBUG,"Thread %ld completed the job: %p (key %s)",
9210 (long) pthread_self(), (void*)j, (char*)j->key->ptr);
9211 lockThreadedIO();
9212 listDelNode(server.io_processing,ln);
9213 listAddNodeTail(server.io_processed,j);
9214 unlockThreadedIO();
9215
9216 /* Signal the main thread there is new stuff to process */
9217 assert(write(server.io_ready_pipe_write,"x",1) == 1);
9218 }
9219 return NULL; /* never reached */
9220 }
9221
9222 static void spawnIOThread(void) {
9223 pthread_t thread;
9224 sigset_t mask, omask;
9225 int err;
9226
9227 sigemptyset(&mask);
9228 sigaddset(&mask,SIGCHLD);
9229 sigaddset(&mask,SIGHUP);
9230 sigaddset(&mask,SIGPIPE);
9231 pthread_sigmask(SIG_SETMASK, &mask, &omask);
9232 while ((err = pthread_create(&thread,&server.io_threads_attr,IOThreadEntryPoint,NULL)) != 0) {
9233 redisLog(REDIS_WARNING,"Unable to spawn an I/O thread: %s",
9234 strerror(err));
9235 usleep(1000000);
9236 }
9237 pthread_sigmask(SIG_SETMASK, &omask, NULL);
9238 server.io_active_threads++;
9239 }
9240
9241 /* We need to wait for the last thread to exit before we are able to
9242 * fork() in order to BGSAVE or BGREWRITEAOF. */
9243 static void waitEmptyIOJobsQueue(void) {
9244 while(1) {
9245 int io_processed_len;
9246
9247 lockThreadedIO();
9248 if (listLength(server.io_newjobs) == 0 &&
9249 listLength(server.io_processing) == 0 &&
9250 server.io_active_threads == 0)
9251 {
9252 unlockThreadedIO();
9253 return;
9254 }
9255 /* While waiting for empty jobs queue condition we post-process some
9256 * finshed job, as I/O threads may be hanging trying to write against
9257 * the io_ready_pipe_write FD but there are so much pending jobs that
9258 * it's blocking. */
9259 io_processed_len = listLength(server.io_processed);
9260 unlockThreadedIO();
9261 if (io_processed_len) {
9262 vmThreadedIOCompletedJob(NULL,server.io_ready_pipe_read,NULL,0);
9263 usleep(1000); /* 1 millisecond */
9264 } else {
9265 usleep(10000); /* 10 milliseconds */
9266 }
9267 }
9268 }
9269
9270 static void vmReopenSwapFile(void) {
9271 /* Note: we don't close the old one as we are in the child process
9272 * and don't want to mess at all with the original file object. */
9273 server.vm_fp = fopen(server.vm_swap_file,"r+b");
9274 if (server.vm_fp == NULL) {
9275 redisLog(REDIS_WARNING,"Can't re-open the VM swap file: %s. Exiting.",
9276 server.vm_swap_file);
9277 _exit(1);
9278 }
9279 server.vm_fd = fileno(server.vm_fp);
9280 }
9281
9282 /* This function must be called while with threaded IO locked */
9283 static void queueIOJob(iojob *j) {
9284 redisLog(REDIS_DEBUG,"Queued IO Job %p type %d about key '%s'\n",
9285 (void*)j, j->type, (char*)j->key->ptr);
9286 listAddNodeTail(server.io_newjobs,j);
9287 if (server.io_active_threads < server.vm_max_threads)
9288 spawnIOThread();
9289 }
9290
9291 static int vmSwapObjectThreaded(robj *key, robj *val, redisDb *db) {
9292 iojob *j;
9293
9294 assert(key->storage == REDIS_VM_MEMORY);
9295 assert(key->refcount == 1);
9296
9297 j = zmalloc(sizeof(*j));
9298 j->type = REDIS_IOJOB_PREPARE_SWAP;
9299 j->db = db;
9300 j->key = key;
9301 j->val = val;
9302 incrRefCount(val);
9303 j->canceled = 0;
9304 j->thread = (pthread_t) -1;
9305 key->storage = REDIS_VM_SWAPPING;
9306
9307 lockThreadedIO();
9308 queueIOJob(j);
9309 unlockThreadedIO();
9310 return REDIS_OK;
9311 }
9312
9313 /* ============ Virtual Memory - Blocking clients on missing keys =========== */
9314
9315 /* This function makes the clinet 'c' waiting for the key 'key' to be loaded.
9316 * If there is not already a job loading the key, it is craeted.
9317 * The key is added to the io_keys list in the client structure, and also
9318 * in the hash table mapping swapped keys to waiting clients, that is,
9319 * server.io_waited_keys. */
9320 static int waitForSwappedKey(redisClient *c, robj *key) {
9321 struct dictEntry *de;
9322 robj *o;
9323 list *l;
9324
9325 /* If the key does not exist or is already in RAM we don't need to
9326 * block the client at all. */
9327 de = dictFind(c->db->dict,key);
9328 if (de == NULL) return 0;
9329 o = dictGetEntryKey(de);
9330 if (o->storage == REDIS_VM_MEMORY) {
9331 return 0;
9332 } else if (o->storage == REDIS_VM_SWAPPING) {
9333 /* We were swapping the key, undo it! */
9334 vmCancelThreadedIOJob(o);
9335 return 0;
9336 }
9337
9338 /* OK: the key is either swapped, or being loaded just now. */
9339
9340 /* Add the key to the list of keys this client is waiting for.
9341 * This maps clients to keys they are waiting for. */
9342 listAddNodeTail(c->io_keys,key);
9343 incrRefCount(key);
9344
9345 /* Add the client to the swapped keys => clients waiting map. */
9346 de = dictFind(c->db->io_keys,key);
9347 if (de == NULL) {
9348 int retval;
9349
9350 /* For every key we take a list of clients blocked for it */
9351 l = listCreate();
9352 retval = dictAdd(c->db->io_keys,key,l);
9353 incrRefCount(key);
9354 assert(retval == DICT_OK);
9355 } else {
9356 l = dictGetEntryVal(de);
9357 }
9358 listAddNodeTail(l,c);
9359
9360 /* Are we already loading the key from disk? If not create a job */
9361 if (o->storage == REDIS_VM_SWAPPED) {
9362 iojob *j;
9363
9364 o->storage = REDIS_VM_LOADING;
9365 j = zmalloc(sizeof(*j));
9366 j->type = REDIS_IOJOB_LOAD;
9367 j->db = c->db;
9368 j->key = o;
9369 j->key->vtype = o->vtype;
9370 j->page = o->vm.page;
9371 j->val = NULL;
9372 j->canceled = 0;
9373 j->thread = (pthread_t) -1;
9374 lockThreadedIO();
9375 queueIOJob(j);
9376 unlockThreadedIO();
9377 }
9378 return 1;
9379 }
9380
9381 /* Preload keys needed for the ZUNION and ZINTER commands. */
9382 static void zunionInterBlockClientOnSwappedKeys(redisClient *c) {
9383 int i, num;
9384 num = atoi(c->argv[2]->ptr);
9385 for (i = 0; i < num; i++) {
9386 waitForSwappedKey(c,c->argv[3+i]);
9387 }
9388 }
9389
9390 /* Is this client attempting to run a command against swapped keys?
9391 * If so, block it ASAP, load the keys in background, then resume it.
9392 *
9393 * The important idea about this function is that it can fail! If keys will
9394 * still be swapped when the client is resumed, this key lookups will
9395 * just block loading keys from disk. In practical terms this should only
9396 * happen with SORT BY command or if there is a bug in this function.
9397 *
9398 * Return 1 if the client is marked as blocked, 0 if the client can
9399 * continue as the keys it is going to access appear to be in memory. */
9400 static int blockClientOnSwappedKeys(struct redisCommand *cmd, redisClient *c) {
9401 int j, last;
9402
9403 if (cmd->vm_preload_proc != NULL) {
9404 cmd->vm_preload_proc(c);
9405 } else {
9406 if (cmd->vm_firstkey == 0) return 0;
9407 last = cmd->vm_lastkey;
9408 if (last < 0) last = c->argc+last;
9409 for (j = cmd->vm_firstkey; j <= last; j += cmd->vm_keystep)
9410 waitForSwappedKey(c,c->argv[j]);
9411 }
9412
9413 /* If the client was blocked for at least one key, mark it as blocked. */
9414 if (listLength(c->io_keys)) {
9415 c->flags |= REDIS_IO_WAIT;
9416 aeDeleteFileEvent(server.el,c->fd,AE_READABLE);
9417 server.vm_blocked_clients++;
9418 return 1;
9419 } else {
9420 return 0;
9421 }
9422 }
9423
9424 /* Remove the 'key' from the list of blocked keys for a given client.
9425 *
9426 * The function returns 1 when there are no longer blocking keys after
9427 * the current one was removed (and the client can be unblocked). */
9428 static int dontWaitForSwappedKey(redisClient *c, robj *key) {
9429 list *l;
9430 listNode *ln;
9431 listIter li;
9432 struct dictEntry *de;
9433
9434 /* Remove the key from the list of keys this client is waiting for. */
9435 listRewind(c->io_keys,&li);
9436 while ((ln = listNext(&li)) != NULL) {
9437 if (compareStringObjects(ln->value,key) == 0) {
9438 listDelNode(c->io_keys,ln);
9439 break;
9440 }
9441 }
9442 assert(ln != NULL);
9443
9444 /* Remove the client form the key => waiting clients map. */
9445 de = dictFind(c->db->io_keys,key);
9446 assert(de != NULL);
9447 l = dictGetEntryVal(de);
9448 ln = listSearchKey(l,c);
9449 assert(ln != NULL);
9450 listDelNode(l,ln);
9451 if (listLength(l) == 0)
9452 dictDelete(c->db->io_keys,key);
9453
9454 return listLength(c->io_keys) == 0;
9455 }
9456
9457 static void handleClientsBlockedOnSwappedKey(redisDb *db, robj *key) {
9458 struct dictEntry *de;
9459 list *l;
9460 listNode *ln;
9461 int len;
9462
9463 de = dictFind(db->io_keys,key);
9464 if (!de) return;
9465
9466 l = dictGetEntryVal(de);
9467 len = listLength(l);
9468 /* Note: we can't use something like while(listLength(l)) as the list
9469 * can be freed by the calling function when we remove the last element. */
9470 while (len--) {
9471 ln = listFirst(l);
9472 redisClient *c = ln->value;
9473
9474 if (dontWaitForSwappedKey(c,key)) {
9475 /* Put the client in the list of clients ready to go as we
9476 * loaded all the keys about it. */
9477 listAddNodeTail(server.io_ready_clients,c);
9478 }
9479 }
9480 }
9481
9482 /* =========================== Remote Configuration ========================= */
9483
9484 static void configSetCommand(redisClient *c) {
9485 robj *o = getDecodedObject(c->argv[3]);
9486 if (!strcasecmp(c->argv[2]->ptr,"dbfilename")) {
9487 zfree(server.dbfilename);
9488 server.dbfilename = zstrdup(o->ptr);
9489 } else if (!strcasecmp(c->argv[2]->ptr,"requirepass")) {
9490 zfree(server.requirepass);
9491 server.requirepass = zstrdup(o->ptr);
9492 } else if (!strcasecmp(c->argv[2]->ptr,"masterauth")) {
9493 zfree(server.masterauth);
9494 server.masterauth = zstrdup(o->ptr);
9495 } else if (!strcasecmp(c->argv[2]->ptr,"maxmemory")) {
9496 server.maxmemory = strtoll(o->ptr, NULL, 10);
9497 } else {
9498 addReplySds(c,sdscatprintf(sdsempty(),
9499 "-ERR not supported CONFIG parameter %s\r\n",
9500 (char*)c->argv[2]->ptr));
9501 decrRefCount(o);
9502 return;
9503 }
9504 decrRefCount(o);
9505 addReply(c,shared.ok);
9506 }
9507
9508 static void configGetCommand(redisClient *c) {
9509 robj *o = getDecodedObject(c->argv[2]);
9510 robj *lenobj = createObject(REDIS_STRING,NULL);
9511 char *pattern = o->ptr;
9512 int matches = 0;
9513
9514 addReply(c,lenobj);
9515 decrRefCount(lenobj);
9516
9517 if (stringmatch(pattern,"dbfilename",0)) {
9518 addReplyBulkCString(c,"dbfilename");
9519 addReplyBulkCString(c,server.dbfilename);
9520 matches++;
9521 }
9522 if (stringmatch(pattern,"requirepass",0)) {
9523 addReplyBulkCString(c,"requirepass");
9524 addReplyBulkCString(c,server.requirepass);
9525 matches++;
9526 }
9527 if (stringmatch(pattern,"masterauth",0)) {
9528 addReplyBulkCString(c,"masterauth");
9529 addReplyBulkCString(c,server.masterauth);
9530 matches++;
9531 }
9532 if (stringmatch(pattern,"maxmemory",0)) {
9533 char buf[128];
9534
9535 snprintf(buf,128,"%llu\n",server.maxmemory);
9536 addReplyBulkCString(c,"maxmemory");
9537 addReplyBulkCString(c,buf);
9538 matches++;
9539 }
9540 decrRefCount(o);
9541 lenobj->ptr = sdscatprintf(sdsempty(),"*%d\r\n",matches*2);
9542 }
9543
9544 static void configCommand(redisClient *c) {
9545 if (!strcasecmp(c->argv[1]->ptr,"set")) {
9546 if (c->argc != 4) goto badarity;
9547 configSetCommand(c);
9548 } else if (!strcasecmp(c->argv[1]->ptr,"get")) {
9549 if (c->argc != 3) goto badarity;
9550 configGetCommand(c);
9551 } else if (!strcasecmp(c->argv[1]->ptr,"resetstat")) {
9552 if (c->argc != 2) goto badarity;
9553 server.stat_numcommands = 0;
9554 server.stat_numconnections = 0;
9555 server.stat_expiredkeys = 0;
9556 server.stat_starttime = time(NULL);
9557 addReply(c,shared.ok);
9558 } else {
9559 addReplySds(c,sdscatprintf(sdsempty(),
9560 "-ERR CONFIG subcommand must be one of GET, SET, RESETSTAT\r\n"));
9561 }
9562 return;
9563
9564 badarity:
9565 addReplySds(c,sdscatprintf(sdsempty(),
9566 "-ERR Wrong number of arguments for CONFIG %s\r\n",
9567 (char*) c->argv[1]->ptr));
9568 }
9569
9570 /* =========================== Pubsub implementation ======================== */
9571
9572 static void freePubsubPattern(void *p) {
9573 pubsubPattern *pat = p;
9574
9575 decrRefCount(pat->pattern);
9576 zfree(pat);
9577 }
9578
9579 static int listMatchPubsubPattern(void *a, void *b) {
9580 pubsubPattern *pa = a, *pb = b;
9581
9582 return (pa->client == pb->client) &&
9583 (compareStringObjects(pa->pattern,pb->pattern) == 0);
9584 }
9585
9586 /* Subscribe a client to a channel. Returns 1 if the operation succeeded, or
9587 * 0 if the client was already subscribed to that channel. */
9588 static int pubsubSubscribeChannel(redisClient *c, robj *channel) {
9589 struct dictEntry *de;
9590 list *clients = NULL;
9591 int retval = 0;
9592
9593 /* Add the channel to the client -> channels hash table */
9594 if (dictAdd(c->pubsub_channels,channel,NULL) == DICT_OK) {
9595 retval = 1;
9596 incrRefCount(channel);
9597 /* Add the client to the channel -> list of clients hash table */
9598 de = dictFind(server.pubsub_channels,channel);
9599 if (de == NULL) {
9600 clients = listCreate();
9601 dictAdd(server.pubsub_channels,channel,clients);
9602 incrRefCount(channel);
9603 } else {
9604 clients = dictGetEntryVal(de);
9605 }
9606 listAddNodeTail(clients,c);
9607 }
9608 /* Notify the client */
9609 addReply(c,shared.mbulk3);
9610 addReply(c,shared.subscribebulk);
9611 addReplyBulk(c,channel);
9612 addReplyLong(c,dictSize(c->pubsub_channels)+listLength(c->pubsub_patterns));
9613 return retval;
9614 }
9615
9616 /* Unsubscribe a client from a channel. Returns 1 if the operation succeeded, or
9617 * 0 if the client was not subscribed to the specified channel. */
9618 static int pubsubUnsubscribeChannel(redisClient *c, robj *channel, int notify) {
9619 struct dictEntry *de;
9620 list *clients;
9621 listNode *ln;
9622 int retval = 0;
9623
9624 /* Remove the channel from the client -> channels hash table */
9625 incrRefCount(channel); /* channel may be just a pointer to the same object
9626 we have in the hash tables. Protect it... */
9627 if (dictDelete(c->pubsub_channels,channel) == DICT_OK) {
9628 retval = 1;
9629 /* Remove the client from the channel -> clients list hash table */
9630 de = dictFind(server.pubsub_channels,channel);
9631 assert(de != NULL);
9632 clients = dictGetEntryVal(de);
9633 ln = listSearchKey(clients,c);
9634 assert(ln != NULL);
9635 listDelNode(clients,ln);
9636 if (listLength(clients) == 0) {
9637 /* Free the list and associated hash entry at all if this was
9638 * the latest client, so that it will be possible to abuse
9639 * Redis PUBSUB creating millions of channels. */
9640 dictDelete(server.pubsub_channels,channel);
9641 }
9642 }
9643 /* Notify the client */
9644 if (notify) {
9645 addReply(c,shared.mbulk3);
9646 addReply(c,shared.unsubscribebulk);
9647 addReplyBulk(c,channel);
9648 addReplyLong(c,dictSize(c->pubsub_channels)+
9649 listLength(c->pubsub_patterns));
9650
9651 }
9652 decrRefCount(channel); /* it is finally safe to release it */
9653 return retval;
9654 }
9655
9656 /* Subscribe a client to a pattern. Returns 1 if the operation succeeded, or 0 if the clinet was already subscribed to that pattern. */
9657 static int pubsubSubscribePattern(redisClient *c, robj *pattern) {
9658 int retval = 0;
9659
9660 if (listSearchKey(c->pubsub_patterns,pattern) == NULL) {
9661 retval = 1;
9662 pubsubPattern *pat;
9663 listAddNodeTail(c->pubsub_patterns,pattern);
9664 incrRefCount(pattern);
9665 pat = zmalloc(sizeof(*pat));
9666 pat->pattern = getDecodedObject(pattern);
9667 pat->client = c;
9668 listAddNodeTail(server.pubsub_patterns,pat);
9669 }
9670 /* Notify the client */
9671 addReply(c,shared.mbulk3);
9672 addReply(c,shared.psubscribebulk);
9673 addReplyBulk(c,pattern);
9674 addReplyLong(c,dictSize(c->pubsub_channels)+listLength(c->pubsub_patterns));
9675 return retval;
9676 }
9677
9678 /* Unsubscribe a client from a channel. Returns 1 if the operation succeeded, or
9679 * 0 if the client was not subscribed to the specified channel. */
9680 static int pubsubUnsubscribePattern(redisClient *c, robj *pattern, int notify) {
9681 listNode *ln;
9682 pubsubPattern pat;
9683 int retval = 0;
9684
9685 incrRefCount(pattern); /* Protect the object. May be the same we remove */
9686 if ((ln = listSearchKey(c->pubsub_patterns,pattern)) != NULL) {
9687 retval = 1;
9688 listDelNode(c->pubsub_patterns,ln);
9689 pat.client = c;
9690 pat.pattern = pattern;
9691 ln = listSearchKey(server.pubsub_patterns,&pat);
9692 listDelNode(server.pubsub_patterns,ln);
9693 }
9694 /* Notify the client */
9695 if (notify) {
9696 addReply(c,shared.mbulk3);
9697 addReply(c,shared.punsubscribebulk);
9698 addReplyBulk(c,pattern);
9699 addReplyLong(c,dictSize(c->pubsub_channels)+
9700 listLength(c->pubsub_patterns));
9701 }
9702 decrRefCount(pattern);
9703 return retval;
9704 }
9705
9706 /* Unsubscribe from all the channels. Return the number of channels the
9707 * client was subscribed from. */
9708 static int pubsubUnsubscribeAllChannels(redisClient *c, int notify) {
9709 dictIterator *di = dictGetIterator(c->pubsub_channels);
9710 dictEntry *de;
9711 int count = 0;
9712
9713 while((de = dictNext(di)) != NULL) {
9714 robj *channel = dictGetEntryKey(de);
9715
9716 count += pubsubUnsubscribeChannel(c,channel,notify);
9717 }
9718 dictReleaseIterator(di);
9719 return count;
9720 }
9721
9722 /* Unsubscribe from all the patterns. Return the number of patterns the
9723 * client was subscribed from. */
9724 static int pubsubUnsubscribeAllPatterns(redisClient *c, int notify) {
9725 listNode *ln;
9726 listIter li;
9727 int count = 0;
9728
9729 listRewind(c->pubsub_patterns,&li);
9730 while ((ln = listNext(&li)) != NULL) {
9731 robj *pattern = ln->value;
9732
9733 count += pubsubUnsubscribePattern(c,pattern,notify);
9734 }
9735 return count;
9736 }
9737
9738 /* Publish a message */
9739 static int pubsubPublishMessage(robj *channel, robj *message) {
9740 int receivers = 0;
9741 struct dictEntry *de;
9742 listNode *ln;
9743 listIter li;
9744
9745 /* Send to clients listening for that channel */
9746 de = dictFind(server.pubsub_channels,channel);
9747 if (de) {
9748 list *list = dictGetEntryVal(de);
9749 listNode *ln;
9750 listIter li;
9751
9752 listRewind(list,&li);
9753 while ((ln = listNext(&li)) != NULL) {
9754 redisClient *c = ln->value;
9755
9756 addReply(c,shared.mbulk3);
9757 addReply(c,shared.messagebulk);
9758 addReplyBulk(c,channel);
9759 addReplyBulk(c,message);
9760 receivers++;
9761 }
9762 }
9763 /* Send to clients listening to matching channels */
9764 if (listLength(server.pubsub_patterns)) {
9765 listRewind(server.pubsub_patterns,&li);
9766 channel = getDecodedObject(channel);
9767 while ((ln = listNext(&li)) != NULL) {
9768 pubsubPattern *pat = ln->value;
9769
9770 if (stringmatchlen((char*)pat->pattern->ptr,
9771 sdslen(pat->pattern->ptr),
9772 (char*)channel->ptr,
9773 sdslen(channel->ptr),0)) {
9774 addReply(pat->client,shared.mbulk3);
9775 addReply(pat->client,shared.messagebulk);
9776 addReplyBulk(pat->client,channel);
9777 addReplyBulk(pat->client,message);
9778 receivers++;
9779 }
9780 }
9781 decrRefCount(channel);
9782 }
9783 return receivers;
9784 }
9785
9786 static void subscribeCommand(redisClient *c) {
9787 int j;
9788
9789 for (j = 1; j < c->argc; j++)
9790 pubsubSubscribeChannel(c,c->argv[j]);
9791 }
9792
9793 static void unsubscribeCommand(redisClient *c) {
9794 if (c->argc == 1) {
9795 pubsubUnsubscribeAllChannels(c,1);
9796 return;
9797 } else {
9798 int j;
9799
9800 for (j = 1; j < c->argc; j++)
9801 pubsubUnsubscribeChannel(c,c->argv[j],1);
9802 }
9803 }
9804
9805 static void psubscribeCommand(redisClient *c) {
9806 int j;
9807
9808 for (j = 1; j < c->argc; j++)
9809 pubsubSubscribePattern(c,c->argv[j]);
9810 }
9811
9812 static void punsubscribeCommand(redisClient *c) {
9813 if (c->argc == 1) {
9814 pubsubUnsubscribeAllPatterns(c,1);
9815 return;
9816 } else {
9817 int j;
9818
9819 for (j = 1; j < c->argc; j++)
9820 pubsubUnsubscribePattern(c,c->argv[j],1);
9821 }
9822 }
9823
9824 static void publishCommand(redisClient *c) {
9825 int receivers = pubsubPublishMessage(c->argv[1],c->argv[2]);
9826 addReplyLong(c,receivers);
9827 }
9828
9829 /* ================================= Debugging ============================== */
9830
9831 static void debugCommand(redisClient *c) {
9832 if (!strcasecmp(c->argv[1]->ptr,"segfault")) {
9833 *((char*)-1) = 'x';
9834 } else if (!strcasecmp(c->argv[1]->ptr,"reload")) {
9835 if (rdbSave(server.dbfilename) != REDIS_OK) {
9836 addReply(c,shared.err);
9837 return;
9838 }
9839 emptyDb();
9840 if (rdbLoad(server.dbfilename) != REDIS_OK) {
9841 addReply(c,shared.err);
9842 return;
9843 }
9844 redisLog(REDIS_WARNING,"DB reloaded by DEBUG RELOAD");
9845 addReply(c,shared.ok);
9846 } else if (!strcasecmp(c->argv[1]->ptr,"loadaof")) {
9847 emptyDb();
9848 if (loadAppendOnlyFile(server.appendfilename) != REDIS_OK) {
9849 addReply(c,shared.err);
9850 return;
9851 }
9852 redisLog(REDIS_WARNING,"Append Only File loaded by DEBUG LOADAOF");
9853 addReply(c,shared.ok);
9854 } else if (!strcasecmp(c->argv[1]->ptr,"object") && c->argc == 3) {
9855 dictEntry *de = dictFind(c->db->dict,c->argv[2]);
9856 robj *key, *val;
9857
9858 if (!de) {
9859 addReply(c,shared.nokeyerr);
9860 return;
9861 }
9862 key = dictGetEntryKey(de);
9863 val = dictGetEntryVal(de);
9864 if (!server.vm_enabled || (key->storage == REDIS_VM_MEMORY ||
9865 key->storage == REDIS_VM_SWAPPING)) {
9866 char *strenc;
9867 char buf[128];
9868
9869 if (val->encoding < (sizeof(strencoding)/sizeof(char*))) {
9870 strenc = strencoding[val->encoding];
9871 } else {
9872 snprintf(buf,64,"unknown encoding %d\n", val->encoding);
9873 strenc = buf;
9874 }
9875 addReplySds(c,sdscatprintf(sdsempty(),
9876 "+Key at:%p refcount:%d, value at:%p refcount:%d "
9877 "encoding:%s serializedlength:%lld\r\n",
9878 (void*)key, key->refcount, (void*)val, val->refcount,
9879 strenc, (long long) rdbSavedObjectLen(val,NULL)));
9880 } else {
9881 addReplySds(c,sdscatprintf(sdsempty(),
9882 "+Key at:%p refcount:%d, value swapped at: page %llu "
9883 "using %llu pages\r\n",
9884 (void*)key, key->refcount, (unsigned long long) key->vm.page,
9885 (unsigned long long) key->vm.usedpages));
9886 }
9887 } else if (!strcasecmp(c->argv[1]->ptr,"swapin") && c->argc == 3) {
9888 lookupKeyRead(c->db,c->argv[2]);
9889 addReply(c,shared.ok);
9890 } else if (!strcasecmp(c->argv[1]->ptr,"swapout") && c->argc == 3) {
9891 dictEntry *de = dictFind(c->db->dict,c->argv[2]);
9892 robj *key, *val;
9893
9894 if (!server.vm_enabled) {
9895 addReplySds(c,sdsnew("-ERR Virtual Memory is disabled\r\n"));
9896 return;
9897 }
9898 if (!de) {
9899 addReply(c,shared.nokeyerr);
9900 return;
9901 }
9902 key = dictGetEntryKey(de);
9903 val = dictGetEntryVal(de);
9904 /* If the key is shared we want to create a copy */
9905 if (key->refcount > 1) {
9906 robj *newkey = dupStringObject(key);
9907 decrRefCount(key);
9908 key = dictGetEntryKey(de) = newkey;
9909 }
9910 /* Swap it */
9911 if (key->storage != REDIS_VM_MEMORY) {
9912 addReplySds(c,sdsnew("-ERR This key is not in memory\r\n"));
9913 } else if (vmSwapObjectBlocking(key,val) == REDIS_OK) {
9914 dictGetEntryVal(de) = NULL;
9915 addReply(c,shared.ok);
9916 } else {
9917 addReply(c,shared.err);
9918 }
9919 } else {
9920 addReplySds(c,sdsnew(
9921 "-ERR Syntax error, try DEBUG [SEGFAULT|OBJECT <key>|SWAPIN <key>|SWAPOUT <key>|RELOAD]\r\n"));
9922 }
9923 }
9924
9925 static void _redisAssert(char *estr, char *file, int line) {
9926 redisLog(REDIS_WARNING,"=== ASSERTION FAILED ===");
9927 redisLog(REDIS_WARNING,"==> %s:%d '%s' is not true\n",file,line,estr);
9928 #ifdef HAVE_BACKTRACE
9929 redisLog(REDIS_WARNING,"(forcing SIGSEGV in order to print the stack trace)");
9930 *((char*)-1) = 'x';
9931 #endif
9932 }
9933
9934 static void _redisPanic(char *msg, char *file, int line) {
9935 redisLog(REDIS_WARNING,"!!! Software Failure. Press left mouse button to continue");
9936 redisLog(REDIS_WARNING,"Guru Meditation: %s #%s:%d",msg,file,line);
9937 #ifdef HAVE_BACKTRACE
9938 redisLog(REDIS_WARNING,"(forcing SIGSEGV in order to print the stack trace)");
9939 *((char*)-1) = 'x';
9940 #endif
9941 }
9942
9943 /* =================================== Main! ================================ */
9944
9945 #ifdef __linux__
9946 int linuxOvercommitMemoryValue(void) {
9947 FILE *fp = fopen("/proc/sys/vm/overcommit_memory","r");
9948 char buf[64];
9949
9950 if (!fp) return -1;
9951 if (fgets(buf,64,fp) == NULL) {
9952 fclose(fp);
9953 return -1;
9954 }
9955 fclose(fp);
9956
9957 return atoi(buf);
9958 }
9959
9960 void linuxOvercommitMemoryWarning(void) {
9961 if (linuxOvercommitMemoryValue() == 0) {
9962 redisLog(REDIS_WARNING,"WARNING overcommit_memory is set to 0! Background save may fail under low memory condition. To fix this issue add 'vm.overcommit_memory = 1' to /etc/sysctl.conf and then reboot or run the command 'sysctl vm.overcommit_memory=1' for this to take effect.");
9963 }
9964 }
9965 #endif /* __linux__ */
9966
9967 static void daemonize(void) {
9968 int fd;
9969 FILE *fp;
9970
9971 if (fork() != 0) exit(0); /* parent exits */
9972 setsid(); /* create a new session */
9973
9974 /* Every output goes to /dev/null. If Redis is daemonized but
9975 * the 'logfile' is set to 'stdout' in the configuration file
9976 * it will not log at all. */
9977 if ((fd = open("/dev/null", O_RDWR, 0)) != -1) {
9978 dup2(fd, STDIN_FILENO);
9979 dup2(fd, STDOUT_FILENO);
9980 dup2(fd, STDERR_FILENO);
9981 if (fd > STDERR_FILENO) close(fd);
9982 }
9983 /* Try to write the pid file */
9984 fp = fopen(server.pidfile,"w");
9985 if (fp) {
9986 fprintf(fp,"%d\n",getpid());
9987 fclose(fp);
9988 }
9989 }
9990
9991 static void version() {
9992 printf("Redis server version %s\n", REDIS_VERSION);
9993 exit(0);
9994 }
9995
9996 static void usage() {
9997 fprintf(stderr,"Usage: ./redis-server [/path/to/redis.conf]\n");
9998 fprintf(stderr," ./redis-server - (read config from stdin)\n");
9999 exit(1);
10000 }
10001
10002 int main(int argc, char **argv) {
10003 time_t start;
10004
10005 initServerConfig();
10006 if (argc == 2) {
10007 if (strcmp(argv[1], "-v") == 0 ||
10008 strcmp(argv[1], "--version") == 0) version();
10009 if (strcmp(argv[1], "--help") == 0) usage();
10010 resetServerSaveParams();
10011 loadServerConfig(argv[1]);
10012 } else if ((argc > 2)) {
10013 usage();
10014 } else {
10015 redisLog(REDIS_WARNING,"Warning: no config file specified, using the default config. In order to specify a config file use 'redis-server /path/to/redis.conf'");
10016 }
10017 if (server.daemonize) daemonize();
10018 initServer();
10019 redisLog(REDIS_NOTICE,"Server started, Redis version " REDIS_VERSION);
10020 #ifdef __linux__
10021 linuxOvercommitMemoryWarning();
10022 #endif
10023 start = time(NULL);
10024 if (server.appendonly) {
10025 if (loadAppendOnlyFile(server.appendfilename) == REDIS_OK)
10026 redisLog(REDIS_NOTICE,"DB loaded from append only file: %ld seconds",time(NULL)-start);
10027 } else {
10028 if (rdbLoad(server.dbfilename) == REDIS_OK)
10029 redisLog(REDIS_NOTICE,"DB loaded from disk: %ld seconds",time(NULL)-start);
10030 }
10031 redisLog(REDIS_NOTICE,"The server is now ready to accept connections on port %d", server.port);
10032 aeSetBeforeSleepProc(server.el,beforeSleep);
10033 aeMain(server.el);
10034 aeDeleteEventLoop(server.el);
10035 return 0;
10036 }
10037
10038 /* ============================= Backtrace support ========================= */
10039
10040 #ifdef HAVE_BACKTRACE
10041 static char *findFuncName(void *pointer, unsigned long *offset);
10042
10043 static void *getMcontextEip(ucontext_t *uc) {
10044 #if defined(__FreeBSD__)
10045 return (void*) uc->uc_mcontext.mc_eip;
10046 #elif defined(__dietlibc__)
10047 return (void*) uc->uc_mcontext.eip;
10048 #elif defined(__APPLE__) && !defined(MAC_OS_X_VERSION_10_6)
10049 #if __x86_64__
10050 return (void*) uc->uc_mcontext->__ss.__rip;
10051 #else
10052 return (void*) uc->uc_mcontext->__ss.__eip;
10053 #endif
10054 #elif defined(__APPLE__) && defined(MAC_OS_X_VERSION_10_6)
10055 #if defined(_STRUCT_X86_THREAD_STATE64) && !defined(__i386__)
10056 return (void*) uc->uc_mcontext->__ss.__rip;
10057 #else
10058 return (void*) uc->uc_mcontext->__ss.__eip;
10059 #endif
10060 #elif defined(__i386__) || defined(__X86_64__) || defined(__x86_64__)
10061 return (void*) uc->uc_mcontext.gregs[REG_EIP]; /* Linux 32/64 bit */
10062 #elif defined(__ia64__) /* Linux IA64 */
10063 return (void*) uc->uc_mcontext.sc_ip;
10064 #else
10065 return NULL;
10066 #endif
10067 }
10068
10069 static void segvHandler(int sig, siginfo_t *info, void *secret) {
10070 void *trace[100];
10071 char **messages = NULL;
10072 int i, trace_size = 0;
10073 unsigned long offset=0;
10074 ucontext_t *uc = (ucontext_t*) secret;
10075 sds infostring;
10076 REDIS_NOTUSED(info);
10077
10078 redisLog(REDIS_WARNING,
10079 "======= Ooops! Redis %s got signal: -%d- =======", REDIS_VERSION, sig);
10080 infostring = genRedisInfoString();
10081 redisLog(REDIS_WARNING, "%s",infostring);
10082 /* It's not safe to sdsfree() the returned string under memory
10083 * corruption conditions. Let it leak as we are going to abort */
10084
10085 trace_size = backtrace(trace, 100);
10086 /* overwrite sigaction with caller's address */
10087 if (getMcontextEip(uc) != NULL) {
10088 trace[1] = getMcontextEip(uc);
10089 }
10090 messages = backtrace_symbols(trace, trace_size);
10091
10092 for (i=1; i<trace_size; ++i) {
10093 char *fn = findFuncName(trace[i], &offset), *p;
10094
10095 p = strchr(messages[i],'+');
10096 if (!fn || (p && ((unsigned long)strtol(p+1,NULL,10)) < offset)) {
10097 redisLog(REDIS_WARNING,"%s", messages[i]);
10098 } else {
10099 redisLog(REDIS_WARNING,"%d redis-server %p %s + %d", i, trace[i], fn, (unsigned int)offset);
10100 }
10101 }
10102 /* free(messages); Don't call free() with possibly corrupted memory. */
10103 _exit(0);
10104 }
10105
10106 static void setupSigSegvAction(void) {
10107 struct sigaction act;
10108
10109 sigemptyset (&act.sa_mask);
10110 /* When the SA_SIGINFO flag is set in sa_flags then sa_sigaction
10111 * is used. Otherwise, sa_handler is used */
10112 act.sa_flags = SA_NODEFER | SA_ONSTACK | SA_RESETHAND | SA_SIGINFO;
10113 act.sa_sigaction = segvHandler;
10114 sigaction (SIGSEGV, &act, NULL);
10115 sigaction (SIGBUS, &act, NULL);
10116 sigaction (SIGFPE, &act, NULL);
10117 sigaction (SIGILL, &act, NULL);
10118 sigaction (SIGBUS, &act, NULL);
10119 return;
10120 }
10121
10122 #include "staticsymbols.h"
10123 /* This function try to convert a pointer into a function name. It's used in
10124 * oreder to provide a backtrace under segmentation fault that's able to
10125 * display functions declared as static (otherwise the backtrace is useless). */
10126 static char *findFuncName(void *pointer, unsigned long *offset){
10127 int i, ret = -1;
10128 unsigned long off, minoff = 0;
10129
10130 /* Try to match against the Symbol with the smallest offset */
10131 for (i=0; symsTable[i].pointer; i++) {
10132 unsigned long lp = (unsigned long) pointer;
10133
10134 if (lp != (unsigned long)-1 && lp >= symsTable[i].pointer) {
10135 off=lp-symsTable[i].pointer;
10136 if (ret < 0 || off < minoff) {
10137 minoff=off;
10138 ret=i;
10139 }
10140 }
10141 }
10142 if (ret == -1) return NULL;
10143 *offset = minoff;
10144 return symsTable[ret].name;
10145 }
10146 #else /* HAVE_BACKTRACE */
10147 static void setupSigSegvAction(void) {
10148 }
10149 #endif /* HAVE_BACKTRACE */
10150
10151
10152
10153 /* The End */
10154
10155
10156