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1 | #include "redis.h" | |
2 | ||
3 | /* ================================ MULTI/EXEC ============================== */ | |
4 | ||
5 | /* Client state initialization for MULTI/EXEC */ | |
6 | void initClientMultiState(redisClient *c) { | |
7 | c->mstate.commands = NULL; | |
8 | c->mstate.count = 0; | |
9 | } | |
10 | ||
11 | /* Release all the resources associated with MULTI/EXEC state */ | |
12 | void freeClientMultiState(redisClient *c) { | |
13 | int j; | |
14 | ||
15 | for (j = 0; j < c->mstate.count; j++) { | |
16 | int i; | |
17 | multiCmd *mc = c->mstate.commands+j; | |
18 | ||
19 | for (i = 0; i < mc->argc; i++) | |
20 | decrRefCount(mc->argv[i]); | |
21 | zfree(mc->argv); | |
22 | } | |
23 | zfree(c->mstate.commands); | |
24 | } | |
25 | ||
26 | /* Add a new command into the MULTI commands queue */ | |
27 | void queueMultiCommand(redisClient *c, struct redisCommand *cmd) { | |
28 | multiCmd *mc; | |
29 | int j; | |
30 | ||
31 | c->mstate.commands = zrealloc(c->mstate.commands, | |
32 | sizeof(multiCmd)*(c->mstate.count+1)); | |
33 | mc = c->mstate.commands+c->mstate.count; | |
34 | mc->cmd = cmd; | |
35 | mc->argc = c->argc; | |
36 | mc->argv = zmalloc(sizeof(robj*)*c->argc); | |
37 | memcpy(mc->argv,c->argv,sizeof(robj*)*c->argc); | |
38 | for (j = 0; j < c->argc; j++) | |
39 | incrRefCount(mc->argv[j]); | |
40 | c->mstate.count++; | |
41 | } | |
42 | ||
43 | void multiCommand(redisClient *c) { | |
44 | if (c->flags & REDIS_MULTI) { | |
45 | addReplyError(c,"MULTI calls can not be nested"); | |
46 | return; | |
47 | } | |
48 | c->flags |= REDIS_MULTI; | |
49 | addReply(c,shared.ok); | |
50 | } | |
51 | ||
52 | void discardCommand(redisClient *c) { | |
53 | if (!(c->flags & REDIS_MULTI)) { | |
54 | addReplyError(c,"DISCARD without MULTI"); | |
55 | return; | |
56 | } | |
57 | ||
58 | freeClientMultiState(c); | |
59 | initClientMultiState(c); | |
60 | c->flags &= (~REDIS_MULTI); | |
61 | unwatchAllKeys(c); | |
62 | addReply(c,shared.ok); | |
63 | } | |
64 | ||
65 | /* Send a MULTI command to all the slaves and AOF file. Check the execCommand | |
66 | * implememntation for more information. */ | |
67 | void execCommandReplicateMulti(redisClient *c) { | |
68 | robj *multistring = createStringObject("MULTI",5); | |
69 | ||
70 | if (server.appendonly) | |
71 | feedAppendOnlyFile(server.multiCommand,c->db->id,&multistring,1); | |
72 | if (listLength(server.slaves)) | |
73 | replicationFeedSlaves(server.slaves,c->db->id,&multistring,1); | |
74 | decrRefCount(multistring); | |
75 | } | |
76 | ||
77 | void execCommand(redisClient *c) { | |
78 | int j; | |
79 | robj **orig_argv; | |
80 | int orig_argc; | |
81 | ||
82 | if (!(c->flags & REDIS_MULTI)) { | |
83 | addReplyError(c,"EXEC without MULTI"); | |
84 | return; | |
85 | } | |
86 | ||
87 | /* Check if we need to abort the EXEC if some WATCHed key was touched. | |
88 | * A failed EXEC will return a multi bulk nil object. */ | |
89 | if (c->flags & REDIS_DIRTY_CAS) { | |
90 | freeClientMultiState(c); | |
91 | initClientMultiState(c); | |
92 | c->flags &= ~(REDIS_MULTI|REDIS_DIRTY_CAS); | |
93 | unwatchAllKeys(c); | |
94 | addReply(c,shared.nullmultibulk); | |
95 | return; | |
96 | } | |
97 | ||
98 | /* Replicate a MULTI request now that we are sure the block is executed. | |
99 | * This way we'll deliver the MULTI/..../EXEC block as a whole and | |
100 | * both the AOF and the replication link will have the same consistency | |
101 | * and atomicity guarantees. */ | |
102 | execCommandReplicateMulti(c); | |
103 | ||
104 | /* Exec all the queued commands */ | |
105 | unwatchAllKeys(c); /* Unwatch ASAP otherwise we'll waste CPU cycles */ | |
106 | orig_argv = c->argv; | |
107 | orig_argc = c->argc; | |
108 | addReplyMultiBulkLen(c,c->mstate.count); | |
109 | for (j = 0; j < c->mstate.count; j++) { | |
110 | c->argc = c->mstate.commands[j].argc; | |
111 | c->argv = c->mstate.commands[j].argv; | |
112 | call(c,c->mstate.commands[j].cmd); | |
113 | ||
114 | /* Commands may alter argc/argv, restore mstate. */ | |
115 | c->mstate.commands[j].argc = c->argc; | |
116 | c->mstate.commands[j].argv = c->argv; | |
117 | } | |
118 | c->argv = orig_argv; | |
119 | c->argc = orig_argc; | |
120 | freeClientMultiState(c); | |
121 | initClientMultiState(c); | |
122 | c->flags &= ~(REDIS_MULTI|REDIS_DIRTY_CAS); | |
123 | /* Make sure the EXEC command is always replicated / AOF, since we | |
124 | * always send the MULTI command (we can't know beforehand if the | |
125 | * next operations will contain at least a modification to the DB). */ | |
126 | server.dirty++; | |
127 | } | |
128 | ||
129 | /* ===================== WATCH (CAS alike for MULTI/EXEC) =================== | |
130 | * | |
131 | * The implementation uses a per-DB hash table mapping keys to list of clients | |
132 | * WATCHing those keys, so that given a key that is going to be modified | |
133 | * we can mark all the associated clients as dirty. | |
134 | * | |
135 | * Also every client contains a list of WATCHed keys so that's possible to | |
136 | * un-watch such keys when the client is freed or when UNWATCH is called. */ | |
137 | ||
138 | /* In the client->watched_keys list we need to use watchedKey structures | |
139 | * as in order to identify a key in Redis we need both the key name and the | |
140 | * DB */ | |
141 | typedef struct watchedKey { | |
142 | robj *key; | |
143 | redisDb *db; | |
144 | } watchedKey; | |
145 | ||
146 | /* Watch for the specified key */ | |
147 | void watchForKey(redisClient *c, robj *key) { | |
148 | list *clients = NULL; | |
149 | listIter li; | |
150 | listNode *ln; | |
151 | watchedKey *wk; | |
152 | ||
153 | /* Check if we are already watching for this key */ | |
154 | listRewind(c->watched_keys,&li); | |
155 | while((ln = listNext(&li))) { | |
156 | wk = listNodeValue(ln); | |
157 | if (wk->db == c->db && equalStringObjects(key,wk->key)) | |
158 | return; /* Key already watched */ | |
159 | } | |
160 | /* This key is not already watched in this DB. Let's add it */ | |
161 | clients = dictFetchValue(c->db->watched_keys,key); | |
162 | if (!clients) { | |
163 | clients = listCreate(); | |
164 | dictAdd(c->db->watched_keys,key,clients); | |
165 | incrRefCount(key); | |
166 | } | |
167 | listAddNodeTail(clients,c); | |
168 | /* Add the new key to the lits of keys watched by this client */ | |
169 | wk = zmalloc(sizeof(*wk)); | |
170 | wk->key = key; | |
171 | wk->db = c->db; | |
172 | incrRefCount(key); | |
173 | listAddNodeTail(c->watched_keys,wk); | |
174 | } | |
175 | ||
176 | /* Unwatch all the keys watched by this client. To clean the EXEC dirty | |
177 | * flag is up to the caller. */ | |
178 | void unwatchAllKeys(redisClient *c) { | |
179 | listIter li; | |
180 | listNode *ln; | |
181 | ||
182 | if (listLength(c->watched_keys) == 0) return; | |
183 | listRewind(c->watched_keys,&li); | |
184 | while((ln = listNext(&li))) { | |
185 | list *clients; | |
186 | watchedKey *wk; | |
187 | ||
188 | /* Lookup the watched key -> clients list and remove the client | |
189 | * from the list */ | |
190 | wk = listNodeValue(ln); | |
191 | clients = dictFetchValue(wk->db->watched_keys, wk->key); | |
192 | redisAssert(clients != NULL); | |
193 | listDelNode(clients,listSearchKey(clients,c)); | |
194 | /* Kill the entry at all if this was the only client */ | |
195 | if (listLength(clients) == 0) | |
196 | dictDelete(wk->db->watched_keys, wk->key); | |
197 | /* Remove this watched key from the client->watched list */ | |
198 | listDelNode(c->watched_keys,ln); | |
199 | decrRefCount(wk->key); | |
200 | zfree(wk); | |
201 | } | |
202 | } | |
203 | ||
204 | /* "Touch" a key, so that if this key is being WATCHed by some client the | |
205 | * next EXEC will fail. */ | |
206 | void touchWatchedKey(redisDb *db, robj *key) { | |
207 | list *clients; | |
208 | listIter li; | |
209 | listNode *ln; | |
210 | ||
211 | if (dictSize(db->watched_keys) == 0) return; | |
212 | clients = dictFetchValue(db->watched_keys, key); | |
213 | if (!clients) return; | |
214 | ||
215 | /* Mark all the clients watching this key as REDIS_DIRTY_CAS */ | |
216 | /* Check if we are already watching for this key */ | |
217 | listRewind(clients,&li); | |
218 | while((ln = listNext(&li))) { | |
219 | redisClient *c = listNodeValue(ln); | |
220 | ||
221 | c->flags |= REDIS_DIRTY_CAS; | |
222 | } | |
223 | } | |
224 | ||
225 | /* On FLUSHDB or FLUSHALL all the watched keys that are present before the | |
226 | * flush but will be deleted as effect of the flushing operation should | |
227 | * be touched. "dbid" is the DB that's getting the flush. -1 if it is | |
228 | * a FLUSHALL operation (all the DBs flushed). */ | |
229 | void touchWatchedKeysOnFlush(int dbid) { | |
230 | listIter li1, li2; | |
231 | listNode *ln; | |
232 | ||
233 | /* For every client, check all the waited keys */ | |
234 | listRewind(server.clients,&li1); | |
235 | while((ln = listNext(&li1))) { | |
236 | redisClient *c = listNodeValue(ln); | |
237 | listRewind(c->watched_keys,&li2); | |
238 | while((ln = listNext(&li2))) { | |
239 | watchedKey *wk = listNodeValue(ln); | |
240 | ||
241 | /* For every watched key matching the specified DB, if the | |
242 | * key exists, mark the client as dirty, as the key will be | |
243 | * removed. */ | |
244 | if (dbid == -1 || wk->db->id == dbid) { | |
245 | if (dictFind(wk->db->dict, wk->key->ptr) != NULL) | |
246 | c->flags |= REDIS_DIRTY_CAS; | |
247 | } | |
248 | } | |
249 | } | |
250 | } | |
251 | ||
252 | void watchCommand(redisClient *c) { | |
253 | int j; | |
254 | ||
255 | if (c->flags & REDIS_MULTI) { | |
256 | addReplyError(c,"WATCH inside MULTI is not allowed"); | |
257 | return; | |
258 | } | |
259 | for (j = 1; j < c->argc; j++) | |
260 | watchForKey(c,c->argv[j]); | |
261 | addReply(c,shared.ok); | |
262 | } | |
263 | ||
264 | void unwatchCommand(redisClient *c) { | |
265 | unwatchAllKeys(c); | |
266 | c->flags &= (~REDIS_DIRTY_CAS); | |
267 | addReply(c,shared.ok); | |
268 | } |