/* * Copyright (c) 2009-2012, Salvatore Sanfilippo * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * * Redistributions of source code must retain the above copyright notice, * this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * Neither the name of Redis nor the names of its contributors may be used * to endorse or promote products derived from this software without * specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include "server.h" #include "atomicvar.h" #include "cluster.h" #include "script.h" #include #include #include #include static void setProtocolError(const char *errstr, client *c); int postponeClientRead(client *c); int ProcessingEventsWhileBlocked = 0; /* See processEventsWhileBlocked(). */ /* Return the size consumed from the allocator, for the specified SDS string, * including internal fragmentation. This function is used in order to compute * the client output buffer size. */ size_t sdsZmallocSize(sds s) { void *sh = sdsAllocPtr(s); return zmalloc_size(sh); } /* Return the amount of memory used by the sds string at object->ptr * for a string object. This includes internal fragmentation. */ size_t getStringObjectSdsUsedMemory(robj *o) { serverAssertWithInfo(NULL,o,o->type == OBJ_STRING); switch(o->encoding) { case OBJ_ENCODING_RAW: return sdsZmallocSize(o->ptr); case OBJ_ENCODING_EMBSTR: return zmalloc_size(o)-sizeof(robj); default: return 0; /* Just integer encoding for now. */ } } /* Return the length of a string object. * This does NOT includes internal fragmentation or sds unused space. */ size_t getStringObjectLen(robj *o) { serverAssertWithInfo(NULL,o,o->type == OBJ_STRING); switch(o->encoding) { case OBJ_ENCODING_RAW: return sdslen(o->ptr); case OBJ_ENCODING_EMBSTR: return sdslen(o->ptr); default: return 0; /* Just integer encoding for now. */ } } /* Client.reply list dup and free methods. */ void *dupClientReplyValue(void *o) { clientReplyBlock *old = o; clientReplyBlock *buf = zmalloc(sizeof(clientReplyBlock) + old->size); memcpy(buf, o, sizeof(clientReplyBlock) + old->size); return buf; } void freeClientReplyValue(void *o) { zfree(o); } int listMatchObjects(void *a, void *b) { return equalStringObjects(a,b); } /* This function links the client to the global linked list of clients. * unlinkClient() does the opposite, among other things. */ void linkClient(client *c) { listAddNodeTail(server.clients,c); /* Note that we remember the linked list node where the client is stored, * this way removing the client in unlinkClient() will not require * a linear scan, but just a constant time operation. */ c->client_list_node = listLast(server.clients); uint64_t id = htonu64(c->id); raxInsert(server.clients_index,(unsigned char*)&id,sizeof(id),c,NULL); } /* Initialize client authentication state. */ static void clientSetDefaultAuth(client *c) { /* If the default user does not require authentication, the user is * directly authenticated. */ c->user = DefaultUser; c->authenticated = (c->user->flags & USER_FLAG_NOPASS) && !(c->user->flags & USER_FLAG_DISABLED); } int authRequired(client *c) { /* Check if the user is authenticated. This check is skipped in case * the default user is flagged as "nopass" and is active. */ int auth_required = (!(DefaultUser->flags & USER_FLAG_NOPASS) || (DefaultUser->flags & USER_FLAG_DISABLED)) && !c->authenticated; return auth_required; } client *createClient(connection *conn) { client *c = zmalloc(sizeof(client)); /* passing NULL as conn it is possible to create a non connected client. * This is useful since all the commands needs to be executed * in the context of a client. When commands are executed in other * contexts (for instance a Lua script) we need a non connected client. */ if (conn) { connEnableTcpNoDelay(conn); if (server.tcpkeepalive) connKeepAlive(conn,server.tcpkeepalive); connSetReadHandler(conn, readQueryFromClient); connSetPrivateData(conn, c); } c->buf = zmalloc_usable(PROTO_REPLY_CHUNK_BYTES, &c->buf_usable_size); selectDb(c,0); uint64_t client_id; atomicGetIncr(server.next_client_id, client_id, 1); c->id = client_id; c->resp = 2; c->conn = conn; c->name = NULL; c->bufpos = 0; c->buf_peak = c->buf_usable_size; c->buf_peak_last_reset_time = server.unixtime; c->ref_repl_buf_node = NULL; c->ref_block_pos = 0; c->qb_pos = 0; c->querybuf = sdsempty(); c->querybuf_peak = 0; c->reqtype = 0; c->argc = 0; c->argv = NULL; c->argv_len = 0; c->argv_len_sum = 0; c->original_argc = 0; c->original_argv = NULL; c->cmd = c->lastcmd = c->realcmd = NULL; c->cur_script = NULL; c->multibulklen = 0; c->bulklen = -1; c->sentlen = 0; c->flags = 0; c->slot = -1; c->ctime = c->lastinteraction = server.unixtime; clientSetDefaultAuth(c); c->replstate = REPL_STATE_NONE; c->repl_start_cmd_stream_on_ack = 0; c->reploff = 0; c->read_reploff = 0; c->repl_applied = 0; c->repl_ack_off = 0; c->repl_ack_time = 0; c->repl_last_partial_write = 0; c->slave_listening_port = 0; c->slave_addr = NULL; c->slave_capa = SLAVE_CAPA_NONE; c->slave_req = SLAVE_REQ_NONE; c->reply = listCreate(); c->deferred_reply_errors = NULL; c->reply_bytes = 0; c->obuf_soft_limit_reached_time = 0; listSetFreeMethod(c->reply,freeClientReplyValue); listSetDupMethod(c->reply,dupClientReplyValue); c->btype = BLOCKED_NONE; c->bpop.timeout = 0; c->bpop.keys = dictCreate(&objectKeyHeapPointerValueDictType); c->bpop.target = NULL; c->bpop.xread_group = NULL; c->bpop.xread_consumer = NULL; c->bpop.xread_group_noack = 0; c->bpop.numreplicas = 0; c->bpop.reploffset = 0; c->woff = 0; c->watched_keys = listCreate(); c->pubsub_channels = dictCreate(&objectKeyPointerValueDictType); c->pubsub_patterns = listCreate(); c->pubsubshard_channels = dictCreate(&objectKeyPointerValueDictType); c->peerid = NULL; c->sockname = NULL; c->client_list_node = NULL; c->postponed_list_node = NULL; c->pending_read_list_node = NULL; c->client_tracking_redirection = 0; c->client_tracking_prefixes = NULL; c->last_memory_usage = 0; c->last_memory_type = CLIENT_TYPE_NORMAL; c->auth_callback = NULL; c->auth_callback_privdata = NULL; c->auth_module = NULL; listSetFreeMethod(c->pubsub_patterns,decrRefCountVoid); listSetMatchMethod(c->pubsub_patterns,listMatchObjects); c->mem_usage_bucket = NULL; c->mem_usage_bucket_node = NULL; if (conn) linkClient(c); initClientMultiState(c); return c; } void installClientWriteHandler(client *c) { int ae_barrier = 0; /* For the fsync=always policy, we want that a given FD is never * served for reading and writing in the same event loop iteration, * so that in the middle of receiving the query, and serving it * to the client, we'll call beforeSleep() that will do the * actual fsync of AOF to disk. the write barrier ensures that. */ if (server.aof_state == AOF_ON && server.aof_fsync == AOF_FSYNC_ALWAYS) { ae_barrier = 1; } if (connSetWriteHandlerWithBarrier(c->conn, sendReplyToClient, ae_barrier) == C_ERR) { freeClientAsync(c); } } /* This function puts the client in the queue of clients that should write * their output buffers to the socket. Note that it does not *yet* install * the write handler, to start clients are put in a queue of clients that need * to write, so we try to do that before returning in the event loop (see the * handleClientsWithPendingWrites() function). * If we fail and there is more data to write, compared to what the socket * buffers can hold, then we'll really install the handler. */ void putClientInPendingWriteQueue(client *c) { /* Schedule the client to write the output buffers to the socket only * if not already done and, for slaves, if the slave can actually receive * writes at this stage. */ if (!(c->flags & CLIENT_PENDING_WRITE) && (c->replstate == REPL_STATE_NONE || (c->replstate == SLAVE_STATE_ONLINE && !c->repl_start_cmd_stream_on_ack))) { /* Here instead of installing the write handler, we just flag the * client and put it into a list of clients that have something * to write to the socket. This way before re-entering the event * loop, we can try to directly write to the client sockets avoiding * a system call. We'll only really install the write handler if * we'll not be able to write the whole reply at once. */ c->flags |= CLIENT_PENDING_WRITE; listAddNodeHead(server.clients_pending_write,c); } } /* This function is called every time we are going to transmit new data * to the client. The behavior is the following: * * If the client should receive new data (normal clients will) the function * returns C_OK, and make sure to install the write handler in our event * loop so that when the socket is writable new data gets written. * * If the client should not receive new data, because it is a fake client * (used to load AOF in memory), a master or because the setup of the write * handler failed, the function returns C_ERR. * * The function may return C_OK without actually installing the write * event handler in the following cases: * * 1) The event handler should already be installed since the output buffer * already contains something. * 2) The client is a slave but not yet online, so we want to just accumulate * writes in the buffer but not actually sending them yet. * * Typically gets called every time a reply is built, before adding more * data to the clients output buffers. If the function returns C_ERR no * data should be appended to the output buffers. */ int prepareClientToWrite(client *c) { /* If it's the Lua client we always return ok without installing any * handler since there is no socket at all. */ if (c->flags & (CLIENT_SCRIPT|CLIENT_MODULE)) return C_OK; /* If CLIENT_CLOSE_ASAP flag is set, we need not write anything. */ if (c->flags & CLIENT_CLOSE_ASAP) return C_ERR; /* CLIENT REPLY OFF / SKIP handling: don't send replies. * CLIENT_PUSHING handling: disables the reply silencing flags. */ if ((c->flags & (CLIENT_REPLY_OFF|CLIENT_REPLY_SKIP)) && !(c->flags & CLIENT_PUSHING)) return C_ERR; /* Masters don't receive replies, unless CLIENT_MASTER_FORCE_REPLY flag * is set. */ if ((c->flags & CLIENT_MASTER) && !(c->flags & CLIENT_MASTER_FORCE_REPLY)) return C_ERR; if (!c->conn) return C_ERR; /* Fake client for AOF loading. */ /* Schedule the client to write the output buffers to the socket, unless * it should already be setup to do so (it has already pending data). * * If CLIENT_PENDING_READ is set, we're in an IO thread and should * not put the client in pending write queue. Instead, it will be * done by handleClientsWithPendingReadsUsingThreads() upon return. */ if (!clientHasPendingReplies(c) && io_threads_op == IO_THREADS_OP_IDLE) putClientInPendingWriteQueue(c); /* Authorize the caller to queue in the output buffer of this client. */ return C_OK; } /* ----------------------------------------------------------------------------- * Low level functions to add more data to output buffers. * -------------------------------------------------------------------------- */ /* Attempts to add the reply to the static buffer in the client struct. * Returns the length of data that is added to the reply buffer. * * Sanitizer suppression: client->buf_usable_size determined by * zmalloc_usable_size() call. Writing beyond client->buf boundaries confuses * sanitizer and generates a false positive out-of-bounds error */ REDIS_NO_SANITIZE("bounds") size_t _addReplyToBuffer(client *c, const char *s, size_t len) { size_t available = c->buf_usable_size - c->bufpos; /* If there already are entries in the reply list, we cannot * add anything more to the static buffer. */ if (listLength(c->reply) > 0) return 0; size_t reply_len = len > available ? available : len; memcpy(c->buf+c->bufpos,s,reply_len); c->bufpos+=reply_len; /* We update the buffer peak after appending the reply to the buffer */ if(c->buf_peak < (size_t)c->bufpos) c->buf_peak = (size_t)c->bufpos; return reply_len; } /* Adds the reply to the reply linked list. * Note: some edits to this function need to be relayed to AddReplyFromClient. */ void _addReplyProtoToList(client *c, const char *s, size_t len) { listNode *ln = listLast(c->reply); clientReplyBlock *tail = ln? listNodeValue(ln): NULL; /* Note that 'tail' may be NULL even if we have a tail node, because when * addReplyDeferredLen() is used, it sets a dummy node to NULL just * to fill it later, when the size of the bulk length is set. */ /* Append to tail string when possible. */ if (tail) { /* Copy the part we can fit into the tail, and leave the rest for a * new node */ size_t avail = tail->size - tail->used; size_t copy = avail >= len? len: avail; memcpy(tail->buf + tail->used, s, copy); tail->used += copy; s += copy; len -= copy; } if (len) { /* Create a new node, make sure it is allocated to at * least PROTO_REPLY_CHUNK_BYTES */ size_t usable_size; size_t size = len < PROTO_REPLY_CHUNK_BYTES? PROTO_REPLY_CHUNK_BYTES: len; tail = zmalloc_usable(size + sizeof(clientReplyBlock), &usable_size); /* take over the allocation's internal fragmentation */ tail->size = usable_size - sizeof(clientReplyBlock); tail->used = len; memcpy(tail->buf, s, len); listAddNodeTail(c->reply, tail); c->reply_bytes += tail->size; closeClientOnOutputBufferLimitReached(c, 1); } } void _addReplyToBufferOrList(client *c, const char *s, size_t len) { if (c->flags & CLIENT_CLOSE_AFTER_REPLY) return; /* Replicas should normally not cause any writes to the reply buffer. In case a rogue replica sent a command on the * replication link that caused a reply to be generated we'll simply disconnect it. * Note this is the simplest way to check a command added a response. Replication links are used to write data but * not for responses, so we should normally never get here on a replica client. */ if (getClientType(c) == CLIENT_TYPE_SLAVE) { sds cmdname = c->lastcmd ? c->lastcmd->fullname : NULL; logInvalidUseAndFreeClientAsync(c, "Replica generated a reply to command '%s'", cmdname ? cmdname : ""); return; } size_t reply_len = _addReplyToBuffer(c,s,len); if (len > reply_len) _addReplyProtoToList(c,s+reply_len,len-reply_len); } /* ----------------------------------------------------------------------------- * Higher level functions to queue data on the client output buffer. * The following functions are the ones that commands implementations will call. * -------------------------------------------------------------------------- */ /* Add the object 'obj' string representation to the client output buffer. */ void addReply(client *c, robj *obj) { if (prepareClientToWrite(c) != C_OK) return; if (sdsEncodedObject(obj)) { _addReplyToBufferOrList(c,obj->ptr,sdslen(obj->ptr)); } else if (obj->encoding == OBJ_ENCODING_INT) { /* For integer encoded strings we just convert it into a string * using our optimized function, and attach the resulting string * to the output buffer. */ char buf[32]; size_t len = ll2string(buf,sizeof(buf),(long)obj->ptr); _addReplyToBufferOrList(c,buf,len); } else { serverPanic("Wrong obj->encoding in addReply()"); } } /* Add the SDS 's' string to the client output buffer, as a side effect * the SDS string is freed. */ void addReplySds(client *c, sds s) { if (prepareClientToWrite(c) != C_OK) { /* The caller expects the sds to be free'd. */ sdsfree(s); return; } _addReplyToBufferOrList(c,s,sdslen(s)); sdsfree(s); } /* This low level function just adds whatever protocol you send it to the * client buffer, trying the static buffer initially, and using the string * of objects if not possible. * * It is efficient because does not create an SDS object nor an Redis object * if not needed. The object will only be created by calling * _addReplyProtoToList() if we fail to extend the existing tail object * in the list of objects. */ void addReplyProto(client *c, const char *s, size_t len) { if (prepareClientToWrite(c) != C_OK) return; _addReplyToBufferOrList(c,s,len); } /* Low level function called by the addReplyError...() functions. * It emits the protocol for a Redis error, in the form: * * -ERRORCODE Error Message * * If the error code is already passed in the string 's', the error * code provided is used, otherwise the string "-ERR " for the generic * error code is automatically added. * Note that 's' must NOT end with \r\n. */ void addReplyErrorLength(client *c, const char *s, size_t len) { /* If the string already starts with "-..." then the error code * is provided by the caller. Otherwise we use "-ERR". */ if (!len || s[0] != '-') addReplyProto(c,"-ERR ",5); addReplyProto(c,s,len); addReplyProto(c,"\r\n",2); } /* Do some actions after an error reply was sent (Log if needed, updates stats, etc.) * Possible flags: * * ERR_REPLY_FLAG_NO_STATS_UPDATE - indicate not to update any error stats. */ void afterErrorReply(client *c, const char *s, size_t len, int flags) { /* Module clients fall into two categories: * Calls to RM_Call, in which case the error isn't being returned to a client, so should not be counted. * Module thread safe context calls to RM_ReplyWithError, which will be added to a real client by the main thread later. */ if (c->flags & CLIENT_MODULE) { if (!c->deferred_reply_errors) { c->deferred_reply_errors = listCreate(); listSetFreeMethod(c->deferred_reply_errors, (void (*)(void*))sdsfree); } listAddNodeTail(c->deferred_reply_errors, sdsnewlen(s, len)); return; } if (!(flags & ERR_REPLY_FLAG_NO_STATS_UPDATE)) { /* Increment the global error counter */ server.stat_total_error_replies++; /* Increment the error stats * If the string already starts with "-..." then the error prefix * is provided by the caller ( we limit the search to 32 chars). Otherwise we use "-ERR". */ if (s[0] != '-') { incrementErrorCount("ERR", 3); } else { char *spaceloc = memchr(s, ' ', len < 32 ? len : 32); if (spaceloc) { const size_t errEndPos = (size_t)(spaceloc - s); incrementErrorCount(s+1, errEndPos-1); } else { /* Fallback to ERR if we can't retrieve the error prefix */ incrementErrorCount("ERR", 3); } } } else { /* stat_total_error_replies will not be updated, which means that * the cmd stats will not be updated as well, we still want this command * to be counted as failed so we update it here. We update c->realcmd in * case c->cmd was changed (like in GEOADD). */ c->realcmd->failed_calls++; } /* Sometimes it could be normal that a slave replies to a master with * an error and this function gets called. Actually the error will never * be sent because addReply*() against master clients has no effect... * A notable example is: * * EVAL 'redis.call("incr",KEYS[1]); redis.call("nonexisting")' 1 x * * Where the master must propagate the first change even if the second * will produce an error. However it is useful to log such events since * they are rare and may hint at errors in a script or a bug in Redis. */ int ctype = getClientType(c); if (ctype == CLIENT_TYPE_MASTER || ctype == CLIENT_TYPE_SLAVE || c->id == CLIENT_ID_AOF) { char *to, *from; if (c->id == CLIENT_ID_AOF) { to = "AOF-loading-client"; from = "server"; } else if (ctype == CLIENT_TYPE_MASTER) { to = "master"; from = "replica"; } else { to = "replica"; from = "master"; } if (len > 4096) len = 4096; sds cmdname = c->lastcmd ? c->lastcmd->fullname : NULL; serverLog(LL_WARNING,"== CRITICAL == This %s is sending an error " "to its %s: '%.*s' after processing the command " "'%s'", from, to, (int)len, s, cmdname ? cmdname : ""); if (ctype == CLIENT_TYPE_MASTER && server.repl_backlog && server.repl_backlog->histlen > 0) { showLatestBacklog(); } server.stat_unexpected_error_replies++; /* Based off the propagation error behavior, check if we need to panic here. There * are currently two checked cases: * * If this command was from our master and we are not a writable replica. * * We are reading from an AOF file. */ int panic_in_replicas = (ctype == CLIENT_TYPE_MASTER && server.repl_slave_ro) && (server.propagation_error_behavior == PROPAGATION_ERR_BEHAVIOR_PANIC || server.propagation_error_behavior == PROPAGATION_ERR_BEHAVIOR_PANIC_ON_REPLICAS); int panic_in_aof = c->id == CLIENT_ID_AOF && server.propagation_error_behavior == PROPAGATION_ERR_BEHAVIOR_PANIC; if (panic_in_replicas || panic_in_aof) { serverPanic("This %s panicked sending an error to its %s" " after processing the command '%s'", from, to, cmdname ? cmdname : ""); } } } /* The 'err' object is expected to start with -ERRORCODE and end with \r\n. * Unlike addReplyErrorSds and others alike which rely on addReplyErrorLength. */ void addReplyErrorObject(client *c, robj *err) { addReply(c, err); afterErrorReply(c, err->ptr, sdslen(err->ptr)-2, 0); /* Ignore trailing \r\n */ } /* Sends either a reply or an error reply by checking the first char.  * If the first char is '-' the reply is considered an error.  * In any case the given reply is sent, if the reply is also recognize * as an error we also perform some post reply operations such as * logging and stats update. */ void addReplyOrErrorObject(client *c, robj *reply) { serverAssert(sdsEncodedObject(reply)); sds rep = reply->ptr; if (sdslen(rep) > 1 && rep[0] == '-') { addReplyErrorObject(c, reply); } else { addReply(c, reply); } } /* See addReplyErrorLength for expectations from the input string. */ void addReplyError(client *c, const char *err) { addReplyErrorLength(c,err,strlen(err)); afterErrorReply(c,err,strlen(err),0); } /* Add error reply to the given client. * Supported flags: * * ERR_REPLY_FLAG_NO_STATS_UPDATE - indicate not to perform any error stats updates */ void addReplyErrorSdsEx(client *c, sds err, int flags) { addReplyErrorLength(c,err,sdslen(err)); afterErrorReply(c,err,sdslen(err),flags); sdsfree(err); } /* See addReplyErrorLength for expectations from the input string. */ /* As a side effect the SDS string is freed. */ void addReplyErrorSds(client *c, sds err) { addReplyErrorSdsEx(c, err, 0); } /* See addReplyErrorLength for expectations from the input string. */ /* As a side effect the SDS string is freed. */ void addReplyErrorSdsSafe(client *c, sds err) { err = sdsmapchars(err, "\r\n", " ", 2); addReplyErrorSdsEx(c, err, 0); } /* Internal function used by addReplyErrorFormat and addReplyErrorFormatEx. * Refer to afterErrorReply for more information about the flags. */ static void addReplyErrorFormatInternal(client *c, int flags, const char *fmt, va_list ap) { va_list cpy; va_copy(cpy,ap); sds s = sdscatvprintf(sdsempty(),fmt,cpy); va_end(cpy); /* Trim any newlines at the end (ones will be added by addReplyErrorLength) */ s = sdstrim(s, "\r\n"); /* Make sure there are no newlines in the middle of the string, otherwise * invalid protocol is emitted. */ s = sdsmapchars(s, "\r\n", " ", 2); addReplyErrorLength(c,s,sdslen(s)); afterErrorReply(c,s,sdslen(s),flags); sdsfree(s); } void addReplyErrorFormatEx(client *c, int flags, const char *fmt, ...) { va_list ap; va_start(ap,fmt); addReplyErrorFormatInternal(c, flags, fmt, ap); va_end(ap); } /* See addReplyErrorLength for expectations from the formatted string. * The formatted string is safe to contain \r and \n anywhere. */ void addReplyErrorFormat(client *c, const char *fmt, ...) { va_list ap; va_start(ap,fmt); addReplyErrorFormatInternal(c, 0, fmt, ap); va_end(ap); } void addReplyErrorArity(client *c) { addReplyErrorFormat(c, "wrong number of arguments for '%s' command", c->cmd->fullname); } void addReplyErrorExpireTime(client *c) { addReplyErrorFormat(c, "invalid expire time in '%s' command", c->cmd->fullname); } void addReplyStatusLength(client *c, const char *s, size_t len) { addReplyProto(c,"+",1); addReplyProto(c,s,len); addReplyProto(c,"\r\n",2); } void addReplyStatus(client *c, const char *status) { addReplyStatusLength(c,status,strlen(status)); } void addReplyStatusFormat(client *c, const char *fmt, ...) { va_list ap; va_start(ap,fmt); sds s = sdscatvprintf(sdsempty(),fmt,ap); va_end(ap); addReplyStatusLength(c,s,sdslen(s)); sdsfree(s); } /* Sometimes we are forced to create a new reply node, and we can't append to * the previous one, when that happens, we wanna try to trim the unused space * at the end of the last reply node which we won't use anymore. */ void trimReplyUnusedTailSpace(client *c) { listNode *ln = listLast(c->reply); clientReplyBlock *tail = ln? listNodeValue(ln): NULL; /* Note that 'tail' may be NULL even if we have a tail node, because when * addReplyDeferredLen() is used */ if (!tail) return; /* We only try to trim the space is relatively high (more than a 1/4 of the * allocation), otherwise there's a high chance realloc will NOP. * Also, to avoid large memmove which happens as part of realloc, we only do * that if the used part is small. */ if (tail->size - tail->used > tail->size / 4 && tail->used < PROTO_REPLY_CHUNK_BYTES) { size_t usable_size; size_t old_size = tail->size; tail = zrealloc_usable(tail, tail->used + sizeof(clientReplyBlock), &usable_size); /* take over the allocation's internal fragmentation (at least for * memory usage tracking) */ tail->size = usable_size - sizeof(clientReplyBlock); c->reply_bytes = c->reply_bytes + tail->size - old_size; listNodeValue(ln) = tail; } } /* Adds an empty object to the reply list that will contain the multi bulk * length, which is not known when this function is called. */ void *addReplyDeferredLen(client *c) { /* Note that we install the write event here even if the object is not * ready to be sent, since we are sure that before returning to the * event loop setDeferredAggregateLen() will be called. */ if (prepareClientToWrite(c) != C_OK) return NULL; /* Replicas should normally not cause any writes to the reply buffer. In case a rogue replica sent a command on the * replication link that caused a reply to be generated we'll simply disconnect it. * Note this is the simplest way to check a command added a response. Replication links are used to write data but * not for responses, so we should normally never get here on a replica client. */ if (getClientType(c) == CLIENT_TYPE_SLAVE) { sds cmdname = c->lastcmd ? c->lastcmd->fullname : NULL; logInvalidUseAndFreeClientAsync(c, "Replica generated a reply to command '%s'", cmdname ? cmdname : ""); return NULL; } trimReplyUnusedTailSpace(c); listAddNodeTail(c->reply,NULL); /* NULL is our placeholder. */ return listLast(c->reply); } void setDeferredReply(client *c, void *node, const char *s, size_t length) { listNode *ln = (listNode*)node; clientReplyBlock *next, *prev; /* Abort when *node is NULL: when the client should not accept writes * we return NULL in addReplyDeferredLen() */ if (node == NULL) return; serverAssert(!listNodeValue(ln)); /* Normally we fill this dummy NULL node, added by addReplyDeferredLen(), * with a new buffer structure containing the protocol needed to specify * the length of the array following. However sometimes there might be room * in the previous/next node so we can instead remove this NULL node, and * suffix/prefix our data in the node immediately before/after it, in order * to save a write(2) syscall later. Conditions needed to do it: * * - The prev node is non-NULL and has space in it or * - The next node is non-NULL, * - It has enough room already allocated * - And not too large (avoid large memmove) */ if (ln->prev != NULL && (prev = listNodeValue(ln->prev)) && prev->size - prev->used > 0) { size_t len_to_copy = prev->size - prev->used; if (len_to_copy > length) len_to_copy = length; memcpy(prev->buf + prev->used, s, len_to_copy); prev->used += len_to_copy; length -= len_to_copy; if (length == 0) { listDelNode(c->reply, ln); return; } s += len_to_copy; } if (ln->next != NULL && (next = listNodeValue(ln->next)) && next->size - next->used >= length && next->used < PROTO_REPLY_CHUNK_BYTES * 4) { memmove(next->buf + length, next->buf, next->used); memcpy(next->buf, s, length); next->used += length; listDelNode(c->reply,ln); } else { /* Create a new node */ size_t usable_size; clientReplyBlock *buf = zmalloc_usable(length + sizeof(clientReplyBlock), &usable_size); /* Take over the allocation's internal fragmentation */ buf->size = usable_size - sizeof(clientReplyBlock); buf->used = length; memcpy(buf->buf, s, length); listNodeValue(ln) = buf; c->reply_bytes += buf->size; closeClientOnOutputBufferLimitReached(c, 1); } } /* Populate the length object and try gluing it to the next chunk. */ void setDeferredAggregateLen(client *c, void *node, long length, char prefix) { serverAssert(length >= 0); /* Abort when *node is NULL: when the client should not accept writes * we return NULL in addReplyDeferredLen() */ if (node == NULL) return; /* Things like *2\r\n, %3\r\n or ~4\r\n are emitted very often by the protocol * so we have a few shared objects to use if the integer is small * like it is most of the times. */ const size_t hdr_len = OBJ_SHARED_HDR_STRLEN(length); const int opt_hdr = length < OBJ_SHARED_BULKHDR_LEN; if (prefix == '*' && opt_hdr) { setDeferredReply(c, node, shared.mbulkhdr[length]->ptr, hdr_len); return; } if (prefix == '%' && opt_hdr) { setDeferredReply(c, node, shared.maphdr[length]->ptr, hdr_len); return; } if (prefix == '~' && opt_hdr) { setDeferredReply(c, node, shared.sethdr[length]->ptr, hdr_len); return; } char lenstr[128]; size_t lenstr_len = sprintf(lenstr, "%c%ld\r\n", prefix, length); setDeferredReply(c, node, lenstr, lenstr_len); } void setDeferredArrayLen(client *c, void *node, long length) { setDeferredAggregateLen(c,node,length,'*'); } void setDeferredMapLen(client *c, void *node, long length) { int prefix = c->resp == 2 ? '*' : '%'; if (c->resp == 2) length *= 2; setDeferredAggregateLen(c,node,length,prefix); } void setDeferredSetLen(client *c, void *node, long length) { int prefix = c->resp == 2 ? '*' : '~'; setDeferredAggregateLen(c,node,length,prefix); } void setDeferredAttributeLen(client *c, void *node, long length) { serverAssert(c->resp >= 3); setDeferredAggregateLen(c,node,length,'|'); } void setDeferredPushLen(client *c, void *node, long length) { serverAssert(c->resp >= 3); setDeferredAggregateLen(c,node,length,'>'); } /* Add a double as a bulk reply */ void addReplyDouble(client *c, double d) { if (isinf(d)) { /* Libc in odd systems (Hi Solaris!) will format infinite in a * different way, so better to handle it in an explicit way. */ if (c->resp == 2) { addReplyBulkCString(c, d > 0 ? "inf" : "-inf"); } else { addReplyProto(c, d > 0 ? ",inf\r\n" : ",-inf\r\n", d > 0 ? 6 : 7); } } else { char dbuf[MAX_LONG_DOUBLE_CHARS+32]; int dlen = 0; if (c->resp == 2) { /* In order to prepend the string length before the formatted number, * but still avoid an extra memcpy of the whole number, we reserve space * for maximum header `$0000\r\n`, print double, add the resp header in * front of it, and then send the buffer with the right `start` offset. */ int dlen = snprintf(dbuf+7,sizeof(dbuf) - 7,"%.17g",d); int digits = digits10(dlen); int start = 4 - digits; dbuf[start] = '$'; /* Convert `dlen` to string, putting it's digits after '$' and before the * formatted double string. */ for(int i = digits, val = dlen; val && i > 0 ; --i, val /= 10) { dbuf[start + i] = "0123456789"[val % 10]; } dbuf[5] = '\r'; dbuf[6] = '\n'; dbuf[dlen+7] = '\r'; dbuf[dlen+8] = '\n'; addReplyProto(c,dbuf+start,dlen+9-start); } else { dlen = snprintf(dbuf,sizeof(dbuf),",%.17g\r\n",d); addReplyProto(c,dbuf,dlen); } } } void addReplyBigNum(client *c, const char* num, size_t len) { if (c->resp == 2) { addReplyBulkCBuffer(c, num, len); } else { addReplyProto(c,"(",1); addReplyProto(c,num,len); addReply(c,shared.crlf); } } /* Add a long double as a bulk reply, but uses a human readable formatting * of the double instead of exposing the crude behavior of doubles to the * dear user. */ void addReplyHumanLongDouble(client *c, long double d) { if (c->resp == 2) { robj *o = createStringObjectFromLongDouble(d,1); addReplyBulk(c,o); decrRefCount(o); } else { char buf[MAX_LONG_DOUBLE_CHARS]; int len = ld2string(buf,sizeof(buf),d,LD_STR_HUMAN); addReplyProto(c,",",1); addReplyProto(c,buf,len); addReplyProto(c,"\r\n",2); } } /* Add a long long as integer reply or bulk len / multi bulk count. * Basically this is used to output . */ void addReplyLongLongWithPrefix(client *c, long long ll, char prefix) { char buf[128]; int len; /* Things like $3\r\n or *2\r\n are emitted very often by the protocol * so we have a few shared objects to use if the integer is small * like it is most of the times. */ const int opt_hdr = ll < OBJ_SHARED_BULKHDR_LEN && ll >= 0; const size_t hdr_len = OBJ_SHARED_HDR_STRLEN(ll); if (prefix == '*' && opt_hdr) { addReplyProto(c,shared.mbulkhdr[ll]->ptr,hdr_len); return; } else if (prefix == '$' && opt_hdr) { addReplyProto(c,shared.bulkhdr[ll]->ptr,hdr_len); return; } else if (prefix == '%' && opt_hdr) { addReplyProto(c,shared.maphdr[ll]->ptr,hdr_len); return; } else if (prefix == '~' && opt_hdr) { addReplyProto(c,shared.sethdr[ll]->ptr,hdr_len); return; } buf[0] = prefix; len = ll2string(buf+1,sizeof(buf)-1,ll); buf[len+1] = '\r'; buf[len+2] = '\n'; addReplyProto(c,buf,len+3); } void addReplyLongLong(client *c, long long ll) { if (ll == 0) addReply(c,shared.czero); else if (ll == 1) addReply(c,shared.cone); else addReplyLongLongWithPrefix(c,ll,':'); } void addReplyAggregateLen(client *c, long length, int prefix) { serverAssert(length >= 0); addReplyLongLongWithPrefix(c,length,prefix); } void addReplyArrayLen(client *c, long length) { addReplyAggregateLen(c,length,'*'); } void addReplyMapLen(client *c, long length) { int prefix = c->resp == 2 ? '*' : '%'; if (c->resp == 2) length *= 2; addReplyAggregateLen(c,length,prefix); } void addReplySetLen(client *c, long length) { int prefix = c->resp == 2 ? '*' : '~'; addReplyAggregateLen(c,length,prefix); } void addReplyAttributeLen(client *c, long length) { serverAssert(c->resp >= 3); addReplyAggregateLen(c,length,'|'); } void addReplyPushLen(client *c, long length) { serverAssert(c->resp >= 3); serverAssertWithInfo(c, NULL, c->flags & CLIENT_PUSHING); addReplyAggregateLen(c,length,'>'); } void addReplyNull(client *c) { if (c->resp == 2) { addReplyProto(c,"$-1\r\n",5); } else { addReplyProto(c,"_\r\n",3); } } void addReplyBool(client *c, int b) { if (c->resp == 2) { addReply(c, b ? shared.cone : shared.czero); } else { addReplyProto(c, b ? "#t\r\n" : "#f\r\n",4); } } /* A null array is a concept that no longer exists in RESP3. However * RESP2 had it, so API-wise we have this call, that will emit the correct * RESP2 protocol, however for RESP3 the reply will always be just the * Null type "_\r\n". */ void addReplyNullArray(client *c) { if (c->resp == 2) { addReplyProto(c,"*-1\r\n",5); } else { addReplyProto(c,"_\r\n",3); } } /* Create the length prefix of a bulk reply, example: $2234 */ void addReplyBulkLen(client *c, robj *obj) { size_t len = stringObjectLen(obj); addReplyLongLongWithPrefix(c,len,'$'); } /* Add a Redis Object as a bulk reply */ void addReplyBulk(client *c, robj *obj) { addReplyBulkLen(c,obj); addReply(c,obj); addReply(c,shared.crlf); } /* Add a C buffer as bulk reply */ void addReplyBulkCBuffer(client *c, const void *p, size_t len) { addReplyLongLongWithPrefix(c,len,'$'); addReplyProto(c,p,len); addReply(c,shared.crlf); } /* Add sds to reply (takes ownership of sds and frees it) */ void addReplyBulkSds(client *c, sds s) { addReplyLongLongWithPrefix(c,sdslen(s),'$'); addReplySds(c,s); addReply(c,shared.crlf); } /* Set sds to a deferred reply (for symmetry with addReplyBulkSds it also frees the sds) */ void setDeferredReplyBulkSds(client *c, void *node, sds s) { sds reply = sdscatprintf(sdsempty(), "$%d\r\n%s\r\n", (unsigned)sdslen(s), s); setDeferredReply(c, node, reply, sdslen(reply)); sdsfree(reply); sdsfree(s); } /* Add a C null term string as bulk reply */ void addReplyBulkCString(client *c, const char *s) { if (s == NULL) { addReplyNull(c); } else { addReplyBulkCBuffer(c,s,strlen(s)); } } /* Add a long long as a bulk reply */ void addReplyBulkLongLong(client *c, long long ll) { char buf[64]; int len; len = ll2string(buf,64,ll); addReplyBulkCBuffer(c,buf,len); } /* Reply with a verbatim type having the specified extension. * * The 'ext' is the "extension" of the file, actually just a three * character type that describes the format of the verbatim string. * For instance "txt" means it should be interpreted as a text only * file by the receiver, "md " as markdown, and so forth. Only the * three first characters of the extension are used, and if the * provided one is shorter than that, the remaining is filled with * spaces. */ void addReplyVerbatim(client *c, const char *s, size_t len, const char *ext) { if (c->resp == 2) { addReplyBulkCBuffer(c,s,len); } else { char buf[32]; size_t preflen = snprintf(buf,sizeof(buf),"=%zu\r\nxxx:",len+4); char *p = buf+preflen-4; for (int i = 0; i < 3; i++) { if (*ext == '\0') { p[i] = ' '; } else { p[i] = *ext++; } } addReplyProto(c,buf,preflen); addReplyProto(c,s,len); addReplyProto(c,"\r\n",2); } } /* Add an array of C strings as status replies with a heading. * This function is typically invoked by from commands that support * subcommands in response to the 'help' subcommand. The help array * is terminated by NULL sentinel. */ void addReplyHelp(client *c, const char **help) { sds cmd = sdsnew((char*) c->argv[0]->ptr); void *blenp = addReplyDeferredLen(c); int blen = 0; sdstoupper(cmd); addReplyStatusFormat(c, "%s [ [value] [opt] ...]. Subcommands are:",cmd); sdsfree(cmd); while (help[blen]) addReplyStatus(c,help[blen++]); addReplyStatus(c,"HELP"); addReplyStatus(c," Prints this help."); blen += 1; /* Account for the header. */ blen += 2; /* Account for the footer. */ setDeferredArrayLen(c,blenp,blen); } /* Add a suggestive error reply. * This function is typically invoked by from commands that support * subcommands in response to an unknown subcommand or argument error. */ void addReplySubcommandSyntaxError(client *c) { sds cmd = sdsnew((char*) c->argv[0]->ptr); sdstoupper(cmd); addReplyErrorFormat(c, "unknown subcommand or wrong number of arguments for '%.128s'. Try %s HELP.", (char*)c->argv[1]->ptr,cmd); sdsfree(cmd); } /* Append 'src' client output buffers into 'dst' client output buffers. * This function clears the output buffers of 'src' */ void AddReplyFromClient(client *dst, client *src) { /* If the source client contains a partial response due to client output * buffer limits, propagate that to the dest rather than copy a partial * reply. We don't wanna run the risk of copying partial response in case * for some reason the output limits don't reach the same decision (maybe * they changed) */ if (src->flags & CLIENT_CLOSE_ASAP) { sds client = catClientInfoString(sdsempty(),dst); freeClientAsync(dst); serverLog(LL_WARNING,"Client %s scheduled to be closed ASAP for overcoming of output buffer limits.", client); sdsfree(client); return; } /* First add the static buffer (either into the static buffer or reply list) */ addReplyProto(dst,src->buf, src->bufpos); /* We need to check with prepareClientToWrite again (after addReplyProto) * since addReplyProto may have changed something (like CLIENT_CLOSE_ASAP) */ if (prepareClientToWrite(dst) != C_OK) return; /* We're bypassing _addReplyProtoToList, so we need to add the pre/post * checks in it. */ if (dst->flags & CLIENT_CLOSE_AFTER_REPLY) return; /* Concatenate the reply list into the dest */ if (listLength(src->reply)) listJoin(dst->reply,src->reply); dst->reply_bytes += src->reply_bytes; src->reply_bytes = 0; src->bufpos = 0; if (src->deferred_reply_errors) { deferredAfterErrorReply(dst, src->deferred_reply_errors); listRelease(src->deferred_reply_errors); src->deferred_reply_errors = NULL; } /* Check output buffer limits */ closeClientOnOutputBufferLimitReached(dst, 1); } /* Append the listed errors to the server error statistics. the input * list is not modified and remains the responsibility of the caller. */ void deferredAfterErrorReply(client *c, list *errors) { listIter li; listNode *ln; listRewind(errors,&li); while((ln = listNext(&li))) { sds err = ln->value; afterErrorReply(c, err, sdslen(err), 0); } } /* Logically copy 'src' replica client buffers info to 'dst' replica. * Basically increase referenced buffer block node reference count. */ void copyReplicaOutputBuffer(client *dst, client *src) { serverAssert(src->bufpos == 0 && listLength(src->reply) == 0); if (src->ref_repl_buf_node == NULL) return; dst->ref_repl_buf_node = src->ref_repl_buf_node; dst->ref_block_pos = src->ref_block_pos; ((replBufBlock *)listNodeValue(dst->ref_repl_buf_node))->refcount++; } /* Return true if the specified client has pending reply buffers to write to * the socket. */ int clientHasPendingReplies(client *c) { if (getClientType(c) == CLIENT_TYPE_SLAVE) { /* Replicas use global shared replication buffer instead of * private output buffer. */ serverAssert(c->bufpos == 0 && listLength(c->reply) == 0); if (c->ref_repl_buf_node == NULL) return 0; /* If the last replication buffer block content is totally sent, * we have nothing to send. */ listNode *ln = listLast(server.repl_buffer_blocks); replBufBlock *tail = listNodeValue(ln); if (ln == c->ref_repl_buf_node && c->ref_block_pos == tail->used) return 0; return 1; } else { return c->bufpos || listLength(c->reply); } } /* Return true if client connected from loopback interface */ int islocalClient(client *c) { /* unix-socket */ if (c->flags & CLIENT_UNIX_SOCKET) return 1; /* tcp */ char cip[NET_IP_STR_LEN+1] = { 0 }; connPeerToString(c->conn, cip, sizeof(cip)-1, NULL); return !strcmp(cip,"127.0.0.1") || !strcmp(cip,"::1"); } void clientAcceptHandler(connection *conn) { client *c = connGetPrivateData(conn); if (connGetState(conn) != CONN_STATE_CONNECTED) { serverLog(LL_WARNING, "Error accepting a client connection: %s", connGetLastError(conn)); freeClientAsync(c); return; } /* If the server is running in protected mode (the default) and there * is no password set, nor a specific interface is bound, we don't accept * requests from non loopback interfaces. Instead we try to explain the * user what to do to fix it if needed. */ if (server.protected_mode && DefaultUser->flags & USER_FLAG_NOPASS) { if (!islocalClient(c)) { char *err = "-DENIED Redis is running in protected mode because protected " "mode is enabled and no password is set for the default user. " "In this mode connections are only accepted from the loopback interface. " "If you want to connect from external computers to Redis you " "may adopt one of the following solutions: " "1) Just disable protected mode sending the command " "'CONFIG SET protected-mode no' from the loopback interface " "by connecting to Redis from the same host the server is " "running, however MAKE SURE Redis is not publicly accessible " "from internet if you do so. Use CONFIG REWRITE to make this " "change permanent. " "2) Alternatively you can just disable the protected mode by " "editing the Redis configuration file, and setting the protected " "mode option to 'no', and then restarting the server. " "3) If you started the server manually just for testing, restart " "it with the '--protected-mode no' option. " "4) Setup a an authentication password for the default user. " "NOTE: You only need to do one of the above things in order for " "the server to start accepting connections from the outside.\r\n"; if (connWrite(c->conn,err,strlen(err)) == -1) { /* Nothing to do, Just to avoid the warning... */ } server.stat_rejected_conn++; freeClientAsync(c); return; } } server.stat_numconnections++; moduleFireServerEvent(REDISMODULE_EVENT_CLIENT_CHANGE, REDISMODULE_SUBEVENT_CLIENT_CHANGE_CONNECTED, c); } #define MAX_ACCEPTS_PER_CALL 1000 static void acceptCommonHandler(connection *conn, int flags, char *ip) { client *c; char conninfo[100]; UNUSED(ip); if (connGetState(conn) != CONN_STATE_ACCEPTING) { serverLog(LL_VERBOSE, "Accepted client connection in error state: %s (conn: %s)", connGetLastError(conn), connGetInfo(conn, conninfo, sizeof(conninfo))); connClose(conn); return; } /* Limit the number of connections we take at the same time. * * Admission control will happen before a client is created and connAccept() * called, because we don't want to even start transport-level negotiation * if rejected. */ if (listLength(server.clients) + getClusterConnectionsCount() >= server.maxclients) { char *err; if (server.cluster_enabled) err = "-ERR max number of clients + cluster " "connections reached\r\n"; else err = "-ERR max number of clients reached\r\n"; /* That's a best effort error message, don't check write errors. * Note that for TLS connections, no handshake was done yet so nothing * is written and the connection will just drop. */ if (connWrite(conn,err,strlen(err)) == -1) { /* Nothing to do, Just to avoid the warning... */ } server.stat_rejected_conn++; connClose(conn); return; } /* Create connection and client */ if ((c = createClient(conn)) == NULL) { serverLog(LL_WARNING, "Error registering fd event for the new client: %s (conn: %s)", connGetLastError(conn), connGetInfo(conn, conninfo, sizeof(conninfo))); connClose(conn); /* May be already closed, just ignore errors */ return; } /* Last chance to keep flags */ c->flags |= flags; /* Initiate accept. * * Note that connAccept() is free to do two things here: * 1. Call clientAcceptHandler() immediately; * 2. Schedule a future call to clientAcceptHandler(). * * Because of that, we must do nothing else afterwards. */ if (connAccept(conn, clientAcceptHandler) == C_ERR) { char conninfo[100]; if (connGetState(conn) == CONN_STATE_ERROR) serverLog(LL_WARNING, "Error accepting a client connection: %s (conn: %s)", connGetLastError(conn), connGetInfo(conn, conninfo, sizeof(conninfo))); freeClient(connGetPrivateData(conn)); return; } } void acceptTcpHandler(aeEventLoop *el, int fd, void *privdata, int mask) { int cport, cfd, max = MAX_ACCEPTS_PER_CALL; char cip[NET_IP_STR_LEN]; UNUSED(el); UNUSED(mask); UNUSED(privdata); while(max--) { cfd = anetTcpAccept(server.neterr, fd, cip, sizeof(cip), &cport); if (cfd == ANET_ERR) { if (errno != EWOULDBLOCK) serverLog(LL_WARNING, "Accepting client connection: %s", server.neterr); return; } serverLog(LL_VERBOSE,"Accepted %s:%d", cip, cport); acceptCommonHandler(connCreateAcceptedSocket(cfd),0,cip); } } void acceptTLSHandler(aeEventLoop *el, int fd, void *privdata, int mask) { int cport, cfd, max = MAX_ACCEPTS_PER_CALL; char cip[NET_IP_STR_LEN]; UNUSED(el); UNUSED(mask); UNUSED(privdata); while(max--) { cfd = anetTcpAccept(server.neterr, fd, cip, sizeof(cip), &cport); if (cfd == ANET_ERR) { if (errno != EWOULDBLOCK) serverLog(LL_WARNING, "Accepting client connection: %s", server.neterr); return; } serverLog(LL_VERBOSE,"Accepted %s:%d", cip, cport); acceptCommonHandler(connCreateAcceptedTLS(cfd, server.tls_auth_clients),0,cip); } } void acceptUnixHandler(aeEventLoop *el, int fd, void *privdata, int mask) { int cfd, max = MAX_ACCEPTS_PER_CALL; UNUSED(el); UNUSED(mask); UNUSED(privdata); while(max--) { cfd = anetUnixAccept(server.neterr, fd); if (cfd == ANET_ERR) { if (errno != EWOULDBLOCK) serverLog(LL_WARNING, "Accepting client connection: %s", server.neterr); return; } serverLog(LL_VERBOSE,"Accepted connection to %s", server.unixsocket); acceptCommonHandler(connCreateAcceptedSocket(cfd),CLIENT_UNIX_SOCKET,NULL); } } void freeClientOriginalArgv(client *c) { /* We didn't rewrite this client */ if (!c->original_argv) return; for (int j = 0; j < c->original_argc; j++) decrRefCount(c->original_argv[j]); zfree(c->original_argv); c->original_argv = NULL; c->original_argc = 0; } void freeClientArgv(client *c) { int j; for (j = 0; j < c->argc; j++) decrRefCount(c->argv[j]); c->argc = 0; c->cmd = NULL; c->argv_len_sum = 0; c->argv_len = 0; zfree(c->argv); c->argv = NULL; } /* Close all the slaves connections. This is useful in chained replication * when we resync with our own master and want to force all our slaves to * resync with us as well. */ void disconnectSlaves(void) { listIter li; listNode *ln; listRewind(server.slaves,&li); while((ln = listNext(&li))) { freeClient((client*)ln->value); } } /* Check if there is any other slave waiting dumping RDB finished expect me. * This function is useful to judge current dumping RDB can be used for full * synchronization or not. */ int anyOtherSlaveWaitRdb(client *except_me) { listIter li; listNode *ln; listRewind(server.slaves, &li); while((ln = listNext(&li))) { client *slave = ln->value; if (slave != except_me && slave->replstate == SLAVE_STATE_WAIT_BGSAVE_END) { return 1; } } return 0; } /* Remove the specified client from global lists where the client could * be referenced, not including the Pub/Sub channels. * This is used by freeClient() and replicationCacheMaster(). */ void unlinkClient(client *c) { listNode *ln; /* If this is marked as current client unset it. */ if (server.current_client == c) server.current_client = NULL; /* Certain operations must be done only if the client has an active connection. * If the client was already unlinked or if it's a "fake client" the * conn is already set to NULL. */ if (c->conn) { /* Remove from the list of active clients. */ if (c->client_list_node) { uint64_t id = htonu64(c->id); raxRemove(server.clients_index,(unsigned char*)&id,sizeof(id),NULL); listDelNode(server.clients,c->client_list_node); c->client_list_node = NULL; } /* Check if this is a replica waiting for diskless replication (rdb pipe), * in which case it needs to be cleaned from that list */ if (c->flags & CLIENT_SLAVE && c->replstate == SLAVE_STATE_WAIT_BGSAVE_END && server.rdb_pipe_conns) { int i; for (i=0; i < server.rdb_pipe_numconns; i++) { if (server.rdb_pipe_conns[i] == c->conn) { rdbPipeWriteHandlerConnRemoved(c->conn); server.rdb_pipe_conns[i] = NULL; break; } } } connClose(c->conn); c->conn = NULL; } /* Remove from the list of pending writes if needed. */ if (c->flags & CLIENT_PENDING_WRITE) { ln = listSearchKey(server.clients_pending_write,c); serverAssert(ln != NULL); listDelNode(server.clients_pending_write,ln); c->flags &= ~CLIENT_PENDING_WRITE; } /* Remove from the list of pending reads if needed. */ serverAssert(io_threads_op == IO_THREADS_OP_IDLE); if (c->pending_read_list_node != NULL) { listDelNode(server.clients_pending_read,c->pending_read_list_node); c->pending_read_list_node = NULL; } /* When client was just unblocked because of a blocking operation, * remove it from the list of unblocked clients. */ if (c->flags & CLIENT_UNBLOCKED) { ln = listSearchKey(server.unblocked_clients,c); serverAssert(ln != NULL); listDelNode(server.unblocked_clients,ln); c->flags &= ~CLIENT_UNBLOCKED; } /* Clear the tracking status. */ if (c->flags & CLIENT_TRACKING) disableTracking(c); } /* Clear the client state to resemble a newly connected client. */ void clearClientConnectionState(client *c) { listNode *ln; /* MONITOR clients are also marked with CLIENT_SLAVE, we need to * distinguish between the two. */ if (c->flags & CLIENT_MONITOR) { ln = listSearchKey(server.monitors,c); serverAssert(ln != NULL); listDelNode(server.monitors,ln); c->flags &= ~(CLIENT_MONITOR|CLIENT_SLAVE); } serverAssert(!(c->flags &(CLIENT_SLAVE|CLIENT_MASTER))); if (c->flags & CLIENT_TRACKING) disableTracking(c); selectDb(c,0); c->resp = 2; clientSetDefaultAuth(c); moduleNotifyUserChanged(c); discardTransaction(c); pubsubUnsubscribeAllChannels(c,0); pubsubUnsubscribeShardAllChannels(c, 0); pubsubUnsubscribeAllPatterns(c,0); if (c->name) { decrRefCount(c->name); c->name = NULL; } /* Selectively clear state flags not covered above */ c->flags &= ~(CLIENT_ASKING|CLIENT_READONLY|CLIENT_PUBSUB| CLIENT_REPLY_OFF|CLIENT_REPLY_SKIP_NEXT); } void freeClient(client *c) { listNode *ln; /* If a client is protected, yet we need to free it right now, make sure * to at least use asynchronous freeing. */ if (c->flags & CLIENT_PROTECTED) { freeClientAsync(c); return; } /* For connected clients, call the disconnection event of modules hooks. */ if (c->conn) { moduleFireServerEvent(REDISMODULE_EVENT_CLIENT_CHANGE, REDISMODULE_SUBEVENT_CLIENT_CHANGE_DISCONNECTED, c); } /* Notify module system that this client auth status changed. */ moduleNotifyUserChanged(c); /* If this client was scheduled for async freeing we need to remove it * from the queue. Note that we need to do this here, because later * we may call replicationCacheMaster() and the client should already * be removed from the list of clients to free. */ if (c->flags & CLIENT_CLOSE_ASAP) { ln = listSearchKey(server.clients_to_close,c); serverAssert(ln != NULL); listDelNode(server.clients_to_close,ln); } /* If it is our master that's being disconnected we should make sure * to cache the state to try a partial resynchronization later. * * Note that before doing this we make sure that the client is not in * some unexpected state, by checking its flags. */ if (server.master && c->flags & CLIENT_MASTER) { serverLog(LL_WARNING,"Connection with master lost."); if (!(c->flags & (CLIENT_PROTOCOL_ERROR|CLIENT_BLOCKED))) { c->flags &= ~(CLIENT_CLOSE_ASAP|CLIENT_CLOSE_AFTER_REPLY); replicationCacheMaster(c); return; } } /* Log link disconnection with slave */ if (getClientType(c) == CLIENT_TYPE_SLAVE) { serverLog(LL_WARNING,"Connection with replica %s lost.", replicationGetSlaveName(c)); } /* Free the query buffer */ sdsfree(c->querybuf); c->querybuf = NULL; /* Deallocate structures used to block on blocking ops. */ if (c->flags & CLIENT_BLOCKED) unblockClient(c); dictRelease(c->bpop.keys); /* UNWATCH all the keys */ unwatchAllKeys(c); listRelease(c->watched_keys); /* Unsubscribe from all the pubsub channels */ pubsubUnsubscribeAllChannels(c,0); pubsubUnsubscribeShardAllChannels(c, 0); pubsubUnsubscribeAllPatterns(c,0); dictRelease(c->pubsub_channels); listRelease(c->pubsub_patterns); dictRelease(c->pubsubshard_channels); /* Free data structures. */ listRelease(c->reply); zfree(c->buf); freeReplicaReferencedReplBuffer(c); freeClientArgv(c); freeClientOriginalArgv(c); if (c->deferred_reply_errors) listRelease(c->deferred_reply_errors); /* Unlink the client: this will close the socket, remove the I/O * handlers, and remove references of the client from different * places where active clients may be referenced. */ unlinkClient(c); /* Master/slave cleanup Case 1: * we lost the connection with a slave. */ if (c->flags & CLIENT_SLAVE) { /* If there is no any other slave waiting dumping RDB finished, the * current child process need not continue to dump RDB, then we kill it. * So child process won't use more memory, and we also can fork a new * child process asap to dump rdb for next full synchronization or bgsave. * But we also need to check if users enable 'save' RDB, if enable, we * should not remove directly since that means RDB is important for users * to keep data safe and we may delay configured 'save' for full sync. */ if (server.saveparamslen == 0 && c->replstate == SLAVE_STATE_WAIT_BGSAVE_END && server.child_type == CHILD_TYPE_RDB && server.rdb_child_type == RDB_CHILD_TYPE_DISK && anyOtherSlaveWaitRdb(c) == 0) { killRDBChild(); } if (c->replstate == SLAVE_STATE_SEND_BULK) { if (c->repldbfd != -1) close(c->repldbfd); if (c->replpreamble) sdsfree(c->replpreamble); } list *l = (c->flags & CLIENT_MONITOR) ? server.monitors : server.slaves; ln = listSearchKey(l,c); serverAssert(ln != NULL); listDelNode(l,ln); /* We need to remember the time when we started to have zero * attached slaves, as after some time we'll free the replication * backlog. */ if (getClientType(c) == CLIENT_TYPE_SLAVE && listLength(server.slaves) == 0) server.repl_no_slaves_since = server.unixtime; refreshGoodSlavesCount(); /* Fire the replica change modules event. */ if (c->replstate == SLAVE_STATE_ONLINE) moduleFireServerEvent(REDISMODULE_EVENT_REPLICA_CHANGE, REDISMODULE_SUBEVENT_REPLICA_CHANGE_OFFLINE, NULL); } /* Master/slave cleanup Case 2: * we lost the connection with the master. */ if (c->flags & CLIENT_MASTER) replicationHandleMasterDisconnection(); /* Remove the contribution that this client gave to our * incrementally computed memory usage. */ server.stat_clients_type_memory[c->last_memory_type] -= c->last_memory_usage; /* Remove client from memory usage buckets */ if (c->mem_usage_bucket) { c->mem_usage_bucket->mem_usage_sum -= c->last_memory_usage; listDelNode(c->mem_usage_bucket->clients, c->mem_usage_bucket_node); } /* Release other dynamically allocated client structure fields, * and finally release the client structure itself. */ if (c->name) decrRefCount(c->name); freeClientMultiState(c); sdsfree(c->peerid); sdsfree(c->sockname); sdsfree(c->slave_addr); zfree(c); } /* Schedule a client to free it at a safe time in the serverCron() function. * This function is useful when we need to terminate a client but we are in * a context where calling freeClient() is not possible, because the client * should be valid for the continuation of the flow of the program. */ void freeClientAsync(client *c) { /* We need to handle concurrent access to the server.clients_to_close list * only in the freeClientAsync() function, since it's the only function that * may access the list while Redis uses I/O threads. All the other accesses * are in the context of the main thread while the other threads are * idle. */ if (c->flags & CLIENT_CLOSE_ASAP || c->flags & CLIENT_SCRIPT) return; c->flags |= CLIENT_CLOSE_ASAP; if (server.io_threads_num == 1) { /* no need to bother with locking if there's just one thread (the main thread) */ listAddNodeTail(server.clients_to_close,c); return; } static pthread_mutex_t async_free_queue_mutex = PTHREAD_MUTEX_INITIALIZER; pthread_mutex_lock(&async_free_queue_mutex); listAddNodeTail(server.clients_to_close,c); pthread_mutex_unlock(&async_free_queue_mutex); } /* Log errors for invalid use and free the client in async way. * We will add additional information about the client to the message. */ void logInvalidUseAndFreeClientAsync(client *c, const char *fmt, ...) { va_list ap; va_start(ap, fmt); sds info = sdscatvprintf(sdsempty(), fmt, ap); va_end(ap); sds client = catClientInfoString(sdsempty(), c); serverLog(LL_WARNING, "%s, disconnecting it: %s", info, client); sdsfree(info); sdsfree(client); freeClientAsync(c); } /* Perform processing of the client before moving on to processing the next client * this is useful for performing operations that affect the global state but can't * wait until we're done with all clients. In other words can't wait until beforeSleep() * return C_ERR in case client is no longer valid after call. * The input client argument: c, may be NULL in case the previous client was * freed before the call. */ int beforeNextClient(client *c) { /* Skip the client processing if we're in an IO thread, in that case we'll perform this operation later (this function is called again) in the fan-in stage of the threading mechanism */ if (io_threads_op != IO_THREADS_OP_IDLE) return C_OK; /* Handle async frees */ /* Note: this doesn't make the server.clients_to_close list redundant because of * cases where we want an async free of a client other than myself. For example * in ACL modifications we disconnect clients authenticated to non-existent * users (see ACL LOAD). */ if (c && (c->flags & CLIENT_CLOSE_ASAP)) { freeClient(c); return C_ERR; } return C_OK; } /* Free the clients marked as CLOSE_ASAP, return the number of clients * freed. */ int freeClientsInAsyncFreeQueue(void) { int freed = 0; listIter li; listNode *ln; listRewind(server.clients_to_close,&li); while ((ln = listNext(&li)) != NULL) { client *c = listNodeValue(ln); if (c->flags & CLIENT_PROTECTED) continue; c->flags &= ~CLIENT_CLOSE_ASAP; freeClient(c); listDelNode(server.clients_to_close,ln); freed++; } return freed; } /* Return a client by ID, or NULL if the client ID is not in the set * of registered clients. Note that "fake clients", created with -1 as FD, * are not registered clients. */ client *lookupClientByID(uint64_t id) { id = htonu64(id); client *c = raxFind(server.clients_index,(unsigned char*)&id,sizeof(id)); return (c == raxNotFound) ? NULL : c; } /* This function should be called from _writeToClient when the reply list is not empty, * it gathers the scattered buffers from reply list and sends them away with connWritev. * If we write successfully, it returns C_OK, otherwise, C_ERR is returned, * and 'nwritten' is an output parameter, it means how many bytes server write * to client. */ static int _writevToClient(client *c, ssize_t *nwritten) { struct iovec iov[IOV_MAX]; int iovcnt = 0; size_t iov_bytes_len = 0; /* If the static reply buffer is not empty, * add it to the iov array for writev() as well. */ if (c->bufpos > 0) { iov[iovcnt].iov_base = c->buf + c->sentlen; iov[iovcnt].iov_len = c->bufpos - c->sentlen; iov_bytes_len += iov[iovcnt++].iov_len; } /* The first node of reply list might be incomplete from the last call, * thus it needs to be calibrated to get the actual data address and length. */ size_t offset = c->bufpos > 0 ? 0 : c->sentlen; listIter iter; listNode *next; clientReplyBlock *o; listRewind(c->reply, &iter); while ((next = listNext(&iter)) && iovcnt < IOV_MAX && iov_bytes_len < NET_MAX_WRITES_PER_EVENT) { o = listNodeValue(next); if (o->used == 0) { /* empty node, just release it and skip. */ c->reply_bytes -= o->size; listDelNode(c->reply, next); offset = 0; continue; } iov[iovcnt].iov_base = o->buf + offset; iov[iovcnt].iov_len = o->used - offset; iov_bytes_len += iov[iovcnt++].iov_len; offset = 0; } if (iovcnt == 0) return C_OK; *nwritten = connWritev(c->conn, iov, iovcnt); if (*nwritten <= 0) return C_ERR; /* Locate the new node which has leftover data and * release all nodes in front of it. */ ssize_t remaining = *nwritten; if (c->bufpos > 0) { /* deal with static reply buffer first. */ int buf_len = c->bufpos - c->sentlen; c->sentlen += remaining; /* If the buffer was sent, set bufpos to zero to continue with * the remainder of the reply. */ if (remaining >= buf_len) { c->bufpos = 0; c->sentlen = 0; } remaining -= buf_len; } listRewind(c->reply, &iter); while (remaining > 0) { next = listNext(&iter); o = listNodeValue(next); if (remaining < (ssize_t)(o->used - c->sentlen)) { c->sentlen += remaining; break; } remaining -= (ssize_t)(o->used - c->sentlen); c->reply_bytes -= o->size; listDelNode(c->reply, next); c->sentlen = 0; } return C_OK; } /* This function does actual writing output buffers to different types of * clients, it is called by writeToClient. * If we write successfully, it returns C_OK, otherwise, C_ERR is returned, * and 'nwritten' is an output parameter, it means how many bytes server write * to client. */ int _writeToClient(client *c, ssize_t *nwritten) { *nwritten = 0; if (getClientType(c) == CLIENT_TYPE_SLAVE) { serverAssert(c->bufpos == 0 && listLength(c->reply) == 0); replBufBlock *o = listNodeValue(c->ref_repl_buf_node); serverAssert(o->used >= c->ref_block_pos); /* Send current block if it is not fully sent. */ if (o->used > c->ref_block_pos) { *nwritten = connWrite(c->conn, o->buf+c->ref_block_pos, o->used-c->ref_block_pos); if (*nwritten <= 0) return C_ERR; c->ref_block_pos += *nwritten; } /* If we fully sent the object on head, go to the next one. */ listNode *next = listNextNode(c->ref_repl_buf_node); if (next && c->ref_block_pos == o->used) { o->refcount--; ((replBufBlock *)(listNodeValue(next)))->refcount++; c->ref_repl_buf_node = next; c->ref_block_pos = 0; incrementalTrimReplicationBacklog(REPL_BACKLOG_TRIM_BLOCKS_PER_CALL); } return C_OK; } /* When the reply list is not empty, it's better to use writev to save us some * system calls and TCP packets. */ if (listLength(c->reply) > 0) { int ret = _writevToClient(c, nwritten); if (ret != C_OK) return ret; /* If there are no longer objects in the list, we expect * the count of reply bytes to be exactly zero. */ if (listLength(c->reply) == 0) serverAssert(c->reply_bytes == 0); } else if (c->bufpos > 0) { *nwritten = connWrite(c->conn, c->buf + c->sentlen, c->bufpos - c->sentlen); if (*nwritten <= 0) return C_ERR; c->sentlen += *nwritten; /* If the buffer was sent, set bufpos to zero to continue with * the remainder of the reply. */ if ((int)c->sentlen == c->bufpos) { c->bufpos = 0; c->sentlen = 0; } } return C_OK; } /* Write data in output buffers to client. Return C_OK if the client * is still valid after the call, C_ERR if it was freed because of some * error. If handler_installed is set, it will attempt to clear the * write event. * * This function is called by threads, but always with handler_installed * set to 0. So when handler_installed is set to 0 the function must be * thread safe. */ int writeToClient(client *c, int handler_installed) { /* Update total number of writes on server */ atomicIncr(server.stat_total_writes_processed, 1); ssize_t nwritten = 0, totwritten = 0; while(clientHasPendingReplies(c)) { int ret = _writeToClient(c, &nwritten); if (ret == C_ERR) break; totwritten += nwritten; /* Note that we avoid to send more than NET_MAX_WRITES_PER_EVENT * bytes, in a single threaded server it's a good idea to serve * other clients as well, even if a very large request comes from * super fast link that is always able to accept data (in real world * scenario think about 'KEYS *' against the loopback interface). * * However if we are over the maxmemory limit we ignore that and * just deliver as much data as it is possible to deliver. * * Moreover, we also send as much as possible if the client is * a slave or a monitor (otherwise, on high-speed traffic, the * replication/output buffer will grow indefinitely) */ if (totwritten > NET_MAX_WRITES_PER_EVENT && (server.maxmemory == 0 || zmalloc_used_memory() < server.maxmemory) && !(c->flags & CLIENT_SLAVE)) break; } if (getClientType(c) == CLIENT_TYPE_SLAVE) { atomicIncr(server.stat_net_repl_output_bytes, totwritten); } else { atomicIncr(server.stat_net_output_bytes, totwritten); } if (nwritten == -1) { if (connGetState(c->conn) != CONN_STATE_CONNECTED) { serverLog(LL_VERBOSE, "Error writing to client: %s", connGetLastError(c->conn)); freeClientAsync(c); return C_ERR; } } if (totwritten > 0) { /* For clients representing masters we don't count sending data * as an interaction, since we always send REPLCONF ACK commands * that take some time to just fill the socket output buffer. * We just rely on data / pings received for timeout detection. */ if (!(c->flags & CLIENT_MASTER)) c->lastinteraction = server.unixtime; } if (!clientHasPendingReplies(c)) { c->sentlen = 0; /* Note that writeToClient() is called in a threaded way, but * aeDeleteFileEvent() is not thread safe: however writeToClient() * is always called with handler_installed set to 0 from threads * so we are fine. */ if (handler_installed) { serverAssert(io_threads_op == IO_THREADS_OP_IDLE); connSetWriteHandler(c->conn, NULL); } /* Close connection after entire reply has been sent. */ if (c->flags & CLIENT_CLOSE_AFTER_REPLY) { freeClientAsync(c); return C_ERR; } } /* Update client's memory usage after writing. * Since this isn't thread safe we do this conditionally. In case of threaded writes this is done in * handleClientsWithPendingWritesUsingThreads(). */ if (io_threads_op == IO_THREADS_OP_IDLE) updateClientMemUsageAndBucket(c); return C_OK; } /* Write event handler. Just send data to the client. */ void sendReplyToClient(connection *conn) { client *c = connGetPrivateData(conn); writeToClient(c,1); } /* This function is called just before entering the event loop, in the hope * we can just write the replies to the client output buffer without any * need to use a syscall in order to install the writable event handler, * get it called, and so forth. */ int handleClientsWithPendingWrites(void) { listIter li; listNode *ln; int processed = listLength(server.clients_pending_write); listRewind(server.clients_pending_write,&li); while((ln = listNext(&li))) { client *c = listNodeValue(ln); c->flags &= ~CLIENT_PENDING_WRITE; listDelNode(server.clients_pending_write,ln); /* If a client is protected, don't do anything, * that may trigger write error or recreate handler. */ if (c->flags & CLIENT_PROTECTED) continue; /* Don't write to clients that are going to be closed anyway. */ if (c->flags & CLIENT_CLOSE_ASAP) continue; /* Try to write buffers to the client socket. */ if (writeToClient(c,0) == C_ERR) continue; /* If after the synchronous writes above we still have data to * output to the client, we need to install the writable handler. */ if (clientHasPendingReplies(c)) { installClientWriteHandler(c); } } return processed; } /* resetClient prepare the client to process the next command */ void resetClient(client *c) { redisCommandProc *prevcmd = c->cmd ? c->cmd->proc : NULL; freeClientArgv(c); c->cur_script = NULL; c->reqtype = 0; c->multibulklen = 0; c->bulklen = -1; c->slot = -1; if (c->deferred_reply_errors) listRelease(c->deferred_reply_errors); c->deferred_reply_errors = NULL; /* We clear the ASKING flag as well if we are not inside a MULTI, and * if what we just executed is not the ASKING command itself. */ if (!(c->flags & CLIENT_MULTI) && prevcmd != askingCommand) c->flags &= ~CLIENT_ASKING; /* We do the same for the CACHING command as well. It also affects * the next command or transaction executed, in a way very similar * to ASKING. */ if (!(c->flags & CLIENT_MULTI) && prevcmd != clientCommand) c->flags &= ~CLIENT_TRACKING_CACHING; /* Remove the CLIENT_REPLY_SKIP flag if any so that the reply * to the next command will be sent, but set the flag if the command * we just processed was "CLIENT REPLY SKIP". */ c->flags &= ~CLIENT_REPLY_SKIP; if (c->flags & CLIENT_REPLY_SKIP_NEXT) { c->flags |= CLIENT_REPLY_SKIP; c->flags &= ~CLIENT_REPLY_SKIP_NEXT; } } /* This function is used when we want to re-enter the event loop but there * is the risk that the client we are dealing with will be freed in some * way. This happens for instance in: * * * DEBUG RELOAD and similar. * * When a Lua script is in -BUSY state. * * So the function will protect the client by doing two things: * * 1) It removes the file events. This way it is not possible that an * error is signaled on the socket, freeing the client. * 2) Moreover it makes sure that if the client is freed in a different code * path, it is not really released, but only marked for later release. */ void protectClient(client *c) { c->flags |= CLIENT_PROTECTED; if (c->conn) { connSetReadHandler(c->conn,NULL); connSetWriteHandler(c->conn,NULL); } } /* This will undo the client protection done by protectClient() */ void unprotectClient(client *c) { if (c->flags & CLIENT_PROTECTED) { c->flags &= ~CLIENT_PROTECTED; if (c->conn) { connSetReadHandler(c->conn,readQueryFromClient); if (clientHasPendingReplies(c)) putClientInPendingWriteQueue(c); } } } /* Like processMultibulkBuffer(), but for the inline protocol instead of RESP, * this function consumes the client query buffer and creates a command ready * to be executed inside the client structure. Returns C_OK if the command * is ready to be executed, or C_ERR if there is still protocol to read to * have a well formed command. The function also returns C_ERR when there is * a protocol error: in such a case the client structure is setup to reply * with the error and close the connection. */ int processInlineBuffer(client *c) { char *newline; int argc, j, linefeed_chars = 1; sds *argv, aux; size_t querylen; /* Search for end of line */ newline = strchr(c->querybuf+c->qb_pos,'\n'); /* Nothing to do without a \r\n */ if (newline == NULL) { if (sdslen(c->querybuf)-c->qb_pos > PROTO_INLINE_MAX_SIZE) { addReplyError(c,"Protocol error: too big inline request"); setProtocolError("too big inline request",c); } return C_ERR; } /* Handle the \r\n case. */ if (newline != c->querybuf+c->qb_pos && *(newline-1) == '\r') newline--, linefeed_chars++; /* Split the input buffer up to the \r\n */ querylen = newline-(c->querybuf+c->qb_pos); aux = sdsnewlen(c->querybuf+c->qb_pos,querylen); argv = sdssplitargs(aux,&argc); sdsfree(aux); if (argv == NULL) { addReplyError(c,"Protocol error: unbalanced quotes in request"); setProtocolError("unbalanced quotes in inline request",c); return C_ERR; } /* Newline from slaves can be used to refresh the last ACK time. * This is useful for a slave to ping back while loading a big * RDB file. */ if (querylen == 0 && getClientType(c) == CLIENT_TYPE_SLAVE) c->repl_ack_time = server.unixtime; /* Masters should never send us inline protocol to run actual * commands. If this happens, it is likely due to a bug in Redis where * we got some desynchronization in the protocol, for example * because of a PSYNC gone bad. * * However there is an exception: masters may send us just a newline * to keep the connection active. */ if (querylen != 0 && c->flags & CLIENT_MASTER) { sdsfreesplitres(argv,argc); serverLog(LL_WARNING,"WARNING: Receiving inline protocol from master, master stream corruption? Closing the master connection and discarding the cached master."); setProtocolError("Master using the inline protocol. Desync?",c); return C_ERR; } /* Move querybuffer position to the next query in the buffer. */ c->qb_pos += querylen+linefeed_chars; /* Setup argv array on client structure */ if (argc) { if (c->argv) zfree(c->argv); c->argv_len = argc; c->argv = zmalloc(sizeof(robj*)*c->argv_len); c->argv_len_sum = 0; } /* Create redis objects for all arguments. */ for (c->argc = 0, j = 0; j < argc; j++) { c->argv[c->argc] = createObject(OBJ_STRING,argv[j]); c->argc++; c->argv_len_sum += sdslen(argv[j]); } zfree(argv); return C_OK; } /* Helper function. Record protocol error details in server log, * and set the client as CLIENT_CLOSE_AFTER_REPLY and * CLIENT_PROTOCOL_ERROR. */ #define PROTO_DUMP_LEN 128 static void setProtocolError(const char *errstr, client *c) { if (server.verbosity <= LL_VERBOSE || c->flags & CLIENT_MASTER) { sds client = catClientInfoString(sdsempty(),c); /* Sample some protocol to given an idea about what was inside. */ char buf[256]; if (sdslen(c->querybuf)-c->qb_pos < PROTO_DUMP_LEN) { snprintf(buf,sizeof(buf),"Query buffer during protocol error: '%s'", c->querybuf+c->qb_pos); } else { snprintf(buf,sizeof(buf),"Query buffer during protocol error: '%.*s' (... more %zu bytes ...) '%.*s'", PROTO_DUMP_LEN/2, c->querybuf+c->qb_pos, sdslen(c->querybuf)-c->qb_pos-PROTO_DUMP_LEN, PROTO_DUMP_LEN/2, c->querybuf+sdslen(c->querybuf)-PROTO_DUMP_LEN/2); } /* Remove non printable chars. */ char *p = buf; while (*p != '\0') { if (!isprint(*p)) *p = '.'; p++; } /* Log all the client and protocol info. */ int loglevel = (c->flags & CLIENT_MASTER) ? LL_WARNING : LL_VERBOSE; serverLog(loglevel, "Protocol error (%s) from client: %s. %s", errstr, client, buf); sdsfree(client); } c->flags |= (CLIENT_CLOSE_AFTER_REPLY|CLIENT_PROTOCOL_ERROR); } /* Process the query buffer for client 'c', setting up the client argument * vector for command execution. Returns C_OK if after running the function * the client has a well-formed ready to be processed command, otherwise * C_ERR if there is still to read more buffer to get the full command. * The function also returns C_ERR when there is a protocol error: in such a * case the client structure is setup to reply with the error and close * the connection. * * This function is called if processInputBuffer() detects that the next * command is in RESP format, so the first byte in the command is found * to be '*'. Otherwise for inline commands processInlineBuffer() is called. */ int processMultibulkBuffer(client *c) { char *newline = NULL; int ok; long long ll; if (c->multibulklen == 0) { /* The client should have been reset */ serverAssertWithInfo(c,NULL,c->argc == 0); /* Multi bulk length cannot be read without a \r\n */ newline = strchr(c->querybuf+c->qb_pos,'\r'); if (newline == NULL) { if (sdslen(c->querybuf)-c->qb_pos > PROTO_INLINE_MAX_SIZE) { addReplyError(c,"Protocol error: too big mbulk count string"); setProtocolError("too big mbulk count string",c); } return C_ERR; } /* Buffer should also contain \n */ if (newline-(c->querybuf+c->qb_pos) > (ssize_t)(sdslen(c->querybuf)-c->qb_pos-2)) return C_ERR; /* We know for sure there is a whole line since newline != NULL, * so go ahead and find out the multi bulk length. */ serverAssertWithInfo(c,NULL,c->querybuf[c->qb_pos] == '*'); ok = string2ll(c->querybuf+1+c->qb_pos,newline-(c->querybuf+1+c->qb_pos),&ll); if (!ok || ll > INT_MAX) { addReplyError(c,"Protocol error: invalid multibulk length"); setProtocolError("invalid mbulk count",c); return C_ERR; } else if (ll > 10 && authRequired(c)) { addReplyError(c, "Protocol error: unauthenticated multibulk length"); setProtocolError("unauth mbulk count", c); return C_ERR; } c->qb_pos = (newline-c->querybuf)+2; if (ll <= 0) return C_OK; c->multibulklen = ll; /* Setup argv array on client structure */ if (c->argv) zfree(c->argv); c->argv_len = min(c->multibulklen, 1024); c->argv = zmalloc(sizeof(robj*)*c->argv_len); c->argv_len_sum = 0; } serverAssertWithInfo(c,NULL,c->multibulklen > 0); while(c->multibulklen) { /* Read bulk length if unknown */ if (c->bulklen == -1) { newline = strchr(c->querybuf+c->qb_pos,'\r'); if (newline == NULL) { if (sdslen(c->querybuf)-c->qb_pos > PROTO_INLINE_MAX_SIZE) { addReplyError(c, "Protocol error: too big bulk count string"); setProtocolError("too big bulk count string",c); return C_ERR; } break; } /* Buffer should also contain \n */ if (newline-(c->querybuf+c->qb_pos) > (ssize_t)(sdslen(c->querybuf)-c->qb_pos-2)) break; if (c->querybuf[c->qb_pos] != '$') { addReplyErrorFormat(c, "Protocol error: expected '$', got '%c'", c->querybuf[c->qb_pos]); setProtocolError("expected $ but got something else",c); return C_ERR; } ok = string2ll(c->querybuf+c->qb_pos+1,newline-(c->querybuf+c->qb_pos+1),&ll); if (!ok || ll < 0 || (!(c->flags & CLIENT_MASTER) && ll > server.proto_max_bulk_len)) { addReplyError(c,"Protocol error: invalid bulk length"); setProtocolError("invalid bulk length",c); return C_ERR; } else if (ll > 16384 && authRequired(c)) { addReplyError(c, "Protocol error: unauthenticated bulk length"); setProtocolError("unauth bulk length", c); return C_ERR; } c->qb_pos = newline-c->querybuf+2; if (!(c->flags & CLIENT_MASTER) && ll >= PROTO_MBULK_BIG_ARG) { /* When the client is not a master client (because master * client's querybuf can only be trimmed after data applied * and sent to replicas). * * If we are going to read a large object from network * try to make it likely that it will start at c->querybuf * boundary so that we can optimize object creation * avoiding a large copy of data. * * But only when the data we have not parsed is less than * or equal to ll+2. If the data length is greater than * ll+2, trimming querybuf is just a waste of time, because * at this time the querybuf contains not only our bulk. */ if (sdslen(c->querybuf)-c->qb_pos <= (size_t)ll+2) { sdsrange(c->querybuf,c->qb_pos,-1); c->qb_pos = 0; /* Hint the sds library about the amount of bytes this string is * going to contain. */ c->querybuf = sdsMakeRoomForNonGreedy(c->querybuf,ll+2-sdslen(c->querybuf)); } } c->bulklen = ll; } /* Read bulk argument */ if (sdslen(c->querybuf)-c->qb_pos < (size_t)(c->bulklen+2)) { /* Not enough data (+2 == trailing \r\n) */ break; } else { /* Check if we have space in argv, grow if needed */ if (c->argc >= c->argv_len) { c->argv_len = min(c->argv_len < INT_MAX/2 ? c->argv_len*2 : INT_MAX, c->argc+c->multibulklen); c->argv = zrealloc(c->argv, sizeof(robj*)*c->argv_len); } /* Optimization: if a non-master client's buffer contains JUST our bulk element * instead of creating a new object by *copying* the sds we * just use the current sds string. */ if (!(c->flags & CLIENT_MASTER) && c->qb_pos == 0 && c->bulklen >= PROTO_MBULK_BIG_ARG && sdslen(c->querybuf) == (size_t)(c->bulklen+2)) { c->argv[c->argc++] = createObject(OBJ_STRING,c->querybuf); c->argv_len_sum += c->bulklen; sdsIncrLen(c->querybuf,-2); /* remove CRLF */ /* Assume that if we saw a fat argument we'll see another one * likely... */ c->querybuf = sdsnewlen(SDS_NOINIT,c->bulklen+2); sdsclear(c->querybuf); } else { c->argv[c->argc++] = createStringObject(c->querybuf+c->qb_pos,c->bulklen); c->argv_len_sum += c->bulklen; c->qb_pos += c->bulklen+2; } c->bulklen = -1; c->multibulklen--; } } /* We're done when c->multibulk == 0 */ if (c->multibulklen == 0) return C_OK; /* Still not ready to process the command */ return C_ERR; } /* Perform necessary tasks after a command was executed: * * 1. The client is reset unless there are reasons to avoid doing it. * 2. In the case of master clients, the replication offset is updated. * 3. Propagate commands we got from our master to replicas down the line. */ void commandProcessed(client *c) { /* If client is blocked(including paused), just return avoid reset and replicate. * * 1. Don't reset the client structure for blocked clients, so that the reply * callback will still be able to access the client argv and argc fields. * The client will be reset in unblockClient(). * 2. Don't update replication offset or propagate commands to replicas, * since we have not applied the command. */ if (c->flags & CLIENT_BLOCKED) return; resetClient(c); long long prev_offset = c->reploff; if (c->flags & CLIENT_MASTER && !(c->flags & CLIENT_MULTI)) { /* Update the applied replication offset of our master. */ c->reploff = c->read_reploff - sdslen(c->querybuf) + c->qb_pos; } /* If the client is a master we need to compute the difference * between the applied offset before and after processing the buffer, * to understand how much of the replication stream was actually * applied to the master state: this quantity, and its corresponding * part of the replication stream, will be propagated to the * sub-replicas and to the replication backlog. */ if (c->flags & CLIENT_MASTER) { long long applied = c->reploff - prev_offset; if (applied) { replicationFeedStreamFromMasterStream(c->querybuf+c->repl_applied,applied); c->repl_applied += applied; } } } /* This function calls processCommand(), but also performs a few sub tasks * for the client that are useful in that context: * * 1. It sets the current client to the client 'c'. * 2. calls commandProcessed() if the command was handled. * * The function returns C_ERR in case the client was freed as a side effect * of processing the command, otherwise C_OK is returned. */ int processCommandAndResetClient(client *c) { int deadclient = 0; client *old_client = server.current_client; server.current_client = c; if (processCommand(c) == C_OK) { commandProcessed(c); /* Update the client's memory to include output buffer growth following the * processed command. */ updateClientMemUsageAndBucket(c); } if (server.current_client == NULL) deadclient = 1; /* * Restore the old client, this is needed because when a script * times out, we will get into this code from processEventsWhileBlocked. * Which will cause to set the server.current_client. If not restored * we will return 1 to our caller which will falsely indicate the client * is dead and will stop reading from its buffer. */ server.current_client = old_client; /* performEvictions may flush slave output buffers. This may * result in a slave, that may be the active client, to be * freed. */ return deadclient ? C_ERR : C_OK; } /* This function will execute any fully parsed commands pending on * the client. Returns C_ERR if the client is no longer valid after executing * the command, and C_OK for all other cases. */ int processPendingCommandAndInputBuffer(client *c) { if (c->flags & CLIENT_PENDING_COMMAND) { c->flags &= ~CLIENT_PENDING_COMMAND; if (processCommandAndResetClient(c) == C_ERR) { return C_ERR; } } /* Now process client if it has more data in it's buffer. * * Note: when a master client steps into this function, * it can always satisfy this condition, because its querbuf * contains data not applied. */ if (c->querybuf && sdslen(c->querybuf) > 0) { return processInputBuffer(c); } return C_OK; } /* This function is called every time, in the client structure 'c', there is * more query buffer to process, because we read more data from the socket * or because a client was blocked and later reactivated, so there could be * pending query buffer, already representing a full command, to process. * return C_ERR in case the client was freed during the processing */ int processInputBuffer(client *c) { /* Keep processing while there is something in the input buffer */ while(c->qb_pos < sdslen(c->querybuf)) { /* Immediately abort if the client is in the middle of something. */ if (c->flags & CLIENT_BLOCKED) break; /* Don't process more buffers from clients that have already pending * commands to execute in c->argv. */ if (c->flags & CLIENT_PENDING_COMMAND) break; /* Don't process input from the master while there is a busy script * condition on the slave. We want just to accumulate the replication * stream (instead of replying -BUSY like we do with other clients) and * later resume the processing. */ if (isInsideYieldingLongCommand() && c->flags & CLIENT_MASTER) break; /* CLIENT_CLOSE_AFTER_REPLY closes the connection once the reply is * written to the client. Make sure to not let the reply grow after * this flag has been set (i.e. don't process more commands). * * The same applies for clients we want to terminate ASAP. */ if (c->flags & (CLIENT_CLOSE_AFTER_REPLY|CLIENT_CLOSE_ASAP)) break; /* Determine request type when unknown. */ if (!c->reqtype) { if (c->querybuf[c->qb_pos] == '*') { c->reqtype = PROTO_REQ_MULTIBULK; } else { c->reqtype = PROTO_REQ_INLINE; } } if (c->reqtype == PROTO_REQ_INLINE) { if (processInlineBuffer(c) != C_OK) break; } else if (c->reqtype == PROTO_REQ_MULTIBULK) { if (processMultibulkBuffer(c) != C_OK) break; } else { serverPanic("Unknown request type"); } /* Multibulk processing could see a <= 0 length. */ if (c->argc == 0) { resetClient(c); } else { /* If we are in the context of an I/O thread, we can't really * execute the command here. All we can do is to flag the client * as one that needs to process the command. */ if (io_threads_op != IO_THREADS_OP_IDLE) { serverAssert(io_threads_op == IO_THREADS_OP_READ); c->flags |= CLIENT_PENDING_COMMAND; break; } /* We are finally ready to execute the command. */ if (processCommandAndResetClient(c) == C_ERR) { /* If the client is no longer valid, we avoid exiting this * loop and trimming the client buffer later. So we return * ASAP in that case. */ return C_ERR; } } } if (c->flags & CLIENT_MASTER) { /* If the client is a master, trim the querybuf to repl_applied, * since master client is very special, its querybuf not only * used to parse command, but also proxy to sub-replicas. * * Here are some scenarios we cannot trim to qb_pos: * 1. we don't receive complete command from master * 2. master client blocked cause of client pause * 3. io threads operate read, master client flagged with CLIENT_PENDING_COMMAND * * In these scenarios, qb_pos points to the part of the current command * or the beginning of next command, and the current command is not applied yet, * so the repl_applied is not equal to qb_pos. */ if (c->repl_applied) { sdsrange(c->querybuf,c->repl_applied,-1); c->qb_pos -= c->repl_applied; c->repl_applied = 0; } } else if (c->qb_pos) { /* Trim to pos */ sdsrange(c->querybuf,c->qb_pos,-1); c->qb_pos = 0; } /* Update client memory usage after processing the query buffer, this is * important in case the query buffer is big and wasn't drained during * the above loop (because of partially sent big commands). */ if (io_threads_op == IO_THREADS_OP_IDLE) updateClientMemUsageAndBucket(c); return C_OK; } void readQueryFromClient(connection *conn) { client *c = connGetPrivateData(conn); int nread, big_arg = 0; size_t qblen, readlen; /* Check if we want to read from the client later when exiting from * the event loop. This is the case if threaded I/O is enabled. */ if (postponeClientRead(c)) return; /* Update total number of reads on server */ atomicIncr(server.stat_total_reads_processed, 1); readlen = PROTO_IOBUF_LEN; /* If this is a multi bulk request, and we are processing a bulk reply * that is large enough, try to maximize the probability that the query * buffer contains exactly the SDS string representing the object, even * at the risk of requiring more read(2) calls. This way the function * processMultiBulkBuffer() can avoid copying buffers to create the * Redis Object representing the argument. */ if (c->reqtype == PROTO_REQ_MULTIBULK && c->multibulklen && c->bulklen != -1 && c->bulklen >= PROTO_MBULK_BIG_ARG) { ssize_t remaining = (size_t)(c->bulklen+2)-(sdslen(c->querybuf)-c->qb_pos); big_arg = 1; /* Note that the 'remaining' variable may be zero in some edge case, * for example once we resume a blocked client after CLIENT PAUSE. */ if (remaining > 0) readlen = remaining; /* Master client needs expand the readlen when meet BIG_ARG(see #9100), * but doesn't need align to the next arg, we can read more data. */ if (c->flags & CLIENT_MASTER && readlen < PROTO_IOBUF_LEN) readlen = PROTO_IOBUF_LEN; } qblen = sdslen(c->querybuf); if (!(c->flags & CLIENT_MASTER) && // master client's querybuf can grow greedy. (big_arg || sdsalloc(c->querybuf) < PROTO_IOBUF_LEN)) { /* When reading a BIG_ARG we won't be reading more than that one arg * into the query buffer, so we don't need to pre-allocate more than we * need, so using the non-greedy growing. For an initial allocation of * the query buffer, we also don't wanna use the greedy growth, in order * to avoid collision with the RESIZE_THRESHOLD mechanism. */ c->querybuf = sdsMakeRoomForNonGreedy(c->querybuf, readlen); } else { c->querybuf = sdsMakeRoomFor(c->querybuf, readlen); /* Read as much as possible from the socket to save read(2) system calls. */ readlen = sdsavail(c->querybuf); } nread = connRead(c->conn, c->querybuf+qblen, readlen); if (nread == -1) { if (connGetState(conn) == CONN_STATE_CONNECTED) { return; } else { serverLog(LL_VERBOSE, "Reading from client: %s",connGetLastError(c->conn)); freeClientAsync(c); goto done; } } else if (nread == 0) { if (server.verbosity <= LL_VERBOSE) { sds info = catClientInfoString(sdsempty(), c); serverLog(LL_VERBOSE, "Client closed connection %s", info); sdsfree(info); } freeClientAsync(c); goto done; } sdsIncrLen(c->querybuf,nread); qblen = sdslen(c->querybuf); if (c->querybuf_peak < qblen) c->querybuf_peak = qblen; c->lastinteraction = server.unixtime; if (c->flags & CLIENT_MASTER) { c->read_reploff += nread; atomicIncr(server.stat_net_repl_input_bytes, nread); } else { atomicIncr(server.stat_net_input_bytes, nread); } if (!(c->flags & CLIENT_MASTER) && sdslen(c->querybuf) > server.client_max_querybuf_len) { sds ci = catClientInfoString(sdsempty(),c), bytes = sdsempty(); bytes = sdscatrepr(bytes,c->querybuf,64); serverLog(LL_WARNING,"Closing client that reached max query buffer length: %s (qbuf initial bytes: %s)", ci, bytes); sdsfree(ci); sdsfree(bytes); freeClientAsync(c); goto done; } /* There is more data in the client input buffer, continue parsing it * and check if there is a full command to execute. */ if (processInputBuffer(c) == C_ERR) c = NULL; done: beforeNextClient(c); } /* A Redis "Address String" is a colon separated ip:port pair. * For IPv4 it's in the form x.y.z.k:port, example: "127.0.0.1:1234". * For IPv6 addresses we use [] around the IP part, like in "[::1]:1234". * For Unix sockets we use path:0, like in "/tmp/redis:0". * * An Address String always fits inside a buffer of NET_ADDR_STR_LEN bytes, * including the null term. * * On failure the function still populates 'addr' with the "?:0" string in case * you want to relax error checking or need to display something anyway (see * anetFdToString implementation for more info). */ void genClientAddrString(client *client, char *addr, size_t addr_len, int fd_to_str_type) { if (client->flags & CLIENT_UNIX_SOCKET) { /* Unix socket client. */ snprintf(addr,addr_len,"%s:0",server.unixsocket); } else { /* TCP client. */ connFormatFdAddr(client->conn,addr,addr_len,fd_to_str_type); } } /* This function returns the client peer id, by creating and caching it * if client->peerid is NULL, otherwise returning the cached value. * The Peer ID never changes during the life of the client, however it * is expensive to compute. */ char *getClientPeerId(client *c) { char peerid[NET_ADDR_STR_LEN]; if (c->peerid == NULL) { genClientAddrString(c,peerid,sizeof(peerid),FD_TO_PEER_NAME); c->peerid = sdsnew(peerid); } return c->peerid; } /* This function returns the client bound socket name, by creating and caching * it if client->sockname is NULL, otherwise returning the cached value. * The Socket Name never changes during the life of the client, however it * is expensive to compute. */ char *getClientSockname(client *c) { char sockname[NET_ADDR_STR_LEN]; if (c->sockname == NULL) { genClientAddrString(c,sockname,sizeof(sockname),FD_TO_SOCK_NAME); c->sockname = sdsnew(sockname); } return c->sockname; } /* Concatenate a string representing the state of a client in a human * readable format, into the sds string 's'. */ sds catClientInfoString(sds s, client *client) { char flags[16], events[3], conninfo[CONN_INFO_LEN], *p; p = flags; if (client->flags & CLIENT_SLAVE) { if (client->flags & CLIENT_MONITOR) *p++ = 'O'; else *p++ = 'S'; } if (client->flags & CLIENT_MASTER) *p++ = 'M'; if (client->flags & CLIENT_PUBSUB) *p++ = 'P'; if (client->flags & CLIENT_MULTI) *p++ = 'x'; if (client->flags & CLIENT_BLOCKED) *p++ = 'b'; if (client->flags & CLIENT_TRACKING) *p++ = 't'; if (client->flags & CLIENT_TRACKING_BROKEN_REDIR) *p++ = 'R'; if (client->flags & CLIENT_TRACKING_BCAST) *p++ = 'B'; if (client->flags & CLIENT_DIRTY_CAS) *p++ = 'd'; if (client->flags & CLIENT_CLOSE_AFTER_REPLY) *p++ = 'c'; if (client->flags & CLIENT_UNBLOCKED) *p++ = 'u'; if (client->flags & CLIENT_CLOSE_ASAP) *p++ = 'A'; if (client->flags & CLIENT_UNIX_SOCKET) *p++ = 'U'; if (client->flags & CLIENT_READONLY) *p++ = 'r'; if (client->flags & CLIENT_NO_EVICT) *p++ = 'e'; if (p == flags) *p++ = 'N'; *p++ = '\0'; p = events; if (client->conn) { if (connHasReadHandler(client->conn)) *p++ = 'r'; if (connHasWriteHandler(client->conn)) *p++ = 'w'; } *p = '\0'; /* Compute the total memory consumed by this client. */ size_t obufmem, total_mem = getClientMemoryUsage(client, &obufmem); size_t used_blocks_of_repl_buf = 0; if (client->ref_repl_buf_node) { replBufBlock *last = listNodeValue(listLast(server.repl_buffer_blocks)); replBufBlock *cur = listNodeValue(client->ref_repl_buf_node); used_blocks_of_repl_buf = last->id - cur->id + 1; } sds ret = sdscatfmt(s, "id=%U addr=%s laddr=%s %s name=%s age=%I idle=%I flags=%s db=%i sub=%i psub=%i ssub=%i multi=%i qbuf=%U qbuf-free=%U argv-mem=%U multi-mem=%U rbs=%U rbp=%U obl=%U oll=%U omem=%U tot-mem=%U events=%s cmd=%s user=%s redir=%I resp=%i", (unsigned long long) client->id, getClientPeerId(client), getClientSockname(client), connGetInfo(client->conn, conninfo, sizeof(conninfo)), client->name ? (char*)client->name->ptr : "", (long long)(server.unixtime - client->ctime), (long long)(server.unixtime - client->lastinteraction), flags, client->db->id, (int) dictSize(client->pubsub_channels), (int) listLength(client->pubsub_patterns), (int) dictSize(client->pubsubshard_channels), (client->flags & CLIENT_MULTI) ? client->mstate.count : -1, (unsigned long long) sdslen(client->querybuf), (unsigned long long) sdsavail(client->querybuf), (unsigned long long) client->argv_len_sum, (unsigned long long) client->mstate.argv_len_sums, (unsigned long long) client->buf_usable_size, (unsigned long long) client->buf_peak, (unsigned long long) client->bufpos, (unsigned long long) listLength(client->reply) + used_blocks_of_repl_buf, (unsigned long long) obufmem, /* should not include client->buf since we want to see 0 for static clients. */ (unsigned long long) total_mem, events, client->lastcmd ? client->lastcmd->fullname : "NULL", client->user ? client->user->name : "(superuser)", (client->flags & CLIENT_TRACKING) ? (long long) client->client_tracking_redirection : -1, client->resp); return ret; } sds getAllClientsInfoString(int type) { listNode *ln; listIter li; client *client; sds o = sdsnewlen(SDS_NOINIT,200*listLength(server.clients)); sdsclear(o); listRewind(server.clients,&li); while ((ln = listNext(&li)) != NULL) { client = listNodeValue(ln); if (type != -1 && getClientType(client) != type) continue; o = catClientInfoString(o,client); o = sdscatlen(o,"\n",1); } return o; } /* Returns C_OK if the name has been set or C_ERR if the name is invalid. */ int clientSetName(client *c, robj *name) { int len = (name != NULL) ? sdslen(name->ptr) : 0; /* Setting the client name to an empty string actually removes * the current name. */ if (len == 0) { if (c->name) decrRefCount(c->name); c->name = NULL; return C_OK; } /* Otherwise check if the charset is ok. We need to do this otherwise * CLIENT LIST format will break. You should always be able to * split by space to get the different fields. */ char *p = name->ptr; for (int j = 0; j < len; j++) { if (p[j] < '!' || p[j] > '~') { /* ASCII is assumed. */ return C_ERR; } } if (c->name) decrRefCount(c->name); c->name = name; incrRefCount(name); return C_OK; } /* This function implements CLIENT SETNAME, including replying to the * user with an error if the charset is wrong (in that case C_ERR is * returned). If the function succeeded C_OK is returned, and it's up * to the caller to send a reply if needed. * * Setting an empty string as name has the effect of unsetting the * currently set name: the client will remain unnamed. * * This function is also used to implement the HELLO SETNAME option. */ int clientSetNameOrReply(client *c, robj *name) { int result = clientSetName(c, name); if (result == C_ERR) { addReplyError(c, "Client names cannot contain spaces, " "newlines or special characters."); } return result; } /* Reset the client state to resemble a newly connected client. */ void resetCommand(client *c) { /* MONITOR clients are also marked with CLIENT_SLAVE, we need to * distinguish between the two. */ uint64_t flags = c->flags; if (flags & CLIENT_MONITOR) flags &= ~(CLIENT_MONITOR|CLIENT_SLAVE); if (flags & (CLIENT_SLAVE|CLIENT_MASTER|CLIENT_MODULE)) { addReplyError(c,"can only reset normal client connections"); return; } clearClientConnectionState(c); addReplyStatus(c,"RESET"); } /* Disconnect the current client */ void quitCommand(client *c) { addReply(c,shared.ok); c->flags |= CLIENT_CLOSE_AFTER_REPLY; } void clientCommand(client *c) { listNode *ln; listIter li; if (c->argc == 2 && !strcasecmp(c->argv[1]->ptr,"help")) { const char *help[] = { "CACHING (YES|NO)", " Enable/disable tracking of the keys for next command in OPTIN/OPTOUT modes.", "GETREDIR", " Return the client ID we are redirecting to when tracking is enabled.", "GETNAME", " Return the name of the current connection.", "ID", " Return the ID of the current connection.", "INFO", " Return information about the current client connection.", "KILL ", " Kill connection made from .", "KILL