/* * 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. */ #ifndef __REDIS_H #define __REDIS_H #include "fmacros.h" #include "config.h" #include "solarisfixes.h" #include "rio.h" #include "atomicvar.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "hdr_histogram.h" #ifdef HAVE_LIBSYSTEMD #include #endif typedef long long mstime_t; /* millisecond time type. */ typedef long long ustime_t; /* microsecond time type. */ #include "ae.h" /* Event driven programming library */ #include "sds.h" /* Dynamic safe strings */ #include "dict.h" /* Hash tables */ #include "adlist.h" /* Linked lists */ #include "zmalloc.h" /* total memory usage aware version of malloc/free */ #include "anet.h" /* Networking the easy way */ #include "ziplist.h" /* Compact list data structure */ #include "intset.h" /* Compact integer set structure */ #include "version.h" /* Version macro */ #include "util.h" /* Misc functions useful in many places */ #include "latency.h" /* Latency monitor API */ #include "sparkline.h" /* ASCII graphs API */ #include "quicklist.h" /* Lists are encoded as linked lists of N-elements flat arrays */ #include "rax.h" /* Radix tree */ #include "connection.h" /* Connection abstraction */ #define REDISMODULE_CORE 1 #include "redismodule.h" /* Redis modules API defines. */ /* Following includes allow test functions to be called from Redis main() */ #include "zipmap.h" #include "sha1.h" #include "endianconv.h" #include "crc64.h" /* min/max */ #define min(a, b) ((a) < (b) ? (a) : (b)) #define max(a, b) ((a) > (b) ? (a) : (b)) /* Error codes */ #define C_OK 0 #define C_ERR -1 /* Static server configuration */ #define CONFIG_DEFAULT_HZ 10 /* Time interrupt calls/sec. */ #define CONFIG_MIN_HZ 1 #define CONFIG_MAX_HZ 500 #define MAX_CLIENTS_PER_CLOCK_TICK 200 /* HZ is adapted based on that. */ #define CONFIG_MAX_LINE 1024 #define CRON_DBS_PER_CALL 16 #define NET_MAX_WRITES_PER_EVENT (1024*64) #define PROTO_SHARED_SELECT_CMDS 10 #define OBJ_SHARED_INTEGERS 10000 #define OBJ_SHARED_BULKHDR_LEN 32 #define LOG_MAX_LEN 1024 /* Default maximum length of syslog messages.*/ #define AOF_REWRITE_ITEMS_PER_CMD 64 #define AOF_ANNOTATION_LINE_MAX_LEN 1024 #define CONFIG_AUTHPASS_MAX_LEN 512 #define CONFIG_RUN_ID_SIZE 40 #define RDB_EOF_MARK_SIZE 40 #define CONFIG_REPL_BACKLOG_MIN_SIZE (1024*16) /* 16k */ #define CONFIG_BGSAVE_RETRY_DELAY 5 /* Wait a few secs before trying again. */ #define CONFIG_DEFAULT_PID_FILE "/var/run/redis.pid" #define CONFIG_DEFAULT_BINDADDR_COUNT 2 #define CONFIG_DEFAULT_BINDADDR { "*", "-::*" } #define NET_HOST_STR_LEN 256 /* Longest valid hostname */ #define NET_IP_STR_LEN 46 /* INET6_ADDRSTRLEN is 46, but we need to be sure */ #define NET_ADDR_STR_LEN (NET_IP_STR_LEN+32) /* Must be enough for ip:port */ #define NET_HOST_PORT_STR_LEN (NET_HOST_STR_LEN+32) /* Must be enough for hostname:port */ #define CONFIG_BINDADDR_MAX 16 #define CONFIG_MIN_RESERVED_FDS 32 #define CONFIG_DEFAULT_PROC_TITLE_TEMPLATE "{title} {listen-addr} {server-mode}" /* Bucket sizes for client eviction pools. Each bucket stores clients with * memory usage of up to twice the size of the bucket below it. */ #define CLIENT_MEM_USAGE_BUCKET_MIN_LOG 15 /* Bucket sizes start at up to 32KB (2^15) */ #define CLIENT_MEM_USAGE_BUCKET_MAX_LOG 33 /* Bucket for largest clients: sizes above 4GB (2^32) */ #define CLIENT_MEM_USAGE_BUCKETS (1+CLIENT_MEM_USAGE_BUCKET_MAX_LOG-CLIENT_MEM_USAGE_BUCKET_MIN_LOG) #define ACTIVE_EXPIRE_CYCLE_SLOW 0 #define ACTIVE_EXPIRE_CYCLE_FAST 1 /* Children process will exit with this status code to signal that the * process terminated without an error: this is useful in order to kill * a saving child (RDB or AOF one), without triggering in the parent the * write protection that is normally turned on on write errors. * Usually children that are terminated with SIGUSR1 will exit with this * special code. */ #define SERVER_CHILD_NOERROR_RETVAL 255 /* Reading copy-on-write info is sometimes expensive and may slow down child * processes that report it continuously. We measure the cost of obtaining it * and hold back additional reading based on this factor. */ #define CHILD_COW_DUTY_CYCLE 100 /* Instantaneous metrics tracking. */ #define STATS_METRIC_SAMPLES 16 /* Number of samples per metric. */ #define STATS_METRIC_COMMAND 0 /* Number of commands executed. */ #define STATS_METRIC_NET_INPUT 1 /* Bytes read to network .*/ #define STATS_METRIC_NET_OUTPUT 2 /* Bytes written to network. */ #define STATS_METRIC_COUNT 3 /* Protocol and I/O related defines */ #define PROTO_IOBUF_LEN (1024*16) /* Generic I/O buffer size */ #define PROTO_REPLY_CHUNK_BYTES (16*1024) /* 16k output buffer */ #define PROTO_INLINE_MAX_SIZE (1024*64) /* Max size of inline reads */ #define PROTO_MBULK_BIG_ARG (1024*32) #define PROTO_RESIZE_THRESHOLD (1024*32) /* Threshold for determining whether to resize query buffer */ #define LONG_STR_SIZE 21 /* Bytes needed for long -> str + '\0' */ #define REDIS_AUTOSYNC_BYTES (1024*1024*4) /* Sync file every 4MB. */ #define LIMIT_PENDING_QUERYBUF (4*1024*1024) /* 4mb */ /* When configuring the server eventloop, we setup it so that the total number * of file descriptors we can handle are server.maxclients + RESERVED_FDS + * a few more to stay safe. Since RESERVED_FDS defaults to 32, we add 96 * in order to make sure of not over provisioning more than 128 fds. */ #define CONFIG_FDSET_INCR (CONFIG_MIN_RESERVED_FDS+96) /* OOM Score Adjustment classes. */ #define CONFIG_OOM_MASTER 0 #define CONFIG_OOM_REPLICA 1 #define CONFIG_OOM_BGCHILD 2 #define CONFIG_OOM_COUNT 3 extern int configOOMScoreAdjValuesDefaults[CONFIG_OOM_COUNT]; /* Hash table parameters */ #define HASHTABLE_MIN_FILL 10 /* Minimal hash table fill 10% */ #define HASHTABLE_MAX_LOAD_FACTOR 1.618 /* Maximum hash table load factor. */ /* Command flags. Please check the definition of struct redisCommand in this file * for more information about the meaning of every flag. */ #define CMD_WRITE (1ULL<<0) #define CMD_READONLY (1ULL<<1) #define CMD_DENYOOM (1ULL<<2) #define CMD_MODULE (1ULL<<3) /* Command exported by module. */ #define CMD_ADMIN (1ULL<<4) #define CMD_PUBSUB (1ULL<<5) #define CMD_NOSCRIPT (1ULL<<6) #define CMD_RANDOM (1ULL<<7) #define CMD_SORT_FOR_SCRIPT (1ULL<<8) #define CMD_LOADING (1ULL<<9) #define CMD_STALE (1ULL<<10) #define CMD_SKIP_MONITOR (1ULL<<11) #define CMD_SKIP_SLOWLOG (1ULL<<12) #define CMD_ASKING (1ULL<<13) #define CMD_FAST (1ULL<<14) #define CMD_NO_AUTH (1ULL<<15) #define CMD_MAY_REPLICATE (1ULL<<16) #define CMD_SENTINEL (1ULL<<17) #define CMD_ONLY_SENTINEL (1ULL<<18) #define CMD_NO_MANDATORY_KEYS (1ULL<<19) #define CMD_PROTECTED (1ULL<<20) #define CMD_MODULE_GETKEYS (1ULL<<21) /* Use the modules getkeys interface. */ #define CMD_MODULE_NO_CLUSTER (1ULL<<22) /* Deny on Redis Cluster. */ #define CMD_NO_ASYNC_LOADING (1ULL<<23) #define CMD_NO_MULTI (1ULL<<24) #define CMD_MOVABLE_KEYS (1ULL<<25) /* populated by populateCommandMovableKeys */ #define CMD_ALLOW_BUSY ((1ULL<<26)) /* Command flags that describe ACLs categories. */ #define ACL_CATEGORY_KEYSPACE (1ULL<<0) #define ACL_CATEGORY_READ (1ULL<<1) #define ACL_CATEGORY_WRITE (1ULL<<2) #define ACL_CATEGORY_SET (1ULL<<3) #define ACL_CATEGORY_SORTEDSET (1ULL<<4) #define ACL_CATEGORY_LIST (1ULL<<5) #define ACL_CATEGORY_HASH (1ULL<<6) #define ACL_CATEGORY_STRING (1ULL<<7) #define ACL_CATEGORY_BITMAP (1ULL<<8) #define ACL_CATEGORY_HYPERLOGLOG (1ULL<<9) #define ACL_CATEGORY_GEO (1ULL<<10) #define ACL_CATEGORY_STREAM (1ULL<<11) #define ACL_CATEGORY_PUBSUB (1ULL<<12) #define ACL_CATEGORY_ADMIN (1ULL<<13) #define ACL_CATEGORY_FAST (1ULL<<14) #define ACL_CATEGORY_SLOW (1ULL<<15) #define ACL_CATEGORY_BLOCKING (1ULL<<16) #define ACL_CATEGORY_DANGEROUS (1ULL<<17) #define ACL_CATEGORY_CONNECTION (1ULL<<18) #define ACL_CATEGORY_TRANSACTION (1ULL<<19) #define ACL_CATEGORY_SCRIPTING (1ULL<<20) /* Key-spec flags * * -------------- */ /* The following refer what the command actually does with the value or metadata * of the key, and not necessarily the user data or how it affects it. * Each key-spec may must have exactly one of these. Any operation that's not * distinctly deletion, overwrite or read-only would be marked as RW. */ #define CMD_KEY_RO (1ULL<<0) /* Read-Only - Reads the value of the key, but * doesn't necessarily returns it. */ #define CMD_KEY_RW (1ULL<<1) /* Read-Write - Modifies the data stored in the * value of the key or its metadata. */ #define CMD_KEY_OW (1ULL<<2) /* Overwrite - Overwrites the data stored in * the value of the key. */ #define CMD_KEY_RM (1ULL<<3) /* Deletes the key. */ /* The following refer to user data inside the value of the key, not the metadata * like LRU, type, cardinality. It refers to the logical operation on the user's * data (actual input strings / TTL), being used / returned / copied / changed, * It doesn't refer to modification or returning of metadata (like type, count, * presence of data). Any write that's not INSERT or DELETE, would be an UPDATE. * Each key-spec may have one of the writes with or without access, or none: */ #define CMD_KEY_ACCESS (1ULL<<4) /* Returns, copies or uses the user data from * the value of the key. */ #define CMD_KEY_UPDATE (1ULL<<5) /* Updates data to the value, new value may * depend on the old value. */ #define CMD_KEY_INSERT (1ULL<<6) /* Adds data to the value with no chance of * modification or deletion of existing data. */ #define CMD_KEY_DELETE (1ULL<<7) /* Explicitly deletes some content * from the value of the key. */ /* Other flags: */ #define CMD_KEY_CHANNEL (1ULL<<8) /* PUBSUB shard channel */ #define CMD_KEY_INCOMPLETE (1ULL<<9) /* Means that the keyspec might not point * out to all keys it should cover */ /* AOF states */ #define AOF_OFF 0 /* AOF is off */ #define AOF_ON 1 /* AOF is on */ #define AOF_WAIT_REWRITE 2 /* AOF waits rewrite to start appending */ /* AOF return values for loadAppendOnlyFile() */ #define AOF_OK 0 #define AOF_NOT_EXIST 1 #define AOF_EMPTY 2 #define AOF_OPEN_ERR 3 #define AOF_FAILED 4 #define AOF_TRUNCATED 5 /* Command doc flags */ #define CMD_DOC_NONE 0 #define CMD_DOC_DEPRECATED (1<<0) /* Command is deprecated */ #define CMD_DOC_SYSCMD (1<<1) /* System (internal) command */ /* Client flags */ #define CLIENT_SLAVE (1<<0) /* This client is a replica */ #define CLIENT_MASTER (1<<1) /* This client is a master */ #define CLIENT_MONITOR (1<<2) /* This client is a slave monitor, see MONITOR */ #define CLIENT_MULTI (1<<3) /* This client is in a MULTI context */ #define CLIENT_BLOCKED (1<<4) /* The client is waiting in a blocking operation */ #define CLIENT_DIRTY_CAS (1<<5) /* Watched keys modified. EXEC will fail. */ #define CLIENT_CLOSE_AFTER_REPLY (1<<6) /* Close after writing entire reply. */ #define CLIENT_UNBLOCKED (1<<7) /* This client was unblocked and is stored in server.unblocked_clients */ #define CLIENT_SCRIPT (1<<8) /* This is a non connected client used by Lua */ #define CLIENT_ASKING (1<<9) /* Client issued the ASKING command */ #define CLIENT_CLOSE_ASAP (1<<10)/* Close this client ASAP */ #define CLIENT_UNIX_SOCKET (1<<11) /* Client connected via Unix domain socket */ #define CLIENT_DIRTY_EXEC (1<<12) /* EXEC will fail for errors while queueing */ #define CLIENT_MASTER_FORCE_REPLY (1<<13) /* Queue replies even if is master */ #define CLIENT_FORCE_AOF (1<<14) /* Force AOF propagation of current cmd. */ #define CLIENT_FORCE_REPL (1<<15) /* Force replication of current cmd. */ #define CLIENT_PRE_PSYNC (1<<16) /* Instance don't understand PSYNC. */ #define CLIENT_READONLY (1<<17) /* Cluster client is in read-only state. */ #define CLIENT_PUBSUB (1<<18) /* Client is in Pub/Sub mode. */ #define CLIENT_PREVENT_AOF_PROP (1<<19) /* Don't propagate to AOF. */ #define CLIENT_PREVENT_REPL_PROP (1<<20) /* Don't propagate to slaves. */ #define CLIENT_PREVENT_PROP (CLIENT_PREVENT_AOF_PROP|CLIENT_PREVENT_REPL_PROP) #define CLIENT_PENDING_WRITE (1<<21) /* Client has output to send but a write handler is yet not installed. */ #define CLIENT_REPLY_OFF (1<<22) /* Don't send replies to client. */ #define CLIENT_REPLY_SKIP_NEXT (1<<23) /* Set CLIENT_REPLY_SKIP for next cmd */ #define CLIENT_REPLY_SKIP (1<<24) /* Don't send just this reply. */ #define CLIENT_LUA_DEBUG (1<<25) /* Run EVAL in debug mode. */ #define CLIENT_LUA_DEBUG_SYNC (1<<26) /* EVAL debugging without fork() */ #define CLIENT_MODULE (1<<27) /* Non connected client used by some module. */ #define CLIENT_PROTECTED (1<<28) /* Client should not be freed for now. */ /* #define CLIENT_... (1<<29) currently unused, feel free to use in the future */ #define CLIENT_PENDING_COMMAND (1<<30) /* Indicates the client has a fully * parsed command ready for execution. */ #define CLIENT_TRACKING (1ULL<<31) /* Client enabled keys tracking in order to perform client side caching. */ #define CLIENT_TRACKING_BROKEN_REDIR (1ULL<<32) /* Target client is invalid. */ #define CLIENT_TRACKING_BCAST (1ULL<<33) /* Tracking in BCAST mode. */ #define CLIENT_TRACKING_OPTIN (1ULL<<34) /* Tracking in opt-in mode. */ #define CLIENT_TRACKING_OPTOUT (1ULL<<35) /* Tracking in opt-out mode. */ #define CLIENT_TRACKING_CACHING (1ULL<<36) /* CACHING yes/no was given, depending on optin/optout mode. */ #define CLIENT_TRACKING_NOLOOP (1ULL<<37) /* Don't send invalidation messages about writes performed by myself.*/ #define CLIENT_IN_TO_TABLE (1ULL<<38) /* This client is in the timeout table. */ #define CLIENT_PROTOCOL_ERROR (1ULL<<39) /* Protocol error chatting with it. */ #define CLIENT_CLOSE_AFTER_COMMAND (1ULL<<40) /* Close after executing commands * and writing entire reply. */ #define CLIENT_DENY_BLOCKING (1ULL<<41) /* Indicate that the client should not be blocked. currently, turned on inside MULTI, Lua, RM_Call, and AOF client */ #define CLIENT_REPL_RDBONLY (1ULL<<42) /* This client is a replica that only wants RDB without replication buffer. */ #define CLIENT_NO_EVICT (1ULL<<43) /* This client is protected against client memory eviction. */ /* Client block type (btype field in client structure) * if CLIENT_BLOCKED flag is set. */ #define BLOCKED_NONE 0 /* Not blocked, no CLIENT_BLOCKED flag set. */ #define BLOCKED_LIST 1 /* BLPOP & co. */ #define BLOCKED_WAIT 2 /* WAIT for synchronous replication. */ #define BLOCKED_MODULE 3 /* Blocked by a loadable module. */ #define BLOCKED_STREAM 4 /* XREAD. */ #define BLOCKED_ZSET 5 /* BZPOP et al. */ #define BLOCKED_POSTPONE 6 /* Blocked by processCommand, re-try processing later. */ #define BLOCKED_SHUTDOWN 7 /* SHUTDOWN. */ #define BLOCKED_NUM 8 /* Number of blocked states. */ /* Client request types */ #define PROTO_REQ_INLINE 1 #define PROTO_REQ_MULTIBULK 2 /* Client classes for client limits, currently used only for * the max-client-output-buffer limit implementation. */ #define CLIENT_TYPE_NORMAL 0 /* Normal req-reply clients + MONITORs */ #define CLIENT_TYPE_SLAVE 1 /* Slaves. */ #define CLIENT_TYPE_PUBSUB 2 /* Clients subscribed to PubSub channels. */ #define CLIENT_TYPE_MASTER 3 /* Master. */ #define CLIENT_TYPE_COUNT 4 /* Total number of client types. */ #define CLIENT_TYPE_OBUF_COUNT 3 /* Number of clients to expose to output buffer configuration. Just the first three: normal, slave, pubsub. */ /* Slave replication state. Used in server.repl_state for slaves to remember * what to do next. */ typedef enum { REPL_STATE_NONE = 0, /* No active replication */ REPL_STATE_CONNECT, /* Must connect to master */ REPL_STATE_CONNECTING, /* Connecting to master */ /* --- Handshake states, must be ordered --- */ REPL_STATE_RECEIVE_PING_REPLY, /* Wait for PING reply */ REPL_STATE_SEND_HANDSHAKE, /* Send handshake sequence to master */ REPL_STATE_RECEIVE_AUTH_REPLY, /* Wait for AUTH reply */ REPL_STATE_RECEIVE_PORT_REPLY, /* Wait for REPLCONF reply */ REPL_STATE_RECEIVE_IP_REPLY, /* Wait for REPLCONF reply */ REPL_STATE_RECEIVE_CAPA_REPLY, /* Wait for REPLCONF reply */ REPL_STATE_SEND_PSYNC, /* Send PSYNC */ REPL_STATE_RECEIVE_PSYNC_REPLY, /* Wait for PSYNC reply */ /* --- End of handshake states --- */ REPL_STATE_TRANSFER, /* Receiving .rdb from master */ REPL_STATE_CONNECTED, /* Connected to master */ } repl_state; /* The state of an in progress coordinated failover */ typedef enum { NO_FAILOVER = 0, /* No failover in progress */ FAILOVER_WAIT_FOR_SYNC, /* Waiting for target replica to catch up */ FAILOVER_IN_PROGRESS /* Waiting for target replica to accept * PSYNC FAILOVER request. */ } failover_state; /* State of slaves from the POV of the master. Used in client->replstate. * In SEND_BULK and ONLINE state the slave receives new updates * in its output queue. In the WAIT_BGSAVE states instead the server is waiting * to start the next background saving in order to send updates to it. */ #define SLAVE_STATE_WAIT_BGSAVE_START 6 /* We need to produce a new RDB file. */ #define SLAVE_STATE_WAIT_BGSAVE_END 7 /* Waiting RDB file creation to finish. */ #define SLAVE_STATE_SEND_BULK 8 /* Sending RDB file to slave. */ #define SLAVE_STATE_ONLINE 9 /* RDB file transmitted, sending just updates. */ /* Slave capabilities. */ #define SLAVE_CAPA_NONE 0 #define SLAVE_CAPA_EOF (1<<0) /* Can parse the RDB EOF streaming format. */ #define SLAVE_CAPA_PSYNC2 (1<<1) /* Supports PSYNC2 protocol. */ /* Slave requirements */ #define SLAVE_REQ_NONE 0 #define SLAVE_REQ_RDB_EXCLUDE_DATA (1 << 0) /* Exclude data from RDB */ #define SLAVE_REQ_RDB_EXCLUDE_FUNCTIONS (1 << 1) /* Exclude functions from RDB */ /* Mask of all bits in the slave requirements bitfield that represent non-standard (filtered) RDB requirements */ #define SLAVE_REQ_RDB_MASK (SLAVE_REQ_RDB_EXCLUDE_DATA | SLAVE_REQ_RDB_EXCLUDE_FUNCTIONS) /* Synchronous read timeout - slave side */ #define CONFIG_REPL_SYNCIO_TIMEOUT 5 /* The default number of replication backlog blocks to trim per call. */ #define REPL_BACKLOG_TRIM_BLOCKS_PER_CALL 64 /* In order to quickly find the requested offset for PSYNC requests, * we index some nodes in the replication buffer linked list into a rax. */ #define REPL_BACKLOG_INDEX_PER_BLOCKS 64 /* List related stuff */ #define LIST_HEAD 0 #define LIST_TAIL 1 #define ZSET_MIN 0 #define ZSET_MAX 1 /* Sort operations */ #define SORT_OP_GET 0 /* Log levels */ #define LL_DEBUG 0 #define LL_VERBOSE 1 #define LL_NOTICE 2 #define LL_WARNING 3 #define LL_RAW (1<<10) /* Modifier to log without timestamp */ /* Supervision options */ #define SUPERVISED_NONE 0 #define SUPERVISED_AUTODETECT 1 #define SUPERVISED_SYSTEMD 2 #define SUPERVISED_UPSTART 3 /* Anti-warning macro... */ #define UNUSED(V) ((void) V) #define ZSKIPLIST_MAXLEVEL 32 /* Should be enough for 2^64 elements */ #define ZSKIPLIST_P 0.25 /* Skiplist P = 1/4 */ /* Append only defines */ #define AOF_FSYNC_NO 0 #define AOF_FSYNC_ALWAYS 1 #define AOF_FSYNC_EVERYSEC 2 /* Replication diskless load defines */ #define REPL_DISKLESS_LOAD_DISABLED 0 #define REPL_DISKLESS_LOAD_WHEN_DB_EMPTY 1 #define REPL_DISKLESS_LOAD_SWAPDB 2 /* TLS Client Authentication */ #define TLS_CLIENT_AUTH_NO 0 #define TLS_CLIENT_AUTH_YES 1 #define TLS_CLIENT_AUTH_OPTIONAL 2 /* Sanitize dump payload */ #define SANITIZE_DUMP_NO 0 #define SANITIZE_DUMP_YES 1 #define SANITIZE_DUMP_CLIENTS 2 /* Enable protected config/command */ #define PROTECTED_ACTION_ALLOWED_NO 0 #define PROTECTED_ACTION_ALLOWED_YES 1 #define PROTECTED_ACTION_ALLOWED_LOCAL 2 /* Sets operations codes */ #define SET_OP_UNION 0 #define SET_OP_DIFF 1 #define SET_OP_INTER 2 /* oom-score-adj defines */ #define OOM_SCORE_ADJ_NO 0 #define OOM_SCORE_RELATIVE 1 #define OOM_SCORE_ADJ_ABSOLUTE 2 /* Redis maxmemory strategies. Instead of using just incremental number * for this defines, we use a set of flags so that testing for certain * properties common to multiple policies is faster. */ #define MAXMEMORY_FLAG_LRU (1<<0) #define MAXMEMORY_FLAG_LFU (1<<1) #define MAXMEMORY_FLAG_ALLKEYS (1<<2) #define MAXMEMORY_FLAG_NO_SHARED_INTEGERS \ (MAXMEMORY_FLAG_LRU|MAXMEMORY_FLAG_LFU) #define MAXMEMORY_VOLATILE_LRU ((0<<8)|MAXMEMORY_FLAG_LRU) #define MAXMEMORY_VOLATILE_LFU ((1<<8)|MAXMEMORY_FLAG_LFU) #define MAXMEMORY_VOLATILE_TTL (2<<8) #define MAXMEMORY_VOLATILE_RANDOM (3<<8) #define MAXMEMORY_ALLKEYS_LRU ((4<<8)|MAXMEMORY_FLAG_LRU|MAXMEMORY_FLAG_ALLKEYS) #define MAXMEMORY_ALLKEYS_LFU ((5<<8)|MAXMEMORY_FLAG_LFU|MAXMEMORY_FLAG_ALLKEYS) #define MAXMEMORY_ALLKEYS_RANDOM ((6<<8)|MAXMEMORY_FLAG_ALLKEYS) #define MAXMEMORY_NO_EVICTION (7<<8) /* Units */ #define UNIT_SECONDS 0 #define UNIT_MILLISECONDS 1 /* SHUTDOWN flags */ #define SHUTDOWN_NOFLAGS 0 /* No flags. */ #define SHUTDOWN_SAVE 1 /* Force SAVE on SHUTDOWN even if no save points are configured. */ #define SHUTDOWN_NOSAVE 2 /* Don't SAVE on SHUTDOWN. */ #define SHUTDOWN_NOW 4 /* Don't wait for replicas to catch up. */ #define SHUTDOWN_FORCE 8 /* Don't let errors prevent shutdown. */ /* Command call flags, see call() function */ #define CMD_CALL_NONE 0 #define CMD_CALL_SLOWLOG (1<<0) #define CMD_CALL_STATS (1<<1) #define CMD_CALL_PROPAGATE_AOF (1<<2) #define CMD_CALL_PROPAGATE_REPL (1<<3) #define CMD_CALL_PROPAGATE (CMD_CALL_PROPAGATE_AOF|CMD_CALL_PROPAGATE_REPL) #define CMD_CALL_FULL (CMD_CALL_SLOWLOG | CMD_CALL_STATS | CMD_CALL_PROPAGATE) #define CMD_CALL_FROM_MODULE (1<<4) /* From RM_Call */ /* Command propagation flags, see propagateNow() function */ #define PROPAGATE_NONE 0 #define PROPAGATE_AOF 1 #define PROPAGATE_REPL 2 /* Client pause types, larger types are more restrictive * pause types than smaller pause types. */ typedef enum { CLIENT_PAUSE_OFF = 0, /* Pause no commands */ CLIENT_PAUSE_WRITE, /* Pause write commands */ CLIENT_PAUSE_ALL /* Pause all commands */ } pause_type; /* Client pause purposes. Each purpose has its own end time and pause type. */ typedef enum { PAUSE_BY_CLIENT_COMMAND = 0, PAUSE_DURING_SHUTDOWN, PAUSE_DURING_FAILOVER, NUM_PAUSE_PURPOSES /* This value is the number of purposes above. */ } pause_purpose; typedef struct { pause_type type; mstime_t end; } pause_event; /* Ways that a clusters endpoint can be described */ typedef enum { CLUSTER_ENDPOINT_TYPE_IP = 0, /* Show IP address */ CLUSTER_ENDPOINT_TYPE_HOSTNAME, /* Show hostname */ CLUSTER_ENDPOINT_TYPE_UNKNOWN_ENDPOINT /* Show NULL or empty */ } cluster_endpoint_type; /* RDB active child save type. */ #define RDB_CHILD_TYPE_NONE 0 #define RDB_CHILD_TYPE_DISK 1 /* RDB is written to disk. */ #define RDB_CHILD_TYPE_SOCKET 2 /* RDB is written to slave socket. */ /* Keyspace changes notification classes. Every class is associated with a * character for configuration purposes. */ #define NOTIFY_KEYSPACE (1<<0) /* K */ #define NOTIFY_KEYEVENT (1<<1) /* E */ #define NOTIFY_GENERIC (1<<2) /* g */ #define NOTIFY_STRING (1<<3) /* $ */ #define NOTIFY_LIST (1<<4) /* l */ #define NOTIFY_SET (1<<5) /* s */ #define NOTIFY_HASH (1<<6) /* h */ #define NOTIFY_ZSET (1<<7) /* z */ #define NOTIFY_EXPIRED (1<<8) /* x */ #define NOTIFY_EVICTED (1<<9) /* e */ #define NOTIFY_STREAM (1<<10) /* t */ #define NOTIFY_KEY_MISS (1<<11) /* m (Note: This one is excluded from NOTIFY_ALL on purpose) */ #define NOTIFY_LOADED (1<<12) /* module only key space notification, indicate a key loaded from rdb */ #define NOTIFY_MODULE (1<<13) /* d, module key space notification */ #define NOTIFY_ALL (NOTIFY_GENERIC | NOTIFY_STRING | NOTIFY_LIST | NOTIFY_SET | NOTIFY_HASH | NOTIFY_ZSET | NOTIFY_EXPIRED | NOTIFY_EVICTED | NOTIFY_STREAM | NOTIFY_MODULE) /* A flag */ /* Using the following macro you can run code inside serverCron() with the * specified period, specified in milliseconds. * The actual resolution depends on server.hz. */ #define run_with_period(_ms_) if ((_ms_ <= 1000/server.hz) || !(server.cronloops%((_ms_)/(1000/server.hz)))) /* We can print the stacktrace, so our assert is defined this way: */ #define serverAssertWithInfo(_c,_o,_e) ((_e)?(void)0 : (_serverAssertWithInfo(_c,_o,#_e,__FILE__,__LINE__),redis_unreachable())) #define serverAssert(_e) ((_e)?(void)0 : (_serverAssert(#_e,__FILE__,__LINE__),redis_unreachable())) #define serverPanic(...) _serverPanic(__FILE__,__LINE__,__VA_ARGS__),redis_unreachable() /* latency histogram per command init settings */ #define LATENCY_HISTOGRAM_MIN_VALUE 1L /* >= 1 nanosec */ #define LATENCY_HISTOGRAM_MAX_VALUE 1000000000L /* <= 1 secs */ #define LATENCY_HISTOGRAM_PRECISION 2 /* Maintain a value precision of 2 significant digits across LATENCY_HISTOGRAM_MIN_VALUE and LATENCY_HISTOGRAM_MAX_VALUE range. * Value quantization within the range will thus be no larger than 1/100th (or 1%) of any value. * The total size per histogram should sit around 40 KiB Bytes. */ /* Busy module flags, see busy_module_yield_flags */ #define BUSY_MODULE_YIELD_NONE (0) #define BUSY_MODULE_YIELD_EVENTS (1<<0) #define BUSY_MODULE_YIELD_CLIENTS (1<<1) /*----------------------------------------------------------------------------- * Data types *----------------------------------------------------------------------------*/ /* A redis object, that is a type able to hold a string / list / set */ /* The actual Redis Object */ #define OBJ_STRING 0 /* String object. */ #define OBJ_LIST 1 /* List object. */ #define OBJ_SET 2 /* Set object. */ #define OBJ_ZSET 3 /* Sorted set object. */ #define OBJ_HASH 4 /* Hash object. */ /* The "module" object type is a special one that signals that the object * is one directly managed by a Redis module. In this case the value points * to a moduleValue struct, which contains the object value (which is only * handled by the module itself) and the RedisModuleType struct which lists * function pointers in order to serialize, deserialize, AOF-rewrite and * free the object. * * Inside the RDB file, module types are encoded as OBJ_MODULE followed * by a 64 bit module type ID, which has a 54 bits module-specific signature * in order to dispatch the loading to the right module, plus a 10 bits * encoding version. */ #define OBJ_MODULE 5 /* Module object. */ #define OBJ_STREAM 6 /* Stream object. */ /* Extract encver / signature from a module type ID. */ #define REDISMODULE_TYPE_ENCVER_BITS 10 #define REDISMODULE_TYPE_ENCVER_MASK ((1<>REDISMODULE_TYPE_ENCVER_BITS) /* Bit flags for moduleTypeAuxSaveFunc */ #define REDISMODULE_AUX_BEFORE_RDB (1<<0) #define REDISMODULE_AUX_AFTER_RDB (1<<1) struct RedisModule; struct RedisModuleIO; struct RedisModuleDigest; struct RedisModuleCtx; struct moduleLoadQueueEntry; struct redisObject; struct RedisModuleDefragCtx; struct RedisModuleInfoCtx; struct RedisModuleKeyOptCtx; /* Each module type implementation should export a set of methods in order * to serialize and deserialize the value in the RDB file, rewrite the AOF * log, create the digest for "DEBUG DIGEST", and free the value when a key * is deleted. */ typedef void *(*moduleTypeLoadFunc)(struct RedisModuleIO *io, int encver); typedef void (*moduleTypeSaveFunc)(struct RedisModuleIO *io, void *value); typedef int (*moduleTypeAuxLoadFunc)(struct RedisModuleIO *rdb, int encver, int when); typedef void (*moduleTypeAuxSaveFunc)(struct RedisModuleIO *rdb, int when); typedef void (*moduleTypeRewriteFunc)(struct RedisModuleIO *io, struct redisObject *key, void *value); typedef void (*moduleTypeDigestFunc)(struct RedisModuleDigest *digest, void *value); typedef size_t (*moduleTypeMemUsageFunc)(const void *value); typedef void (*moduleTypeFreeFunc)(void *value); typedef size_t (*moduleTypeFreeEffortFunc)(struct redisObject *key, const void *value); typedef void (*moduleTypeUnlinkFunc)(struct redisObject *key, void *value); typedef void *(*moduleTypeCopyFunc)(struct redisObject *fromkey, struct redisObject *tokey, const void *value); typedef int (*moduleTypeDefragFunc)(struct RedisModuleDefragCtx *ctx, struct redisObject *key, void **value); typedef void (*RedisModuleInfoFunc)(struct RedisModuleInfoCtx *ctx, int for_crash_report); typedef void (*RedisModuleDefragFunc)(struct RedisModuleDefragCtx *ctx); typedef size_t (*moduleTypeMemUsageFunc2)(struct RedisModuleKeyOptCtx *ctx, const void *value, size_t sample_size); typedef void (*moduleTypeFreeFunc2)(struct RedisModuleKeyOptCtx *ctx, void *value); typedef size_t (*moduleTypeFreeEffortFunc2)(struct RedisModuleKeyOptCtx *ctx, const void *value); typedef void (*moduleTypeUnlinkFunc2)(struct RedisModuleKeyOptCtx *ctx, void *value); typedef void *(*moduleTypeCopyFunc2)(struct RedisModuleKeyOptCtx *ctx, const void *value); /* This callback type is called by moduleNotifyUserChanged() every time * a user authenticated via the module API is associated with a different * user or gets disconnected. This needs to be exposed since you can't cast * a function pointer to (void *). */ typedef void (*RedisModuleUserChangedFunc) (uint64_t client_id, void *privdata); /* The module type, which is referenced in each value of a given type, defines * the methods and links to the module exporting the type. */ typedef struct RedisModuleType { uint64_t id; /* Higher 54 bits of type ID + 10 lower bits of encoding ver. */ struct RedisModule *module; moduleTypeLoadFunc rdb_load; moduleTypeSaveFunc rdb_save; moduleTypeRewriteFunc aof_rewrite; moduleTypeMemUsageFunc mem_usage; moduleTypeDigestFunc digest; moduleTypeFreeFunc free; moduleTypeFreeEffortFunc free_effort; moduleTypeUnlinkFunc unlink; moduleTypeCopyFunc copy; moduleTypeDefragFunc defrag; moduleTypeAuxLoadFunc aux_load; moduleTypeAuxSaveFunc aux_save; moduleTypeMemUsageFunc2 mem_usage2; moduleTypeFreeEffortFunc2 free_effort2; moduleTypeUnlinkFunc2 unlink2; moduleTypeCopyFunc2 copy2; int aux_save_triggers; char name[10]; /* 9 bytes name + null term. Charset: A-Z a-z 0-9 _- */ } moduleType; /* In Redis objects 'robj' structures of type OBJ_MODULE, the value pointer * is set to the following structure, referencing the moduleType structure * in order to work with the value, and at the same time providing a raw * pointer to the value, as created by the module commands operating with * the module type. * * So for example in order to free such a value, it is possible to use * the following code: * * if (robj->type == OBJ_MODULE) { * moduleValue *mt = robj->ptr; * mt->type->free(mt->value); * zfree(mt); // We need to release this in-the-middle struct as well. * } */ typedef struct moduleValue { moduleType *type; void *value; } moduleValue; /* This structure represents a module inside the system. */ struct RedisModule { void *handle; /* Module dlopen() handle. */ char *name; /* Module name. */ int ver; /* Module version. We use just progressive integers. */ int apiver; /* Module API version as requested during initialization.*/ list *types; /* Module data types. */ list *usedby; /* List of modules using APIs from this one. */ list *using; /* List of modules we use some APIs of. */ list *filters; /* List of filters the module has registered. */ int in_call; /* RM_Call() nesting level */ int in_hook; /* Hooks callback nesting level for this module (0 or 1). */ int options; /* Module options and capabilities. */ int blocked_clients; /* Count of RedisModuleBlockedClient in this module. */ RedisModuleInfoFunc info_cb; /* Callback for module to add INFO fields. */ RedisModuleDefragFunc defrag_cb; /* Callback for global data defrag. */ struct moduleLoadQueueEntry *loadmod; /* Module load arguments for config rewrite. */ }; typedef struct RedisModule RedisModule; /* This is a wrapper for the 'rio' streams used inside rdb.c in Redis, so that * the user does not have to take the total count of the written bytes nor * to care about error conditions. */ typedef struct RedisModuleIO { size_t bytes; /* Bytes read / written so far. */ rio *rio; /* Rio stream. */ moduleType *type; /* Module type doing the operation. */ int error; /* True if error condition happened. */ int ver; /* Module serialization version: 1 (old), * 2 (current version with opcodes annotation). */ struct RedisModuleCtx *ctx; /* Optional context, see RM_GetContextFromIO()*/ struct redisObject *key; /* Optional name of key processed */ int dbid; /* The dbid of the key being processed, -1 when unknown. */ } RedisModuleIO; /* Macro to initialize an IO context. Note that the 'ver' field is populated * inside rdb.c according to the version of the value to load. */ #define moduleInitIOContext(iovar,mtype,rioptr,keyptr,db) do { \ iovar.rio = rioptr; \ iovar.type = mtype; \ iovar.bytes = 0; \ iovar.error = 0; \ iovar.ver = 0; \ iovar.key = keyptr; \ iovar.dbid = db; \ iovar.ctx = NULL; \ } while(0) /* This is a structure used to export DEBUG DIGEST capabilities to Redis * modules. We want to capture both the ordered and unordered elements of * a data structure, so that a digest can be created in a way that correctly * reflects the values. See the DEBUG DIGEST command implementation for more * background. */ typedef struct RedisModuleDigest { unsigned char o[20]; /* Ordered elements. */ unsigned char x[20]; /* Xored elements. */ struct redisObject *key; /* Optional name of key processed */ int dbid; /* The dbid of the key being processed */ } RedisModuleDigest; /* Just start with a digest composed of all zero bytes. */ #define moduleInitDigestContext(mdvar) do { \ memset(mdvar.o,0,sizeof(mdvar.o)); \ memset(mdvar.x,0,sizeof(mdvar.x)); \ } while(0) /* Objects encoding. Some kind of objects like Strings and Hashes can be * internally represented in multiple ways. The 'encoding' field of the object * is set to one of this fields for this object. */ #define OBJ_ENCODING_RAW 0 /* Raw representation */ #define OBJ_ENCODING_INT 1 /* Encoded as integer */ #define OBJ_ENCODING_HT 2 /* Encoded as hash table */ #define OBJ_ENCODING_ZIPMAP 3 /* Encoded as zipmap */ #define OBJ_ENCODING_LINKEDLIST 4 /* No longer used: old list encoding. */ #define OBJ_ENCODING_ZIPLIST 5 /* Encoded as ziplist */ #define OBJ_ENCODING_INTSET 6 /* Encoded as intset */ #define OBJ_ENCODING_SKIPLIST 7 /* Encoded as skiplist */ #define OBJ_ENCODING_EMBSTR 8 /* Embedded sds string encoding */ #define OBJ_ENCODING_QUICKLIST 9 /* Encoded as linked list of listpacks */ #define OBJ_ENCODING_STREAM 10 /* Encoded as a radix tree of listpacks */ #define OBJ_ENCODING_LISTPACK 11 /* Encoded as a listpack */ #define LRU_BITS 24 #define LRU_CLOCK_MAX ((1<lru */ #define LRU_CLOCK_RESOLUTION 1000 /* LRU clock resolution in ms */ #define OBJ_SHARED_REFCOUNT INT_MAX /* Global object never destroyed. */ #define OBJ_STATIC_REFCOUNT (INT_MAX-1) /* Object allocated in the stack. */ #define OBJ_FIRST_SPECIAL_REFCOUNT OBJ_STATIC_REFCOUNT typedef struct redisObject { unsigned type:4; unsigned encoding:4; unsigned lru:LRU_BITS; /* LRU time (relative to global lru_clock) or * LFU data (least significant 8 bits frequency * and most significant 16 bits access time). */ int refcount; void *ptr; } robj; /* The a string name for an object's type as listed above * Native types are checked against the OBJ_STRING, OBJ_LIST, OBJ_* defines, * and Module types have their registered name returned. */ char *getObjectTypeName(robj*); /* Macro used to initialize a Redis object allocated on the stack. * Note that this macro is taken near the structure definition to make sure * we'll update it when the structure is changed, to avoid bugs like * bug #85 introduced exactly in this way. */ #define initStaticStringObject(_var,_ptr) do { \ _var.refcount = OBJ_STATIC_REFCOUNT; \ _var.type = OBJ_STRING; \ _var.encoding = OBJ_ENCODING_RAW; \ _var.ptr = _ptr; \ } while(0) struct evictionPoolEntry; /* Defined in evict.c */ /* This structure is used in order to represent the output buffer of a client, * which is actually a linked list of blocks like that, that is: client->reply. */ typedef struct clientReplyBlock { size_t size, used; char buf[]; } clientReplyBlock; /* Replication buffer blocks is the list of replBufBlock. * * +--------------+ +--------------+ +--------------+ * | refcount = 1 | ... | refcount = 0 | ... | refcount = 2 | * +--------------+ +--------------+ +--------------+ * | / \ * | / \ * | / \ * Repl Backlog Replia_A Replia_B * * Each replica or replication backlog increments only the refcount of the * 'ref_repl_buf_node' which it points to. So when replica walks to the next * node, it should first increase the next node's refcount, and when we trim * the replication buffer nodes, we remove node always from the head node which * refcount is 0. If the refcount of the head node is not 0, we must stop * trimming and never iterate the next node. */ /* Similar with 'clientReplyBlock', it is used for shared buffers between * all replica clients and replication backlog. */ typedef struct replBufBlock { int refcount; /* Number of replicas or repl backlog using. */ long long id; /* The unique incremental number. */ long long repl_offset; /* Start replication offset of the block. */ size_t size, used; char buf[]; } replBufBlock; /* Opaque type for the Slot to Key API. */ typedef struct clusterSlotToKeyMapping clusterSlotToKeyMapping; /* Redis database representation. There are multiple databases identified * by integers from 0 (the default database) up to the max configured * database. The database number is the 'id' field in the structure. */ typedef struct redisDb { dict *dict; /* The keyspace for this DB */ dict *expires; /* Timeout of keys with a timeout set */ dict *blocking_keys; /* Keys with clients waiting for data (BLPOP)*/ dict *ready_keys; /* Blocked keys that received a PUSH */ dict *watched_keys; /* WATCHED keys for MULTI/EXEC CAS */ int id; /* Database ID */ long long avg_ttl; /* Average TTL, just for stats */ unsigned long expires_cursor; /* Cursor of the active expire cycle. */ list *defrag_later; /* List of key names to attempt to defrag one by one, gradually. */ clusterSlotToKeyMapping *slots_to_keys; /* Array of slots to keys. Only used in cluster mode (db 0). */ } redisDb; /* forward declaration for functions ctx */ typedef struct functionsLibCtx functionsLibCtx; /* Holding object that need to be populated during * rdb loading. On loading end it is possible to decide * whether not to set those objects on their rightful place. * For example: dbarray need to be set as main database on * successful loading and dropped on failure. */ typedef struct rdbLoadingCtx { redisDb* dbarray; functionsLibCtx* functions_lib_ctx; }rdbLoadingCtx; /* Client MULTI/EXEC state */ typedef struct multiCmd { robj **argv; int argv_len; int argc; struct redisCommand *cmd; } multiCmd; typedef struct multiState { multiCmd *commands; /* Array of MULTI commands */ int count; /* Total number of MULTI commands */ int cmd_flags; /* The accumulated command flags OR-ed together. So if at least a command has a given flag, it will be set in this field. */ int cmd_inv_flags; /* Same as cmd_flags, OR-ing the ~flags. so that it is possible to know if all the commands have a certain flag. */ size_t argv_len_sums; /* mem used by all commands arguments */ } multiState; /* This structure holds the blocking operation state for a client. * The fields used depend on client->btype. */ typedef struct blockingState { /* Generic fields. */ long count; /* Elements to pop if count was specified (BLMPOP/BZMPOP), -1 otherwise. */ mstime_t timeout; /* Blocking operation timeout. If UNIX current time * is > timeout then the operation timed out. */ /* BLOCKED_LIST, BLOCKED_ZSET and BLOCKED_STREAM */ dict *keys; /* The keys we are waiting to terminate a blocking * operation such as BLPOP or XREAD. Or NULL. */ robj *target; /* The key that should receive the element, * for BLMOVE. */ struct blockPos { int wherefrom; /* Where to pop from */ int whereto; /* Where to push to */ } blockpos; /* The positions in the src/dst lists/zsets * where we want to pop/push an element * for BLPOP, BRPOP, BLMOVE and BZMPOP. */ /* BLOCK_STREAM */ size_t xread_count; /* XREAD COUNT option. */ robj *xread_group; /* XREADGROUP group name. */ robj *xread_consumer; /* XREADGROUP consumer name. */ int xread_group_noack; /* BLOCKED_WAIT */ int numreplicas; /* Number of replicas we are waiting for ACK. */ long long reploffset; /* Replication offset to reach. */ /* BLOCKED_MODULE */ void *module_blocked_handle; /* RedisModuleBlockedClient structure. which is opaque for the Redis core, only handled in module.c. */ } blockingState; /* The following structure represents a node in the server.ready_keys list, * where we accumulate all the keys that had clients blocked with a blocking * operation such as B[LR]POP, but received new data in the context of the * last executed command. * * After the execution of every command or script, we run this list to check * if as a result we should serve data to clients blocked, unblocking them. * Note that server.ready_keys will not have duplicates as there dictionary * also called ready_keys in every structure representing a Redis database, * where we make sure to remember if a given key was already added in the * server.ready_keys list. */ typedef struct readyList { redisDb *db; robj *key; } readyList; /* This structure represents a Redis user. This is useful for ACLs, the * user is associated to the connection after the connection is authenticated. * If there is no associated user, the connection uses the default user. */ #define USER_COMMAND_BITS_COUNT 1024 /* The total number of command bits in the user structure. The last valid command ID we can set in the user is USER_COMMAND_BITS_COUNT-1. */ #define USER_FLAG_ENABLED (1<<0) /* The user is active. */ #define USER_FLAG_DISABLED (1<<1) /* The user is disabled. */ #define USER_FLAG_ALLKEYS (1<<2) /* The user can mention any key. */ #define USER_FLAG_ALLCOMMANDS (1<<3) /* The user can run all commands. */ #define USER_FLAG_NOPASS (1<<4) /* The user requires no password, any provided password will work. For the default user, this also means that no AUTH is needed, and every connection is immediately authenticated. */ #define USER_FLAG_ALLCHANNELS (1<<5) /* The user can mention any Pub/Sub channel. */ #define USER_FLAG_SANITIZE_PAYLOAD (1<<6) /* The user require a deep RESTORE * payload sanitization. */ #define USER_FLAG_SANITIZE_PAYLOAD_SKIP (1<<7) /* The user should skip the * deep sanitization of RESTORE * payload. */ typedef struct { sds name; /* The username as an SDS string. */ uint64_t flags; /* See USER_FLAG_* */ /* The bit in allowed_commands is set if this user has the right to * execute this command. * * If the bit for a given command is NOT set and the command has * allowed first-args, Redis will also check allowed_firstargs in order to * understand if the command can be executed. */ uint64_t allowed_commands[USER_COMMAND_BITS_COUNT/64]; /* allowed_firstargs is used by ACL rules to block access to a command unless a * specific argv[1] is given (or argv[2] in case it is applied on a sub-command). * For example, a user can use the rule "-select +select|0" to block all * SELECT commands, except "SELECT 0". * And for a sub-command: "+config -config|set +config|set|loglevel" * * For each command ID (corresponding to the command bit set in allowed_commands), * This array points to an array of SDS strings, terminated by a NULL pointer, * with all the first-args that are allowed for this command. When no first-arg * matching is used, the field is just set to NULL to avoid allocating * USER_COMMAND_BITS_COUNT pointers. */ sds **allowed_firstargs; list *passwords; /* A list of SDS valid passwords for this user. */ list *patterns; /* A list of allowed key patterns. If this field is NULL the user cannot mention any key in a command, unless the flag ALLKEYS is set in the user. */ list *channels; /* A list of allowed Pub/Sub channel patterns. If this field is NULL the user cannot mention any channel in a `PUBLISH` or [P][UNSUBSCRIBE] command, unless the flag ALLCHANNELS is set in the user. */ } user; /* With multiplexing we need to take per-client state. * Clients are taken in a linked list. */ #define CLIENT_ID_AOF (UINT64_MAX) /* Reserved ID for the AOF client. If you need more reserved IDs use UINT64_MAX-1, -2, ... and so forth. */ /* Replication backlog is not separate memory, it just is one consumer of * the global replication buffer. This structure records the reference of * replication buffers. Since the replication buffer block list may be very long, * it would cost much time to search replication offset on partial resync, so * we use one rax tree to index some blocks every REPL_BACKLOG_INDEX_PER_BLOCKS * to make searching offset from replication buffer blocks list faster. */ typedef struct replBacklog { listNode *ref_repl_buf_node; /* Referenced node of replication buffer blocks, * see the definition of replBufBlock. */ size_t unindexed_count; /* The count from last creating index block. */ rax *blocks_index; /* The index of reocrded blocks of replication * buffer for quickly searching replication * offset on partial resynchronization. */ long long histlen; /* Backlog actual data length */ long long offset; /* Replication "master offset" of first * byte in the replication backlog buffer.*/ } replBacklog; typedef struct { list *clients; size_t mem_usage_sum; } clientMemUsageBucket; typedef struct client { uint64_t id; /* Client incremental unique ID. */ connection *conn; int resp; /* RESP protocol version. Can be 2 or 3. */ redisDb *db; /* Pointer to currently SELECTed DB. */ robj *name; /* As set by CLIENT SETNAME. */ sds querybuf; /* Buffer we use to accumulate client queries. */ size_t qb_pos; /* The position we have read in querybuf. */ sds pending_querybuf; /* If this client is flagged as master, this buffer represents the yet not applied portion of the replication stream that we are receiving from the master. */ size_t querybuf_peak; /* Recent (100ms or more) peak of querybuf size. */ int argc; /* Num of arguments of current command. */ robj **argv; /* Arguments of current command. */ int argv_len; /* Size of argv array (may be more than argc) */ int original_argc; /* Num of arguments of original command if arguments were rewritten. */ robj **original_argv; /* Arguments of original command if arguments were rewritten. */ size_t argv_len_sum; /* Sum of lengths of objects in argv list. */ struct redisCommand *cmd, *lastcmd; /* Last command executed. */ user *user; /* User associated with this connection. If the user is set to NULL the connection can do anything (admin). */ int reqtype; /* Request protocol type: PROTO_REQ_* */ int multibulklen; /* Number of multi bulk arguments left to read. */ long bulklen; /* Length of bulk argument in multi bulk request. */ list *reply; /* List of reply objects to send to the client. */ unsigned long long reply_bytes; /* Tot bytes of objects in reply list. */ size_t sentlen; /* Amount of bytes already sent in the current buffer or object being sent. */ time_t ctime; /* Client creation time. */ long duration; /* Current command duration. Used for measuring latency of blocking/non-blocking cmds */ time_t lastinteraction; /* Time of the last interaction, used for timeout */ time_t obuf_soft_limit_reached_time; uint64_t flags; /* Client flags: CLIENT_* macros. */ int authenticated; /* Needed when the default user requires auth. */ int replstate; /* Replication state if this is a slave. */ int repl_start_cmd_stream_on_ack; /* Install slave write handler on first ACK. */ int repldbfd; /* Replication DB file descriptor. */ off_t repldboff; /* Replication DB file offset. */ off_t repldbsize; /* Replication DB file size. */ sds replpreamble; /* Replication DB preamble. */ long long read_reploff; /* Read replication offset if this is a master. */ long long reploff; /* Applied replication offset if this is a master. */ long long repl_ack_off; /* Replication ack offset, if this is a slave. */ long long repl_ack_time;/* Replication ack time, if this is a slave. */ long long repl_last_partial_write; /* The last time the server did a partial write from the RDB child pipe to this replica */ long long psync_initial_offset; /* FULLRESYNC reply offset other slaves copying this slave output buffer should use. */ char replid[CONFIG_RUN_ID_SIZE+1]; /* Master replication ID (if master). */ int slave_listening_port; /* As configured with: REPLCONF listening-port */ char *slave_addr; /* Optionally given by REPLCONF ip-address */ int slave_capa; /* Slave capabilities: SLAVE_CAPA_* bitwise OR. */ int slave_req; /* Slave requirements: SLAVE_REQ_* */ multiState mstate; /* MULTI/EXEC state */ int btype; /* Type of blocking op if CLIENT_BLOCKED. */ blockingState bpop; /* blocking state */ long long woff; /* Last write global replication offset. */ list *watched_keys; /* Keys WATCHED for MULTI/EXEC CAS */ dict *pubsub_channels; /* channels a client is interested in (SUBSCRIBE) */ list *pubsub_patterns; /* patterns a client is interested in (SUBSCRIBE) */ dict *pubsubshard_channels; /* shard level channels a client is interested in (SSUBSCRIBE) */ sds peerid; /* Cached peer ID. */ sds sockname; /* Cached connection target address. */ listNode *client_list_node; /* list node in client list */ listNode *postponed_list_node; /* list node within the postponed list */ listNode *pending_read_list_node; /* list node in clients pending read list */ RedisModuleUserChangedFunc auth_callback; /* Module callback to execute * when the authenticated user * changes. */ void *auth_callback_privdata; /* Private data that is passed when the auth * changed callback is executed. Opaque for * Redis Core. */ void *auth_module; /* The module that owns the callback, which is used * to disconnect the client if the module is * unloaded for cleanup. Opaque for Redis Core.*/ /* If this client is in tracking mode and this field is non zero, * invalidation messages for keys fetched by this client will be send to * the specified client ID. */ uint64_t client_tracking_redirection; rax *client_tracking_prefixes; /* A dictionary of prefixes we are already subscribed to in BCAST mode, in the context of client side caching. */ /* In updateClientMemUsage() we track the memory usage of * each client and add it to the sum of all the clients of a given type, * however we need to remember what was the old contribution of each * client, and in which category the client was, in order to remove it * before adding it the new value. */ size_t last_memory_usage; int last_memory_type; size_t last_memory_usage_on_bucket_update; listNode *mem_usage_bucket_node; clientMemUsageBucket *mem_usage_bucket; listNode *ref_repl_buf_node; /* Referenced node of replication buffer blocks, * see the definition of replBufBlock. */ size_t ref_block_pos; /* Access position of referenced buffer block, * i.e. the next offset to send. */ /* Response buffer */ int bufpos; size_t buf_usable_size; /* Usable size of buffer. */ /* Note that 'buf' must be the last field of client struct, because memory * allocator may give us more memory than our apply for reducing fragments, * but we want to make full use of given memory, i.e. we may access the * memory after 'buf'. To avoid make others fields corrupt, 'buf' must be * the last one. */ char buf[PROTO_REPLY_CHUNK_BYTES]; } client; struct saveparam { time_t seconds; int changes; }; struct moduleLoadQueueEntry { sds path; int argc; robj **argv; }; struct sentinelLoadQueueEntry { int argc; sds *argv; int linenum; sds line; }; struct sentinelConfig { list *pre_monitor_cfg; list *monitor_cfg; list *post_monitor_cfg; }; struct sharedObjectsStruct { robj *crlf, *ok, *err, *emptybulk, *czero, *cone, *pong, *space, *queued, *null[4], *nullarray[4], *emptymap[4], *emptyset[4], *emptyarray, *wrongtypeerr, *nokeyerr, *syntaxerr, *sameobjecterr, *outofrangeerr, *noscripterr, *loadingerr, *slowevalerr, *slowscripterr, *slowmoduleerr, *bgsaveerr, *masterdownerr, *roslaveerr, *execaborterr, *noautherr, *noreplicaserr, *busykeyerr, *oomerr, *plus, *messagebulk, *pmessagebulk, *subscribebulk, *unsubscribebulk, *psubscribebulk, *punsubscribebulk, *del, *unlink, *rpop, *lpop, *lpush, *rpoplpush, *lmove, *blmove, *zpopmin, *zpopmax, *emptyscan, *multi, *exec, *left, *right, *hset, *srem, *xgroup, *xclaim, *script, *replconf, *eval, *persist, *set, *pexpireat, *pexpire, *time, *pxat, *absttl, *retrycount, *force, *justid, *lastid, *ping, *setid, *keepttl, *load, *createconsumer, *getack, *special_asterick, *special_equals, *default_username, *redacted, *ssubscribebulk,*sunsubscribebulk, *select[PROTO_SHARED_SELECT_CMDS], *integers[OBJ_SHARED_INTEGERS], *mbulkhdr[OBJ_SHARED_BULKHDR_LEN], /* "*\r\n" */ *bulkhdr[OBJ_SHARED_BULKHDR_LEN]; /* "$\r\n" */ sds minstring, maxstring; }; /* ZSETs use a specialized version of Skiplists */ typedef struct zskiplistNode { sds ele; double score; struct zskiplistNode *backward; struct zskiplistLevel { struct zskiplistNode *forward; unsigned long span; } level[]; } zskiplistNode; typedef struct zskiplist { struct zskiplistNode *header, *tail; unsigned long length; int level; } zskiplist; typedef struct zset { dict *dict; zskiplist *zsl; } zset; typedef struct clientBufferLimitsConfig { unsigned long long hard_limit_bytes; unsigned long long soft_limit_bytes; time_t soft_limit_seconds; } clientBufferLimitsConfig; extern clientBufferLimitsConfig clientBufferLimitsDefaults[CLIENT_TYPE_OBUF_COUNT]; /* The redisOp structure defines a Redis Operation, that is an instance of * a command with an argument vector, database ID, propagation target * (PROPAGATE_*), and command pointer. * * Currently only used to additionally propagate more commands to AOF/Replication * after the propagation of the executed command. */ typedef struct redisOp { robj **argv; int argc, dbid, target; } redisOp; /* Defines an array of Redis operations. There is an API to add to this * structure in an easy way. * * redisOpArrayInit(); * redisOpArrayAppend(); * redisOpArrayFree(); */ typedef struct redisOpArray { redisOp *ops; int numops; int capacity; } redisOpArray; /* This structure is returned by the getMemoryOverheadData() function in * order to return memory overhead information. */ struct redisMemOverhead { size_t peak_allocated; size_t total_allocated; size_t startup_allocated; size_t repl_backlog; size_t clients_slaves; size_t clients_normal; size_t cluster_links; size_t aof_buffer; size_t lua_caches; size_t functions_caches; size_t overhead_total; size_t dataset; size_t total_keys; size_t bytes_per_key; float dataset_perc; float peak_perc; float total_frag; ssize_t total_frag_bytes; float allocator_frag; ssize_t allocator_frag_bytes; float allocator_rss; ssize_t allocator_rss_bytes; float rss_extra; size_t rss_extra_bytes; size_t num_dbs; struct { size_t dbid; size_t overhead_ht_main; size_t overhead_ht_expires; size_t overhead_ht_slot_to_keys; } *db; }; /* This structure can be optionally passed to RDB save/load functions in * order to implement additional functionalities, by storing and loading * metadata to the RDB file. * * For example, to use select a DB at load time, useful in * replication in order to make sure that chained slaves (slaves of slaves) * select the correct DB and are able to accept the stream coming from the * top-level master. */ typedef struct rdbSaveInfo { /* Used saving and loading. */ int repl_stream_db; /* DB to select in server.master client. */ /* Used only loading. */ int repl_id_is_set; /* True if repl_id field is set. */ char repl_id[CONFIG_RUN_ID_SIZE+1]; /* Replication ID. */ long long repl_offset; /* Replication offset. */ } rdbSaveInfo; #define RDB_SAVE_INFO_INIT {-1,0,"0000000000000000000000000000000000000000",-1} struct malloc_stats { size_t zmalloc_used; size_t process_rss; size_t allocator_allocated; size_t allocator_active; size_t allocator_resident; }; typedef struct socketFds { int fd[CONFIG_BINDADDR_MAX]; int count; } socketFds; /*----------------------------------------------------------------------------- * TLS Context Configuration *----------------------------------------------------------------------------*/ typedef struct redisTLSContextConfig { char *cert_file; /* Server side and optionally client side cert file name */ char *key_file; /* Private key filename for cert_file */ char *key_file_pass; /* Optional password for key_file */ char *client_cert_file; /* Certificate to use as a client; if none, use cert_file */ char *client_key_file; /* Private key filename for client_cert_file */ char *client_key_file_pass; /* Optional password for client_key_file */ char *dh_params_file; char *ca_cert_file; char *ca_cert_dir; char *protocols; char *ciphers; char *ciphersuites; int prefer_server_ciphers; int session_caching; int session_cache_size; int session_cache_timeout; } redisTLSContextConfig; /*----------------------------------------------------------------------------- * AOF manifest definition *----------------------------------------------------------------------------*/ typedef enum { AOF_FILE_TYPE_BASE = 'b', /* BASE file */ AOF_FILE_TYPE_HIST = 'h', /* HISTORY file */ AOF_FILE_TYPE_INCR = 'i', /* INCR file */ } aof_file_type; typedef struct { sds file_name; /* file name */ long long file_seq; /* file sequence */ aof_file_type file_type; /* file type */ } aofInfo; typedef struct { aofInfo *base_aof_info; /* BASE file information. NULL if there is no BASE file. */ list *incr_aof_list; /* INCR AOFs list. We may have multiple INCR AOF when rewrite fails. */ list *history_aof_list; /* HISTORY AOF list. When the AOFRW success, The aofInfo contained in `base_aof_info` and `incr_aof_list` will be moved to this list. We will delete these AOF files when AOFRW finish. */ long long curr_base_file_seq; /* The sequence number used by the current BASE file. */ long long curr_incr_file_seq; /* The sequence number used by the current INCR file. */ int dirty; /* 1 Indicates that the aofManifest in the memory is inconsistent with disk, we need to persist it immediately. */ } aofManifest; /*----------------------------------------------------------------------------- * Global server state *----------------------------------------------------------------------------*/ /* AIX defines hz to __hz, we don't use this define and in order to allow * Redis build on AIX we need to undef it. */ #ifdef _AIX #undef hz #endif #define CHILD_TYPE_NONE 0 #define CHILD_TYPE_RDB 1 #define CHILD_TYPE_AOF 2 #define CHILD_TYPE_LDB 3 #define CHILD_TYPE_MODULE 4 typedef enum childInfoType { CHILD_INFO_TYPE_CURRENT_INFO, CHILD_INFO_TYPE_AOF_COW_SIZE, CHILD_INFO_TYPE_RDB_COW_SIZE, CHILD_INFO_TYPE_MODULE_COW_SIZE } childInfoType; struct redisServer { /* General */ pid_t pid; /* Main process pid. */ pthread_t main_thread_id; /* Main thread id */ char *configfile; /* Absolute config file path, or NULL */ char *executable; /* Absolute executable file path. */ char **exec_argv; /* Executable argv vector (copy). */ int dynamic_hz; /* Change hz value depending on # of clients. */ int config_hz; /* Configured HZ value. May be different than the actual 'hz' field value if dynamic-hz is enabled. */ mode_t umask; /* The umask value of the process on startup */ int hz; /* serverCron() calls frequency in hertz */ int in_fork_child; /* indication that this is a fork child */ redisDb *db; dict *commands; /* Command table */ dict *orig_commands; /* Command table before command renaming. */ aeEventLoop *el; rax *errors; /* Errors table */ redisAtomic unsigned int lruclock; /* Clock for LRU eviction */ volatile sig_atomic_t shutdown_asap; /* Shutdown ordered by signal handler. */ mstime_t shutdown_mstime; /* Timestamp to limit graceful shutdown. */ int shutdown_flags; /* Flags passed to prepareForShutdown(). */ int activerehashing; /* Incremental rehash in serverCron() */ int active_defrag_running; /* Active defragmentation running (holds current scan aggressiveness) */ char *pidfile; /* PID file path */ int arch_bits; /* 32 or 64 depending on sizeof(long) */ int cronloops; /* Number of times the cron function run */ char runid[CONFIG_RUN_ID_SIZE+1]; /* ID always different at every exec. */ int sentinel_mode; /* True if this instance is a Sentinel. */ size_t initial_memory_usage; /* Bytes used after initialization. */ int always_show_logo; /* Show logo even for non-stdout logging. */ int in_script; /* Are we inside EVAL? */ int in_exec; /* Are we inside EXEC? */ int busy_module_yield_flags; /* Are we inside a busy module? (triggered by RM_Yield). see BUSY_MODULE_YIELD_ flags. */ const char *busy_module_yield_reply; /* When non-null, we are inside RM_Yield. */ int core_propagates; /* Is the core (in oppose to the module subsystem) is in charge of calling propagatePendingCommands? */ int propagate_no_multi; /* True if propagatePendingCommands should avoid wrapping command in MULTI/EXEC */ int module_ctx_nesting; /* moduleCreateContext() nesting level */ char *ignore_warnings; /* Config: warnings that should be ignored. */ int client_pause_in_transaction; /* Was a client pause executed during this Exec? */ int thp_enabled; /* If true, THP is enabled. */ size_t page_size; /* The page size of OS. */ /* Modules */ dict *moduleapi; /* Exported core APIs dictionary for modules. */ dict *sharedapi; /* Like moduleapi but containing the APIs that modules share with each other. */ list *loadmodule_queue; /* List of modules to load at startup. */ int module_pipe[2]; /* Pipe used to awake the event loop by module threads. */ pid_t child_pid; /* PID of current child */ int child_type; /* Type of current child */ /* Networking */ int port; /* TCP listening port */ int tls_port; /* TLS listening port */ int tcp_backlog; /* TCP listen() backlog */ char *bindaddr[CONFIG_BINDADDR_MAX]; /* Addresses we should bind to */ int bindaddr_count; /* Number of addresses in server.bindaddr[] */ char *bind_source_addr; /* Source address to bind on for outgoing connections */ char *unixsocket; /* UNIX socket path */ unsigned int unixsocketperm; /* UNIX socket permission (see mode_t) */ socketFds ipfd; /* TCP socket file descriptors */ socketFds tlsfd; /* TLS socket file descriptors */ int sofd; /* Unix socket file descriptor */ socketFds cfd; /* Cluster bus listening socket */ list *clients; /* List of active clients */ list *clients_to_close; /* Clients to close asynchronously */ list *clients_pending_write; /* There is to write or install handler. */ list *clients_pending_read; /* Client has pending read socket buffers. */ list *slaves, *monitors; /* List of slaves and MONITORs */ client *current_client; /* Current client executing the command. */ /* Stuff for client mem eviction */ clientMemUsageBucket client_mem_usage_buckets[CLIENT_MEM_USAGE_BUCKETS]; rax *clients_timeout_table; /* Radix tree for blocked clients timeouts. */ long fixed_time_expire; /* If > 0, expire keys against server.mstime. */ int in_nested_call; /* If > 0, in a nested call of a call */ rax *clients_index; /* Active clients dictionary by client ID. */ pause_type client_pause_type; /* True if clients are currently paused */ list *postponed_clients; /* List of postponed clients */ mstime_t client_pause_end_time; /* Time when we undo clients_paused */ pause_event *client_pause_per_purpose[NUM_PAUSE_PURPOSES]; char neterr[ANET_ERR_LEN]; /* Error buffer for anet.c */ dict *migrate_cached_sockets;/* MIGRATE cached sockets */ redisAtomic uint64_t next_client_id; /* Next client unique ID. Incremental. */ int protected_mode; /* Don't accept external connections. */ int io_threads_num; /* Number of IO threads to use. */ int io_threads_do_reads; /* Read and parse from IO threads? */ int io_threads_active; /* Is IO threads currently active? */ long long events_processed_while_blocked; /* processEventsWhileBlocked() */ int enable_protected_configs; /* Enable the modification of protected configs, see PROTECTED_ACTION_ALLOWED_* */ int enable_debug_cmd; /* Enable DEBUG commands, see PROTECTED_ACTION_ALLOWED_* */ int enable_module_cmd; /* Enable MODULE commands, see PROTECTED_ACTION_ALLOWED_* */ /* RDB / AOF loading information */ volatile sig_atomic_t loading; /* We are loading data from disk if true */ volatile sig_atomic_t async_loading; /* We are loading data without blocking the db being served */ off_t loading_total_bytes; off_t loading_rdb_used_mem; off_t loading_loaded_bytes; time_t loading_start_time; off_t loading_process_events_interval_bytes; /* Fields used only for stats */ time_t stat_starttime; /* Server start time */ long long stat_numcommands; /* Number of processed commands */ long long stat_numconnections; /* Number of connections received */ long long stat_expiredkeys; /* Number of expired keys */ double stat_expired_stale_perc; /* Percentage of keys probably expired */ long long stat_expired_time_cap_reached_count; /* Early expire cycle stops.*/ long long stat_expire_cycle_time_used; /* Cumulative microseconds used. */ long long stat_evictedkeys; /* Number of evicted keys (maxmemory) */ long long stat_evictedclients; /* Number of evicted clients */ long long stat_total_eviction_exceeded_time; /* Total time over the memory limit, unit us */ monotime stat_last_eviction_exceeded_time; /* Timestamp of current eviction start, unit us */ long long stat_keyspace_hits; /* Number of successful lookups of keys */ long long stat_keyspace_misses; /* Number of failed lookups of keys */ long long stat_active_defrag_hits; /* number of allocations moved */ long long stat_active_defrag_misses; /* number of allocations scanned but not moved */ long long stat_active_defrag_key_hits; /* number of keys with moved allocations */ long long stat_active_defrag_key_misses;/* number of keys scanned and not moved */ long long stat_active_defrag_scanned; /* number of dictEntries scanned */ long long stat_total_active_defrag_time; /* Total time memory fragmentation over the limit, unit us */ monotime stat_last_active_defrag_time; /* Timestamp of current active defrag start */ size_t stat_peak_memory; /* Max used memory record */ long long stat_fork_time; /* Time needed to perform latest fork() */ double stat_fork_rate; /* Fork rate in GB/sec. */ long long stat_total_forks; /* Total count of fork. */ long long stat_rejected_conn; /* Clients rejected because of maxclients */ long long stat_sync_full; /* Number of full resyncs with slaves. */ long long stat_sync_partial_ok; /* Number of accepted PSYNC requests. */ long long stat_sync_partial_err;/* Number of unaccepted PSYNC requests. */ list *slowlog; /* SLOWLOG list of commands */ long long slowlog_entry_id; /* SLOWLOG current entry ID */ long long slowlog_log_slower_than; /* SLOWLOG time limit (to get logged) */ unsigned long slowlog_max_len; /* SLOWLOG max number of items logged */ struct malloc_stats cron_malloc_stats; /* sampled in serverCron(). */ redisAtomic long long stat_net_input_bytes; /* Bytes read from network. */ redisAtomic long long stat_net_output_bytes; /* Bytes written to network. */ size_t stat_current_cow_peak; /* Peak size of copy on write bytes. */ size_t stat_current_cow_bytes; /* Copy on write bytes while child is active. */ monotime stat_current_cow_updated; /* Last update time of stat_current_cow_bytes */ size_t stat_current_save_keys_processed; /* Processed keys while child is active. */ size_t stat_current_save_keys_total; /* Number of keys when child started. */ size_t stat_rdb_cow_bytes; /* Copy on write bytes during RDB saving. */ size_t stat_aof_cow_bytes; /* Copy on write bytes during AOF rewrite. */ size_t stat_module_cow_bytes; /* Copy on write bytes during module fork. */ double stat_module_progress; /* Module save progress. */ redisAtomic size_t stat_clients_type_memory[CLIENT_TYPE_COUNT];/* Mem usage by type */ size_t stat_cluster_links_memory;/* Mem usage by cluster links */ long long stat_unexpected_error_replies; /* Number of unexpected (aof-loading, replica to master, etc.) error replies */ long long stat_total_error_replies; /* Total number of issued error replies ( command + rejected errors ) */ long long stat_dump_payload_sanitizations; /* Number deep dump payloads integrity validations. */ long long stat_io_reads_processed; /* Number of read events processed by IO / Main threads */ long long stat_io_writes_processed; /* Number of write events processed by IO / Main threads */ redisAtomic long long stat_total_reads_processed; /* Total number of read events processed */ redisAtomic long long stat_total_writes_processed; /* Total number of write events processed */ /* The following two are used to track instantaneous metrics, like * number of operations per second, network traffic. */ struct { long long last_sample_time; /* Timestamp of last sample in ms */ long long last_sample_count;/* Count in last sample */ long long samples[STATS_METRIC_SAMPLES]; int idx; } inst_metric[STATS_METRIC_COUNT]; /* Configuration */ int verbosity; /* Loglevel in redis.conf */ int maxidletime; /* Client timeout in seconds */ int tcpkeepalive; /* Set SO_KEEPALIVE if non-zero. */ int active_expire_enabled; /* Can be disabled for testing purposes. */ int active_expire_effort; /* From 1 (default) to 10, active effort. */ int active_defrag_enabled; int sanitize_dump_payload; /* Enables deep sanitization for ziplist and listpack in RDB and RESTORE. */ int skip_checksum_validation; /* Disable checksum validation for RDB and RESTORE payload. */ int jemalloc_bg_thread; /* Enable jemalloc background thread */ size_t active_defrag_ignore_bytes; /* minimum amount of fragmentation waste to start active defrag */ int active_defrag_threshold_lower; /* minimum percentage of fragmentation to start active defrag */ int active_defrag_threshold_upper; /* maximum percentage of fragmentation at which we use maximum effort */ int active_defrag_cycle_min; /* minimal effort for defrag in CPU percentage */ int active_defrag_cycle_max; /* maximal effort for defrag in CPU percentage */ unsigned long active_defrag_max_scan_fields; /* maximum number of fields of set/hash/zset/list to process from within the main dict scan */ size_t client_max_querybuf_len; /* Limit for client query buffer length */ int dbnum; /* Total number of configured DBs */ int supervised; /* 1 if supervised, 0 otherwise. */ int supervised_mode; /* See SUPERVISED_* */ int daemonize; /* True if running as a daemon */ int set_proc_title; /* True if change proc title */ char *proc_title_template; /* Process title template format */ clientBufferLimitsConfig client_obuf_limits[CLIENT_TYPE_OBUF_COUNT]; int pause_cron; /* Don't run cron tasks (debug) */ int latency_tracking_enabled; /* 1 if extended latency tracking is enabled, 0 otherwise. */ double *latency_tracking_info_percentiles; /* Extended latency tracking info output percentile list configuration. */ int latency_tracking_info_percentiles_len; /* AOF persistence */ int aof_enabled; /* AOF configuration */ int aof_state; /* AOF_(ON|OFF|WAIT_REWRITE) */ int aof_fsync; /* Kind of fsync() policy */ char *aof_filename; /* Basename of the AOF file and manifest file */ char *aof_dirname; /* Name of the AOF directory */ int aof_no_fsync_on_rewrite; /* Don't fsync if a rewrite is in prog. */ int aof_rewrite_perc; /* Rewrite AOF if % growth is > M and... */ off_t aof_rewrite_min_size; /* the AOF file is at least N bytes. */ off_t aof_rewrite_base_size; /* AOF size on latest startup or rewrite. */ off_t aof_current_size; /* AOF current size (Including BASE + INCRs). */ off_t aof_last_incr_size; /* The size of the latest incr AOF. */ off_t aof_fsync_offset; /* AOF offset which is already synced to disk. */ int aof_flush_sleep; /* Micros to sleep before flush. (used by tests) */ int aof_rewrite_scheduled; /* Rewrite once BGSAVE terminates. */ list *aof_rewrite_buf_blocks; /* Hold changes during an AOF rewrite. */ sds aof_buf; /* AOF buffer, written before entering the event loop */ int aof_fd; /* File descriptor of currently selected AOF file */ int aof_selected_db; /* Currently selected DB in AOF */ time_t aof_flush_postponed_start; /* UNIX time of postponed AOF flush */ time_t aof_last_fsync; /* UNIX time of last fsync() */ time_t aof_rewrite_time_last; /* Time used by last AOF rewrite run. */ time_t aof_rewrite_time_start; /* Current AOF rewrite start time. */ time_t aof_cur_timestamp; /* Current record timestamp in AOF */ int aof_timestamp_enabled; /* Enable record timestamp in AOF */ int aof_lastbgrewrite_status; /* C_OK or C_ERR */ unsigned long aof_delayed_fsync; /* delayed AOF fsync() counter */ int aof_rewrite_incremental_fsync;/* fsync incrementally while aof rewriting? */ int rdb_save_incremental_fsync; /* fsync incrementally while rdb saving? */ int aof_last_write_status; /* C_OK or C_ERR */ int aof_last_write_errno; /* Valid if aof write/fsync status is ERR */ int aof_load_truncated; /* Don't stop on unexpected AOF EOF. */ int aof_use_rdb_preamble; /* Use RDB preamble on AOF rewrites. */ redisAtomic int aof_bio_fsync_status; /* Status of AOF fsync in bio job. */ redisAtomic int aof_bio_fsync_errno; /* Errno of AOF fsync in bio job. */ aofManifest *aof_manifest; /* Used to track AOFs. */ int aof_disable_auto_gc; /* If disable automatically deleting HISTORY type AOFs? default no. (for testings). */ /* RDB persistence */ long long dirty; /* Changes to DB from the last save */ long long dirty_before_bgsave; /* Used to restore dirty on failed BGSAVE */ long long rdb_last_load_keys_expired; /* number of expired keys when loading RDB */ long long rdb_last_load_keys_loaded; /* number of loaded keys when loading RDB */ struct saveparam *saveparams; /* Save points array for RDB */ int saveparamslen; /* Number of saving points */ char *rdb_filename; /* Name of RDB file */ int rdb_compression; /* Use compression in RDB? */ int rdb_checksum; /* Use RDB checksum? */ int rdb_del_sync_files; /* Remove RDB files used only for SYNC if the instance does not use persistence. */ time_t lastsave; /* Unix time of last successful save */ time_t lastbgsave_try; /* Unix time of last attempted bgsave */ time_t rdb_save_time_last; /* Time used by last RDB save run. */ time_t rdb_save_time_start; /* Current RDB save start time. */ int rdb_bgsave_scheduled; /* BGSAVE when possible if true. */ int rdb_child_type; /* Type of save by active child. */ int lastbgsave_status; /* C_OK or C_ERR */ int stop_writes_on_bgsave_err; /* Don't allow writes if can't BGSAVE */ int rdb_pipe_read; /* RDB pipe used to transfer the rdb data */ /* to the parent process in diskless repl. */ int rdb_child_exit_pipe; /* Used by the diskless parent allow child exit. */ connection **rdb_pipe_conns; /* Connections which are currently the */ int rdb_pipe_numconns; /* target of diskless rdb fork child. */ int rdb_pipe_numconns_writing; /* Number of rdb conns with pending writes. */ char *rdb_pipe_buff; /* In diskless replication, this buffer holds data */ int rdb_pipe_bufflen; /* that was read from the the rdb pipe. */ int rdb_key_save_delay; /* Delay in microseconds between keys while * writing the RDB. (for testings). negative * value means fractions of microseconds (on average). */ int key_load_delay; /* Delay in microseconds between keys while * loading aof or rdb. (for testings). negative * value means fractions of microseconds (on average). */ /* Pipe and data structures for child -> parent info sharing. */ int child_info_pipe[2]; /* Pipe used to write the child_info_data. */ int child_info_nread; /* Num of bytes of the last read from pipe */ /* Propagation of commands in AOF / replication */ redisOpArray also_propagate; /* Additional command to propagate. */ int replication_allowed; /* Are we allowed to replicate? */ /* Logging */ char *logfile; /* Path of log file */ int syslog_enabled; /* Is syslog enabled? */ char *syslog_ident; /* Syslog ident */ int syslog_facility; /* Syslog facility */ int crashlog_enabled; /* Enable signal handler for crashlog. * disable for clean core dumps. */ int memcheck_enabled; /* Enable memory check on crash. */ int use_exit_on_panic; /* Use exit() on panic and assert rather than * abort(). useful for Valgrind. */ /* Shutdown */ int shutdown_timeout; /* Graceful shutdown time limit in seconds. */ /* Replication (master) */ char replid[CONFIG_RUN_ID_SIZE+1]; /* My current replication ID. */ char replid2[CONFIG_RUN_ID_SIZE+1]; /* replid inherited from master*/ long long master_repl_offset; /* My current replication offset */ long long second_replid_offset; /* Accept offsets up to this for replid2. */ int slaveseldb; /* Last SELECTed DB in replication output */ int repl_ping_slave_period; /* Master pings the slave every N seconds */ replBacklog *repl_backlog; /* Replication backlog for partial syncs */ long long repl_backlog_size; /* Backlog circular buffer size */ time_t repl_backlog_time_limit; /* Time without slaves after the backlog gets released. */ time_t repl_no_slaves_since; /* We have no slaves since that time. Only valid if server.slaves len is 0. */ int repl_min_slaves_to_write; /* Min number of slaves to write. */ int repl_min_slaves_max_lag; /* Max lag of slaves to write. */ int repl_good_slaves_count; /* Number of slaves with lag <= max_lag. */ int repl_diskless_sync; /* Master send RDB to slaves sockets directly. */ int repl_diskless_load; /* Slave parse RDB directly from the socket. * see REPL_DISKLESS_LOAD_* enum */ int repl_diskless_sync_delay; /* Delay to start a diskless repl BGSAVE. */ int repl_diskless_sync_max_replicas;/* Max replicas for diskless repl BGSAVE * delay (start sooner if they all connect). */ size_t repl_buffer_mem; /* The memory of replication buffer. */ list *repl_buffer_blocks; /* Replication buffers blocks list * (serving replica clients and repl backlog) */ /* Replication (slave) */ char *masteruser; /* AUTH with this user and masterauth with master */ sds masterauth; /* AUTH with this password with master */ char *masterhost; /* Hostname of master */ int masterport; /* Port of master */ int repl_timeout; /* Timeout after N seconds of master idle */ client *master; /* Client that is master for this slave */ client *cached_master; /* Cached master to be reused for PSYNC. */ int repl_syncio_timeout; /* Timeout for synchronous I/O calls */ int repl_state; /* Replication status if the instance is a slave */ off_t repl_transfer_size; /* Size of RDB to read from master during sync. */ off_t repl_transfer_read; /* Amount of RDB read from master during sync. */ off_t repl_transfer_last_fsync_off; /* Offset when we fsync-ed last time. */ connection *repl_transfer_s; /* Slave -> Master SYNC connection */ int repl_transfer_fd; /* Slave -> Master SYNC temp file descriptor */ char *repl_transfer_tmpfile; /* Slave-> master SYNC temp file name */ time_t repl_transfer_lastio; /* Unix time of the latest read, for timeout */ int repl_serve_stale_data; /* Serve stale data when link is down? */ int repl_slave_ro; /* Slave is read only? */ int repl_slave_ignore_maxmemory; /* If true slaves do not evict. */ time_t repl_down_since; /* Unix time at which link with master went down */ int repl_disable_tcp_nodelay; /* Disable TCP_NODELAY after SYNC? */ int slave_priority; /* Reported in INFO and used by Sentinel. */ int replica_announced; /* If true, replica is announced by Sentinel */ int slave_announce_port; /* Give the master this listening port. */ char *slave_announce_ip; /* Give the master this ip address. */ /* The following two fields is where we store master PSYNC replid/offset * while the PSYNC is in progress. At the end we'll copy the fields into * the server->master client structure. */ char master_replid[CONFIG_RUN_ID_SIZE+1]; /* Master PSYNC runid. */ long long master_initial_offset; /* Master PSYNC offset. */ int repl_slave_lazy_flush; /* Lazy FLUSHALL before loading DB? */ /* Replication script cache. */ dict *repl_scriptcache_dict; /* SHA1 all slaves are aware of. */ list *repl_scriptcache_fifo; /* First in, first out LRU eviction. */ unsigned int repl_scriptcache_size; /* Max number of elements. */ /* Synchronous replication. */ list *clients_waiting_acks; /* Clients waiting in WAIT command. */ int get_ack_from_slaves; /* If true we send REPLCONF GETACK. */ /* Limits */ unsigned int maxclients; /* Max number of simultaneous clients */ unsigned long long maxmemory; /* Max number of memory bytes to use */ ssize_t maxmemory_clients; /* Memory limit for total client buffers */ int maxmemory_policy; /* Policy for key eviction */ int maxmemory_samples; /* Precision of random sampling */ int maxmemory_eviction_tenacity;/* Aggressiveness of eviction processing */ int lfu_log_factor; /* LFU logarithmic counter factor. */ int lfu_decay_time; /* LFU counter decay factor. */ long long proto_max_bulk_len; /* Protocol bulk length maximum size. */ int oom_score_adj_values[CONFIG_OOM_COUNT]; /* Linux oom_score_adj configuration */ int oom_score_adj; /* If true, oom_score_adj is managed */ int disable_thp; /* If true, disable THP by syscall */ /* Blocked clients */ unsigned int blocked_clients; /* # of clients executing a blocking cmd.*/ unsigned int blocked_clients_by_type[BLOCKED_NUM]; list *unblocked_clients; /* list of clients to unblock before next loop */ list *ready_keys; /* List of readyList structures for BLPOP & co */ /* Client side caching. */ unsigned int tracking_clients; /* # of clients with tracking enabled.*/ size_t tracking_table_max_keys; /* Max number of keys in tracking table. */ list *tracking_pending_keys; /* tracking invalidation keys pending to flush */ /* Sort parameters - qsort_r() is only available under BSD so we * have to take this state global, in order to pass it to sortCompare() */ int sort_desc; int sort_alpha; int sort_bypattern; int sort_store; /* Zip structure config, see redis.conf for more information */ size_t hash_max_listpack_entries; size_t hash_max_listpack_value; size_t set_max_intset_entries; size_t zset_max_listpack_entries; size_t zset_max_listpack_value; size_t hll_sparse_max_bytes; size_t stream_node_max_bytes; long long stream_node_max_entries; /* List parameters */ int list_max_listpack_size; int list_compress_depth; /* time cache */ redisAtomic time_t unixtime; /* Unix time sampled every cron cycle. */ time_t timezone; /* Cached timezone. As set by tzset(). */ int daylight_active; /* Currently in daylight saving time. */ mstime_t mstime; /* 'unixtime' in milliseconds. */ ustime_t ustime; /* 'unixtime' in microseconds. */ size_t blocking_op_nesting; /* Nesting level of blocking operation, used to reset blocked_last_cron. */ long long blocked_last_cron; /* Indicate the mstime of the last time we did cron jobs from a blocking operation */ /* Pubsub */ dict *pubsub_channels; /* Map channels to list of subscribed clients */ dict *pubsub_patterns; /* A dict of pubsub_patterns */ int notify_keyspace_events; /* Events to propagate via Pub/Sub. This is an xor of NOTIFY_... flags. */ dict *pubsubshard_channels; /* Map channels to list of subscribed clients */ /* Cluster */ int cluster_enabled; /* Is cluster enabled? */ int cluster_port; /* Set the cluster port for a node. */ mstime_t cluster_node_timeout; /* Cluster node timeout. */ char *cluster_configfile; /* Cluster auto-generated config file name. */ struct clusterState *cluster; /* State of the cluster */ int cluster_migration_barrier; /* Cluster replicas migration barrier. */ int cluster_allow_replica_migration; /* Automatic replica migrations to orphaned masters and from empty masters */ int cluster_slave_validity_factor; /* Slave max data age for failover. */ int cluster_require_full_coverage; /* If true, put the cluster down if there is at least an uncovered slot.*/ int cluster_slave_no_failover; /* Prevent slave from starting a failover if the master is in failure state. */ char *cluster_announce_ip; /* IP address to announce on cluster bus. */ char *cluster_announce_hostname; /* IP address to announce on cluster bus. */ int cluster_preferred_endpoint_type; /* Use the announced hostname when available. */ int cluster_announce_port; /* base port to announce on cluster bus. */ int cluster_announce_tls_port; /* TLS port to announce on cluster bus. */ int cluster_announce_bus_port; /* bus port to announce on cluster bus. */ int cluster_module_flags; /* Set of flags that Redis modules are able to set in order to suppress certain native Redis Cluster features. Check the REDISMODULE_CLUSTER_FLAG_*. */ int cluster_allow_reads_when_down; /* Are reads allowed when the cluster is down? */ int cluster_config_file_lock_fd; /* cluster config fd, will be flock */ unsigned long long cluster_link_sendbuf_limit_bytes; /* Memory usage limit on individual link send buffers*/ int cluster_drop_packet_filter; /* Debug config that allows tactically * dropping packets of a specific type */ /* Scripting */ client *script_caller; /* The client running script right now, or NULL */ mstime_t busy_reply_threshold; /* Script / module timeout in milliseconds */ int script_oom; /* OOM detected when script start */ int script_disable_deny_script; /* Allow running commands marked "no-script" inside a script. */ /* Lazy free */ int lazyfree_lazy_eviction; int lazyfree_lazy_expire; int lazyfree_lazy_server_del; int lazyfree_lazy_user_del; int lazyfree_lazy_user_flush; /* Latency monitor */ long long latency_monitor_threshold; dict *latency_events; /* ACLs */ char *acl_filename; /* ACL Users file. NULL if not configured. */ unsigned long acllog_max_len; /* Maximum length of the ACL LOG list. */ sds requirepass; /* Remember the cleartext password set with the old "requirepass" directive for backward compatibility with Redis <= 5. */ int acl_pubsub_default; /* Default ACL pub/sub channels flag */ /* Assert & bug reporting */ int watchdog_period; /* Software watchdog period in ms. 0 = off */ /* System hardware info */ size_t system_memory_size; /* Total memory in system as reported by OS */ /* TLS Configuration */ int tls_cluster; int tls_replication; int tls_auth_clients; redisTLSContextConfig tls_ctx_config; /* cpu affinity */ char *server_cpulist; /* cpu affinity list of redis server main/io thread. */ char *bio_cpulist; /* cpu affinity list of bio thread. */ char *aof_rewrite_cpulist; /* cpu affinity list of aof rewrite process. */ char *bgsave_cpulist; /* cpu affinity list of bgsave process. */ /* Sentinel config */ struct sentinelConfig *sentinel_config; /* sentinel config to load at startup time. */ /* Coordinate failover info */ mstime_t failover_end_time; /* Deadline for failover command. */ int force_failover; /* If true then failover will be forced at the * deadline, otherwise failover is aborted. */ char *target_replica_host; /* Failover target host. If null during a * failover then any replica can be used. */ int target_replica_port; /* Failover target port */ int failover_state; /* Failover state */ int cluster_allow_pubsubshard_when_down; /* Is pubsubshard allowed when the cluster is down, doesn't affect pubsub global. */ }; #define MAX_KEYS_BUFFER 256 /* A result structure for the various getkeys function calls. It lists the * keys as indices to the provided argv. */ typedef struct { int keysbuf[MAX_KEYS_BUFFER]; /* Pre-allocated buffer, to save heap allocations */ int *keys; /* Key indices array, points to keysbuf or heap */ int numkeys; /* Number of key indices return */ int size; /* Available array size */ } getKeysResult; #define GETKEYS_RESULT_INIT { {0}, NULL, 0, MAX_KEYS_BUFFER } /* Key specs definitions. * * Brief: This is a scheme that tries to describe the location * of key arguments better than the old [first,last,step] scheme * which is limited and doesn't fit many commands. * * There are two steps: * 1. begin_search (BS): in which index should we start seacrhing for keys? * 2. find_keys (FK): relative to the output of BS, how can we will which args are keys? * * There are two types of BS: * 1. index: key args start at a constant index * 2. keyword: key args start just after a specific keyword * * There are two kinds of FK: * 1. range: keys end at a specific index (or relative to the last argument) * 2. keynum: there's an arg that contains the number of key args somewhere before the keys themselves */ /* Must be synced with generate-command-code.py */ typedef enum { KSPEC_BS_INVALID = 0, /* Must be 0 */ KSPEC_BS_UNKNOWN, KSPEC_BS_INDEX, KSPEC_BS_KEYWORD } kspec_bs_type; /* Must be synced with generate-command-code.py */ typedef enum { KSPEC_FK_INVALID = 0, /* Must be 0 */ KSPEC_FK_UNKNOWN, KSPEC_FK_RANGE, KSPEC_FK_KEYNUM } kspec_fk_type; typedef struct { /* Declarative data */ uint64_t flags; kspec_bs_type begin_search_type; union { struct { /* The index from which we start the search for keys */ int pos; } index; struct { /* The keyword that indicates the beginning of key args */ const char *keyword; /* An index in argv from which to start searching. * Can be negative, which means start search from the end, in reverse * (Example: -2 means to start in reverse from the panultimate arg) */ int startfrom; } keyword; } bs; kspec_fk_type find_keys_type; union { /* NOTE: Indices in this struct are relative to the result of the begin_search step! * These are: range.lastkey, keynum.keynumidx, keynum.firstkey */ struct { /* Index of the last key. * Can be negative, in which case it's not relative. -1 indicating till the last argument, * -2 one before the last and so on. */ int lastkey; /* How many args should we skip after finding a key, in order to find the next one. */ int keystep; /* If lastkey is -1, we use limit to stop the search by a factor. 0 and 1 mean no limit. * 2 means 1/2 of the remaining args, 3 means 1/3, and so on. */ int limit; } range; struct { /* Index of the argument containing the number of keys to come */ int keynumidx; /* Index of the fist key (Usually it's just after keynumidx, in * which case it should be set to keynumidx+1). */ int firstkey; /* How many args should we skip after finding a key, in order to find the next one. */ int keystep; } keynum; } fk; } keySpec; /* Number of static key specs */ #define STATIC_KEY_SPECS_NUM 4 /* Must be synced with ARG_TYPE_STR and generate-command-code.py */ typedef enum { ARG_TYPE_STRING, ARG_TYPE_INTEGER, ARG_TYPE_DOUBLE, ARG_TYPE_KEY, ARG_TYPE_PATTERN, ARG_TYPE_UNIX_TIME, ARG_TYPE_PURE_TOKEN, ARG_TYPE_ONEOF, /* Has subargs */ ARG_TYPE_BLOCK /* Has subargs */ } redisCommandArgType; #define CMD_ARG_NONE (0) #define CMD_ARG_OPTIONAL (1<<0) #define CMD_ARG_MULTIPLE (1<<1) #define CMD_ARG_MULTIPLE_TOKEN (1<<2) typedef struct redisCommandArg { const char *name; redisCommandArgType type; int key_spec_index; const char *token; const char *summary; const char *since; int flags; struct redisCommandArg *subargs; /* runtime populated data */ int num_args; } redisCommandArg; /* Must be synced with RESP2_TYPE_STR and generate-command-code.py */ typedef enum { RESP2_SIMPLE_STRING, RESP2_ERROR, RESP2_INTEGER, RESP2_BULK_STRING, RESP2_NULL_BULK_STRING, RESP2_ARRAY, RESP2_NULL_ARRAY, } redisCommandRESP2Type; /* Must be synced with RESP3_TYPE_STR and generate-command-code.py */ typedef enum { RESP3_SIMPLE_STRING, RESP3_ERROR, RESP3_INTEGER, RESP3_DOUBLE, RESP3_BULK_STRING, RESP3_ARRAY, RESP3_MAP, RESP3_SET, RESP3_BOOL, RESP3_NULL, } redisCommandRESP3Type; typedef struct { const char *since; const char *changes; } commandHistory; /* Must be synced with COMMAND_GROUP_STR and generate-command-code.py */ typedef enum { COMMAND_GROUP_GENERIC, COMMAND_GROUP_STRING, COMMAND_GROUP_LIST, COMMAND_GROUP_SET, COMMAND_GROUP_SORTED_SET, COMMAND_GROUP_HASH, COMMAND_GROUP_PUBSUB, COMMAND_GROUP_TRANSACTIONS, COMMAND_GROUP_CONNECTION, COMMAND_GROUP_SERVER, COMMAND_GROUP_SCRIPTING, COMMAND_GROUP_HYPERLOGLOG, COMMAND_GROUP_CLUSTER, COMMAND_GROUP_SENTINEL, COMMAND_GROUP_GEO, COMMAND_GROUP_STREAM, COMMAND_GROUP_BITMAP, COMMAND_GROUP_MODULE, } redisCommandGroup; typedef void redisCommandProc(client *c); typedef int redisGetKeysProc(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); /* Redis command structure. * * Note that the command table is in commands.c and it is auto-generated. * * This is the meaning of the flags: * * CMD_WRITE: Write command (may modify the key space). * * CMD_READONLY: Commands just reading from keys without changing the content. * Note that commands that don't read from the keyspace such as * TIME, SELECT, INFO, administrative commands, and connection * or transaction related commands (multi, exec, discard, ...) * are not flagged as read-only commands, since they affect the * server or the connection in other ways. * * CMD_DENYOOM: May increase memory usage once called. Don't allow if out * of memory. * * CMD_ADMIN: Administrative command, like SAVE or SHUTDOWN. * * CMD_PUBSUB: Pub/Sub related command. * * CMD_NOSCRIPT: Command not allowed in scripts. * * CMD_RANDOM: Random command. Command is not deterministic, that is, the same * command with the same arguments, with the same key space, may * have different results. For instance SPOP and RANDOMKEY are * two random commands. * * CMD_SORT_FOR_SCRIPT: Sort command output array if called from script, so that the * output is deterministic. When this flag is used (not always * possible), then the "random" flag is not needed. * * CMD_LOADING: Allow the command while loading the database. * * CMD_NO_ASYNC_LOADING: Deny during async loading (when a replica uses diskless * sync swapdb, and allows access to the old dataset) * * CMD_STALE: Allow the command while a slave has stale data but is not * allowed to serve this data. Normally no command is accepted * in this condition but just a few. * * CMD_SKIP_MONITOR: Do not automatically propagate the command on MONITOR. * * CMD_SKIP_SLOWLOG: Do not automatically propagate the command to the slowlog. * * CMD_ASKING: Perform an implicit ASKING for this command, so the * command will be accepted in cluster mode if the slot is marked * as 'importing'. * * CMD_FAST: Fast command: O(1) or O(log(N)) command that should never * delay its execution as long as the kernel scheduler is giving * us time. Note that commands that may trigger a DEL as a side * effect (like SET) are not fast commands. * * CMD_NO_AUTH: Command doesn't require authentication * * CMD_MAY_REPLICATE: Command may produce replication traffic, but should be * allowed under circumstances where write commands are disallowed. * Examples include PUBLISH, which replicates pubsub messages,and * EVAL, which may execute write commands, which are replicated, * or may just execute read commands. A command can not be marked * both CMD_WRITE and CMD_MAY_REPLICATE * * CMD_SENTINEL: This command is present in sentinel mode too. * * CMD_SENTINEL_ONLY: This command is present only when in sentinel mode. * * CMD_NO_MANDATORY_KEYS: This key arguments for this command are optional. * * CMD_NO_MULTI: The command is nt allowed inside a transaction * * The following additional flags are only used in order to put commands * in a specific ACL category. Commands can have multiple ACL categories. * See redis.conf for the exact meaning of each. * * @keyspace, @read, @write, @set, @sortedset, @list, @hash, @string, @bitmap, * @hyperloglog, @stream, @admin, @fast, @slow, @pubsub, @blocking, @dangerous, * @connection, @transaction, @scripting, @geo. * * Note that: * * 1) The read-only flag implies the @read ACL category. * 2) The write flag implies the @write ACL category. * 3) The fast flag implies the @fast ACL category. * 4) The admin flag implies the @admin and @dangerous ACL category. * 5) The pub-sub flag implies the @pubsub ACL category. * 6) The lack of fast flag implies the @slow ACL category. * 7) The non obvious "keyspace" category includes the commands * that interact with keys without having anything to do with * specific data structures, such as: DEL, RENAME, MOVE, SELECT, * TYPE, EXPIRE*, PEXPIRE*, TTL, PTTL, ... */ struct redisCommand { /* Declarative data */ const char *name; /* A string representing the command name. */ const char *summary; /* Summary of the command (optional). */ const char *complexity; /* Complexity description (optional). */ const char *since; /* Debut version of the command (optional). */ int doc_flags; /* Flags for documentation (see CMD_DOC_*). */ const char *replaced_by; /* In case the command is deprecated, this is the successor command. */ const char *deprecated_since; /* In case the command is deprecated, when did it happen? */ redisCommandGroup group; /* Command group */ commandHistory *history; /* History of the command */ const char **hints; /* An array of strings that are meant o be hints for clients/proxies regarding this command */ redisCommandProc *proc; /* Command implementation */ int arity; /* Number of arguments, it is possible to use -N to say >= N */ uint64_t flags; /* Command flags, see CMD_*. */ uint64_t acl_categories; /* ACl categories, see ACL_CATEGORY_*. */ keySpec key_specs_static[STATIC_KEY_SPECS_NUM]; /* Key specs. See keySpec */ /* Use a function to determine keys arguments in a command line. * Used for Redis Cluster redirect (may be NULL) */ redisGetKeysProc *getkeys_proc; /* Array of subcommands (may be NULL) */ struct redisCommand *subcommands; /* Array of arguments (may be NULL) */ struct redisCommandArg *args; /* Runtime populated data */ /* What keys should be loaded in background when calling this command? */ long long microseconds, calls, rejected_calls, failed_calls; int id; /* Command ID. This is a progressive ID starting from 0 that is assigned at runtime, and is used in order to check ACLs. A connection is able to execute a given command if the user associated to the connection has this command bit set in the bitmap of allowed commands. */ struct hdr_histogram* latency_histogram; /*points to the command latency command histogram (unit of time nanosecond) */ keySpec *key_specs; keySpec legacy_range_key_spec; /* The legacy (first,last,step) key spec is * still maintained (if applicable) so that * we can still support the reply format of * COMMAND INFO and COMMAND GETKEYS */ int num_args; int num_history; int num_hints; int key_specs_num; int key_specs_max; dict *subcommands_dict; struct redisCommand *parent; }; struct redisError { long long count; }; struct redisFunctionSym { char *name; unsigned long pointer; }; typedef struct _redisSortObject { robj *obj; union { double score; robj *cmpobj; } u; } redisSortObject; typedef struct _redisSortOperation { int type; robj *pattern; } redisSortOperation; /* Structure to hold list iteration abstraction. */ typedef struct { robj *subject; unsigned char encoding; unsigned char direction; /* Iteration direction */ quicklistIter *iter; } listTypeIterator; /* Structure for an entry while iterating over a list. */ typedef struct { listTypeIterator *li; quicklistEntry entry; /* Entry in quicklist */ } listTypeEntry; /* Structure to hold set iteration abstraction. */ typedef struct { robj *subject; int encoding; int ii; /* intset iterator */ dictIterator *di; } setTypeIterator; /* Structure to hold hash iteration abstraction. Note that iteration over * hashes involves both fields and values. Because it is possible that * not both are required, store pointers in the iterator to avoid * unnecessary memory allocation for fields/values. */ typedef struct { robj *subject; int encoding; unsigned char *fptr, *vptr; dictIterator *di; dictEntry *de; } hashTypeIterator; #include "stream.h" /* Stream data type header file. */ #define OBJ_HASH_KEY 1 #define OBJ_HASH_VALUE 2 #define IO_THREADS_OP_IDLE 0 #define IO_THREADS_OP_READ 1 #define IO_THREADS_OP_WRITE 2 extern int io_threads_op; /*----------------------------------------------------------------------------- * Extern declarations *----------------------------------------------------------------------------*/ extern struct redisServer server; extern struct sharedObjectsStruct shared; extern dictType objectKeyPointerValueDictType; extern dictType objectKeyHeapPointerValueDictType; extern dictType setDictType; extern dictType zsetDictType; extern dictType dbDictType; extern dictType shaScriptObjectDictType; extern double R_Zero, R_PosInf, R_NegInf, R_Nan; extern dictType hashDictType; extern dictType replScriptCacheDictType; extern dictType dbExpiresDictType; extern dictType modulesDictType; extern dictType sdsReplyDictType; extern dict *modules; /*----------------------------------------------------------------------------- * Functions prototypes *----------------------------------------------------------------------------*/ /* Key arguments specs */ void populateCommandLegacyRangeSpec(struct redisCommand *c); /* Modules */ void moduleInitModulesSystem(void); void moduleInitModulesSystemLast(void); void modulesCron(void); int moduleLoad(const char *path, void **argv, int argc); void moduleLoadFromQueue(void); int moduleGetCommandKeysViaAPI(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); moduleType *moduleTypeLookupModuleByID(uint64_t id); void moduleTypeNameByID(char *name, uint64_t moduleid); const char *moduleTypeModuleName(moduleType *mt); void moduleFreeContext(struct RedisModuleCtx *ctx); void unblockClientFromModule(client *c); void moduleHandleBlockedClients(void); void moduleBlockedClientTimedOut(client *c); void modulePipeReadable(aeEventLoop *el, int fd, void *privdata, int mask); size_t moduleCount(void); void moduleAcquireGIL(void); int moduleTryAcquireGIL(void); void moduleReleaseGIL(void); void moduleNotifyKeyspaceEvent(int type, const char *event, robj *key, int dbid); void moduleCallCommandFilters(client *c); void ModuleForkDoneHandler(int exitcode, int bysignal); int TerminateModuleForkChild(int child_pid, int wait); ssize_t rdbSaveModulesAux(rio *rdb, int when); int moduleAllDatatypesHandleErrors(); int moduleAllModulesHandleReplAsyncLoad(); sds modulesCollectInfo(sds info, const char *section, int for_crash_report, int sections); void moduleFireServerEvent(uint64_t eid, int subid, void *data); void processModuleLoadingProgressEvent(int is_aof); int moduleTryServeClientBlockedOnKey(client *c, robj *key); void moduleUnblockClient(client *c); int moduleBlockedClientMayTimeout(client *c); int moduleClientIsBlockedOnKeys(client *c); void moduleNotifyUserChanged(client *c); void moduleNotifyKeyUnlink(robj *key, robj *val, int dbid); size_t moduleGetFreeEffort(robj *key, robj *val, int dbid); size_t moduleGetMemUsage(robj *key, robj *val, size_t sample_size, int dbid); robj *moduleTypeDupOrReply(client *c, robj *fromkey, robj *tokey, int todb, robj *value); int moduleDefragValue(robj *key, robj *obj, long *defragged, int dbid); int moduleLateDefrag(robj *key, robj *value, unsigned long *cursor, long long endtime, long long *defragged, int dbid); long moduleDefragGlobals(void); void *moduleGetHandleByName(char *modulename); int moduleIsModuleCommand(void *module_handle, struct redisCommand *cmd); /* Utils */ long long ustime(void); long long mstime(void); void getRandomHexChars(char *p, size_t len); void getRandomBytes(unsigned char *p, size_t len); uint64_t crc64(uint64_t crc, const unsigned char *s, uint64_t l); void exitFromChild(int retcode); long long redisPopcount(void *s, long count); int redisSetProcTitle(char *title); int validateProcTitleTemplate(const char *template); int redisCommunicateSystemd(const char *sd_notify_msg); void redisSetCpuAffinity(const char *cpulist); /* networking.c -- Networking and Client related operations */ client *createClient(connection *conn); void freeClient(client *c); void freeClientAsync(client *c); void logInvalidUseAndFreeClientAsync(client *c, const char *fmt, ...); int beforeNextClient(client *c); void clearClientConnectionState(client *c); void resetClient(client *c); void freeClientOriginalArgv(client *c); void sendReplyToClient(connection *conn); void *addReplyDeferredLen(client *c); void setDeferredArrayLen(client *c, void *node, long length); void setDeferredMapLen(client *c, void *node, long length); void setDeferredSetLen(client *c, void *node, long length); void setDeferredAttributeLen(client *c, void *node, long length); void setDeferredPushLen(client *c, void *node, long length); int processInputBuffer(client *c); void acceptTcpHandler(aeEventLoop *el, int fd, void *privdata, int mask); void acceptTLSHandler(aeEventLoop *el, int fd, void *privdata, int mask); void acceptUnixHandler(aeEventLoop *el, int fd, void *privdata, int mask); void readQueryFromClient(connection *conn); int prepareClientToWrite(client *c); void addReplyNull(client *c); void addReplyNullArray(client *c); void addReplyBool(client *c, int b); void addReplyVerbatim(client *c, const char *s, size_t len, const char *ext); void addReplyProto(client *c, const char *s, size_t len); void AddReplyFromClient(client *c, client *src); void addReplyBulk(client *c, robj *obj); void addReplyBulkCString(client *c, const char *s); void addReplyBulkCBuffer(client *c, const void *p, size_t len); void addReplyBulkLongLong(client *c, long long ll); void addReply(client *c, robj *obj); void addReplySds(client *c, sds s); void addReplyBulkSds(client *c, sds s); void setDeferredReplyBulkSds(client *c, void *node, sds s); void addReplyErrorObject(client *c, robj *err); void addReplyOrErrorObject(client *c, robj *reply); void addReplyErrorSds(client *c, sds err); void addReplyError(client *c, const char *err); void addReplyStatus(client *c, const char *status); void addReplyDouble(client *c, double d); void addReplyLongLongWithPrefix(client *c, long long ll, char prefix); void addReplyBigNum(client *c, const char* num, size_t len); void addReplyHumanLongDouble(client *c, long double d); void addReplyLongLong(client *c, long long ll); void addReplyArrayLen(client *c, long length); void addReplyMapLen(client *c, long length); void addReplySetLen(client *c, long length); void addReplyAttributeLen(client *c, long length); void addReplyPushLen(client *c, long length); void addReplyHelp(client *c, const char **help); void addReplySubcommandSyntaxError(client *c); void addReplyLoadedModules(client *c); void copyReplicaOutputBuffer(client *dst, client *src); void addListRangeReply(client *c, robj *o, long start, long end, int reverse); size_t sdsZmallocSize(sds s); size_t getStringObjectSdsUsedMemory(robj *o); void freeClientReplyValue(void *o); void *dupClientReplyValue(void *o); char *getClientPeerId(client *client); char *getClientSockName(client *client); sds catClientInfoString(sds s, client *client); sds getAllClientsInfoString(int type); void rewriteClientCommandVector(client *c, int argc, ...); void rewriteClientCommandArgument(client *c, int i, robj *newval); void replaceClientCommandVector(client *c, int argc, robj **argv); void redactClientCommandArgument(client *c, int argc); size_t getClientOutputBufferMemoryUsage(client *c); size_t getClientMemoryUsage(client *c, size_t *output_buffer_mem_usage); int freeClientsInAsyncFreeQueue(void); int closeClientOnOutputBufferLimitReached(client *c, int async); int getClientType(client *c); int getClientTypeByName(char *name); char *getClientTypeName(int class); void flushSlavesOutputBuffers(void); void disconnectSlaves(void); void evictClients(void); int listenToPort(int port, socketFds *fds); void pauseClients(pause_purpose purpose, mstime_t end, pause_type type); void unpauseClients(pause_purpose purpose); int areClientsPaused(void); int checkClientPauseTimeoutAndReturnIfPaused(void); void unblockPostponedClients(); void processEventsWhileBlocked(void); void whileBlockedCron(); void blockingOperationStarts(); void blockingOperationEnds(); int handleClientsWithPendingWrites(void); int handleClientsWithPendingWritesUsingThreads(void); int handleClientsWithPendingReadsUsingThreads(void); int stopThreadedIOIfNeeded(void); int clientHasPendingReplies(client *c); int islocalClient(client *c); int updateClientMemUsage(client *c); void updateClientMemUsageBucket(client *c); void unlinkClient(client *c); int writeToClient(client *c, int handler_installed); void linkClient(client *c); void protectClient(client *c); void unprotectClient(client *c); void initThreadedIO(void); client *lookupClientByID(uint64_t id); int authRequired(client *c); void clientInstallWriteHandler(client *c); #ifdef __GNUC__ void addReplyErrorFormat(client *c, const char *fmt, ...) __attribute__((format(printf, 2, 3))); void addReplyStatusFormat(client *c, const char *fmt, ...) __attribute__((format(printf, 2, 3))); #else void addReplyErrorFormat(client *c, const char *fmt, ...); void addReplyStatusFormat(client *c, const char *fmt, ...); #endif /* Client side caching (tracking mode) */ void enableTracking(client *c, uint64_t redirect_to, uint64_t options, robj **prefix, size_t numprefix); void disableTracking(client *c); void trackingRememberKeys(client *c); void trackingInvalidateKey(client *c, robj *keyobj, int bcast); void trackingScheduleKeyInvalidation(uint64_t client_id, robj *keyobj); void trackingHandlePendingKeyInvalidations(void); void trackingInvalidateKeysOnFlush(int async); void freeTrackingRadixTree(rax *rt); void freeTrackingRadixTreeAsync(rax *rt); void trackingLimitUsedSlots(void); uint64_t trackingGetTotalItems(void); uint64_t trackingGetTotalKeys(void); uint64_t trackingGetTotalPrefixes(void); void trackingBroadcastInvalidationMessages(void); int checkPrefixCollisionsOrReply(client *c, robj **prefix, size_t numprefix); /* List data type */ void listTypePush(robj *subject, robj *value, int where); robj *listTypePop(robj *subject, int where); unsigned long listTypeLength(const robj *subject); listTypeIterator *listTypeInitIterator(robj *subject, long index, unsigned char direction); void listTypeReleaseIterator(listTypeIterator *li); void listTypeSetIteratorDirection(listTypeIterator *li, unsigned char direction); int listTypeNext(listTypeIterator *li, listTypeEntry *entry); robj *listTypeGet(listTypeEntry *entry); void listTypeInsert(listTypeEntry *entry, robj *value, int where); void listTypeReplace(listTypeEntry *entry, robj *value); int listTypeEqual(listTypeEntry *entry, robj *o); void listTypeDelete(listTypeIterator *iter, listTypeEntry *entry); robj *listTypeDup(robj *o); int listTypeDelRange(robj *o, long start, long stop); void unblockClientWaitingData(client *c); void popGenericCommand(client *c, int where); void listElementsRemoved(client *c, robj *key, int where, robj *o, long count, int *deleted); /* MULTI/EXEC/WATCH... */ void unwatchAllKeys(client *c); void initClientMultiState(client *c); void freeClientMultiState(client *c); void queueMultiCommand(client *c); size_t multiStateMemOverhead(client *c); void touchWatchedKey(redisDb *db, robj *key); int isWatchedKeyExpired(client *c); void touchAllWatchedKeysInDb(redisDb *emptied, redisDb *replaced_with); void discardTransaction(client *c); void flagTransaction(client *c); void execCommandAbort(client *c, sds error); /* Redis object implementation */ void decrRefCount(robj *o); void decrRefCountVoid(void *o); void incrRefCount(robj *o); robj *makeObjectShared(robj *o); robj *resetRefCount(robj *obj); void freeStringObject(robj *o); void freeListObject(robj *o); void freeSetObject(robj *o); void freeZsetObject(robj *o); void freeHashObject(robj *o); void dismissObject(robj *o, size_t dump_size); robj *createObject(int type, void *ptr); robj *createStringObject(const char *ptr, size_t len); robj *createRawStringObject(const char *ptr, size_t len); robj *createEmbeddedStringObject(const char *ptr, size_t len); robj *tryCreateRawStringObject(const char *ptr, size_t len); robj *tryCreateStringObject(const char *ptr, size_t len); robj *dupStringObject(const robj *o); int isSdsRepresentableAsLongLong(sds s, long long *llval); int isObjectRepresentableAsLongLong(robj *o, long long *llongval); robj *tryObjectEncoding(robj *o); robj *getDecodedObject(robj *o); size_t stringObjectLen(robj *o); robj *createStringObjectFromLongLong(long long value); robj *createStringObjectFromLongLongForValue(long long value); robj *createStringObjectFromLongDouble(long double value, int humanfriendly); robj *createQuicklistObject(void); robj *createSetObject(void); robj *createIntsetObject(void); robj *createHashObject(void); robj *createZsetObject(void); robj *createZsetListpackObject(void); robj *createStreamObject(void); robj *createModuleObject(moduleType *mt, void *value); int getLongFromObjectOrReply(client *c, robj *o, long *target, const char *msg); int getPositiveLongFromObjectOrReply(client *c, robj *o, long *target, const char *msg); int getRangeLongFromObjectOrReply(client *c, robj *o, long min, long max, long *target, const char *msg); int checkType(client *c, robj *o, int type); int getLongLongFromObjectOrReply(client *c, robj *o, long long *target, const char *msg); int getDoubleFromObjectOrReply(client *c, robj *o, double *target, const char *msg); int getDoubleFromObject(const robj *o, double *target); int getLongLongFromObject(robj *o, long long *target); int getLongDoubleFromObject(robj *o, long double *target); int getLongDoubleFromObjectOrReply(client *c, robj *o, long double *target, const char *msg); int getIntFromObjectOrReply(client *c, robj *o, int *target, const char *msg); char *strEncoding(int encoding); int compareStringObjects(robj *a, robj *b); int collateStringObjects(robj *a, robj *b); int equalStringObjects(robj *a, robj *b); unsigned long long estimateObjectIdleTime(robj *o); void trimStringObjectIfNeeded(robj *o); #define sdsEncodedObject(objptr) (objptr->encoding == OBJ_ENCODING_RAW || objptr->encoding == OBJ_ENCODING_EMBSTR) /* Synchronous I/O with timeout */ ssize_t syncWrite(int fd, char *ptr, ssize_t size, long long timeout); ssize_t syncRead(int fd, char *ptr, ssize_t size, long long timeout); ssize_t syncReadLine(int fd, char *ptr, ssize_t size, long long timeout); /* Replication */ void replicationFeedSlaves(list *slaves, int dictid, robj **argv, int argc); void replicationFeedStreamFromMasterStream(char *buf, size_t buflen); void resetReplicationBuffer(void); void feedReplicationBuffer(char *buf, size_t len); void freeReplicaReferencedReplBuffer(client *replica); void replicationFeedMonitors(client *c, list *monitors, int dictid, robj **argv, int argc); void updateSlavesWaitingBgsave(int bgsaveerr, int type); void replicationCron(void); void replicationStartPendingFork(void); void replicationHandleMasterDisconnection(void); void replicationCacheMaster(client *c); void resizeReplicationBacklog(); void replicationSetMaster(char *ip, int port); void replicationUnsetMaster(void); void refreshGoodSlavesCount(void); void processClientsWaitingReplicas(void); void unblockClientWaitingReplicas(client *c); int replicationCountAcksByOffset(long long offset); void replicationSendNewlineToMaster(void); long long replicationGetSlaveOffset(void); char *replicationGetSlaveName(client *c); long long getPsyncInitialOffset(void); int replicationSetupSlaveForFullResync(client *slave, long long offset); void changeReplicationId(void); void clearReplicationId2(void); void createReplicationBacklog(void); void freeReplicationBacklog(void); void replicationCacheMasterUsingMyself(void); void feedReplicationBacklog(void *ptr, size_t len); void incrementalTrimReplicationBacklog(size_t blocks); int canFeedReplicaReplBuffer(client *replica); void rebaseReplicationBuffer(long long base_repl_offset); void showLatestBacklog(void); void rdbPipeReadHandler(struct aeEventLoop *eventLoop, int fd, void *clientData, int mask); void rdbPipeWriteHandlerConnRemoved(struct connection *conn); void clearFailoverState(void); void updateFailoverStatus(void); void abortFailover(const char *err); const char *getFailoverStateString(); /* Generic persistence functions */ void startLoadingFile(size_t size, char* filename, int rdbflags); void startLoading(size_t size, int rdbflags, int async); void loadingAbsProgress(off_t pos); void loadingIncrProgress(off_t size); void stopLoading(int success); void updateLoadingFileName(char* filename); void startSaving(int rdbflags); void stopSaving(int success); int allPersistenceDisabled(void); #define DISK_ERROR_TYPE_AOF 1 /* Don't accept writes: AOF errors. */ #define DISK_ERROR_TYPE_RDB 2 /* Don't accept writes: RDB errors. */ #define DISK_ERROR_TYPE_NONE 0 /* No problems, we can accept writes. */ int writeCommandsDeniedByDiskError(void); /* RDB persistence */ #include "rdb.h" void killRDBChild(void); int bg_unlink(const char *filename); /* AOF persistence */ void flushAppendOnlyFile(int force); void feedAppendOnlyFile(int dictid, robj **argv, int argc); void aofRemoveTempFile(pid_t childpid); int rewriteAppendOnlyFileBackground(void); int loadAppendOnlyFiles(aofManifest *am); void stopAppendOnly(void); int startAppendOnly(void); void backgroundRewriteDoneHandler(int exitcode, int bysignal); ssize_t aofReadDiffFromParent(void); void killAppendOnlyChild(void); void restartAOFAfterSYNC(); void aofLoadManifestFromDisk(void); void aofOpenIfNeededOnServerStart(void); void aofManifestFree(aofManifest *am); int aofDelHistoryFiles(void); int aofRewriteLimited(void); /* Child info */ void openChildInfoPipe(void); void closeChildInfoPipe(void); void sendChildInfoGeneric(childInfoType info_type, size_t keys, double progress, char *pname); void sendChildCowInfo(childInfoType info_type, char *pname); void sendChildInfo(childInfoType info_type, size_t keys, char *pname); void receiveChildInfo(void); /* Fork helpers */ int redisFork(int type); int hasActiveChildProcess(); void resetChildState(); int isMutuallyExclusiveChildType(int type); /* acl.c -- Authentication related prototypes. */ extern rax *Users; extern user *DefaultUser; void ACLInit(void); /* Return values for ACLCheckAllPerm(). */ #define ACL_OK 0 #define ACL_DENIED_CMD 1 #define ACL_DENIED_KEY 2 #define ACL_DENIED_AUTH 3 /* Only used for ACL LOG entries. */ #define ACL_DENIED_CHANNEL 4 /* Only used for pub/sub commands */ /* Context values for addACLLogEntry(). */ #define ACL_LOG_CTX_TOPLEVEL 0 #define ACL_LOG_CTX_LUA 1 #define ACL_LOG_CTX_MULTI 2 #define ACL_LOG_CTX_MODULE 3 int ACLCheckUserCredentials(robj *username, robj *password); int ACLAuthenticateUser(client *c, robj *username, robj *password); unsigned long ACLGetCommandID(const char *cmdname); void ACLClearCommandID(void); user *ACLGetUserByName(const char *name, size_t namelen); int ACLCheckKey(const user *u, const char *key, int keylen); int ACLCheckPubsubChannelPerm(sds channel, list *allowed, int literal); int ACLCheckAllUserCommandPerm(const user *u, struct redisCommand *cmd, robj **argv, int argc, int *idxptr); int ACLCheckAllPerm(client *c, int *idxptr); int ACLSetUser(user *u, const char *op, ssize_t oplen); uint64_t ACLGetCommandCategoryFlagByName(const char *name); int ACLAppendUserForLoading(sds *argv, int argc, int *argc_err); const char *ACLSetUserStringError(void); int ACLLoadConfiguredUsers(void); sds ACLDescribeUser(user *u); void ACLLoadUsersAtStartup(void); void addReplyCommandCategories(client *c, struct redisCommand *cmd); user *ACLCreateUnlinkedUser(); void ACLFreeUserAndKillClients(user *u); void addACLLogEntry(client *c, int reason, int context, int argpos, sds username, sds object); void ACLUpdateDefaultUserPassword(sds password); /* Sorted sets data type */ /* Input flags. */ #define ZADD_IN_NONE 0 #define ZADD_IN_INCR (1<<0) /* Increment the score instead of setting it. */ #define ZADD_IN_NX (1<<1) /* Don't touch elements not already existing. */ #define ZADD_IN_XX (1<<2) /* Only touch elements already existing. */ #define ZADD_IN_GT (1<<3) /* Only update existing when new scores are higher. */ #define ZADD_IN_LT (1<<4) /* Only update existing when new scores are lower. */ /* Output flags. */ #define ZADD_OUT_NOP (1<<0) /* Operation not performed because of conditionals.*/ #define ZADD_OUT_NAN (1<<1) /* Only touch elements already existing. */ #define ZADD_OUT_ADDED (1<<2) /* The element was new and was added. */ #define ZADD_OUT_UPDATED (1<<3) /* The element already existed, score updated. */ /* Struct to hold an inclusive/exclusive range spec by score comparison. */ typedef struct { double min, max; int minex, maxex; /* are min or max exclusive? */ } zrangespec; /* Struct to hold an inclusive/exclusive range spec by lexicographic comparison. */ typedef struct { sds min, max; /* May be set to shared.(minstring|maxstring) */ int minex, maxex; /* are min or max exclusive? */ } zlexrangespec; zskiplist *zslCreate(void); void zslFree(zskiplist *zsl); zskiplistNode *zslInsert(zskiplist *zsl, double score, sds ele); unsigned char *zzlInsert(unsigned char *zl, sds ele, double score); int zslDelete(zskiplist *zsl, double score, sds ele, zskiplistNode **node); zskiplistNode *zslFirstInRange(zskiplist *zsl, zrangespec *range); zskiplistNode *zslLastInRange(zskiplist *zsl, zrangespec *range); double zzlGetScore(unsigned char *sptr); void zzlNext(unsigned char *zl, unsigned char **eptr, unsigned char **sptr); void zzlPrev(unsigned char *zl, unsigned char **eptr, unsigned char **sptr); unsigned char *zzlFirstInRange(unsigned char *zl, zrangespec *range); unsigned char *zzlLastInRange(unsigned char *zl, zrangespec *range); unsigned long zsetLength(const robj *zobj); void zsetConvert(robj *zobj, int encoding); void zsetConvertToListpackIfNeeded(robj *zobj, size_t maxelelen, size_t totelelen); int zsetScore(robj *zobj, sds member, double *score); unsigned long zslGetRank(zskiplist *zsl, double score, sds o); int zsetAdd(robj *zobj, double score, sds ele, int in_flags, int *out_flags, double *newscore); long zsetRank(robj *zobj, sds ele, int reverse); int zsetDel(robj *zobj, sds ele); robj *zsetDup(robj *o); void genericZpopCommand(client *c, robj **keyv, int keyc, int where, int emitkey, long count, int use_nested_array, int reply_nil_when_empty, int *deleted); sds lpGetObject(unsigned char *sptr); int zslValueGteMin(double value, zrangespec *spec); int zslValueLteMax(double value, zrangespec *spec); void zslFreeLexRange(zlexrangespec *spec); int zslParseLexRange(robj *min, robj *max, zlexrangespec *spec); unsigned char *zzlFirstInLexRange(unsigned char *zl, zlexrangespec *range); unsigned char *zzlLastInLexRange(unsigned char *zl, zlexrangespec *range); zskiplistNode *zslFirstInLexRange(zskiplist *zsl, zlexrangespec *range); zskiplistNode *zslLastInLexRange(zskiplist *zsl, zlexrangespec *range); int zzlLexValueGteMin(unsigned char *p, zlexrangespec *spec); int zzlLexValueLteMax(unsigned char *p, zlexrangespec *spec); int zslLexValueGteMin(sds value, zlexrangespec *spec); int zslLexValueLteMax(sds value, zlexrangespec *spec); /* Core functions */ int getMaxmemoryState(size_t *total, size_t *logical, size_t *tofree, float *level); size_t freeMemoryGetNotCountedMemory(); int overMaxmemoryAfterAlloc(size_t moremem); int processCommand(client *c); int processPendingCommandsAndResetClient(client *c); void setupSignalHandlers(void); void removeSignalHandlers(void); int createSocketAcceptHandler(socketFds *sfd, aeFileProc *accept_handler); int changeListenPort(int port, socketFds *sfd, aeFileProc *accept_handler); int changeBindAddr(void); struct redisCommand *lookupCommand(robj **argv ,int argc); struct redisCommand *lookupCommandBySdsLogic(dict *commands, sds s); struct redisCommand *lookupCommandBySds(sds s); struct redisCommand *lookupCommandByCStringLogic(dict *commands, const char *s); struct redisCommand *lookupCommandByCString(const char *s); struct redisCommand *lookupCommandOrOriginal(robj **argv ,int argc); void call(client *c, int flags); void alsoPropagate(int dbid, robj **argv, int argc, int target); void propagatePendingCommands(); void redisOpArrayInit(redisOpArray *oa); void redisOpArrayFree(redisOpArray *oa); void forceCommandPropagation(client *c, int flags); void preventCommandPropagation(client *c); void preventCommandAOF(client *c); void preventCommandReplication(client *c); void slowlogPushCurrentCommand(client *c, struct redisCommand *cmd, ustime_t duration); void updateCommandLatencyHistogram(struct hdr_histogram** latency_histogram, int64_t duration_hist); int prepareForShutdown(int flags); void replyToClientsBlockedOnShutdown(void); int abortShutdown(void); void afterCommand(client *c); int inNestedCall(void); #ifdef __GNUC__ void _serverLog(int level, const char *fmt, ...) __attribute__((format(printf, 2, 3))); #else void _serverLog(int level, const char *fmt, ...); #endif void serverLogRaw(int level, const char *msg); void serverLogFromHandler(int level, const char *msg); void usage(void); void updateDictResizePolicy(void); int htNeedsResize(dict *dict); void populateCommandTable(void); void resetCommandTableStats(dict* commands); void resetErrorTableStats(void); void adjustOpenFilesLimit(void); void incrementErrorCount(const char *fullerr, size_t namelen); void closeListeningSockets(int unlink_unix_socket); void updateCachedTime(int update_daylight_info); void resetServerStats(void); void activeDefragCycle(void); unsigned int getLRUClock(void); unsigned int LRU_CLOCK(void); const char *evictPolicyToString(void); struct redisMemOverhead *getMemoryOverheadData(void); void freeMemoryOverheadData(struct redisMemOverhead *mh); void checkChildrenDone(void); int setOOMScoreAdj(int process_class); void rejectCommandFormat(client *c, const char *fmt, ...); void *activeDefragAlloc(void *ptr); robj *activeDefragStringOb(robj* ob, long *defragged); void dismissSds(sds s); void dismissMemory(void* ptr, size_t size_hint); void dismissMemoryInChild(void); #define RESTART_SERVER_NONE 0 #define RESTART_SERVER_GRACEFULLY (1<<0) /* Do proper shutdown. */ #define RESTART_SERVER_CONFIG_REWRITE (1<<1) /* CONFIG REWRITE before restart.*/ int restartServer(int flags, mstime_t delay); /* Set data type */ robj *setTypeCreate(sds value); int setTypeAdd(robj *subject, sds value); int setTypeRemove(robj *subject, sds value); int setTypeIsMember(robj *subject, sds value); setTypeIterator *setTypeInitIterator(robj *subject); void setTypeReleaseIterator(setTypeIterator *si); int setTypeNext(setTypeIterator *si, sds *sdsele, int64_t *llele); sds setTypeNextObject(setTypeIterator *si); int setTypeRandomElement(robj *setobj, sds *sdsele, int64_t *llele); unsigned long setTypeRandomElements(robj *set, unsigned long count, robj *aux_set); unsigned long setTypeSize(const robj *subject); void setTypeConvert(robj *subject, int enc); robj *setTypeDup(robj *o); /* Hash data type */ #define HASH_SET_TAKE_FIELD (1<<0) #define HASH_SET_TAKE_VALUE (1<<1) #define HASH_SET_COPY 0 void hashTypeConvert(robj *o, int enc); void hashTypeTryConversion(robj *subject, robj **argv, int start, int end); int hashTypeExists(robj *o, sds key); int hashTypeDelete(robj *o, sds key); unsigned long hashTypeLength(const robj *o); hashTypeIterator *hashTypeInitIterator(robj *subject); void hashTypeReleaseIterator(hashTypeIterator *hi); int hashTypeNext(hashTypeIterator *hi); void hashTypeCurrentFromListpack(hashTypeIterator *hi, int what, unsigned char **vstr, unsigned int *vlen, long long *vll); sds hashTypeCurrentFromHashTable(hashTypeIterator *hi, int what); void hashTypeCurrentObject(hashTypeIterator *hi, int what, unsigned char **vstr, unsigned int *vlen, long long *vll); sds hashTypeCurrentObjectNewSds(hashTypeIterator *hi, int what); robj *hashTypeLookupWriteOrCreate(client *c, robj *key); robj *hashTypeGetValueObject(robj *o, sds field); int hashTypeSet(robj *o, sds field, sds value, int flags); robj *hashTypeDup(robj *o); /* Pub / Sub */ int pubsubUnsubscribeAllChannels(client *c, int notify); int pubsubUnsubscribeShardAllChannels(client *c, int notify); void pubsubUnsubscribeShardChannels(robj **channels, unsigned int count); int pubsubUnsubscribeAllPatterns(client *c, int notify); int pubsubPublishMessage(robj *channel, robj *message); int pubsubPublishMessageShard(robj *channel, robj *message); void addReplyPubsubMessage(client *c, robj *channel, robj *msg); int serverPubsubSubscriptionCount(); int serverPubsubShardSubscriptionCount(); /* Keyspace events notification */ void notifyKeyspaceEvent(int type, char *event, robj *key, int dbid); int keyspaceEventsStringToFlags(char *classes); sds keyspaceEventsFlagsToString(int flags); /* Configuration */ void loadServerConfig(char *filename, char config_from_stdin, char *options); void appendServerSaveParams(time_t seconds, int changes); void resetServerSaveParams(void); struct rewriteConfigState; /* Forward declaration to export API. */ void rewriteConfigRewriteLine(struct rewriteConfigState *state, const char *option, sds line, int force); void rewriteConfigMarkAsProcessed(struct rewriteConfigState *state, const char *option); int rewriteConfig(char *path, int force_all); void initConfigValues(); sds getConfigDebugInfo(); int allowProtectedAction(int config, client *c); /* db.c -- Keyspace access API */ int removeExpire(redisDb *db, robj *key); void deleteExpiredKeyAndPropagate(redisDb *db, robj *keyobj); void propagateDeletion(redisDb *db, robj *key, int lazy); int keyIsExpired(redisDb *db, robj *key); long long getExpire(redisDb *db, robj *key); void setExpire(client *c, redisDb *db, robj *key, long long when); int checkAlreadyExpired(long long when); robj *lookupKeyRead(redisDb *db, robj *key); robj *lookupKeyWrite(redisDb *db, robj *key); robj *lookupKeyReadOrReply(client *c, robj *key, robj *reply); robj *lookupKeyWriteOrReply(client *c, robj *key, robj *reply); robj *lookupKeyReadWithFlags(redisDb *db, robj *key, int flags); robj *lookupKeyWriteWithFlags(redisDb *db, robj *key, int flags); robj *objectCommandLookup(client *c, robj *key); robj *objectCommandLookupOrReply(client *c, robj *key, robj *reply); int objectSetLRUOrLFU(robj *val, long long lfu_freq, long long lru_idle, long long lru_clock, int lru_multiplier); #define LOOKUP_NONE 0 #define LOOKUP_NOTOUCH (1<<0) /* Don't update LRU. */ #define LOOKUP_NONOTIFY (1<<1) /* Don't trigger keyspace event on key misses. */ #define LOOKUP_NOSTATS (1<<2) /* Don't update keyspace hits/misses counters. */ #define LOOKUP_WRITE (1<<3) /* Delete expired keys even in replicas. */ void dbAdd(redisDb *db, robj *key, robj *val); int dbAddRDBLoad(redisDb *db, sds key, robj *val); void dbOverwrite(redisDb *db, robj *key, robj *val); #define SETKEY_KEEPTTL 1 #define SETKEY_NO_SIGNAL 2 #define SETKEY_ALREADY_EXIST 4 #define SETKEY_DOESNT_EXIST 8 void setKey(client *c, redisDb *db, robj *key, robj *val, int flags); robj *dbRandomKey(redisDb *db); int dbSyncDelete(redisDb *db, robj *key); int dbDelete(redisDb *db, robj *key); robj *dbUnshareStringValue(redisDb *db, robj *key, robj *o); #define EMPTYDB_NO_FLAGS 0 /* No flags. */ #define EMPTYDB_ASYNC (1<<0) /* Reclaim memory in another thread. */ #define EMPTYDB_NOFUNCTIONS (1<<1) /* Indicate not to flush the functions. */ long long emptyData(int dbnum, int flags, void(callback)(dict*)); long long emptyDbStructure(redisDb *dbarray, int dbnum, int async, void(callback)(dict*)); void flushAllDataAndResetRDB(int flags); long long dbTotalServerKeyCount(); redisDb *initTempDb(void); void discardTempDb(redisDb *tempDb, void(callback)(dict*)); int selectDb(client *c, int id); void signalModifiedKey(client *c, redisDb *db, robj *key); void signalFlushedDb(int dbid, int async); void scanGenericCommand(client *c, robj *o, unsigned long cursor); int parseScanCursorOrReply(client *c, robj *o, unsigned long *cursor); int dbAsyncDelete(redisDb *db, robj *key); void emptyDbAsync(redisDb *db); size_t lazyfreeGetPendingObjectsCount(void); size_t lazyfreeGetFreedObjectsCount(void); void lazyfreeResetStats(void); void freeObjAsync(robj *key, robj *obj, int dbid); void freeReplicationBacklogRefMemAsync(list *blocks, rax *index); /* API to get key arguments from commands */ int *getKeysPrepareResult(getKeysResult *result, int numkeys); int getKeysFromCommand(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int getChannelsFromCommand(struct redisCommand *cmd, int argc, getKeysResult *result); void getKeysFreeResult(getKeysResult *result); int sintercardGetKeys(struct redisCommand *cmd,robj **argv, int argc, getKeysResult *result); int zunionInterDiffGetKeys(struct redisCommand *cmd,robj **argv, int argc, getKeysResult *result); int zunionInterDiffStoreGetKeys(struct redisCommand *cmd,robj **argv, int argc, getKeysResult *result); int evalGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int functionGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int sortGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int migrateGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int georadiusGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int xreadGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int lmpopGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int blmpopGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int zmpopGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); int bzmpopGetKeys(struct redisCommand *cmd, robj **argv, int argc, getKeysResult *result); unsigned short crc16(const char *buf, int len); /* Sentinel */ void initSentinelConfig(void); void initSentinel(void); void sentinelTimer(void); const char *sentinelHandleConfiguration(char **argv, int argc); void queueSentinelConfig(sds *argv, int argc, int linenum, sds line); void loadSentinelConfigFromQueue(void); void sentinelIsRunning(void); void sentinelCheckConfigFile(void); void sentinelCommand(client *c); void sentinelInfoCommand(client *c); void sentinelPublishCommand(client *c); void sentinelRoleCommand(client *c); /* redis-check-rdb & aof */ int redis_check_rdb(char *rdbfilename, FILE *fp); int redis_check_rdb_main(int argc, char **argv, FILE *fp); int redis_check_aof_main(int argc, char **argv); /* Scripting */ void scriptingInit(int setup); int ldbRemoveChild(pid_t pid); void ldbKillForkedSessions(void); int ldbPendingChildren(void); sds luaCreateFunction(client *c, robj *body); void luaLdbLineHook(lua_State *lua, lua_Debug *ar); void freeLuaScriptsAsync(dict *lua_scripts); void freeFunctionsAsync(functionsLibCtx *lib_ctx); int ldbIsEnabled(); void ldbLog(sds entry); void ldbLogRedisReply(char *reply); void sha1hex(char *digest, char *script, size_t len); unsigned long evalMemory(); dict* evalScriptsDict(); unsigned long evalScriptsMemory(); /* Blocked clients */ void processUnblockedClients(void); void blockClient(client *c, int btype); void unblockClient(client *c); void queueClientForReprocessing(client *c); void replyToBlockedClientTimedOut(client *c); int getTimeoutFromObjectOrReply(client *c, robj *object, mstime_t *timeout, int unit); void disconnectAllBlockedClients(void); void handleClientsBlockedOnKeys(void); void signalKeyAsReady(redisDb *db, robj *key, int type); void blockForKeys(client *c, int btype, robj **keys, int numkeys, long count, mstime_t timeout, robj *target, struct blockPos *blockpos, streamID *ids); void updateStatsOnUnblock(client *c, long blocked_us, long reply_us); /* timeout.c -- Blocked clients timeout and connections timeout. */ void addClientToTimeoutTable(client *c); void removeClientFromTimeoutTable(client *c); void handleBlockedClientsTimeout(void); int clientsCronHandleTimeout(client *c, mstime_t now_ms); /* expire.c -- Handling of expired keys */ void activeExpireCycle(int type); void expireSlaveKeys(void); void rememberSlaveKeyWithExpire(redisDb *db, robj *key); void flushSlaveKeysWithExpireList(void); size_t getSlaveKeyWithExpireCount(void); /* evict.c -- maxmemory handling and LRU eviction. */ void evictionPoolAlloc(void); #define LFU_INIT_VAL 5 unsigned long LFUGetTimeInMinutes(void); uint8_t LFULogIncr(uint8_t value); unsigned long LFUDecrAndReturn(robj *o); #define EVICT_OK 0 #define EVICT_RUNNING 1 #define EVICT_FAIL 2 int performEvictions(void); void startEvictionTimeProc(void); /* Keys hashing / comparison functions for dict.c hash tables. */ uint64_t dictSdsHash(const void *key); uint64_t dictSdsCaseHash(const void *key); int dictSdsKeyCompare(dict *d, const void *key1, const void *key2); int dictSdsKeyCaseCompare(dict *d, const void *key1, const void *key2); void dictSdsDestructor(dict *d, void *val); void *dictSdsDup(dict *d, const void *key); /* Git SHA1 */ char *redisGitSHA1(void); char *redisGitDirty(void); uint64_t redisBuildId(void); char *redisBuildIdString(void); /* Commands prototypes */ void authCommand(client *c); void pingCommand(client *c); void echoCommand(client *c); void commandCommand(client *c); void commandCountCommand(client *c); void commandListCommand(client *c); void commandInfoCommand(client *c); void commandGetKeysCommand(client *c); void commandHelpCommand(client *c); void commandDocsCommand(client *c); void setCommand(client *c); void setnxCommand(client *c); void setexCommand(client *c); void psetexCommand(client *c); void getCommand(client *c); void getexCommand(client *c); void getdelCommand(client *c); void delCommand(client *c); void unlinkCommand(client *c); void existsCommand(client *c); void setbitCommand(client *c); void getbitCommand(client *c); void bitfieldCommand(client *c); void bitfieldroCommand(client *c); void setrangeCommand(client *c); void getrangeCommand(client *c); void incrCommand(client *c); void decrCommand(client *c); void incrbyCommand(client *c); void decrbyCommand(client *c); void incrbyfloatCommand(client *c); void selectCommand(client *c); void swapdbCommand(client *c); void randomkeyCommand(client *c); void keysCommand(client *c); void scanCommand(client *c); void dbsizeCommand(client *c); void lastsaveCommand(client *c); void saveCommand(client *c); void bgsaveCommand(client *c); void bgrewriteaofCommand(client *c); void shutdownCommand(client *c); void slowlogCommand(client *c); void moveCommand(client *c); void copyCommand(client *c); void renameCommand(client *c); void renamenxCommand(client *c); void lpushCommand(client *c); void rpushCommand(client *c); void lpushxCommand(client *c); void rpushxCommand(client *c); void linsertCommand(client *c); void lpopCommand(client *c); void rpopCommand(client *c); void lmpopCommand(client *c); void llenCommand(client *c); void lindexCommand(client *c); void lrangeCommand(client *c); void ltrimCommand(client *c); void typeCommand(client *c); void lsetCommand(client *c); void saddCommand(client *c); void sremCommand(client *c); void smoveCommand(client *c); void sismemberCommand(client *c); void smismemberCommand(client *c); void scardCommand(client *c); void spopCommand(client *c); void srandmemberCommand(client *c); void sinterCommand(client *c); void sinterCardCommand(client *c); void sinterstoreCommand(client *c); void sunionCommand(client *c); void sunionstoreCommand(client *c); void sdiffCommand(client *c); void sdiffstoreCommand(client *c); void sscanCommand(client *c); void syncCommand(client *c); void flushdbCommand(client *c); void flushallCommand(client *c); void sortCommand(client *c); void sortroCommand(client *c); void lremCommand(client *c); void lposCommand(client *c); void rpoplpushCommand(client *c); void lmoveCommand(client *c); void infoCommand(client *c); void mgetCommand(client *c); void monitorCommand(client *c); void expireCommand(client *c); void expireatCommand(client *c); void pexpireCommand(client *c); void pexpireatCommand(client *c); void getsetCommand(client *c); void ttlCommand(client *c); void touchCommand(client *c); void pttlCommand(client *c); void expiretimeCommand(client *c); void pexpiretimeCommand(client *c); void persistCommand(client *c); void replicaofCommand(client *c); void roleCommand(client *c); void debugCommand(client *c); void msetCommand(client *c); void msetnxCommand(client *c); void zaddCommand(client *c); void zincrbyCommand(client *c); void zrangeCommand(client *c); void zrangebyscoreCommand(client *c); void zrevrangebyscoreCommand(client *c); void zrangebylexCommand(client *c); void zrevrangebylexCommand(client *c); void zcountCommand(client *c); void zlexcountCommand(client *c); void zrevrangeCommand(client *c); void zcardCommand(client *c); void zremCommand(client *c); void zscoreCommand(client *c); void zmscoreCommand(client *c); void zremrangebyscoreCommand(client *c); void zremrangebylexCommand(client *c); void zpopminCommand(client *c); void zpopmaxCommand(client *c); void zmpopCommand(client *c); void bzpopminCommand(client *c); void bzpopmaxCommand(client *c); void bzmpopCommand(client *c); void zrandmemberCommand(client *c); void multiCommand(client *c); void execCommand(client *c); void discardCommand(client *c); void blpopCommand(client *c); void brpopCommand(client *c); void blmpopCommand(client *c); void brpoplpushCommand(client *c); void blmoveCommand(client *c); void appendCommand(client *c); void strlenCommand(client *c); void zrankCommand(client *c); void zrevrankCommand(client *c); void hsetCommand(client *c); void hsetnxCommand(client *c); void hgetCommand(client *c); void hmgetCommand(client *c); void hdelCommand(client *c); void hlenCommand(client *c); void hstrlenCommand(client *c); void zremrangebyrankCommand(client *c); void zunionstoreCommand(client *c); void zinterstoreCommand(client *c); void zdiffstoreCommand(client *c); void zunionCommand(client *c); void zinterCommand(client *c); void zinterCardCommand(client *c); void zrangestoreCommand(client *c); void zdiffCommand(client *c); void zscanCommand(client *c); void hkeysCommand(client *c); void hvalsCommand(client *c); void hgetallCommand(client *c); void hexistsCommand(client *c); void hscanCommand(client *c); void hrandfieldCommand(client *c); void configSetCommand(client *c); void configGetCommand(client *c); void configResetStatCommand(client *c); void configRewriteCommand(client *c); void configHelpCommand(client *c); void hincrbyCommand(client *c); void hincrbyfloatCommand(client *c); void subscribeCommand(client *c); void unsubscribeCommand(client *c); void psubscribeCommand(client *c); void punsubscribeCommand(client *c); void publishCommand(client *c); void pubsubCommand(client *c); void spublishCommand(client *c); void ssubscribeCommand(client *c); void sunsubscribeCommand(client *c); void watchCommand(client *c); void unwatchCommand(client *c); void clusterCommand(client *c); void restoreCommand(client *c); void migrateCommand(client *c); void askingCommand(client *c); void readonlyCommand(client *c); void readwriteCommand(client *c); int verifyDumpPayload(unsigned char *p, size_t len, uint16_t *rdbver_ptr); void dumpCommand(client *c); void objectCommand(client *c); void memoryCommand(client *c); void clientCommand(client *c); void helloCommand(client *c); void evalCommand(client *c); void evalRoCommand(client *c); void evalShaCommand(client *c); void evalShaRoCommand(client *c); void scriptCommand(client *c); void fcallCommand(client *c); void fcallroCommand(client *c); void functionLoadCommand(client *c); void functionDeleteCommand(client *c); void functionKillCommand(client *c); void functionStatsCommand(client *c); void functionListCommand(client *c); void functionHelpCommand(client *c); void functionFlushCommand(client *c); void functionRestoreCommand(client *c); void functionDumpCommand(client *c); void timeCommand(client *c); void bitopCommand(client *c); void bitcountCommand(client *c); void bitposCommand(client *c); void replconfCommand(client *c); void waitCommand(client *c); void georadiusbymemberCommand(client *c); void georadiusbymemberroCommand(client *c); void georadiusCommand(client *c); void georadiusroCommand(client *c); void geoaddCommand(client *c); void geohashCommand(client *c); void geoposCommand(client *c); void geodistCommand(client *c); void geosearchCommand(client *c); void geosearchstoreCommand(client *c); void pfselftestCommand(client *c); void pfaddCommand(client *c); void pfcountCommand(client *c); void pfmergeCommand(client *c); void pfdebugCommand(client *c); void latencyCommand(client *c); void moduleCommand(client *c); void securityWarningCommand(client *c); void xaddCommand(client *c); void xrangeCommand(client *c); void xrevrangeCommand(client *c); void xlenCommand(client *c); void xreadCommand(client *c); void xgroupCommand(client *c); void xsetidCommand(client *c); void xackCommand(client *c); void xpendingCommand(client *c); void xclaimCommand(client *c); void xautoclaimCommand(client *c); void xinfoCommand(client *c); void xdelCommand(client *c); void xtrimCommand(client *c); void lolwutCommand(client *c); void aclCommand(client *c); void lcsCommand(client *c); void quitCommand(client *c); void resetCommand(client *c); void failoverCommand(client *c); #if defined(__GNUC__) void *calloc(size_t count, size_t size) __attribute__ ((deprecated)); void free(void *ptr) __attribute__ ((deprecated)); void *malloc(size_t size) __attribute__ ((deprecated)); void *realloc(void *ptr, size_t size) __attribute__ ((deprecated)); #endif /* Debugging stuff */ void _serverAssertWithInfo(const client *c, const robj *o, const char *estr, const char *file, int line); void _serverAssert(const char *estr, const char *file, int line); #ifdef __GNUC__ void _serverPanic(const char *file, int line, const char *msg, ...) __attribute__ ((format (printf, 3, 4))); #else void _serverPanic(const char *file, int line, const char *msg, ...); #endif void serverLogObjectDebugInfo(const robj *o); void sigsegvHandler(int sig, siginfo_t *info, void *secret); sds getFullCommandName(struct redisCommand *cmd); const char *getSafeInfoString(const char *s, size_t len, char **tmp); sds genRedisInfoString(const char *section); sds genModulesInfoString(sds info); void applyWatchdogPeriod(); void watchdogScheduleSignal(int period); void serverLogHexDump(int level, char *descr, void *value, size_t len); int memtest_preserving_test(unsigned long *m, size_t bytes, int passes); void mixDigest(unsigned char *digest, const void *ptr, size_t len); void xorDigest(unsigned char *digest, const void *ptr, size_t len); int populateSingleCommand(struct redisCommand *c, char *strflags); void commandAddSubcommand(struct redisCommand *parent, struct redisCommand *subcommand); void populateCommandMovableKeys(struct redisCommand *cmd); void debugDelay(int usec); void killIOThreads(void); void killThreads(void); void makeThreadKillable(void); void swapMainDbWithTempDb(redisDb *tempDb); /* Use macro for checking log level to avoid evaluating arguments in cases log * should be ignored due to low level. */ #define serverLog(level, ...) do {\ if (((level)&0xff) < server.verbosity) break;\ _serverLog(level, __VA_ARGS__);\ } while(0) /* TLS stuff */ void tlsInit(void); void tlsCleanup(void); int tlsConfigure(redisTLSContextConfig *ctx_config); int isTlsConfigured(void); #define redisDebug(fmt, ...) \ printf("DEBUG %s:%d > " fmt "\n", __FILE__, __LINE__, __VA_ARGS__) #define redisDebugMark() \ printf("-- MARK %s:%d --\n", __FILE__, __LINE__) int iAmMaster(void); #define STRINGIFY_(x) #x #define STRINGIFY(x) STRINGIFY_(x) #endif