package redis import ( "context" "errors" "fmt" "net" "sync" "sync/atomic" "time" "github.com/redis/go-redis/v9/internal" "github.com/redis/go-redis/v9/internal/hscan" "github.com/redis/go-redis/v9/internal/pool" "github.com/redis/go-redis/v9/internal/proto" ) // Scanner internal/hscan.Scanner exposed interface. type Scanner = hscan.Scanner // Nil reply returned by Redis when key does not exist. const Nil = proto.Nil // SetLogger set custom log func SetLogger(logger internal.Logging) { internal.Logger = logger } //------------------------------------------------------------------------------ type Hook interface { DialHook(next DialHook) DialHook ProcessHook(next ProcessHook) ProcessHook ProcessPipelineHook(next ProcessPipelineHook) ProcessPipelineHook } type ( DialHook func(ctx context.Context, network, addr string) (net.Conn, error) ProcessHook func(ctx context.Context, cmd Cmder) error ProcessPipelineHook func(ctx context.Context, cmds []Cmder) error ) type hooksMixin struct { hooksMu *sync.Mutex slice []Hook initial hooks current hooks } func (hs *hooksMixin) initHooks(hooks hooks) { hs.hooksMu = new(sync.Mutex) hs.initial = hooks hs.chain() } type hooks struct { dial DialHook process ProcessHook pipeline ProcessPipelineHook txPipeline ProcessPipelineHook } func (h *hooks) setDefaults() { if h.dial == nil { h.dial = func(ctx context.Context, network, addr string) (net.Conn, error) { return nil, nil } } if h.process == nil { h.process = func(ctx context.Context, cmd Cmder) error { return nil } } if h.pipeline == nil { h.pipeline = func(ctx context.Context, cmds []Cmder) error { return nil } } if h.txPipeline == nil { h.txPipeline = func(ctx context.Context, cmds []Cmder) error { return nil } } } // AddHook is to add a hook to the queue. // Hook is a function executed during network connection, command execution, and pipeline, // it is a first-in-first-out stack queue (FIFO). // You need to execute the next hook in each hook, unless you want to terminate the execution of the command. // For example, you added hook-1, hook-2: // // client.AddHook(hook-1, hook-2) // // hook-1: // // func (Hook1) ProcessHook(next redis.ProcessHook) redis.ProcessHook { // return func(ctx context.Context, cmd Cmder) error { // print("hook-1 start") // next(ctx, cmd) // print("hook-1 end") // return nil // } // } // // hook-2: // // func (Hook2) ProcessHook(next redis.ProcessHook) redis.ProcessHook { // return func(ctx context.Context, cmd redis.Cmder) error { // print("hook-2 start") // next(ctx, cmd) // print("hook-2 end") // return nil // } // } // // The execution sequence is: // // hook-1 start -> hook-2 start -> exec redis cmd -> hook-2 end -> hook-1 end // // Please note: "next(ctx, cmd)" is very important, it will call the next hook, // if "next(ctx, cmd)" is not executed, the redis command will not be executed. func (hs *hooksMixin) AddHook(hook Hook) { hs.slice = append(hs.slice, hook) hs.chain() } func (hs *hooksMixin) chain() { hs.initial.setDefaults() hs.hooksMu.Lock() defer hs.hooksMu.Unlock() hs.current.dial = hs.initial.dial hs.current.process = hs.initial.process hs.current.pipeline = hs.initial.pipeline hs.current.txPipeline = hs.initial.txPipeline for i := len(hs.slice) - 1; i >= 0; i-- { if wrapped := hs.slice[i].DialHook(hs.current.dial); wrapped != nil { hs.current.dial = wrapped } if wrapped := hs.slice[i].ProcessHook(hs.current.process); wrapped != nil { hs.current.process = wrapped } if wrapped := hs.slice[i].ProcessPipelineHook(hs.current.pipeline); wrapped != nil { hs.current.pipeline = wrapped } if wrapped := hs.slice[i].ProcessPipelineHook(hs.current.txPipeline); wrapped != nil { hs.current.txPipeline = wrapped } } } func (hs *hooksMixin) clone() hooksMixin { hs.hooksMu.Lock() defer hs.hooksMu.Unlock() clone := *hs l := len(clone.slice) clone.slice = clone.slice[:l:l] clone.hooksMu = new(sync.Mutex) return clone } func (hs *hooksMixin) withProcessHook(ctx context.Context, cmd Cmder, hook ProcessHook) error { for i := len(hs.slice) - 1; i >= 0; i-- { if wrapped := hs.slice[i].ProcessHook(hook); wrapped != nil { hook = wrapped } } return hook(ctx, cmd) } func (hs *hooksMixin) withProcessPipelineHook( ctx context.Context, cmds []Cmder, hook ProcessPipelineHook, ) error { for i := len(hs.slice) - 1; i >= 0; i-- { if wrapped := hs.slice[i].ProcessPipelineHook(hook); wrapped != nil { hook = wrapped } } return hook(ctx, cmds) } func (hs *hooksMixin) dialHook(ctx context.Context, network, addr string) (net.Conn, error) { hs.hooksMu.Lock() defer hs.hooksMu.Unlock() return hs.current.dial(ctx, network, addr) } func (hs *hooksMixin) processHook(ctx context.Context, cmd Cmder) error { return hs.current.process(ctx, cmd) } func (hs *hooksMixin) processPipelineHook(ctx context.Context, cmds []Cmder) error { return hs.current.pipeline(ctx, cmds) } func (hs *hooksMixin) processTxPipelineHook(ctx context.Context, cmds []Cmder) error { return hs.current.txPipeline(ctx, cmds) } //------------------------------------------------------------------------------ type baseClient struct { opt *Options connPool pool.Pooler onClose func() error // hook called when client is closed } func (c *baseClient) clone() *baseClient { clone := *c return &clone } func (c *baseClient) withTimeout(timeout time.Duration) *baseClient { opt := c.opt.clone() opt.ReadTimeout = timeout opt.WriteTimeout = timeout clone := c.clone() clone.opt = opt return clone } func (c *baseClient) String() string { return fmt.Sprintf("Redis<%s db:%d>", c.getAddr(), c.opt.DB) } func (c *baseClient) newConn(ctx context.Context) (*pool.Conn, error) { cn, err := c.connPool.NewConn(ctx) if err != nil { return nil, err } err = c.initConn(ctx, cn) if err != nil { _ = c.connPool.CloseConn(cn) return nil, err } return cn, nil } func (c *baseClient) getConn(ctx context.Context) (*pool.Conn, error) { if c.opt.Limiter != nil { err := c.opt.Limiter.Allow() if err != nil { return nil, err } } cn, err := c._getConn(ctx) if err != nil { if c.opt.Limiter != nil { c.opt.Limiter.ReportResult(err) } return nil, err } return cn, nil } func (c *baseClient) _getConn(ctx context.Context) (*pool.Conn, error) { cn, err := c.connPool.Get(ctx) if err != nil { return nil, err } if cn.Inited { return cn, nil } if err := c.initConn(ctx, cn); err != nil { c.connPool.Remove(ctx, cn, err) if err := errors.Unwrap(err); err != nil { return nil, err } return nil, err } return cn, nil } func (c *baseClient) initConn(ctx context.Context, cn *pool.Conn) error { if cn.Inited { return nil } cn.Inited = true username, password := c.opt.Username, c.opt.Password if c.opt.CredentialsProvider != nil { username, password = c.opt.CredentialsProvider() } connPool := pool.NewSingleConnPool(c.connPool, cn) conn := newConn(c.opt, connPool) var auth bool protocol := c.opt.Protocol // By default, use RESP3 in current version. if protocol < 2 { protocol = 3 } // for redis-server versions that do not support the HELLO command, // RESP2 will continue to be used. if err := conn.Hello(ctx, protocol, username, password, "").Err(); err == nil { auth = true } else if !isRedisError(err) { // When the server responds with the RESP protocol and the result is not a normal // execution result of the HELLO command, we consider it to be an indication that // the server does not support the HELLO command. // The server may be a redis-server that does not support the HELLO command, // or it could be DragonflyDB or a third-party redis-proxy. They all respond // with different error string results for unsupported commands, making it // difficult to rely on error strings to determine all results. return err } _, err := conn.Pipelined(ctx, func(pipe Pipeliner) error { if !auth && password != "" { if username != "" { pipe.AuthACL(ctx, username, password) } else { pipe.Auth(ctx, password) } } if c.opt.DB > 0 { pipe.Select(ctx, c.opt.DB) } if c.opt.readOnly { pipe.ReadOnly(ctx) } if c.opt.ClientName != "" { pipe.ClientSetName(ctx, c.opt.ClientName) } if !c.opt.DisableIndentity { libName := "" libVer := Version() if c.opt.IdentitySuffix != "" { libName = c.opt.IdentitySuffix } pipe.ClientSetInfo(ctx, WithLibraryName(libName)) pipe.ClientSetInfo(ctx, WithLibraryVersion(libVer)) } return nil }) if err != nil { return err } if c.opt.OnConnect != nil { return c.opt.OnConnect(ctx, conn) } return nil } func (c *baseClient) releaseConn(ctx context.Context, cn *pool.Conn, err error) { if c.opt.Limiter != nil { c.opt.Limiter.ReportResult(err) } if isBadConn(err, false, c.opt.Addr) { c.connPool.Remove(ctx, cn, err) } else { c.connPool.Put(ctx, cn) } } func (c *baseClient) withConn( ctx context.Context, fn func(context.Context, *pool.Conn) error, ) error { cn, err := c.getConn(ctx) if err != nil { return err } var fnErr error defer func() { c.releaseConn(ctx, cn, fnErr) }() fnErr = fn(ctx, cn) return fnErr } func (c *baseClient) dial(ctx context.Context, network, addr string) (net.Conn, error) { return c.opt.Dialer(ctx, network, addr) } func (c *baseClient) process(ctx context.Context, cmd Cmder) error { var lastErr error for attempt := 0; attempt <= c.opt.MaxRetries; attempt++ { attempt := attempt retry, err := c._process(ctx, cmd, attempt) if err == nil || !retry { return err } lastErr = err } return lastErr } func (c *baseClient) _process(ctx context.Context, cmd Cmder, attempt int) (bool, error) { if attempt > 0 { if err := internal.Sleep(ctx, c.retryBackoff(attempt)); err != nil { return false, err } } retryTimeout := uint32(0) if err := c.withConn(ctx, func(ctx context.Context, cn *pool.Conn) error { if err := cn.WithWriter(c.context(ctx), c.opt.WriteTimeout, func(wr *proto.Writer) error { return writeCmd(wr, cmd) }); err != nil { atomic.StoreUint32(&retryTimeout, 1) return err } if err := cn.WithReader(c.context(ctx), c.cmdTimeout(cmd), cmd.readReply); err != nil { if cmd.readTimeout() == nil { atomic.StoreUint32(&retryTimeout, 1) } else { atomic.StoreUint32(&retryTimeout, 0) } return err } return nil }); err != nil { retry := shouldRetry(err, atomic.LoadUint32(&retryTimeout) == 1) return retry, err } return false, nil } func (c *baseClient) retryBackoff(attempt int) time.Duration { return internal.RetryBackoff(attempt, c.opt.MinRetryBackoff, c.opt.MaxRetryBackoff) } func (c *baseClient) cmdTimeout(cmd Cmder) time.Duration { if timeout := cmd.readTimeout(); timeout != nil { t := *timeout if t == 0 { return 0 } return t + 10*time.Second } return c.opt.ReadTimeout } // Close closes the client, releasing any open resources. // // It is rare to Close a Client, as the Client is meant to be // long-lived and shared between many goroutines. func (c *baseClient) Close() error { var firstErr error if c.onClose != nil { if err := c.onClose(); err != nil { firstErr = err } } if err := c.connPool.Close(); err != nil && firstErr == nil { firstErr = err } return firstErr } func (c *baseClient) getAddr() string { return c.opt.Addr } func (c *baseClient) processPipeline(ctx context.Context, cmds []Cmder) error { if err := c.generalProcessPipeline(ctx, cmds, c.pipelineProcessCmds); err != nil { return err } return cmdsFirstErr(cmds) } func (c *baseClient) processTxPipeline(ctx context.Context, cmds []Cmder) error { if err := c.generalProcessPipeline(ctx, cmds, c.txPipelineProcessCmds); err != nil { return err } return cmdsFirstErr(cmds) } type pipelineProcessor func(context.Context, *pool.Conn, []Cmder) (bool, error) func (c *baseClient) generalProcessPipeline( ctx context.Context, cmds []Cmder, p pipelineProcessor, ) error { var lastErr error for attempt := 0; attempt <= c.opt.MaxRetries; attempt++ { if attempt > 0 { if err := internal.Sleep(ctx, c.retryBackoff(attempt)); err != nil { setCmdsErr(cmds, err) return err } } // Enable retries by default to retry dial errors returned by withConn. canRetry := true lastErr = c.withConn(ctx, func(ctx context.Context, cn *pool.Conn) error { var err error canRetry, err = p(ctx, cn, cmds) return err }) if lastErr == nil || !canRetry || !shouldRetry(lastErr, true) { return lastErr } } return lastErr } func (c *baseClient) pipelineProcessCmds( ctx context.Context, cn *pool.Conn, cmds []Cmder, ) (bool, error) { if err := cn.WithWriter(c.context(ctx), c.opt.WriteTimeout, func(wr *proto.Writer) error { return writeCmds(wr, cmds) }); err != nil { setCmdsErr(cmds, err) return true, err } if err := cn.WithReader(c.context(ctx), c.opt.ReadTimeout, func(rd *proto.Reader) error { return pipelineReadCmds(rd, cmds) }); err != nil { return true, err } return false, nil } func pipelineReadCmds(rd *proto.Reader, cmds []Cmder) error { for i, cmd := range cmds { err := cmd.readReply(rd) cmd.SetErr(err) if err != nil && !isRedisError(err) { setCmdsErr(cmds[i+1:], err) return err } } // Retry errors like "LOADING redis is loading the dataset in memory". return cmds[0].Err() } func (c *baseClient) txPipelineProcessCmds( ctx context.Context, cn *pool.Conn, cmds []Cmder, ) (bool, error) { if err := cn.WithWriter(c.context(ctx), c.opt.WriteTimeout, func(wr *proto.Writer) error { return writeCmds(wr, cmds) }); err != nil { setCmdsErr(cmds, err) return true, err } if err := cn.WithReader(c.context(ctx), c.opt.ReadTimeout, func(rd *proto.Reader) error { statusCmd := cmds[0].(*StatusCmd) // Trim multi and exec. trimmedCmds := cmds[1 : len(cmds)-1] if err := txPipelineReadQueued(rd, statusCmd, trimmedCmds); err != nil { setCmdsErr(cmds, err) return err } return pipelineReadCmds(rd, trimmedCmds) }); err != nil { return false, err } return false, nil } func txPipelineReadQueued(rd *proto.Reader, statusCmd *StatusCmd, cmds []Cmder) error { // Parse +OK. if err := statusCmd.readReply(rd); err != nil { return err } // Parse +QUEUED. for range cmds { if err := statusCmd.readReply(rd); err != nil && !isRedisError(err) { return err } } // Parse number of replies. line, err := rd.ReadLine() if err != nil { if err == Nil { err = TxFailedErr } return err } if line[0] != proto.RespArray { return fmt.Errorf("redis: expected '*', but got line %q", line) } return nil } func (c *baseClient) context(ctx context.Context) context.Context { if c.opt.ContextTimeoutEnabled { return ctx } return context.Background() } //------------------------------------------------------------------------------ // Client is a Redis client representing a pool of zero or more underlying connections. // It's safe for concurrent use by multiple goroutines. // // Client creates and frees connections automatically; it also maintains a free pool // of idle connections. You can control the pool size with Config.PoolSize option. type Client struct { *baseClient cmdable hooksMixin } // NewClient returns a client to the Redis Server specified by Options. func NewClient(opt *Options) *Client { opt.init() c := Client{ baseClient: &baseClient{ opt: opt, }, } c.init() c.connPool = newConnPool(opt, c.dialHook) return &c } func (c *Client) init() { c.cmdable = c.Process c.initHooks(hooks{ dial: c.baseClient.dial, process: c.baseClient.process, pipeline: c.baseClient.processPipeline, txPipeline: c.baseClient.processTxPipeline, }) } func (c *Client) WithTimeout(timeout time.Duration) *Client { clone := *c clone.baseClient = c.baseClient.withTimeout(timeout) clone.init() return &clone } func (c *Client) Conn() *Conn { return newConn(c.opt, pool.NewStickyConnPool(c.connPool)) } // Do create a Cmd from the args and processes the cmd. func (c *Client) Do(ctx context.Context, args ...interface{}) *Cmd { cmd := NewCmd(ctx, args...) _ = c.Process(ctx, cmd) return cmd } func (c *Client) Process(ctx context.Context, cmd Cmder) error { err := c.processHook(ctx, cmd) cmd.SetErr(err) return err } // Options returns read-only Options that were used to create the client. func (c *Client) Options() *Options { return c.opt } type PoolStats pool.Stats // PoolStats returns connection pool stats. func (c *Client) PoolStats() *PoolStats { stats := c.connPool.Stats() return (*PoolStats)(stats) } func (c *Client) Pipelined(ctx context.Context, fn func(Pipeliner) error) ([]Cmder, error) { return c.Pipeline().Pipelined(ctx, fn) } func (c *Client) Pipeline() Pipeliner { pipe := Pipeline{ exec: pipelineExecer(c.processPipelineHook), } pipe.init() return &pipe } func (c *Client) TxPipelined(ctx context.Context, fn func(Pipeliner) error) ([]Cmder, error) { return c.TxPipeline().Pipelined(ctx, fn) } // TxPipeline acts like Pipeline, but wraps queued commands with MULTI/EXEC. func (c *Client) TxPipeline() Pipeliner { pipe := Pipeline{ exec: func(ctx context.Context, cmds []Cmder) error { cmds = wrapMultiExec(ctx, cmds) return c.processTxPipelineHook(ctx, cmds) }, } pipe.init() return &pipe } func (c *Client) pubSub() *PubSub { pubsub := &PubSub{ opt: c.opt, newConn: func(ctx context.Context, channels []string) (*pool.Conn, error) { return c.newConn(ctx) }, closeConn: c.connPool.CloseConn, } pubsub.init() return pubsub } // Subscribe subscribes the client to the specified channels. // Channels can be omitted to create empty subscription. // Note that this method does not wait on a response from Redis, so the // subscription may not be active immediately. To force the connection to wait, // you may call the Receive() method on the returned *PubSub like so: // // sub := client.Subscribe(queryResp) // iface, err := sub.Receive() // if err != nil { // // handle error // } // // // Should be *Subscription, but others are possible if other actions have been // // taken on sub since it was created. // switch iface.(type) { // case *Subscription: // // subscribe succeeded // case *Message: // // received first message // case *Pong: // // pong received // default: // // handle error // } // // ch := sub.Channel() func (c *Client) Subscribe(ctx context.Context, channels ...string) *PubSub { pubsub := c.pubSub() if len(channels) > 0 { _ = pubsub.Subscribe(ctx, channels...) } return pubsub } // PSubscribe subscribes the client to the given patterns. // Patterns can be omitted to create empty subscription. func (c *Client) PSubscribe(ctx context.Context, channels ...string) *PubSub { pubsub := c.pubSub() if len(channels) > 0 { _ = pubsub.PSubscribe(ctx, channels...) } return pubsub } // SSubscribe Subscribes the client to the specified shard channels. // Channels can be omitted to create empty subscription. func (c *Client) SSubscribe(ctx context.Context, channels ...string) *PubSub { pubsub := c.pubSub() if len(channels) > 0 { _ = pubsub.SSubscribe(ctx, channels...) } return pubsub } //------------------------------------------------------------------------------ // Conn represents a single Redis connection rather than a pool of connections. // Prefer running commands from Client unless there is a specific need // for a continuous single Redis connection. type Conn struct { baseClient cmdable statefulCmdable hooksMixin } func newConn(opt *Options, connPool pool.Pooler) *Conn { c := Conn{ baseClient: baseClient{ opt: opt, connPool: connPool, }, } c.cmdable = c.Process c.statefulCmdable = c.Process c.initHooks(hooks{ dial: c.baseClient.dial, process: c.baseClient.process, pipeline: c.baseClient.processPipeline, txPipeline: c.baseClient.processTxPipeline, }) return &c } func (c *Conn) Process(ctx context.Context, cmd Cmder) error { err := c.processHook(ctx, cmd) cmd.SetErr(err) return err } func (c *Conn) Pipelined(ctx context.Context, fn func(Pipeliner) error) ([]Cmder, error) { return c.Pipeline().Pipelined(ctx, fn) } func (c *Conn) Pipeline() Pipeliner { pipe := Pipeline{ exec: c.processPipelineHook, } pipe.init() return &pipe } func (c *Conn) TxPipelined(ctx context.Context, fn func(Pipeliner) error) ([]Cmder, error) { return c.TxPipeline().Pipelined(ctx, fn) } // TxPipeline acts like Pipeline, but wraps queued commands with MULTI/EXEC. func (c *Conn) TxPipeline() Pipeliner { pipe := Pipeline{ exec: func(ctx context.Context, cmds []Cmder) error { cmds = wrapMultiExec(ctx, cmds) return c.processTxPipelineHook(ctx, cmds) }, } pipe.init() return &pipe }