/* * * Copyright 2014, Google Inc. * 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 Google Inc. 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. * */ package grpc import ( "errors" "fmt" "net" "strings" "sync" "time" "golang.org/x/net/context" "golang.org/x/net/trace" "google.golang.org/grpc/credentials" "google.golang.org/grpc/grpclog" "google.golang.org/grpc/transport" ) var ( // ErrClientConnClosing indicates that the operation is illegal because // the ClientConn is closing. ErrClientConnClosing = errors.New("grpc: the client connection is closing") // ErrClientConnTimeout indicates that the ClientConn cannot establish the // underlying connections within the specified timeout. ErrClientConnTimeout = errors.New("grpc: timed out when dialing") // errNoTransportSecurity indicates that there is no transport security // being set for ClientConn. Users should either set one or explicitly // call WithInsecure DialOption to disable security. errNoTransportSecurity = errors.New("grpc: no transport security set (use grpc.WithInsecure() explicitly or set credentials)") // errTransportCredentialsMissing indicates that users want to transmit security // information (e.g., oauth2 token) which requires secure connection on an insecure // connection. errTransportCredentialsMissing = errors.New("grpc: the credentials require transport level security (use grpc.WithTransportCredentials() to set)") // errCredentialsConflict indicates that grpc.WithTransportCredentials() // and grpc.WithInsecure() are both called for a connection. errCredentialsConflict = errors.New("grpc: transport credentials are set for an insecure connection (grpc.WithTransportCredentials() and grpc.WithInsecure() are both called)") // errNetworkIO indicates that the connection is down due to some network I/O error. errNetworkIO = errors.New("grpc: failed with network I/O error") // errConnDrain indicates that the connection starts to be drained and does not accept any new RPCs. errConnDrain = errors.New("grpc: the connection is drained") // errConnClosing indicates that the connection is closing. errConnClosing = errors.New("grpc: the connection is closing") // errConnUnavailable indicates that the connection is unavailable. errConnUnavailable = errors.New("grpc: the connection is unavailable") errNoAddr = errors.New("grpc: there is no address available to dial") // minimum time to give a connection to complete minConnectTimeout = 20 * time.Second ) // dialOptions configure a Dial call. dialOptions are set by the DialOption // values passed to Dial. type dialOptions struct { unaryInt UnaryClientInterceptor streamInt StreamClientInterceptor codec Codec cp Compressor dc Decompressor bs backoffStrategy balancer Balancer block bool insecure bool timeout time.Duration copts transport.ConnectOptions } // DialOption configures how we set up the connection. type DialOption func(*dialOptions) // WithCodec returns a DialOption which sets a codec for message marshaling and unmarshaling. func WithCodec(c Codec) DialOption { return func(o *dialOptions) { o.codec = c } } // WithCompressor returns a DialOption which sets a CompressorGenerator for generating message // compressor. func WithCompressor(cp Compressor) DialOption { return func(o *dialOptions) { o.cp = cp } } // WithDecompressor returns a DialOption which sets a DecompressorGenerator for generating // message decompressor. func WithDecompressor(dc Decompressor) DialOption { return func(o *dialOptions) { o.dc = dc } } // WithBalancer returns a DialOption which sets a load balancer. func WithBalancer(b Balancer) DialOption { return func(o *dialOptions) { o.balancer = b } } // WithBackoffMaxDelay configures the dialer to use the provided maximum delay // when backing off after failed connection attempts. func WithBackoffMaxDelay(md time.Duration) DialOption { return WithBackoffConfig(BackoffConfig{MaxDelay: md}) } // WithBackoffConfig configures the dialer to use the provided backoff // parameters after connection failures. // // Use WithBackoffMaxDelay until more parameters on BackoffConfig are opened up // for use. func WithBackoffConfig(b BackoffConfig) DialOption { // Set defaults to ensure that provided BackoffConfig is valid and // unexported fields get default values. setDefaults(&b) return withBackoff(b) } // withBackoff sets the backoff strategy used for retries after a // failed connection attempt. // // This can be exported if arbitrary backoff strategies are allowed by gRPC. func withBackoff(bs backoffStrategy) DialOption { return func(o *dialOptions) { o.bs = bs } } // WithBlock returns a DialOption which makes caller of Dial blocks until the underlying // connection is up. Without this, Dial returns immediately and connecting the server // happens in background. func WithBlock() DialOption { return func(o *dialOptions) { o.block = true } } // WithInsecure returns a DialOption which disables transport security for this ClientConn. // Note that transport security is required unless WithInsecure is set. func WithInsecure() DialOption { return func(o *dialOptions) { o.insecure = true } } // WithTransportCredentials returns a DialOption which configures a // connection level security credentials (e.g., TLS/SSL). func WithTransportCredentials(creds credentials.TransportCredentials) DialOption { return func(o *dialOptions) { o.copts.TransportCredentials = creds } } // WithPerRPCCredentials returns a DialOption which sets // credentials which will place auth state on each outbound RPC. func WithPerRPCCredentials(creds credentials.PerRPCCredentials) DialOption { return func(o *dialOptions) { o.copts.PerRPCCredentials = append(o.copts.PerRPCCredentials, creds) } } // WithTimeout returns a DialOption that configures a timeout for dialing a ClientConn // initially. This is valid if and only if WithBlock() is present. func WithTimeout(d time.Duration) DialOption { return func(o *dialOptions) { o.timeout = d } } // WithDialer returns a DialOption that specifies a function to use for dialing network addresses. func WithDialer(f func(string, time.Duration) (net.Conn, error)) DialOption { return func(o *dialOptions) { o.copts.Dialer = func(ctx context.Context, addr string) (net.Conn, error) { if deadline, ok := ctx.Deadline(); ok { return f(addr, deadline.Sub(time.Now())) } return f(addr, 0) } } } // WithUserAgent returns a DialOption that specifies a user agent string for all the RPCs. func WithUserAgent(s string) DialOption { return func(o *dialOptions) { o.copts.UserAgent = s } } // WithUnaryInterceptor returns a DialOption that specifies the interceptor for unary RPCs. func WithUnaryInterceptor(f UnaryClientInterceptor) DialOption { return func(o *dialOptions) { o.unaryInt = f } } // WithStreamInterceptor returns a DialOption that specifies the interceptor for streaming RPCs. func WithStreamInterceptor(f StreamClientInterceptor) DialOption { return func(o *dialOptions) { o.streamInt = f } } // Dial creates a client connection to the given target. func Dial(target string, opts ...DialOption) (*ClientConn, error) { return DialContext(context.Background(), target, opts...) } // DialContext creates a client connection to the given target. ctx can be used to // cancel or expire the pending connecting. Once this function returns, the // cancellation and expiration of ctx will be noop. Users should call ClientConn.Close // to terminate all the pending operations after this function returns. // This is the EXPERIMENTAL API. func DialContext(ctx context.Context, target string, opts ...DialOption) (conn *ClientConn, err error) { cc := &ClientConn{ target: target, conns: make(map[Address]*addrConn), } cc.ctx, cc.cancel = context.WithCancel(context.Background()) defer func() { select { case <-ctx.Done(): conn, err = nil, ctx.Err() default: } if err != nil { cc.Close() } }() for _, opt := range opts { opt(&cc.dopts) } // Set defaults. if cc.dopts.codec == nil { cc.dopts.codec = protoCodec{} } if cc.dopts.bs == nil { cc.dopts.bs = DefaultBackoffConfig } creds := cc.dopts.copts.TransportCredentials if creds != nil && creds.Info().ServerName != "" { cc.authority = creds.Info().ServerName } else { colonPos := strings.LastIndex(target, ":") if colonPos == -1 { colonPos = len(target) } cc.authority = target[:colonPos] } var ok bool waitC := make(chan error, 1) go func() { var addrs []Address if cc.dopts.balancer == nil { // Connect to target directly if balancer is nil. addrs = append(addrs, Address{Addr: target}) } else { var credsClone credentials.TransportCredentials if creds != nil { credsClone = creds.Clone() } config := BalancerConfig{ DialCreds: credsClone, } if err := cc.dopts.balancer.Start(target, config); err != nil { waitC <- err return } ch := cc.dopts.balancer.Notify() if ch == nil { // There is no name resolver installed. addrs = append(addrs, Address{Addr: target}) } else { addrs, ok = <-ch if !ok || len(addrs) == 0 { waitC <- errNoAddr return } } } for _, a := range addrs { if err := cc.resetAddrConn(a, false, nil); err != nil { waitC <- err return } } close(waitC) }() var timeoutCh <-chan time.Time if cc.dopts.timeout > 0 { timeoutCh = time.After(cc.dopts.timeout) } select { case <-ctx.Done(): return nil, ctx.Err() case err := <-waitC: if err != nil { return nil, err } case <-timeoutCh: return nil, ErrClientConnTimeout } // If balancer is nil or balancer.Notify() is nil, ok will be false here. // The lbWatcher goroutine will not be created. if ok { go cc.lbWatcher() } return cc, nil } // ConnectivityState indicates the state of a client connection. type ConnectivityState int const ( // Idle indicates the ClientConn is idle. Idle ConnectivityState = iota // Connecting indicates the ClienConn is connecting. Connecting // Ready indicates the ClientConn is ready for work. Ready // TransientFailure indicates the ClientConn has seen a failure but expects to recover. TransientFailure // Shutdown indicates the ClientConn has started shutting down. Shutdown ) func (s ConnectivityState) String() string { switch s { case Idle: return "IDLE" case Connecting: return "CONNECTING" case Ready: return "READY" case TransientFailure: return "TRANSIENT_FAILURE" case Shutdown: return "SHUTDOWN" default: panic(fmt.Sprintf("unknown connectivity state: %d", s)) } } // ClientConn represents a client connection to an RPC server. type ClientConn struct { ctx context.Context cancel context.CancelFunc target string authority string dopts dialOptions mu sync.RWMutex conns map[Address]*addrConn } func (cc *ClientConn) lbWatcher() { for addrs := range cc.dopts.balancer.Notify() { var ( add []Address // Addresses need to setup connections. del []*addrConn // Connections need to tear down. ) cc.mu.Lock() for _, a := range addrs { if _, ok := cc.conns[a]; !ok { add = append(add, a) } } for k, c := range cc.conns { var keep bool for _, a := range addrs { if k == a { keep = true break } } if !keep { del = append(del, c) delete(cc.conns, c.addr) } } cc.mu.Unlock() for _, a := range add { cc.resetAddrConn(a, true, nil) } for _, c := range del { c.tearDown(errConnDrain) } } } // resetAddrConn creates an addrConn for addr and adds it to cc.conns. // If there is an old addrConn for addr, it will be torn down, using tearDownErr as the reason. // If tearDownErr is nil, errConnDrain will be used instead. func (cc *ClientConn) resetAddrConn(addr Address, skipWait bool, tearDownErr error) error { ac := &addrConn{ cc: cc, addr: addr, dopts: cc.dopts, } ac.ctx, ac.cancel = context.WithCancel(cc.ctx) ac.stateCV = sync.NewCond(&ac.mu) if EnableTracing { ac.events = trace.NewEventLog("grpc.ClientConn", ac.addr.Addr) } if !ac.dopts.insecure { if ac.dopts.copts.TransportCredentials == nil { return errNoTransportSecurity } } else { if ac.dopts.copts.TransportCredentials != nil { return errCredentialsConflict } for _, cd := range ac.dopts.copts.PerRPCCredentials { if cd.RequireTransportSecurity() { return errTransportCredentialsMissing } } } // Track ac in cc. This needs to be done before any getTransport(...) is called. cc.mu.Lock() if cc.conns == nil { cc.mu.Unlock() return ErrClientConnClosing } stale := cc.conns[ac.addr] cc.conns[ac.addr] = ac cc.mu.Unlock() if stale != nil { // There is an addrConn alive on ac.addr already. This could be due to // 1) a buggy Balancer notifies duplicated Addresses; // 2) goaway was received, a new ac will replace the old ac. // The old ac should be deleted from cc.conns, but the // underlying transport should drain rather than close. if tearDownErr == nil { // tearDownErr is nil if resetAddrConn is called by // 1) Dial // 2) lbWatcher // In both cases, the stale ac should drain, not close. stale.tearDown(errConnDrain) } else { stale.tearDown(tearDownErr) } } // skipWait may overwrite the decision in ac.dopts.block. if ac.dopts.block && !skipWait { if err := ac.resetTransport(false); err != nil { if err != errConnClosing { // Tear down ac and delete it from cc.conns. cc.mu.Lock() delete(cc.conns, ac.addr) cc.mu.Unlock() ac.tearDown(err) } if e, ok := err.(transport.ConnectionError); ok && !e.Temporary() { return e.Origin() } return err } // Start to monitor the error status of transport. go ac.transportMonitor() } else { // Start a goroutine connecting to the server asynchronously. go func() { if err := ac.resetTransport(false); err != nil { grpclog.Printf("Failed to dial %s: %v; please retry.", ac.addr.Addr, err) if err != errConnClosing { // Keep this ac in cc.conns, to get the reason it's torn down. ac.tearDown(err) } return } ac.transportMonitor() }() } return nil } func (cc *ClientConn) getTransport(ctx context.Context, opts BalancerGetOptions) (transport.ClientTransport, func(), error) { var ( ac *addrConn ok bool put func() ) if cc.dopts.balancer == nil { // If balancer is nil, there should be only one addrConn available. cc.mu.RLock() if cc.conns == nil { cc.mu.RUnlock() return nil, nil, toRPCErr(ErrClientConnClosing) } for _, ac = range cc.conns { // Break after the first iteration to get the first addrConn. ok = true break } cc.mu.RUnlock() } else { var ( addr Address err error ) addr, put, err = cc.dopts.balancer.Get(ctx, opts) if err != nil { return nil, nil, toRPCErr(err) } cc.mu.RLock() if cc.conns == nil { cc.mu.RUnlock() return nil, nil, toRPCErr(ErrClientConnClosing) } ac, ok = cc.conns[addr] cc.mu.RUnlock() } if !ok { if put != nil { put() } return nil, nil, errConnClosing } t, err := ac.wait(ctx, cc.dopts.balancer != nil, !opts.BlockingWait) if err != nil { if put != nil { put() } return nil, nil, err } return t, put, nil } // Close tears down the ClientConn and all underlying connections. func (cc *ClientConn) Close() error { cc.cancel() cc.mu.Lock() if cc.conns == nil { cc.mu.Unlock() return ErrClientConnClosing } conns := cc.conns cc.conns = nil cc.mu.Unlock() if cc.dopts.balancer != nil { cc.dopts.balancer.Close() } for _, ac := range conns { ac.tearDown(ErrClientConnClosing) } return nil } // addrConn is a network connection to a given address. type addrConn struct { ctx context.Context cancel context.CancelFunc cc *ClientConn addr Address dopts dialOptions events trace.EventLog mu sync.Mutex state ConnectivityState stateCV *sync.Cond down func(error) // the handler called when a connection is down. // ready is closed and becomes nil when a new transport is up or failed // due to timeout. ready chan struct{} transport transport.ClientTransport // The reason this addrConn is torn down. tearDownErr error } // printf records an event in ac's event log, unless ac has been closed. // REQUIRES ac.mu is held. func (ac *addrConn) printf(format string, a ...interface{}) { if ac.events != nil { ac.events.Printf(format, a...) } } // errorf records an error in ac's event log, unless ac has been closed. // REQUIRES ac.mu is held. func (ac *addrConn) errorf(format string, a ...interface{}) { if ac.events != nil { ac.events.Errorf(format, a...) } } // getState returns the connectivity state of the Conn func (ac *addrConn) getState() ConnectivityState { ac.mu.Lock() defer ac.mu.Unlock() return ac.state } // waitForStateChange blocks until the state changes to something other than the sourceState. func (ac *addrConn) waitForStateChange(ctx context.Context, sourceState ConnectivityState) (ConnectivityState, error) { ac.mu.Lock() defer ac.mu.Unlock() if sourceState != ac.state { return ac.state, nil } done := make(chan struct{}) var err error go func() { select { case <-ctx.Done(): ac.mu.Lock() err = ctx.Err() ac.stateCV.Broadcast() ac.mu.Unlock() case <-done: } }() defer close(done) for sourceState == ac.state { ac.stateCV.Wait() if err != nil { return ac.state, err } } return ac.state, nil } func (ac *addrConn) resetTransport(closeTransport bool) error { for retries := 0; ; retries++ { ac.mu.Lock() ac.printf("connecting") if ac.state == Shutdown { // ac.tearDown(...) has been invoked. ac.mu.Unlock() return errConnClosing } if ac.down != nil { ac.down(downErrorf(false, true, "%v", errNetworkIO)) ac.down = nil } ac.state = Connecting ac.stateCV.Broadcast() t := ac.transport ac.mu.Unlock() if closeTransport && t != nil { t.Close() } sleepTime := ac.dopts.bs.backoff(retries) timeout := minConnectTimeout if timeout < sleepTime { timeout = sleepTime } ctx, cancel := context.WithTimeout(ac.ctx, timeout) connectTime := time.Now() newTransport, err := transport.NewClientTransport(ctx, ac.addr.Addr, ac.dopts.copts) if err != nil { cancel() if e, ok := err.(transport.ConnectionError); ok && !e.Temporary() { return err } grpclog.Printf("grpc: addrConn.resetTransport failed to create client transport: %v; Reconnecting to %v", err, ac.addr) ac.mu.Lock() if ac.state == Shutdown { // ac.tearDown(...) has been invoked. ac.mu.Unlock() return errConnClosing } ac.errorf("transient failure: %v", err) ac.state = TransientFailure ac.stateCV.Broadcast() if ac.ready != nil { close(ac.ready) ac.ready = nil } ac.mu.Unlock() closeTransport = false select { case <-time.After(sleepTime - time.Since(connectTime)): case <-ac.ctx.Done(): return ac.ctx.Err() } continue } ac.mu.Lock() ac.printf("ready") if ac.state == Shutdown { // ac.tearDown(...) has been invoked. ac.mu.Unlock() newTransport.Close() return errConnClosing } ac.state = Ready ac.stateCV.Broadcast() ac.transport = newTransport if ac.ready != nil { close(ac.ready) ac.ready = nil } if ac.cc.dopts.balancer != nil { ac.down = ac.cc.dopts.balancer.Up(ac.addr) } ac.mu.Unlock() return nil } } // Run in a goroutine to track the error in transport and create the // new transport if an error happens. It returns when the channel is closing. func (ac *addrConn) transportMonitor() { for { ac.mu.Lock() t := ac.transport ac.mu.Unlock() select { // This is needed to detect the teardown when // the addrConn is idle (i.e., no RPC in flight). case <-ac.ctx.Done(): select { case <-t.Error(): t.Close() default: } return case <-t.GoAway(): // If GoAway happens without any network I/O error, ac is closed without shutting down the // underlying transport (the transport will be closed when all the pending RPCs finished or // failed.). // If GoAway and some network I/O error happen concurrently, ac and its underlying transport // are closed. // In both cases, a new ac is created. select { case <-t.Error(): ac.cc.resetAddrConn(ac.addr, true, errNetworkIO) default: ac.cc.resetAddrConn(ac.addr, true, errConnDrain) } return case <-t.Error(): select { case <-ac.ctx.Done(): t.Close() return case <-t.GoAway(): ac.cc.resetAddrConn(ac.addr, true, errNetworkIO) return default: } ac.mu.Lock() if ac.state == Shutdown { // ac has been shutdown. ac.mu.Unlock() return } ac.state = TransientFailure ac.stateCV.Broadcast() ac.mu.Unlock() if err := ac.resetTransport(true); err != nil { ac.mu.Lock() ac.printf("transport exiting: %v", err) ac.mu.Unlock() grpclog.Printf("grpc: addrConn.transportMonitor exits due to: %v", err) if err != errConnClosing { // Keep this ac in cc.conns, to get the reason it's torn down. ac.tearDown(err) } return } } } } // wait blocks until i) the new transport is up or ii) ctx is done or iii) ac is closed or // iv) transport is in TransientFailure and there's no balancer/failfast is true. func (ac *addrConn) wait(ctx context.Context, hasBalancer, failfast bool) (transport.ClientTransport, error) { for { ac.mu.Lock() switch { case ac.state == Shutdown: if failfast || !hasBalancer { // RPC is failfast or balancer is nil. This RPC should fail with ac.tearDownErr. err := ac.tearDownErr ac.mu.Unlock() return nil, err } ac.mu.Unlock() return nil, errConnClosing case ac.state == Ready: ct := ac.transport ac.mu.Unlock() return ct, nil case ac.state == TransientFailure: if failfast || hasBalancer { ac.mu.Unlock() return nil, errConnUnavailable } } ready := ac.ready if ready == nil { ready = make(chan struct{}) ac.ready = ready } ac.mu.Unlock() select { case <-ctx.Done(): return nil, toRPCErr(ctx.Err()) // Wait until the new transport is ready or failed. case <-ready: } } } // tearDown starts to tear down the addrConn. // TODO(zhaoq): Make this synchronous to avoid unbounded memory consumption in // some edge cases (e.g., the caller opens and closes many addrConn's in a // tight loop. // tearDown doesn't remove ac from ac.cc.conns. func (ac *addrConn) tearDown(err error) { ac.cancel() ac.mu.Lock() defer ac.mu.Unlock() if ac.down != nil { ac.down(downErrorf(false, false, "%v", err)) ac.down = nil } if err == errConnDrain && ac.transport != nil { // GracefulClose(...) may be executed multiple times when // i) receiving multiple GoAway frames from the server; or // ii) there are concurrent name resolver/Balancer triggered // address removal and GoAway. ac.transport.GracefulClose() } if ac.state == Shutdown { return } ac.state = Shutdown ac.tearDownErr = err ac.stateCV.Broadcast() if ac.events != nil { ac.events.Finish() ac.events = nil } if ac.ready != nil { close(ac.ready) ac.ready = nil } if ac.transport != nil && err != errConnDrain { ac.transport.Close() } return }