balancer_conn_wrappers.go - third_party/github.com/grpc/grpc-go - Git at Google

 /*
  *
  * Copyright 2017 gRPC authors.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  */

 package grpc

 import (
 	"context"
 	"fmt"
 	"strings"
 	"sync"

 	"google.golang.org/grpc/balancer"
 	"google.golang.org/grpc/codes"
 	"google.golang.org/grpc/connectivity"
 	"google.golang.org/grpc/internal/balancer/gracefulswitch"
 	"google.golang.org/grpc/internal/buffer"
 	"google.golang.org/grpc/internal/channelz"
 	"google.golang.org/grpc/internal/grpcsync"
 	"google.golang.org/grpc/resolver"
 	"google.golang.org/grpc/status"
 )

 // ccBalancerWrapper sits between the ClientConn and the Balancer.
 //
 // ccBalancerWrapper implements methods corresponding to the ones on the
 // balancer.Balancer interface. The ClientConn is free to call these methods
 // concurrently and the ccBalancerWrapper ensures that calls from the ClientConn
 // to the Balancer happen synchronously and in order.
 //
 // ccBalancerWrapper also implements the balancer.ClientConn interface and is
 // passed to the Balancer implementations. It invokes unexported methods on the
 // ClientConn to handle these calls from the Balancer.
 //
 // It uses the gracefulswitch.Balancer internally to ensure that balancer
 // switches happen in a graceful manner.
 type ccBalancerWrapper struct {
 	cc *ClientConn

 	// Since these fields are accessed only from handleXxx() methods which are
 	// synchronized by the watcher goroutine, we do not need a mutex to protect
 	// these fields.
 	balancer        *gracefulswitch.Balancer
 	curBalancerName string

 	updateCh *buffer.Unbounded // Updates written on this channel are processed by watcher().
 	resultCh *buffer.Unbounded // Results of calls to UpdateClientConnState() are pushed here.
 	closed   *grpcsync.Event   // Indicates if close has been called.
 	done     *grpcsync.Event   // Indicates if close has completed its work.
 }

 // newCCBalancerWrapper creates a new balancer wrapper. The underlying balancer
 // is not created until the switchTo() method is invoked.
 func newCCBalancerWrapper(cc *ClientConn, bopts balancer.BuildOptions) *ccBalancerWrapper {
 	ccb := &ccBalancerWrapper{
 		cc:       cc,
 		updateCh: buffer.NewUnbounded(),
 		resultCh: buffer.NewUnbounded(),
 		closed:   grpcsync.NewEvent(),
 		done:     grpcsync.NewEvent(),
 	}
 	go ccb.watcher()
 	ccb.balancer = gracefulswitch.NewBalancer(ccb, bopts)
 	return ccb
 }

 // The following xxxUpdate structs wrap the arguments received as part of the
 // corresponding update. The watcher goroutine uses the 'type' of the update to
 // invoke the appropriate handler routine to handle the update.

 type ccStateUpdate struct {
 	ccs *balancer.ClientConnState
 }

 type scStateUpdate struct {
 	sc    balancer.SubConn
 	state connectivity.State
 	err   error
 }

 type exitIdleUpdate struct{}

 type resolverErrorUpdate struct {
 	err error
 }

 type switchToUpdate struct {
 	name string
 }

 type subConnUpdate struct {
 	acbw *acBalancerWrapper
 }

 // watcher is a long-running goroutine which reads updates from a channel and
 // invokes corresponding methods on the underlying balancer. It ensures that
 // these methods are invoked in a synchronous fashion. It also ensures that
 // these methods are invoked in the order in which the updates were received.
 func (ccb *ccBalancerWrapper) watcher() {
 	for {
 		select {
 		case u := <-ccb.updateCh.Get():
 			ccb.updateCh.Load()
 			if ccb.closed.HasFired() {
 				break
 			}
 			switch update := u.(type) {
 			case *ccStateUpdate:
 				ccb.handleClientConnStateChange(update.ccs)
 			case *scStateUpdate:
 				ccb.handleSubConnStateChange(update)
 			case *exitIdleUpdate:
 				ccb.handleExitIdle()
 			case *resolverErrorUpdate:
 				ccb.handleResolverError(update.err)
 			case *switchToUpdate:
 				ccb.handleSwitchTo(update.name)
 			case *subConnUpdate:
 				ccb.handleRemoveSubConn(update.acbw)
 			default:
 				logger.Errorf("ccBalancerWrapper.watcher: unknown update %+v, type %T", update, update)
 			}
 		case <-ccb.closed.Done():
 		}

 		if ccb.closed.HasFired() {
 			ccb.handleClose()
 			return
 		}
 	}
 }

 // updateClientConnState is invoked by grpc to push a ClientConnState update to
 // the underlying balancer.
 //
 // Unlike other methods invoked by grpc to push updates to the underlying
 // balancer, this method cannot simply push the update onto the update channel
 // and return. It needs to return the error returned by the underlying balancer
 // back to grpc which propagates that to the resolver.
 func (ccb *ccBalancerWrapper) updateClientConnState(ccs *balancer.ClientConnState) error {
 	ccb.updateCh.Put(&ccStateUpdate{ccs: ccs})

 	var res interface{}
 	select {
 	case res = <-ccb.resultCh.Get():
 		ccb.resultCh.Load()
 	case <-ccb.closed.Done():
 		// Return early if the balancer wrapper is closed while we are waiting for
 		// the underlying balancer to process a ClientConnState update.
 		return nil
 	}
 	// If the returned error is nil, attempting to type assert to error leads to
 	// panic. So, this needs to handled separately.
 	if res == nil {
 		return nil
 	}
 	return res.(error)
 }

 // handleClientConnStateChange handles a ClientConnState update from the update
 // channel and invokes the appropriate method on the underlying balancer.
 //
 // If the addresses specified in the update contain addresses of type "grpclb"
 // and the selected LB policy is not "grpclb", these addresses will be filtered
 // out and ccs will be modified with the updated address list.
 func (ccb *ccBalancerWrapper) handleClientConnStateChange(ccs *balancer.ClientConnState) {
 	if ccb.curBalancerName != grpclbName {
 		// Filter any grpclb addresses since we don't have the grpclb balancer.
 		var addrs []resolver.Address
 		for _, addr := range ccs.ResolverState.Addresses {
 			if addr.Type == resolver.GRPCLB {
 				continue
 			}
 			addrs = append(addrs, addr)
 		}
 		ccs.ResolverState.Addresses = addrs
 	}
 	ccb.resultCh.Put(ccb.balancer.UpdateClientConnState(*ccs))
 }

 // updateSubConnState is invoked by grpc to push a subConn state update to the
 // underlying balancer.
 func (ccb *ccBalancerWrapper) updateSubConnState(sc balancer.SubConn, s connectivity.State, err error) {
 	// When updating addresses for a SubConn, if the address in use is not in
 	// the new addresses, the old ac will be tearDown() and a new ac will be
 	// created. tearDown() generates a state change with Shutdown state, we
 	// don't want the balancer to receive this state change. So before
 	// tearDown() on the old ac, ac.acbw (acWrapper) will be set to nil, and
 	// this function will be called with (nil, Shutdown). We don't need to call
 	// balancer method in this case.
 	if sc == nil {
 		return
 	}
 	ccb.updateCh.Put(&scStateUpdate{
 		sc:    sc,
 		state: s,
 		err:   err,
 	})
 }

 // handleSubConnStateChange handles a SubConnState update from the update
 // channel and invokes the appropriate method on the underlying balancer.
 func (ccb *ccBalancerWrapper) handleSubConnStateChange(update *scStateUpdate) {
 	ccb.balancer.UpdateSubConnState(update.sc, balancer.SubConnState{ConnectivityState: update.state, ConnectionError: update.err})
 }

 func (ccb *ccBalancerWrapper) exitIdle() {
 	ccb.updateCh.Put(&exitIdleUpdate{})
 }

 func (ccb *ccBalancerWrapper) handleExitIdle() {
 	if ccb.cc.GetState() != connectivity.Idle {
 		return
 	}
 	ccb.balancer.ExitIdle()
 }

 func (ccb *ccBalancerWrapper) resolverError(err error) {
 	ccb.updateCh.Put(&resolverErrorUpdate{err: err})
 }

 func (ccb *ccBalancerWrapper) handleResolverError(err error) {
 	ccb.balancer.ResolverError(err)
 }

 // switchTo is invoked by grpc to instruct the balancer wrapper to switch to the
 // LB policy identified by name.
 //
 // ClientConn calls newCCBalancerWrapper() at creation time. Upon receipt of the
 // first good update from the name resolver, it determines the LB policy to use
 // and invokes the switchTo() method. Upon receipt of every subsequent update
 // from the name resolver, it invokes this method.
 //
 // the ccBalancerWrapper keeps track of the current LB policy name, and skips
 // the graceful balancer switching process if the name does not change.
 func (ccb *ccBalancerWrapper) switchTo(name string) {
 	ccb.updateCh.Put(&switchToUpdate{name: name})
 }

 // handleSwitchTo handles a balancer switch update from the update channel. It
 // calls the SwitchTo() method on the gracefulswitch.Balancer with a
 // balancer.Builder corresponding to name. If no balancer.Builder is registered
 // for the given name, it uses the default LB policy which is "pick_first".
 func (ccb *ccBalancerWrapper) handleSwitchTo(name string) {
 	// TODO: Other languages use case-insensitive balancer registries. We should
 	// switch as well. See: https://github.com/grpc/grpc-go/issues/5288.
 	if strings.EqualFold(ccb.curBalancerName, name) {
 		return
 	}

 	// TODO: Ensure that name is a registered LB policy when we get here.
 	// We currently only validate the `loadBalancingConfig` field. We need to do
 	// the same for the `loadBalancingPolicy` field and reject the service config
 	// if the specified policy is not registered.
 	builder := balancer.Get(name)
 	if builder == nil {
 		channelz.Warningf(logger, ccb.cc.channelzID, "Channel switches to new LB policy %q, since the specified LB policy %q was not registered", PickFirstBalancerName, name)
 		builder = newPickfirstBuilder()
 	} else {
 		channelz.Infof(logger, ccb.cc.channelzID, "Channel switches to new LB policy %q", name)
 	}

 	if err := ccb.balancer.SwitchTo(builder); err != nil {
 		channelz.Errorf(logger, ccb.cc.channelzID, "Channel failed to build new LB policy %q: %v", name, err)
 		return
 	}
 	ccb.curBalancerName = builder.Name()
 }

 // handleRemoveSucConn handles a request from the underlying balancer to remove
 // a subConn.
 //
 // See comments in RemoveSubConn() for more details.
 func (ccb *ccBalancerWrapper) handleRemoveSubConn(acbw *acBalancerWrapper) {
 	ccb.cc.removeAddrConn(acbw.getAddrConn(), errConnDrain)
 }

 func (ccb *ccBalancerWrapper) close() {
 	ccb.closed.Fire()
 	<-ccb.done.Done()
 }

 func (ccb *ccBalancerWrapper) handleClose() {
 	ccb.balancer.Close()
 	ccb.done.Fire()
 }

 func (ccb *ccBalancerWrapper) NewSubConn(addrs []resolver.Address, opts balancer.NewSubConnOptions) (balancer.SubConn, error) {
 	if len(addrs) <= 0 {
 		return nil, fmt.Errorf("grpc: cannot create SubConn with empty address list")
 	}
 	ac, err := ccb.cc.newAddrConn(addrs, opts)
 	if err != nil {
 		channelz.Warningf(logger, ccb.cc.channelzID, "acBalancerWrapper: NewSubConn: failed to newAddrConn: %v", err)
 		return nil, err
 	}
 	acbw := &acBalancerWrapper{ac: ac, producers: make(map[balancer.ProducerBuilder]*refCountedProducer)}
 	acbw.ac.mu.Lock()
 	ac.acbw = acbw
 	acbw.ac.mu.Unlock()
 	return acbw, nil
 }

 func (ccb *ccBalancerWrapper) RemoveSubConn(sc balancer.SubConn) {
 	// Before we switched the ccBalancerWrapper to use gracefulswitch.Balancer, it
 	// was required to handle the RemoveSubConn() method asynchronously by pushing
 	// the update onto the update channel. This was done to avoid a deadlock as
 	// switchBalancer() was holding cc.mu when calling Close() on the old
 	// balancer, which would in turn call RemoveSubConn().
 	//
 	// With the use of gracefulswitch.Balancer in ccBalancerWrapper, handling this
 	// asynchronously is probably not required anymore since the switchTo() method
 	// handles the balancer switch by pushing the update onto the channel.
 	// TODO(easwars): Handle this inline.
 	acbw, ok := sc.(*acBalancerWrapper)
 	if !ok {
 		return
 	}
 	ccb.updateCh.Put(&subConnUpdate{acbw: acbw})
 }

 func (ccb *ccBalancerWrapper) UpdateAddresses(sc balancer.SubConn, addrs []resolver.Address) {
 	acbw, ok := sc.(*acBalancerWrapper)
 	if !ok {
 		return
 	}
 	acbw.UpdateAddresses(addrs)
 }

 func (ccb *ccBalancerWrapper) UpdateState(s balancer.State) {
 	// Update picker before updating state.  Even though the ordering here does
 	// not matter, it can lead to multiple calls of Pick in the common start-up
 	// case where we wait for ready and then perform an RPC.  If the picker is
 	// updated later, we could call the "connecting" picker when the state is
 	// updated, and then call the "ready" picker after the picker gets updated.
 	ccb.cc.blockingpicker.updatePicker(s.Picker)
 	ccb.cc.csMgr.updateState(s.ConnectivityState)
 }

 func (ccb *ccBalancerWrapper) ResolveNow(o resolver.ResolveNowOptions) {
 	ccb.cc.resolveNow(o)
 }

 func (ccb *ccBalancerWrapper) Target() string {
 	return ccb.cc.target
 }

 // acBalancerWrapper is a wrapper on top of ac for balancers.
 // It implements balancer.SubConn interface.
 type acBalancerWrapper struct {
 	mu        sync.Mutex
 	ac        *addrConn
 	producers map[balancer.ProducerBuilder]*refCountedProducer
 }

 func (acbw *acBalancerWrapper) UpdateAddresses(addrs []resolver.Address) {
 	acbw.mu.Lock()
 	defer acbw.mu.Unlock()
 	if len(addrs) <= 0 {
 		acbw.ac.cc.removeAddrConn(acbw.ac, errConnDrain)
 		return
 	}
 	if !acbw.ac.tryUpdateAddrs(addrs) {
 		cc := acbw.ac.cc
 		opts := acbw.ac.scopts
 		acbw.ac.mu.Lock()
 		// Set old ac.acbw to nil so the Shutdown state update will be ignored
 		// by balancer.
 		//
 		// TODO(bar) the state transition could be wrong when tearDown() old ac
 		// and creating new ac, fix the transition.
 		acbw.ac.acbw = nil
 		acbw.ac.mu.Unlock()
 		acState := acbw.ac.getState()
 		acbw.ac.cc.removeAddrConn(acbw.ac, errConnDrain)

 		if acState == connectivity.Shutdown {
 			return
 		}

 		newAC, err := cc.newAddrConn(addrs, opts)
 		if err != nil {
 			channelz.Warningf(logger, acbw.ac.channelzID, "acBalancerWrapper: UpdateAddresses: failed to newAddrConn: %v", err)
 			return
 		}
 		acbw.ac = newAC
 		newAC.mu.Lock()
 		newAC.acbw = acbw
 		newAC.mu.Unlock()
 		if acState != connectivity.Idle {
 			go newAC.connect()
 		}
 	}
 }

 func (acbw *acBalancerWrapper) Connect() {
 	acbw.mu.Lock()
 	defer acbw.mu.Unlock()
 	go acbw.ac.connect()
 }

 func (acbw *acBalancerWrapper) getAddrConn() *addrConn {
 	acbw.mu.Lock()
 	defer acbw.mu.Unlock()
 	return acbw.ac
 }

 var errSubConnNotReady = status.Error(codes.Unavailable, "SubConn not currently connected")

 // NewStream begins a streaming RPC on the addrConn.  If the addrConn is not
 // ready, returns errSubConnNotReady.
 func (acbw *acBalancerWrapper) NewStream(ctx context.Context, desc *StreamDesc, method string, opts ...CallOption) (ClientStream, error) {
 	transport := acbw.ac.getReadyTransport()
 	if transport == nil {
 		return nil, errSubConnNotReady
 	}
 	return newNonRetryClientStream(ctx, desc, method, transport, acbw.ac, opts...)
 }

 // Invoke performs a unary RPC.  If the addrConn is not ready, returns
 // errSubConnNotReady.
 func (acbw *acBalancerWrapper) Invoke(ctx context.Context, method string, args interface{}, reply interface{}, opts ...CallOption) error {
 	cs, err := acbw.NewStream(ctx, unaryStreamDesc, method, opts...)
 	if err != nil {
 		return err
 	}
 	if err := cs.SendMsg(args); err != nil {
 		return err
 	}
 	return cs.RecvMsg(reply)
 }

 type refCountedProducer struct {
 	producer balancer.Producer
 	refs     int    // number of current refs to the producer
 	close    func() // underlying producer's close function
 }

 func (acbw *acBalancerWrapper) GetOrBuildProducer(pb balancer.ProducerBuilder) (balancer.Producer, func()) {
 	acbw.mu.Lock()
 	defer acbw.mu.Unlock()

 	// Look up existing producer from this builder.
 	pData := acbw.producers[pb]
 	if pData == nil {
 		// Not found; create a new one and add it to the producers map.
 		p, close := pb.Build(acbw)
 		pData = &refCountedProducer{producer: p, close: close}
 		acbw.producers[pb] = pData
 	}
 	// Account for this new reference.
 	pData.refs++

 	// Return a cleanup function wrapped in a OnceFunc to remove this reference
 	// and delete the refCountedProducer from the map if the total reference
 	// count goes to zero.
 	unref := func() {
 		acbw.mu.Lock()
 		pData.refs--
 		if pData.refs == 0 {
 			defer pData.close() // Run outside the acbw mutex
 			delete(acbw.producers, pb)
 		}
 		acbw.mu.Unlock()
 	}
 	return pData.producer, grpcsync.OnceFunc(unref)
 }
	/*
	*
	* Copyright 2017 gRPC authors.
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	*/

	package grpc

	import (
	"context"
	"fmt"
	"strings"
	"sync"

	"google.golang.org/grpc/balancer"
	"google.golang.org/grpc/codes"
	"google.golang.org/grpc/connectivity"
	"google.golang.org/grpc/internal/balancer/gracefulswitch"
	"google.golang.org/grpc/internal/buffer"
	"google.golang.org/grpc/internal/channelz"
	"google.golang.org/grpc/internal/grpcsync"
	"google.golang.org/grpc/resolver"
	"google.golang.org/grpc/status"
	)

	// ccBalancerWrapper sits between the ClientConn and the Balancer.
	//
	// ccBalancerWrapper implements methods corresponding to the ones on the
	// balancer.Balancer interface. The ClientConn is free to call these methods
	// concurrently and the ccBalancerWrapper ensures that calls from the ClientConn
	// to the Balancer happen synchronously and in order.
	//
	// ccBalancerWrapper also implements the balancer.ClientConn interface and is
	// passed to the Balancer implementations. It invokes unexported methods on the
	// ClientConn to handle these calls from the Balancer.
	//
	// It uses the gracefulswitch.Balancer internally to ensure that balancer
	// switches happen in a graceful manner.
	type ccBalancerWrapper struct {
	cc *ClientConn

	// Since these fields are accessed only from handleXxx() methods which are
	// synchronized by the watcher goroutine, we do not need a mutex to protect
	// these fields.
	balancer *gracefulswitch.Balancer
	curBalancerName string

	updateCh *buffer.Unbounded // Updates written on this channel are processed by watcher().
	resultCh *buffer.Unbounded // Results of calls to UpdateClientConnState() are pushed here.
	closed *grpcsync.Event // Indicates if close has been called.
	done *grpcsync.Event // Indicates if close has completed its work.
	}

	// newCCBalancerWrapper creates a new balancer wrapper. The underlying balancer
	// is not created until the switchTo() method is invoked.
	func newCCBalancerWrapper(cc ClientConn, bopts balancer.BuildOptions) ccBalancerWrapper {
	ccb := &ccBalancerWrapper{
	cc: cc,
	updateCh: buffer.NewUnbounded(),
	resultCh: buffer.NewUnbounded(),
	closed: grpcsync.NewEvent(),
	done: grpcsync.NewEvent(),
	}
	go ccb.watcher()
	ccb.balancer = gracefulswitch.NewBalancer(ccb, bopts)
	return ccb
	}

	// The following xxxUpdate structs wrap the arguments received as part of the
	// corresponding update. The watcher goroutine uses the 'type' of the update to
	// invoke the appropriate handler routine to handle the update.

	type ccStateUpdate struct {
	ccs *balancer.ClientConnState
	}

	type scStateUpdate struct {
	sc balancer.SubConn
	state connectivity.State
	err error
	}

	type exitIdleUpdate struct{}

	type resolverErrorUpdate struct {
	err error
	}

	type switchToUpdate struct {
	name string
	}

	type subConnUpdate struct {
	acbw *acBalancerWrapper
	}

	// watcher is a long-running goroutine which reads updates from a channel and
	// invokes corresponding methods on the underlying balancer. It ensures that
	// these methods are invoked in a synchronous fashion. It also ensures that
	// these methods are invoked in the order in which the updates were received.
	func (ccb *ccBalancerWrapper) watcher() {
	for {
	select {
	case u := <-ccb.updateCh.Get():
	ccb.updateCh.Load()
	if ccb.closed.HasFired() {
	break
	}
	switch update := u.(type) {
	case *ccStateUpdate:
	ccb.handleClientConnStateChange(update.ccs)
	case *scStateUpdate:
	ccb.handleSubConnStateChange(update)
	case *exitIdleUpdate:
	ccb.handleExitIdle()
	case *resolverErrorUpdate:
	ccb.handleResolverError(update.err)
	case *switchToUpdate:
	ccb.handleSwitchTo(update.name)
	case *subConnUpdate:
	ccb.handleRemoveSubConn(update.acbw)
	default:
	logger.Errorf("ccBalancerWrapper.watcher: unknown update %+v, type %T", update, update)
	}
	case <-ccb.closed.Done():
	}

	if ccb.closed.HasFired() {
	ccb.handleClose()
	return
	}
	}
	}

	// updateClientConnState is invoked by grpc to push a ClientConnState update to
	// the underlying balancer.
	//
	// Unlike other methods invoked by grpc to push updates to the underlying
	// balancer, this method cannot simply push the update onto the update channel
	// and return. It needs to return the error returned by the underlying balancer
	// back to grpc which propagates that to the resolver.
	func (ccb ccBalancerWrapper) updateClientConnState(ccs balancer.ClientConnState) error {
	ccb.updateCh.Put(&ccStateUpdate{ccs: ccs})

	var res interface{}
	select {
	case res = <-ccb.resultCh.Get():
	ccb.resultCh.Load()
	case <-ccb.closed.Done():
	// Return early if the balancer wrapper is closed while we are waiting for
	// the underlying balancer to process a ClientConnState update.
	return nil
	}
	// If the returned error is nil, attempting to type assert to error leads to
	// panic. So, this needs to handled separately.
	if res == nil {
	return nil
	}
	return res.(error)
	}

	// handleClientConnStateChange handles a ClientConnState update from the update
	// channel and invokes the appropriate method on the underlying balancer.
	//
	// If the addresses specified in the update contain addresses of type "grpclb"
	// and the selected LB policy is not "grpclb", these addresses will be filtered
	// out and ccs will be modified with the updated address list.
	func (ccb ccBalancerWrapper) handleClientConnStateChange(ccs balancer.ClientConnState) {
	if ccb.curBalancerName != grpclbName {
	// Filter any grpclb addresses since we don't have the grpclb balancer.
	var addrs []resolver.Address
	for _, addr := range ccs.ResolverState.Addresses {
	if addr.Type == resolver.GRPCLB {
	continue
	}
	addrs = append(addrs, addr)
	}
	ccs.ResolverState.Addresses = addrs
	}
	ccb.resultCh.Put(ccb.balancer.UpdateClientConnState(*ccs))
	}

	// updateSubConnState is invoked by grpc to push a subConn state update to the
	// underlying balancer.
	func (ccb *ccBalancerWrapper) updateSubConnState(sc balancer.SubConn, s connectivity.State, err error) {
	// When updating addresses for a SubConn, if the address in use is not in
	// the new addresses, the old ac will be tearDown() and a new ac will be
	// created. tearDown() generates a state change with Shutdown state, we
	// don't want the balancer to receive this state change. So before
	// tearDown() on the old ac, ac.acbw (acWrapper) will be set to nil, and
	// this function will be called with (nil, Shutdown). We don't need to call
	// balancer method in this case.
	if sc == nil {
	return
	}
	ccb.updateCh.Put(&scStateUpdate{
	sc: sc,
	state: s,
	err: err,
	})
	}

	// handleSubConnStateChange handles a SubConnState update from the update
	// channel and invokes the appropriate method on the underlying balancer.
	func (ccb ccBalancerWrapper) handleSubConnStateChange(update scStateUpdate) {
	ccb.balancer.UpdateSubConnState(update.sc, balancer.SubConnState{ConnectivityState: update.state, ConnectionError: update.err})
	}

	func (ccb *ccBalancerWrapper) exitIdle() {
	ccb.updateCh.Put(&exitIdleUpdate{})
	}

	func (ccb *ccBalancerWrapper) handleExitIdle() {
	if ccb.cc.GetState() != connectivity.Idle {
	return
	}
	ccb.balancer.ExitIdle()
	}

	func (ccb *ccBalancerWrapper) resolverError(err error) {
	ccb.updateCh.Put(&resolverErrorUpdate{err: err})
	}

	func (ccb *ccBalancerWrapper) handleResolverError(err error) {
	ccb.balancer.ResolverError(err)
	}

	// switchTo is invoked by grpc to instruct the balancer wrapper to switch to the
	// LB policy identified by name.
	//
	// ClientConn calls newCCBalancerWrapper() at creation time. Upon receipt of the
	// first good update from the name resolver, it determines the LB policy to use
	// and invokes the switchTo() method. Upon receipt of every subsequent update
	// from the name resolver, it invokes this method.
	//
	// the ccBalancerWrapper keeps track of the current LB policy name, and skips
	// the graceful balancer switching process if the name does not change.
	func (ccb *ccBalancerWrapper) switchTo(name string) {
	ccb.updateCh.Put(&switchToUpdate{name: name})
	}

	// handleSwitchTo handles a balancer switch update from the update channel. It
	// calls the SwitchTo() method on the gracefulswitch.Balancer with a
	// balancer.Builder corresponding to name. If no balancer.Builder is registered
	// for the given name, it uses the default LB policy which is "pick_first".
	func (ccb *ccBalancerWrapper) handleSwitchTo(name string) {
	// TODO: Other languages use case-insensitive balancer registries. We should
	// switch as well. See: https://github.com/grpc/grpc-go/issues/5288.
	if strings.EqualFold(ccb.curBalancerName, name) {
	return
	}

	// TODO: Ensure that name is a registered LB policy when we get here.
	// We currently only validate the `loadBalancingConfig` field. We need to do
	// the same for the `loadBalancingPolicy` field and reject the service config
	// if the specified policy is not registered.
	builder := balancer.Get(name)
	if builder == nil {
	channelz.Warningf(logger, ccb.cc.channelzID, "Channel switches to new LB policy %q, since the specified LB policy %q was not registered", PickFirstBalancerName, name)
	builder = newPickfirstBuilder()
	} else {
	channelz.Infof(logger, ccb.cc.channelzID, "Channel switches to new LB policy %q", name)
	}

	if err := ccb.balancer.SwitchTo(builder); err != nil {
	channelz.Errorf(logger, ccb.cc.channelzID, "Channel failed to build new LB policy %q: %v", name, err)
	return
	}
	ccb.curBalancerName = builder.Name()
	}

	// handleRemoveSucConn handles a request from the underlying balancer to remove
	// a subConn.
	//
	// See comments in RemoveSubConn() for more details.
	func (ccb ccBalancerWrapper) handleRemoveSubConn(acbw acBalancerWrapper) {
	ccb.cc.removeAddrConn(acbw.getAddrConn(), errConnDrain)
	}

	func (ccb *ccBalancerWrapper) close() {
	ccb.closed.Fire()
	<-ccb.done.Done()
	}

	func (ccb *ccBalancerWrapper) handleClose() {
	ccb.balancer.Close()
	ccb.done.Fire()
	}

	func (ccb *ccBalancerWrapper) NewSubConn(addrs []resolver.Address, opts balancer.NewSubConnOptions) (balancer.SubConn, error) {
	if len(addrs) <= 0 {
	return nil, fmt.Errorf("grpc: cannot create SubConn with empty address list")
	}
	ac, err := ccb.cc.newAddrConn(addrs, opts)
	if err != nil {
	channelz.Warningf(logger, ccb.cc.channelzID, "acBalancerWrapper: NewSubConn: failed to newAddrConn: %v", err)
	return nil, err
	}
	acbw := &acBalancerWrapper{ac: ac, producers: make(map[balancer.ProducerBuilder]*refCountedProducer)}
	acbw.ac.mu.Lock()
	ac.acbw = acbw
	acbw.ac.mu.Unlock()
	return acbw, nil
	}

	func (ccb *ccBalancerWrapper) RemoveSubConn(sc balancer.SubConn) {
	// Before we switched the ccBalancerWrapper to use gracefulswitch.Balancer, it
	// was required to handle the RemoveSubConn() method asynchronously by pushing
	// the update onto the update channel. This was done to avoid a deadlock as
	// switchBalancer() was holding cc.mu when calling Close() on the old
	// balancer, which would in turn call RemoveSubConn().
	//
	// With the use of gracefulswitch.Balancer in ccBalancerWrapper, handling this
	// asynchronously is probably not required anymore since the switchTo() method
	// handles the balancer switch by pushing the update onto the channel.
	// TODO(easwars): Handle this inline.
	acbw, ok := sc.(*acBalancerWrapper)
	if !ok {
	return
	}
	ccb.updateCh.Put(&subConnUpdate{acbw: acbw})
	}

	func (ccb *ccBalancerWrapper) UpdateAddresses(sc balancer.SubConn, addrs []resolver.Address) {
	acbw, ok := sc.(*acBalancerWrapper)
	if !ok {
	return
	}
	acbw.UpdateAddresses(addrs)
	}

	func (ccb *ccBalancerWrapper) UpdateState(s balancer.State) {
	// Update picker before updating state. Even though the ordering here does
	// not matter, it can lead to multiple calls of Pick in the common start-up
	// case where we wait for ready and then perform an RPC. If the picker is
	// updated later, we could call the "connecting" picker when the state is
	// updated, and then call the "ready" picker after the picker gets updated.
	ccb.cc.blockingpicker.updatePicker(s.Picker)
	ccb.cc.csMgr.updateState(s.ConnectivityState)
	}

	func (ccb *ccBalancerWrapper) ResolveNow(o resolver.ResolveNowOptions) {
	ccb.cc.resolveNow(o)
	}

	func (ccb *ccBalancerWrapper) Target() string {
	return ccb.cc.target
	}

	// acBalancerWrapper is a wrapper on top of ac for balancers.
	// It implements balancer.SubConn interface.
	type acBalancerWrapper struct {
	mu sync.Mutex
	ac *addrConn
	producers map[balancer.ProducerBuilder]*refCountedProducer
	}

	func (acbw *acBalancerWrapper) UpdateAddresses(addrs []resolver.Address) {
	acbw.mu.Lock()
	defer acbw.mu.Unlock()
	if len(addrs) <= 0 {
	acbw.ac.cc.removeAddrConn(acbw.ac, errConnDrain)
	return
	}
	if !acbw.ac.tryUpdateAddrs(addrs) {
	cc := acbw.ac.cc
	opts := acbw.ac.scopts
	acbw.ac.mu.Lock()
	// Set old ac.acbw to nil so the Shutdown state update will be ignored
	// by balancer.
	//
	// TODO(bar) the state transition could be wrong when tearDown() old ac
	// and creating new ac, fix the transition.
	acbw.ac.acbw = nil
	acbw.ac.mu.Unlock()
	acState := acbw.ac.getState()
	acbw.ac.cc.removeAddrConn(acbw.ac, errConnDrain)

	if acState == connectivity.Shutdown {
	return
	}

	newAC, err := cc.newAddrConn(addrs, opts)
	if err != nil {
	channelz.Warningf(logger, acbw.ac.channelzID, "acBalancerWrapper: UpdateAddresses: failed to newAddrConn: %v", err)
	return
	}
	acbw.ac = newAC
	newAC.mu.Lock()
	newAC.acbw = acbw
	newAC.mu.Unlock()
	if acState != connectivity.Idle {
	go newAC.connect()
	}
	}
	}

	func (acbw *acBalancerWrapper) Connect() {
	acbw.mu.Lock()
	defer acbw.mu.Unlock()
	go acbw.ac.connect()
	}

	func (acbw acBalancerWrapper) getAddrConn() addrConn {
	acbw.mu.Lock()
	defer acbw.mu.Unlock()
	return acbw.ac
	}

	var errSubConnNotReady = status.Error(codes.Unavailable, "SubConn not currently connected")

	// NewStream begins a streaming RPC on the addrConn. If the addrConn is not
	// ready, returns errSubConnNotReady.
	func (acbw acBalancerWrapper) NewStream(ctx context.Context, desc StreamDesc, method string, opts ...CallOption) (ClientStream, error) {
	transport := acbw.ac.getReadyTransport()
	if transport == nil {
	return nil, errSubConnNotReady
	}
	return newNonRetryClientStream(ctx, desc, method, transport, acbw.ac, opts...)
	}

	// Invoke performs a unary RPC. If the addrConn is not ready, returns
	// errSubConnNotReady.
	func (acbw *acBalancerWrapper) Invoke(ctx context.Context, method string, args interface{}, reply interface{}, opts ...CallOption) error {
	cs, err := acbw.NewStream(ctx, unaryStreamDesc, method, opts...)
	if err != nil {
	return err
	}
	if err := cs.SendMsg(args); err != nil {
	return err
	}
	return cs.RecvMsg(reply)
	}

	type refCountedProducer struct {
	producer balancer.Producer
	refs int // number of current refs to the producer
	close func() // underlying producer's close function
	}

	func (acbw *acBalancerWrapper) GetOrBuildProducer(pb balancer.ProducerBuilder) (balancer.Producer, func()) {
	acbw.mu.Lock()
	defer acbw.mu.Unlock()

	// Look up existing producer from this builder.
	pData := acbw.producers[pb]
	if pData == nil {
	// Not found; create a new one and add it to the producers map.
	p, close := pb.Build(acbw)
	pData = &refCountedProducer{producer: p, close: close}
	acbw.producers[pb] = pData
	}
	// Account for this new reference.
	pData.refs++

	// Return a cleanup function wrapped in a OnceFunc to remove this reference
	// and delete the refCountedProducer from the map if the total reference
	// count goes to zero.
	unref := func() {
	acbw.mu.Lock()
	pData.refs--
	if pData.refs == 0 {
	defer pData.close() // Run outside the acbw mutex
	delete(acbw.producers, pb)
	}
	acbw.mu.Unlock()
	}
	return pData.producer, grpcsync.OnceFunc(unref)
	}