open-consul/agent/consul/leader_peering.go

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package consul
import (
"container/ring"
"context"
"errors"
"fmt"
"math"
"strings"
"time"
"github.com/armon/go-metrics"
"github.com/armon/go-metrics/prometheus"
"github.com/hashicorp/go-hclog"
"github.com/hashicorp/go-memdb"
"github.com/hashicorp/go-multierror"
"github.com/hashicorp/go-uuid"
"golang.org/x/time/rate"
"google.golang.org/grpc"
"google.golang.org/grpc/codes"
"google.golang.org/grpc/keepalive"
grpcstatus "google.golang.org/grpc/status"
"github.com/hashicorp/consul/acl"
"github.com/hashicorp/consul/agent/consul/state"
"github.com/hashicorp/consul/agent/grpc-external/services/peerstream"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/api"
"github.com/hashicorp/consul/logging"
"github.com/hashicorp/consul/proto/pbpeering"
"github.com/hashicorp/consul/proto/pbpeerstream"
)
var leaderExportedServicesCountKeyDeprecated = []string{"consul", "peering", "exported_services"}
var leaderExportedServicesCountKey = []string{"peering", "exported_services"}
var leaderHealthyPeeringKeyDeprecated = []string{"consul", "peering", "healthy"}
var leaderHealthyPeeringKey = []string{"peering", "healthy"}
var LeaderPeeringMetrics = []prometheus.GaugeDefinition{
{
Name: leaderExportedServicesCountKeyDeprecated,
Help: fmt.Sprint("Deprecated - please use ", strings.Join(leaderExportedServicesCountKey, "_")),
},
{
Name: leaderExportedServicesCountKey,
Help: "A gauge that tracks how many services are exported for the peering. " +
"The labels are \"peer_name\", \"peer_id\" and, for enterprise, \"partition\". " +
"We emit this metric every 9 seconds",
},
{
Name: leaderHealthyPeeringKeyDeprecated,
Help: fmt.Sprint("Deprecated - please use ", strings.Join(leaderExportedServicesCountKey, "_")),
},
{
Name: leaderHealthyPeeringKey,
Help: "A gauge that tracks how if a peering is healthy (1) or not (0). " +
"The labels are \"peer_name\", \"peer_id\" and, for enterprise, \"partition\". " +
"We emit this metric every 9 seconds",
},
}
var (
// fastConnRetryTimeout is how long we wait between retrying connections following the "fast" path
// which is triggered on specific connection errors.
fastConnRetryTimeout = 8 * time.Millisecond
// maxFastConnRetries is the maximum number of fast connection retries before we follow exponential backoff.
maxFastConnRetries = uint(5)
// maxFastRetryBackoff is the maximum amount of time we'll wait between retries following the fast path.
maxFastRetryBackoff = 8192 * time.Millisecond
)
func (s *Server) startPeeringStreamSync(ctx context.Context) {
s.leaderRoutineManager.Start(ctx, peeringStreamsRoutineName, s.runPeeringSync)
s.leaderRoutineManager.Start(ctx, peeringStreamsMetricsRoutineName, s.runPeeringMetrics)
}
func (s *Server) runPeeringMetrics(ctx context.Context) error {
ticker := time.NewTicker(s.config.MetricsReportingInterval)
defer ticker.Stop()
logger := s.logger.Named(logging.PeeringMetrics)
defaultMetrics := metrics.Default
for {
select {
case <-ctx.Done():
logger.Info("stopping peering metrics")
// "Zero-out" the metric on exit so that when prometheus scrapes this
// metric from a non-leader, it does not get a stale value.
metrics.SetGauge(leaderExportedServicesCountKeyDeprecated, float32(0))
metrics.SetGauge(leaderExportedServicesCountKey, float32(0))
return nil
case <-ticker.C:
if err := s.emitPeeringMetricsOnce(defaultMetrics()); err != nil {
s.logger.Error("error emitting peering stream metrics", "error", err)
}
}
}
}
func (s *Server) emitPeeringMetricsOnce(metricsImpl *metrics.Metrics) error {
_, peers, err := s.fsm.State().PeeringList(nil, *structs.NodeEnterpriseMetaInPartition(structs.WildcardSpecifier))
if err != nil {
return err
}
for _, peer := range peers {
part := peer.Partition
labels := []metrics.Label{
{Name: "peer_name", Value: peer.Name},
{Name: "peer_id", Value: peer.ID},
}
if part != "" {
labels = append(labels, metrics.Label{Name: "partition", Value: part})
}
status, found := s.peerStreamServer.StreamStatus(peer.ID)
if found {
// exported services count metric
esc := status.GetExportedServicesCount()
metricsImpl.SetGaugeWithLabels(leaderExportedServicesCountKeyDeprecated, float32(esc), labels)
metricsImpl.SetGaugeWithLabels(leaderExportedServicesCountKey, float32(esc), labels)
}
// peering health metric
healthy := 0
switch {
case status.NeverConnected:
case s.peerStreamServer.Tracker.IsHealthy(status):
healthy = 1
}
metricsImpl.SetGaugeWithLabels(leaderHealthyPeeringKeyDeprecated, float32(healthy), labels)
metricsImpl.SetGaugeWithLabels(leaderHealthyPeeringKey, float32(healthy), labels)
}
return nil
}
func (s *Server) runPeeringSync(ctx context.Context) error {
logger := s.logger.Named("peering-syncer")
cancelFns := make(map[string]context.CancelFunc)
retryLoopBackoff(ctx, func() error {
if err := s.syncPeeringsAndBlock(ctx, logger, cancelFns); err != nil {
return err
}
return nil
}, func(err error) {
s.logger.Error("error syncing peering streams from state store", "error", err)
})
return nil
}
func (s *Server) stopPeeringStreamSync() {
// will be a no-op when not started
s.leaderRoutineManager.Stop(peeringStreamsRoutineName)
s.leaderRoutineManager.Stop(peeringStreamsMetricsRoutineName)
}
// syncPeeringsAndBlock is a long-running goroutine that is responsible for watching
// changes to peerings in the state store and managing streams to those peers.
func (s *Server) syncPeeringsAndBlock(ctx context.Context, logger hclog.Logger, cancelFns map[string]context.CancelFunc) error {
// We have to be careful not to introduce a data race here. We want to
// compare the current known peerings in the state store with known
// connected streams to know when we should TERMINATE stray peerings.
//
// If you read the current peerings from the state store, then read the
// current established streams you could lose the data race and have the
// sequence of events be:
//
// 1. list peerings [A,B,C]
// 2. persist new peering [D]
// 3. accept new stream for [D]
// 4. list streams [A,B,C,D]
// 5. terminate [D]
//
// Which is wrong. If we instead ensure that (4) happens before (1), given
// that you can't get an established stream without first passing a "does
// this peering exist in the state store?" inquiry then this happens:
//
// 1. list streams [A,B,C]
// 2. list peerings [A,B,C]
// 3. persist new peering [D]
// 4. accept new stream for [D]
// 5. terminate []
//
// Or even this is fine:
//
// 1. list streams [A,B,C]
// 2. persist new peering [D]
// 3. accept new stream for [D]
// 4. list peerings [A,B,C,D]
// 5. terminate []
connectedStreams := s.peerStreamServer.ConnectedStreams()
state := s.fsm.State()
// Pull the state store contents and set up to block for changes.
ws := memdb.NewWatchSet()
ws.Add(state.AbandonCh())
ws.Add(ctx.Done())
_, peers, err := state.PeeringList(ws, *structs.NodeEnterpriseMetaInPartition(structs.WildcardSpecifier))
if err != nil {
return err
}
// TODO(peering) Adjust this debug info.
// Generate a UUID to trace different passes through this function.
seq, err := uuid.GenerateUUID()
if err != nil {
s.logger.Debug("failed to generate sequence uuid while syncing peerings")
}
logger.Trace("syncing new list of peers", "num_peers", len(peers), "sequence_id", seq)
// Stored tracks the unique set of peers that should be dialed.
// It is used to reconcile the list of active streams.
stored := make(map[string]struct{})
var merr *multierror.Error
// Create connections and streams to peers in the state store that do not have an active stream.
for _, peer := range peers {
logger.Trace("evaluating stored peer", "peer", peer.Name, "should_dial", peer.ShouldDial(), "sequence_id", seq)
if !peer.IsActive() {
// The peering was marked for deletion by ourselves or our peer, no need to dial or track them.
continue
}
// Track all active peerings,since the reconciliation loop below applies to the token generator as well.
stored[peer.ID] = struct{}{}
if !peer.ShouldDial() {
// We do not need to dial peerings where we generated the peering token.
continue
}
// We may have written this peering to the store to trigger xDS updates, but still in the process of establishing.
// If there isn't a secret yet, we're still trying to reach the other server.
logger.Trace("reading peering secret", "sequence_id", seq)
secret, err := s.fsm.State().PeeringSecretsRead(ws, peer.ID)
if err != nil {
return fmt.Errorf("failed to read secret for peering: %w", err)
}
if secret.GetStream().GetActiveSecretID() == "" {
continue
}
status, found := s.peerStreamServer.StreamStatus(peer.ID)
if found && status.Connected {
// Nothing to do when we already have an active stream to the peer.
// Updated data will only be used if the stream becomes disconnected
// since there's no need to tear down an active stream.
continue
}
logger.Trace("ensuring stream to peer", "peer_id", peer.ID, "sequence_id", seq)
if cancel, ok := cancelFns[peer.ID]; ok {
// If the peer is known but we're not connected, clean up the retry-er and start over.
// There may be new data in the state store that would enable us to get out of an error state.
logger.Trace("cancelling context to re-establish stream", "peer_id", peer.ID, "sequence_id", seq)
cancel()
}
if err := s.establishStream(ctx, logger, peer, secret, cancelFns); err != nil {
// TODO(peering): These errors should be reported in the peer status, otherwise they're only in the logs.
// Lockable status isn't available here though. Could report it via the peering.Service?
logger.Error("error establishing peering stream", "peer_id", peer.ID, "error", err)
merr = multierror.Append(merr, err)
// Continue on errors to avoid one bad peering from blocking the establishment and cleanup of others.
continue
}
}
logger.Trace("checking connected streams", "streams", connectedStreams, "sequence_id", seq)
// Clean up active streams of peerings that were deleted from the state store.
for stream, doneCh := range connectedStreams {
if _, ok := stored[stream]; ok {
// Active stream is in the state store, nothing to do.
continue
}
select {
case <-doneCh:
// channel is closed, do nothing to avoid a panic
default:
logger.Trace("tearing down stream for deleted peer", "peer_id", stream, "sequence_id", seq)
close(doneCh)
}
}
logger.Trace("blocking for changes", "sequence_id", seq)
// Block for any changes to the state store.
ws.WatchCtx(ctx)
logger.Trace("unblocked", "sequence_id", seq)
return merr.ErrorOrNil()
}
func (s *Server) establishStream(ctx context.Context,
logger hclog.Logger,
peer *pbpeering.Peering,
secret *pbpeering.PeeringSecrets,
cancelFns map[string]context.CancelFunc) error {
logger = logger.With("peer_name", peer.Name, "peer_id", peer.ID)
if peer.PeerID == "" {
return fmt.Errorf("expected PeerID to be non empty; the wrong end of peering is being dialed")
}
tlsOption, err := peer.TLSDialOption()
if err != nil {
return fmt.Errorf("failed to build TLS dial option from peering: %w", err)
}
if secret.GetStream().GetActiveSecretID() == "" {
return errors.New("missing stream secret for peering stream authorization, peering must be re-established")
}
logger.Trace("establishing stream to peer")
streamStatus, err := s.peerStreamServer.Tracker.Register(peer.ID)
if err != nil {
return fmt.Errorf("failed to register stream: %v", err)
}
streamCtx, cancel := context.WithCancel(ctx)
cancelFns[peer.ID] = cancel
// Start a goroutine to watch for updates to peer server addresses.
// The latest valid server address can be received from nextServerAddr.
nextServerAddr := make(chan string)
go s.watchAddresses(streamCtx, peer.ID, nextServerAddr)
// Establish a stream-specific retry so that retrying stream/conn errors isn't dependent on state store changes.
go retryLoopBackoffPeering(streamCtx, logger, func() error {
// Try a new address on each iteration by advancing the ring buffer on errors.
addr, stillOpen := <-nextServerAddr
if !stillOpen {
// If the channel was closed that means the context was canceled, so we return.
return streamCtx.Err()
}
opts := []grpc.DialOption{
tlsOption,
// TODO(peering): Use a grpc.WithStatsHandler here.
// This should wait until the grpc-external server is wired up with a stats handler in NET-50.
// For keep alive parameters there is a larger comment in ClientConnPool.dial about that.
grpc.WithKeepaliveParams(keepalive.ClientParameters{
Time: 30 * time.Second,
Timeout: 10 * time.Second,
// send keepalive pings even if there is no active streams
PermitWithoutStream: true,
}),
grpc.WithDefaultCallOptions(grpc.MaxCallSendMsgSize(50 * 1024 * 1024)),
}
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logger.Trace("dialing peer", "addr", addr)
conn, err := grpc.DialContext(streamCtx, addr, opts...)
if err != nil {
return fmt.Errorf("failed to dial: %w", err)
}
defer conn.Close()
client := pbpeerstream.NewPeerStreamServiceClient(conn)
stream, err := client.StreamResources(streamCtx)
if err != nil {
return err
}
initialReq := &pbpeerstream.ReplicationMessage{
Payload: &pbpeerstream.ReplicationMessage_Open_{
Open: &pbpeerstream.ReplicationMessage_Open{
PeerID: peer.PeerID,
StreamSecretID: secret.GetStream().GetActiveSecretID(),
Remote: &pbpeering.RemoteInfo{
Partition: peer.Partition,
Datacenter: s.config.Datacenter,
},
},
},
}
if err := stream.Send(initialReq); err != nil {
return fmt.Errorf("failed to send initial stream request: %w", err)
}
streamReq := peerstream.HandleStreamRequest{
LocalID: peer.ID,
RemoteID: peer.PeerID,
PeerName: peer.Name,
Partition: peer.Partition,
Stream: stream,
}
err = s.peerStreamServer.HandleStream(streamReq)
// A nil error indicates that the peering was deleted and the stream needs to be gracefully shutdown.
if err == nil {
stream.CloseSend()
s.peerStreamServer.DrainStream(streamReq)
cancel()
logger.Info("closed outbound stream")
}
return err
}, func(err error) {
// TODO(peering): why are we using TrackSendError here? This could also be a receive error.
streamStatus.TrackSendError(err.Error())
switch {
case isErrCode(err, codes.FailedPrecondition):
logger.Debug("stream disconnected due to 'failed precondition' error; reconnecting",
"error", err)
case isErrCode(err, codes.ResourceExhausted):
logger.Debug("stream disconnected due to 'resource exhausted' error; reconnecting",
"error", err)
case errors.Is(err, context.Canceled) || errors.Is(err, context.DeadlineExceeded):
logger.Debug("stream context was canceled", "error", err)
case err != nil:
logger.Error("error managing peering stream", "error", err)
}
}, peeringRetryTimeout)
return nil
}
// watchAddresses sends an up-to-date address to nextServerAddr.
// These could be either remote peer server addresses, or local mesh gateways.
// The function loads the addresses into a ring buffer and cycles through them until:
// 1. streamCtx is cancelled (peer is deleted or we're re-establishing the stream with new data)
// 2. the peer, Mesh config entry, or (optionally) mesh gateway address set is modified, and the watchset fires.
//
// In case (2) we re-fetch all the data sources and rebuild the ring buffer.
// In the event that the PeerThroughMeshGateways is set in the Mesh entry, we front-load the ring buffer with
// local mesh gateway addresses, so we can try those first, with the option to fall back to remote server addresses.
func (s *Server) watchAddresses(ctx context.Context, peerID string, nextServerAddr chan<- string) {
defer close(nextServerAddr)
var ringbuf *ring.Ring
var ws memdb.WatchSet
fetchAddresses := func() error {
// Re-instantiate ws since it can only be watched once.
ws = memdb.NewWatchSet()
newRing, _, err := s.peeringBackend.GetDialAddresses(s.logger, ws, peerID)
if err != nil {
return fmt.Errorf("failed to fetch updated addresses to dial peer: %w", err)
}
ringbuf = newRing
return nil
}
// Initialize the first ring buffer.
if err := fetchAddresses(); err != nil {
s.logger.Warn("error fetching addresses", "peer_id", peerID, "error", err)
}
for {
select {
case nextServerAddr <- ringbuf.Value.(string):
ringbuf = ringbuf.Next()
case err := <-ws.WatchCh(ctx):
if err != nil {
// Context was cancelled.
return
}
// Watch fired so we re-fetch the necessary addresses and replace the ring buffer.
if err := fetchAddresses(); err != nil {
s.logger.Warn("watch for new addresses fired but the address list to dial may not have been updated",
"peer_id", peerID,
"error", err)
}
}
}
}
func (s *Server) startPeeringDeferredDeletion(ctx context.Context) {
s.leaderRoutineManager.Start(ctx, peeringDeletionRoutineName, s.runPeeringDeletions)
}
// runPeeringDeletions watches for peerings marked for deletions and then cleans up data for them.
func (s *Server) runPeeringDeletions(ctx context.Context) error {
logger := s.loggers.Named(logging.Peering)
// This limiter's purpose is to control the rate of raft applies caused by the deferred deletion
// process. This includes deletion of the peerings themselves in addition to any peering data
raftLimiter := rate.NewLimiter(defaultDeletionApplyRate, int(defaultDeletionApplyRate))
for {
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select {
case <-ctx.Done():
return nil
default:
}
ws := memdb.NewWatchSet()
state := s.fsm.State()
_, peerings, err := s.fsm.State().PeeringListDeleted(ws)
if err != nil {
logger.Warn("encountered an error while searching for deleted peerings", "error", err)
continue
}
if len(peerings) == 0 {
ws.Add(state.AbandonCh())
// wait for a peering to be deleted or the routine to be cancelled
if err := ws.WatchCtx(ctx); err != nil {
return err
}
continue
}
for _, p := range peerings {
s.removePeeringAndData(ctx, logger, raftLimiter, p)
}
}
}
// removepPeeringAndData removes data imported for a peering and the peering itself.
func (s *Server) removePeeringAndData(ctx context.Context, logger hclog.Logger, limiter *rate.Limiter, peer *pbpeering.Peering) {
logger = logger.With("peer_name", peer.Name, "peer_id", peer.ID)
entMeta := *structs.NodeEnterpriseMetaInPartition(peer.Partition)
// First delete all imported data.
// By deleting all imported nodes we also delete all services and checks registered on them.
if err := s.deleteAllNodes(ctx, limiter, entMeta, peer.Name); err != nil {
logger.Error("Failed to remove Nodes for peer", "error", err)
return
}
if err := s.deleteTrustBundleFromPeer(ctx, limiter, entMeta, peer.Name); err != nil {
logger.Error("Failed to remove trust bundle for peer", "error", err)
return
}
if err := limiter.Wait(ctx); err != nil {
return
}
if peer.State == pbpeering.PeeringState_TERMINATED {
// For peerings terminated by our peer we only clean up the local data, we do not delete the peering itself.
// This is to avoid a situation where the peering disappears without the local operator's knowledge.
return
}
// Once all imported data is deleted, the peering itself is also deleted.
req := &pbpeering.PeeringDeleteRequest{
Name: peer.Name,
Partition: acl.PartitionOrDefault(peer.Partition),
}
_, err := s.raftApplyProtobuf(structs.PeeringDeleteType, req)
if err != nil {
logger.Error("failed to apply full peering deletion", "error", err)
return
}
}
// deleteAllNodes will delete all nodes in a partition or all nodes imported from a given peer name.
func (s *Server) deleteAllNodes(ctx context.Context, limiter *rate.Limiter, entMeta acl.EnterpriseMeta, peerName string) error {
// Same as ACL batch upsert size
nodeBatchSizeBytes := 256 * 1024
_, nodes, err := s.fsm.State().NodeDump(nil, &entMeta, peerName)
if err != nil {
return err
}
if len(nodes) == 0 {
return nil
}
i := 0
for {
var ops structs.TxnOps
for batchSize := 0; batchSize < nodeBatchSizeBytes && i < len(nodes); i++ {
entry := nodes[i]
op := structs.TxnOp{
Node: &structs.TxnNodeOp{
Verb: api.NodeDelete,
Node: structs.Node{
Node: entry.Node,
Partition: entry.Partition,
PeerName: entry.PeerName,
},
},
}
ops = append(ops, &op)
// Add entries to the transaction until it reaches the max batch size
batchSize += len(entry.Node) + len(entry.Partition) + len(entry.PeerName)
}
// Send each batch as a TXN Req to avoid sending one at a time
req := structs.TxnRequest{
Datacenter: s.config.Datacenter,
Ops: ops,
}
if len(req.Ops) > 0 {
if err := limiter.Wait(ctx); err != nil {
return err
}
_, err := s.raftApplyMsgpack(structs.TxnRequestType, &req)
if err != nil {
return err
}
} else {
break
}
}
return nil
}
// deleteTrustBundleFromPeer deletes the trust bundle imported from a peer, if present.
func (s *Server) deleteTrustBundleFromPeer(ctx context.Context, limiter *rate.Limiter, entMeta acl.EnterpriseMeta, peerName string) error {
_, bundle, err := s.fsm.State().PeeringTrustBundleRead(nil, state.Query{Value: peerName, EnterpriseMeta: entMeta})
if err != nil {
return err
}
if bundle == nil {
return nil
}
if err := limiter.Wait(ctx); err != nil {
return err
}
req := &pbpeering.PeeringTrustBundleDeleteRequest{
Name: peerName,
Partition: entMeta.PartitionOrDefault(),
}
_, err = s.raftApplyProtobuf(structs.PeeringTrustBundleDeleteType, req)
return err
}
// retryLoopBackoffPeering re-runs loopFn with a backoff on error. errFn is run whenever
// loopFn returns an error. retryTimeFn is used to calculate the time between retries on error.
// It is passed the number of errors in a row that loopFn has returned and the latest error
// from loopFn.
//
// This function is modelled off of retryLoopBackoffHandleSuccess but is specific to peering
// because peering needs to use different retry times depending on which error is returned.
// This function doesn't use a rate limiter, unlike retryLoopBackoffHandleSuccess, because
// the rate limiter is only needed in the success case when loopFn returns nil and we want to
// loop again. In the peering case, we exit on a successful loop so we don't need the limter.
func retryLoopBackoffPeering(ctx context.Context, logger hclog.Logger, loopFn func() error, errFn func(error),
retryTimeFn func(failedAttempts uint, loopErr error) time.Duration) {
var failedAttempts uint
var err error
for {
if err = loopFn(); err != nil {
errFn(err)
if failedAttempts < math.MaxUint {
failedAttempts++
}
retryTime := retryTimeFn(failedAttempts, err)
logger.Trace("in connection retry backoff", "delay", retryTime)
timer := time.NewTimer(retryTime)
select {
case <-ctx.Done():
timer.Stop()
return
case <-timer.C:
}
continue
}
return
}
}
// peeringRetryTimeout returns the time that should be waited between re-establishing a peering
// connection after an error. We follow the default backoff from retryLoopBackoff
// unless the error is a "failed precondition" error in which case we retry much more quickly.
// Retrying quickly is important in the case of a failed precondition error because we expect it to resolve
// quickly. For example in the case of connecting with a follower through a load balancer, we just need to retry
// until our request lands on a leader.
func peeringRetryTimeout(failedAttempts uint, loopErr error) time.Duration {
if loopErr != nil && isErrCode(loopErr, codes.FailedPrecondition) {
// Wait a constant time for the first number of retries.
if failedAttempts <= maxFastConnRetries {
return fastConnRetryTimeout
}
// From here, follow an exponential backoff maxing out at maxFastRetryBackoff.
// The below equation multiples the constantRetryTimeout by 2^n where n is the number of failed attempts
// we're on, starting at 1 now that we're past our maxFastConnRetries.
// For example if fastConnRetryTimeout == 8ms and maxFastConnRetries == 5, then at 6 failed retries
// we'll do 8ms * 2^1 = 16ms, then 8ms * 2^2 = 32ms, etc.
ms := fastConnRetryTimeout * (1 << (failedAttempts - maxFastConnRetries))
if ms > maxFastRetryBackoff {
return maxFastRetryBackoff
}
return ms
}
// if the message sent is too large probably should not retry at all
if loopErr != nil && isErrCode(loopErr, codes.ResourceExhausted) {
return maxFastRetryBackoff
}
// Else we go with the default backoff from retryLoopBackoff.
if (1 << failedAttempts) < maxRetryBackoff {
return (1 << failedAttempts) * time.Second
}
return time.Duration(maxRetryBackoff) * time.Second
}
// isErrCode returns true if err is a gRPC error with given error code.
func isErrCode(err error, code codes.Code) bool {
if err == nil {
return false
}
// Handle wrapped errors, since status.FromError does a naive assertion.
var statusErr interface {
GRPCStatus() *grpcstatus.Status
}
if errors.As(err, &statusErr) {
return statusErr.GRPCStatus().Code() == code
}
grpcErr, ok := grpcstatus.FromError(err)
if !ok {
return false
}
return grpcErr.Code() == code
}