// Copyright (c) HashiCorp, Inc. // SPDX-License-Identifier: MPL-2.0 package consul import ( "context" "net" "sync" "github.com/hashicorp/go-hclog" "github.com/hashicorp/raft" autopilot "github.com/hashicorp/raft-autopilot" "github.com/hashicorp/consul/agent/pool" "github.com/hashicorp/consul/agent/structs" ) // StatsFetcher has two functions for autopilot. First, lets us fetch all the // stats in parallel so we are taking a sample as close to the same time as // possible, since we are comparing time-sensitive info for the health check. // Second, it bounds the time so that one slow RPC can't hold up the health // check loop; as a side effect of how it implements this, it also limits to // a single in-flight RPC to any given server, so goroutines don't accumulate // as we run the health check fairly frequently. type StatsFetcher struct { logger hclog.Logger pool *pool.ConnPool datacenter string inflight map[raft.ServerID]struct{} inflightLock sync.Mutex } // NewStatsFetcher returns a stats fetcher. func NewStatsFetcher(logger hclog.Logger, pool *pool.ConnPool, datacenter string) *StatsFetcher { return &StatsFetcher{ logger: logger, pool: pool, datacenter: datacenter, inflight: make(map[raft.ServerID]struct{}), } } // fetch does the RPC to fetch the server stats from a single server. We don't // cancel this when the context is canceled because we only want one in-flight // RPC to each server, so we let it finish and then clean up the in-flight // tracking. func (f *StatsFetcher) fetch(server *autopilot.Server, replyCh chan *autopilot.ServerStats) { var args EmptyReadRequest var reply structs.RaftStats // defer some cleanup to notify everything else that the fetching is no longer occurring // this is easier than trying to make the conditionals line up just right. defer func() { f.inflightLock.Lock() delete(f.inflight, server.ID) f.inflightLock.Unlock() }() addr, err := net.ResolveTCPAddr("tcp", string(server.Address)) if err != nil { f.logger.Warn("error resolving TCP address for server", "address", server.Address, "error", err) return } err = f.pool.RPC(f.datacenter, server.Name, addr, "Status.RaftStats", &args, &reply) if err != nil { f.logger.Warn("error getting server health from server", "server", server.Name, "error", err, ) return } replyCh <- reply.ToAutopilotServerStats() } // Fetch will attempt to query all the servers in parallel. func (f *StatsFetcher) Fetch(ctx context.Context, servers map[raft.ServerID]*autopilot.Server) map[raft.ServerID]*autopilot.ServerStats { type workItem struct { server *autopilot.Server replyCh chan *autopilot.ServerStats } // Skip any servers that have inflight requests. var work []*workItem f.inflightLock.Lock() for _, server := range servers { if _, ok := f.inflight[server.ID]; ok { f.logger.Warn("error getting server health from server", "server", server.Name, "error", "last request still outstanding", ) } else { workItem := &workItem{ server: server, replyCh: make(chan *autopilot.ServerStats, 1), } work = append(work, workItem) f.inflight[server.ID] = struct{}{} go f.fetch(workItem.server, workItem.replyCh) } } f.inflightLock.Unlock() // Now wait for the results to come in, or for the context to be // canceled. replies := make(map[raft.ServerID]*autopilot.ServerStats) for _, workItem := range work { // Drain the reply first if there is one. select { case reply := <-workItem.replyCh: replies[workItem.server.ID] = reply continue default: } select { case reply := <-workItem.replyCh: replies[workItem.server.ID] = reply case <-ctx.Done(): f.logger.Warn("error getting server health from server", "server", workItem.server.Name, "error", ctx.Err(), ) f.inflightLock.Lock() delete(f.inflight, workItem.server.ID) f.inflightLock.Unlock() } } return replies }