package consul import ( "fmt" "io" "net" "os" "time" "github.com/hashicorp/consul/tlsutil" "github.com/hashicorp/memberlist" "github.com/hashicorp/raft" "github.com/hashicorp/serf/serf" ) const ( DefaultDC = "dc1" DefaultLANSerfPort = 8301 DefaultWANSerfPort = 8302 // See docs/guides/performance.html for information on how this value // was obtained. DefaultRaftMultiplier uint = 5 ) var ( DefaultRPCAddr = &net.TCPAddr{IP: net.ParseIP("0.0.0.0"), Port: 8300} ) // ProtocolVersionMap is the mapping of Consul protocol versions // to Serf protocol versions. We mask the Serf protocols using // our own protocol version. var protocolVersionMap map[uint8]uint8 func init() { protocolVersionMap = map[uint8]uint8{ 1: 4, 2: 4, 3: 4, } } // Config is used to configure the server type Config struct { // Bootstrap mode is used to bring up the first Consul server. // It is required so that it can elect a leader without any // other nodes being present Bootstrap bool // BootstrapExpect mode is used to automatically bring up a collection of // Consul servers. This can be used to automatically bring up a collection // of nodes. BootstrapExpect int // Datacenter is the datacenter this Consul server represents Datacenter string // DataDir is the directory to store our state in DataDir string // DevMode is used to enable a development server mode. DevMode bool // Node name is the name we use to advertise. Defaults to hostname. NodeName string // Domain is the DNS domain for the records. Defaults to "consul." Domain string // RaftConfig is the configuration used for Raft in the local DC RaftConfig *raft.Config // RPCAddr is the RPC address used by Consul. This should be reachable // by the WAN and LAN RPCAddr *net.TCPAddr // RPCAdvertise is the address that is advertised to other nodes for // the RPC endpoint. This can differ from the RPC address, if for example // the RPCAddr is unspecified "0.0.0.0:8300", but this address must be // reachable RPCAdvertise *net.TCPAddr // SerfLANConfig is the configuration for the intra-dc serf SerfLANConfig *serf.Config // SerfWANConfig is the configuration for the cross-dc serf SerfWANConfig *serf.Config // ReconcileInterval controls how often we reconcile the strongly // consistent store with the Serf info. This is used to handle nodes // that are force removed, as well as intermittent unavailability during // leader election. ReconcileInterval time.Duration // LogOutput is the location to write logs to. If this is not set, // logs will go to stderr. LogOutput io.Writer // ProtocolVersion is the protocol version to speak. This must be between // ProtocolVersionMin and ProtocolVersionMax. ProtocolVersion uint8 // VerifyIncoming is used to verify the authenticity of incoming connections. // This means that TCP requests are forbidden, only allowing for TLS. TLS connections // must match a provided certificate authority. This can be used to force client auth. VerifyIncoming bool // VerifyOutgoing is used to verify the authenticity of outgoing connections. // This means that TLS requests are used, and TCP requests are not made. TLS connections // must match a provided certificate authority. This is used to verify authenticity of // server nodes. VerifyOutgoing bool // VerifyServerHostname is used to enable hostname verification of servers. This // ensures that the certificate presented is valid for server... // This prevents a compromised client from being restarted as a server, and then // intercepting request traffic as well as being added as a raft peer. This should be // enabled by default with VerifyOutgoing, but for legacy reasons we cannot break // existing clients. VerifyServerHostname bool // CAFile is a path to a certificate authority file. This is used with VerifyIncoming // or VerifyOutgoing to verify the TLS connection. CAFile string // CertFile is used to provide a TLS certificate that is used for serving TLS connections. // Must be provided to serve TLS connections. CertFile string // KeyFile is used to provide a TLS key that is used for serving TLS connections. // Must be provided to serve TLS connections. KeyFile string // ServerName is used with the TLS certificate to ensure the name we // provide matches the certificate ServerName string // RejoinAfterLeave controls our interaction with Serf. // When set to false (default), a leave causes a Consul to not rejoin // the cluster until an explicit join is received. If this is set to // true, we ignore the leave, and rejoin the cluster on start. RejoinAfterLeave bool // Build is a string that is gossiped around, and can be used to help // operators track which versions are actively deployed Build string // ACLToken is the default token to use when making a request. // If not provided, the anonymous token is used. This enables // backwards compatibility as well. ACLToken string // ACLMasterToken is used to bootstrap the ACL system. It should be specified // on the servers in the ACLDatacenter. When the leader comes online, it ensures // that the Master token is available. This provides the initial token. ACLMasterToken string // ACLDatacenter provides the authoritative datacenter for ACL // tokens. If not provided, ACL verification is disabled. ACLDatacenter string // ACLTTL controls the time-to-live of cached ACL policies. // It can be set to zero to disable caching, but this adds // a substantial cost. ACLTTL time.Duration // ACLDefaultPolicy is used to control the ACL interaction when // there is no defined policy. This can be "allow" which means // ACLs are used to black-list, or "deny" which means ACLs are // white-lists. ACLDefaultPolicy string // ACLDownPolicy controls the behavior of ACLs if the ACLDatacenter // cannot be contacted. It can be either "deny" to deny all requests, // or "extend-cache" which ignores the ACLCacheInterval and uses // cached policies. If a policy is not in the cache, it acts like deny. // "allow" can be used to allow all requests. This is not recommended. ACLDownPolicy string // ACLReplicationToken is used to fetch ACLs from the ACLDatacenter in // order to replicate them locally. Setting this to a non-empty value // also enables replication. Replication is only available in datacenters // other than the ACLDatacenter. ACLReplicationToken string // ACLReplicationInterval is the interval at which replication passes // will occur. Queries to the ACLDatacenter may block, so replication // can happen less often than this, but the interval forms the upper // limit to how fast we will go if there was constant ACL churn on the // remote end. ACLReplicationInterval time.Duration // ACLReplicationApplyLimit is the max number of replication-related // apply operations that we allow during a one second period. This is // used to limit the amount of Raft bandwidth used for replication. ACLReplicationApplyLimit int // TombstoneTTL is used to control how long KV tombstones are retained. // This provides a window of time where the X-Consul-Index is monotonic. // Outside this window, the index may not be monotonic. This is a result // of a few trade offs: // 1) The index is defined by the data view and not globally. This is a // performance optimization that prevents any write from incrementing the // index for all data views. // 2) Tombstones are not kept indefinitely, since otherwise storage required // is also monotonic. This prevents deletes from reducing the disk space // used. // In theory, neither of these are intrinsic limitations, however for the // purposes of building a practical system, they are reasonable trade offs. // // It is also possible to set this to an incredibly long time, thereby // simulating infinite retention. This is not recommended however. // TombstoneTTL time.Duration // TombstoneTTLGranularity is used to control how granular the timers are // for the Tombstone GC. This is used to batch the GC of many keys together // to reduce overhead. It is unlikely a user would ever need to tune this. TombstoneTTLGranularity time.Duration // Minimum Session TTL SessionTTLMin time.Duration // ServerUp callback can be used to trigger a notification that // a Consul server is now up and known about. ServerUp func() // UserEventHandler callback can be used to handle incoming // user events. This function should not block. UserEventHandler func(serf.UserEvent) // DisableCoordinates controls features related to network coordinates. DisableCoordinates bool // CoordinateUpdatePeriod controls how long a server batches coordinate // updates before applying them in a Raft transaction. A larger period // leads to fewer Raft transactions, but also the stored coordinates // being more stale. CoordinateUpdatePeriod time.Duration // CoordinateUpdateBatchSize controls the maximum number of updates a // server batches before applying them in a Raft transaction. CoordinateUpdateBatchSize int // CoordinateUpdateMaxBatches controls the maximum number of batches we // are willing to apply in one period. After this limit we will issue a // warning and discard the remaining updates. CoordinateUpdateMaxBatches int // RPCHoldTimeout is how long an RPC can be "held" before it is errored. // This is used to paper over a loss of leadership by instead holding RPCs, // so that the caller experiences a slow response rather than an error. // This period is meant to be long enough for a leader election to take // place, and a small jitter is applied to avoid a thundering herd. RPCHoldTimeout time.Duration } // CheckVersion is used to check if the ProtocolVersion is valid func (c *Config) CheckVersion() error { if c.ProtocolVersion < ProtocolVersionMin { return fmt.Errorf("Protocol version '%d' too low. Must be in range: [%d, %d]", c.ProtocolVersion, ProtocolVersionMin, ProtocolVersionMax) } else if c.ProtocolVersion > ProtocolVersionMax { return fmt.Errorf("Protocol version '%d' too high. Must be in range: [%d, %d]", c.ProtocolVersion, ProtocolVersionMin, ProtocolVersionMax) } return nil } // CheckACL is used to sanity check the ACL configuration func (c *Config) CheckACL() error { switch c.ACLDefaultPolicy { case "allow": case "deny": default: return fmt.Errorf("Unsupported default ACL policy: %s", c.ACLDefaultPolicy) } switch c.ACLDownPolicy { case "allow": case "deny": case "extend-cache": default: return fmt.Errorf("Unsupported down ACL policy: %s", c.ACLDownPolicy) } return nil } // DefaultConfig is used to return a sane default configuration func DefaultConfig() *Config { hostname, err := os.Hostname() if err != nil { panic(err) } conf := &Config{ Datacenter: DefaultDC, NodeName: hostname, RPCAddr: DefaultRPCAddr, RaftConfig: raft.DefaultConfig(), SerfLANConfig: serf.DefaultConfig(), SerfWANConfig: serf.DefaultConfig(), ReconcileInterval: 60 * time.Second, ProtocolVersion: ProtocolVersion2Compatible, ACLTTL: 30 * time.Second, ACLDefaultPolicy: "allow", ACLDownPolicy: "extend-cache", ACLReplicationInterval: 30 * time.Second, ACLReplicationApplyLimit: 100, // ops / sec TombstoneTTL: 15 * time.Minute, TombstoneTTLGranularity: 30 * time.Second, SessionTTLMin: 10 * time.Second, DisableCoordinates: false, // These are tuned to provide a total throughput of 128 updates // per second. If you update these, you should update the client- // side SyncCoordinateRateTarget parameter accordingly. CoordinateUpdatePeriod: 5 * time.Second, CoordinateUpdateBatchSize: 128, CoordinateUpdateMaxBatches: 5, // Hold an RPC for up to 5 seconds by default RPCHoldTimeout: 5 * time.Second, } // Increase our reap interval to 3 days instead of 24h. conf.SerfLANConfig.ReconnectTimeout = 3 * 24 * time.Hour conf.SerfWANConfig.ReconnectTimeout = 3 * 24 * time.Hour // WAN Serf should use the WAN timing, since we are using it // to communicate between DC's conf.SerfWANConfig.MemberlistConfig = memberlist.DefaultWANConfig() // Ensure we don't have port conflicts conf.SerfLANConfig.MemberlistConfig.BindPort = DefaultLANSerfPort conf.SerfWANConfig.MemberlistConfig.BindPort = DefaultWANSerfPort // Enable interoperability with unversioned Raft library, and don't // start using new ID-based features yet. conf.RaftConfig.ProtocolVersion = 1 conf.ScaleRaft(DefaultRaftMultiplier) // Disable shutdown on removal conf.RaftConfig.ShutdownOnRemove = false return conf } // ScaleRaft sets the config to have Raft timing parameters scaled by the given // performance multiplier. This is done in an idempotent way so it's not tricky // to call this when composing configurations and potentially calling this // multiple times on the same structure. func (c *Config) ScaleRaft(raftMultRaw uint) { raftMult := time.Duration(raftMultRaw) def := raft.DefaultConfig() c.RaftConfig.HeartbeatTimeout = raftMult * def.HeartbeatTimeout c.RaftConfig.ElectionTimeout = raftMult * def.ElectionTimeout c.RaftConfig.CommitTimeout = raftMult * def.CommitTimeout c.RaftConfig.LeaderLeaseTimeout = raftMult * def.LeaderLeaseTimeout } func (c *Config) tlsConfig() *tlsutil.Config { tlsConf := &tlsutil.Config{ VerifyIncoming: c.VerifyIncoming, VerifyOutgoing: c.VerifyOutgoing, VerifyServerHostname: c.VerifyServerHostname, CAFile: c.CAFile, CertFile: c.CertFile, KeyFile: c.KeyFile, NodeName: c.NodeName, ServerName: c.ServerName, Domain: c.Domain, } return tlsConf }