consul/agent/config/runtime.go

1795 lines
62 KiB
Go

package config
import (
"fmt"
"net"
"reflect"
"strings"
"time"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/api"
"github.com/hashicorp/consul/lib"
"github.com/hashicorp/consul/tlsutil"
"github.com/hashicorp/consul/types"
"golang.org/x/time/rate"
)
type RuntimeSOAConfig struct {
Refresh uint32 // 3600 by default
Retry uint32 // 600
Expire uint32 // 86400
Minttl uint32 // 0,
}
// RuntimeConfig specifies the configuration the consul agent actually
// uses. Is is derived from one or more Config structures which can come
// from files, flags and/or environment variables.
type RuntimeConfig struct {
// non-user configurable values
AEInterval time.Duration
CheckDeregisterIntervalMin time.Duration
CheckReapInterval time.Duration
SegmentLimit int
SegmentNameLimit int
SyncCoordinateRateTarget float64
SyncCoordinateIntervalMin time.Duration
Revision string
Version string
VersionPrerelease string
// consul config
ConsulCoordinateUpdateMaxBatches int
ConsulCoordinateUpdateBatchSize int
ConsulCoordinateUpdatePeriod time.Duration
ConsulRaftElectionTimeout time.Duration
ConsulRaftHeartbeatTimeout time.Duration
ConsulRaftLeaderLeaseTimeout time.Duration
ConsulServerHealthInterval time.Duration
// ACLDisabledTTL is used by agents to determine how long they will
// wait to check again with the servers if they discover ACLs are not
// enabled. (not user configurable)
//
// hcl: acl.disabled_ttl = "duration"
ACLDisabledTTL time.Duration
// ACLsEnabled is used to determine whether ACLs should be enabled
//
// hcl: acl.enabled = boolean
ACLsEnabled bool
// ACLAgentMasterToken is a special token that has full read and write
// privileges for this agent, and can be used to call agent endpoints
// when no servers are available.
//
// hcl: acl.tokens.agent_master = string
ACLAgentMasterToken string
// ACLAgentToken is the default token used to make requests for the agent
// itself, such as for registering itself with the catalog. If not
// configured, the 'acl_token' will be used.
//
// hcl: acl.tokens.agent = string
ACLAgentToken string
// ACLDatacenter is the central datacenter that holds authoritative
// ACL records. This must be the same for the entire cluster.
// If this is not set, ACLs are not enabled. Off by default.
//
// hcl: acl_datacenter = string
ACLDatacenter string
// 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.
//
// hcl: acl.default_policy = ("allow"|"deny")
ACLDefaultPolicy string
// ACLDownPolicy is used to control the ACL interaction when we cannot
// reach the ACLDatacenter and the token is not in the cache.
// There are the following modes:
// * allow - Allow all requests
// * deny - Deny all requests
// * extend-cache - Ignore the cache expiration, and allow cached
// ACL's to be used to service requests. This
// is the default. If the ACL is not in the cache,
// this acts like deny.
// * async-cache - Same behavior as extend-cache, but perform ACL
// Lookups asynchronously when cache TTL is expired.
//
// hcl: acl.down_policy = ("allow"|"deny"|"extend-cache"|"async-cache")
ACLDownPolicy string
// DEPRECATED (ACL-Legacy-Compat)
// ACLEnforceVersion8 is used to gate a set of ACL policy features that
// are opt-in prior to Consul 0.8 and opt-out in Consul 0.8 and later.
//
// hcl: acl_enforce_version_8 = (true|false)
ACLEnforceVersion8 bool
// ACLEnableKeyListPolicy is used to opt-in to the "list" policy added to
// KV ACLs in Consul 1.0.
//
// See https://www.consul.io/docs/guides/acl.html#list-policy-for-keys for
// more details.
//
// hcl: acl.enable_key_list_policy = (true|false)
ACLEnableKeyListPolicy bool
// 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.
//
// hcl: acl.tokens.master = string
ACLMasterToken string
// ACLReplicationToken is used to replicate data locally from the
// PrimaryDatacenter. Replication is only available on servers in
// datacenters other than the PrimaryDatacenter
//
// DEPRECATED (ACL-Legacy-Compat): Setting this to a non-empty value
// also enables legacy ACL replication if ACLs are enabled and in legacy mode.
//
// hcl: acl.tokens.replication = string
ACLReplicationToken string
// ACLtokenReplication is used to indicate that both tokens and policies
// should be replicated instead of just policies
//
// hcl: acl.token_replication = boolean
ACLTokenReplication bool
// ACLTokenTTL is used to control the time-to-live of cached ACL tokens. This has
// a major impact on performance. By default, it is set to 30 seconds.
//
// hcl: acl.policy_ttl = "duration"
ACLTokenTTL time.Duration
// ACLPolicyTTL is used to control the time-to-live of cached ACL policies. This has
// a major impact on performance. By default, it is set to 30 seconds.
//
// hcl: acl.token_ttl = "duration"
ACLPolicyTTL time.Duration
// ACLRoleTTL is used to control the time-to-live of cached ACL roles. This has
// a major impact on performance. By default, it is set to 30 seconds.
//
// hcl: acl.role_ttl = "duration"
ACLRoleTTL time.Duration
// ACLToken is the default token used to make requests if a per-request
// token is not provided. If not configured the 'anonymous' token is used.
//
// hcl: acl.tokens.default = string
ACLToken string
// ACLEnableTokenPersistence determines whether or not tokens set via the agent HTTP API
// should be persisted to disk and reloaded when an agent restarts.
ACLEnableTokenPersistence bool
// AutopilotCleanupDeadServers enables the automatic cleanup of dead servers when new ones
// are added to the peer list. Defaults to true.
//
// hcl: autopilot { cleanup_dead_servers = (true|false) }
AutopilotCleanupDeadServers bool
// AutopilotDisableUpgradeMigration will disable Autopilot's upgrade migration
// strategy of waiting until enough newer-versioned servers have been added to the
// cluster before promoting them to voters. (Enterprise-only)
//
// hcl: autopilot { disable_upgrade_migration = (true|false)
AutopilotDisableUpgradeMigration bool
// AutopilotLastContactThreshold is the limit on the amount of time a server can go
// without leader contact before being considered unhealthy.
//
// hcl: autopilot { last_contact_threshold = "duration" }
AutopilotLastContactThreshold time.Duration
// AutopilotMaxTrailingLogs is the amount of entries in the Raft Log that a server can
// be behind before being considered unhealthy. The value must be positive.
//
// hcl: autopilot { max_trailing_logs = int }
AutopilotMaxTrailingLogs int
// AutopilotMinQuorum sets the minimum number of servers required in a cluster
// before autopilot can prune dead servers.
//
//hcl: autopilot { min_quorum = int }
AutopilotMinQuorum uint
// AutopilotRedundancyZoneTag is the Meta tag to use for separating servers
// into zones for redundancy. If left blank, this feature will be disabled.
// (Enterprise-only)
//
// hcl: autopilot { redundancy_zone_tag = string }
AutopilotRedundancyZoneTag string
// AutopilotServerStabilizationTime is the minimum amount of time a server must be
// in a stable, healthy state before it can be added to the cluster. Only
// applicable with Raft protocol version 3 or higher.
//
// hcl: autopilot { server_stabilization_time = "duration" }
AutopilotServerStabilizationTime time.Duration
// AutopilotUpgradeVersionTag is the node tag to use for version info when
// performing upgrade migrations. If left blank, the Consul version will be used.
//
// (Enterprise-only)
//
// hcl: autopilot { upgrade_version_tag = string }
AutopilotUpgradeVersionTag string
// DNSAllowStale is used to enable lookups with stale
// data. This gives horizontal read scalability since
// any Consul server can service the query instead of
// only the leader.
//
// hcl: dns_config { allow_stale = (true|false) }
DNSAllowStale bool
// DNSARecordLimit is used to limit the maximum number of DNS Resource
// Records returned in the ANSWER section of a DNS response for A or AAAA
// records for both UDP and TCP queries.
//
// This is not normally useful and will be limited based on the querying
// protocol, however systems that implemented §6 Rule 9 in RFC3484
// may want to set this to `1` in order to subvert §6 Rule 9 and
// re-obtain the effect of randomized resource records (i.e. each
// answer contains only one IP, but the IP changes every request).
// RFC3484 sorts answers in a deterministic order, which defeats the
// purpose of randomized DNS responses. This RFC has been obsoleted
// by RFC6724 and restores the desired behavior of randomized
// responses, however a large number of Linux hosts using glibc(3)
// implemented §6 Rule 9 and may need this option (e.g. CentOS 5-6,
// Debian Squeeze, etc).
//
// hcl: dns_config { a_record_limit = int }
DNSARecordLimit int
// DNSDisableCompression is used to control whether DNS responses are
// compressed. In Consul 0.7 this was turned on by default and this
// config was added as an opt-out.
//
// hcl: dns_config { disable_compression = (true|false) }
DNSDisableCompression bool
// DNSDomain is the DNS domain for the records. Should end with a dot.
// Defaults to "consul."
//
// hcl: domain = string
// flag: -domain string
DNSDomain string
// DNSAltDomain can be set to support resolution on an additional
// consul domain. Should end with a dot.
// If left blank, only the primary domain will be used.
//
// hcl: alt_domain = string
// flag: -alt-domain string
DNSAltDomain string
// DNSEnableTruncate is used to enable setting the truncate
// flag for UDP DNS queries. This allows unmodified
// clients to re-query the consul server using TCP
// when the total number of records exceeds the number
// returned by default for UDP.
//
// hcl: dns_config { enable_truncate = (true|false) }
DNSEnableTruncate bool
// DNSMaxStale is used to bound how stale of a result is
// accepted for a DNS lookup. This can be used with
// AllowStale to limit how old of a value is served up.
// If the stale result exceeds this, another non-stale
// stale read is performed.
//
// hcl: dns_config { max_stale = "duration" }
DNSMaxStale time.Duration
// DNSNodeTTL provides the TTL value for a node query.
//
// hcl: dns_config { node_ttl = "duration" }
DNSNodeTTL time.Duration
// DNSOnlyPassing is used to determine whether to filter nodes
// whose health checks are in any non-passing state. By
// default, only nodes in a critical state are excluded.
//
// hcl: dns_config { only_passing = "duration" }
DNSOnlyPassing bool
// DNSRecursorTimeout specifies the timeout in seconds
// for Consul's internal dns client used for recursion.
// This value is used for the connection, read and write timeout.
//
// hcl: dns_config { recursor_timeout = "duration" }
DNSRecursorTimeout time.Duration
// DNSServiceTTL provides the TTL value for a service
// query for given service. The "*" wildcard can be used
// to set a default for all services.
//
// hcl: dns_config { service_ttl = map[string]"duration" }
DNSServiceTTL map[string]time.Duration
// DNSUDPAnswerLimit is used to limit the maximum number of DNS Resource
// Records returned in the ANSWER section of a DNS response for UDP
// responses without EDNS support (limited to 512 bytes).
// This parameter is deprecated, if you want to limit the number of
// records returned by A or AAAA questions, please use DNSARecordLimit
// instead.
//
// hcl: dns_config { udp_answer_limit = int }
DNSUDPAnswerLimit int
// DNSNodeMetaTXT controls whether DNS queries will synthesize
// TXT records for the node metadata and add them when not specifically
// request (query type = TXT). If unset this will default to true
DNSNodeMetaTXT bool
// DNSRecursors can be set to allow the DNS servers to recursively
// resolve non-consul domains.
//
// hcl: recursors = []string
// flag: -recursor string [-recursor string]
DNSRecursors []string
// DNSUseCache wether or not to use cache for dns queries
//
// hcl: dns_config { use_cache = (true|false) }
DNSUseCache bool
// DNSUseCache wether or not to use cache for dns queries
//
// hcl: dns_config { cache_max_age = "duration" }
DNSCacheMaxAge time.Duration
// HTTPBlockEndpoints is a list of endpoint prefixes to block in the
// HTTP API. Any requests to these will get a 403 response.
//
// hcl: http_config { block_endpoints = []string }
HTTPBlockEndpoints []string
// AllowWriteHTTPFrom restricts the agent write endpoints to the given
// networks. Any request to a protected endpoint that is not mactched
// by one of these networks will get a 403 response.
// An empty slice means no restriction.
//
// hcl: http_config { allow_write_http_from = []string }
AllowWriteHTTPFrom []*net.IPNet
// HTTPResponseHeaders are used to add HTTP header response fields to the HTTP API responses.
//
// hcl: http_config { response_headers = map[string]string }
HTTPResponseHeaders map[string]string
// Embed Telemetry Config
Telemetry lib.TelemetryConfig
// Datacenter is the datacenter this node is in. Defaults to "dc1".
//
// Datacenter is exposed via /v1/agent/self from here and
// used in lots of places like CLI commands. Treat this as an interface
// that must be stable.
//
// hcl: datacenter = string
// flag: -datacenter string
Datacenter string
// Defines the maximum stale value for discovery path. Defaults to "0s".
// Discovery paths are /v1/heath/ paths
//
// If not set to 0, it will try to perform stale read and perform only a
// consistent read whenever the value is too old.
// hcl: discovery_max_stale = "duration"
DiscoveryMaxStale time.Duration
// Node name is the name we use to advertise. Defaults to hostname.
//
// NodeName is exposed via /v1/agent/self from here and
// used in lots of places like CLI commands. Treat this as an interface
// that must be stable.
//
// hcl: node_name = string
// flag: -node string
NodeName string
// AdvertiseAddrLAN is the address we use for advertising our Serf, and
// Consul RPC IP. The address can be specified as an ip address or as a
// go-sockaddr template which resolves to a single ip address. If not
// specified, the bind address is used.
//
// hcl: advertise_addr = string
AdvertiseAddrLAN *net.IPAddr
// AdvertiseAddrWAN is the address we use for advertising our Serf, and
// Consul RPC IP. The address can be specified as an ip address or as a
// go-sockaddr template which resolves to a single ip address. If not
// specified, the bind address is used.
//
// hcl: advertise_addr_wan = string
AdvertiseAddrWAN *net.IPAddr
// BindAddr is used to control the address we bind to.
// If not specified, the first private IP we find is used.
// This controls the address we use for cluster facing
// services (Gossip, Server RPC)
//
// The value can be either an ip address or a go-sockaddr
// template which resolves to a single ip address.
//
// hcl: bind_addr = string
// flag: -bind string
BindAddr *net.IPAddr
// Bootstrap is used to bring up the first Consul server, and
// permits that node to elect itself leader
//
// hcl: bootstrap = (true|false)
// flag: -bootstrap
Bootstrap bool
// BootstrapExpect tries to automatically bootstrap the Consul cluster, by
// having servers wait to bootstrap until enough servers join, and then
// performing the bootstrap process automatically. They will disable their
// automatic bootstrap process if they detect any servers that are part of
// an existing cluster, so it's safe to leave this set to a non-zero value.
//
// hcl: bootstrap_expect = int
// flag: -bootstrap-expect=int
BootstrapExpect int
// CAFile is a path to a certificate authority file. This is used with
// VerifyIncoming or VerifyOutgoing to verify the TLS connection.
//
// hcl: ca_file = string
CAFile string
// CAPath is a path to a directory of certificate authority files. This is
// used with VerifyIncoming or VerifyOutgoing to verify the TLS connection.
//
// hcl: ca_path = string
CAPath string
// CertFile is used to provide a TLS certificate that is used for serving
// TLS connections. Must be provided to serve TLS connections.
//
// hcl: cert_file = string
CertFile string
// CheckUpdateInterval controls the interval on which the output of a health check
// is updated if there is no change to the state. For example, a check in a steady
// state may run every 5 second generating a unique output (timestamp, etc), forcing
// constant writes. This allows Consul to defer the write for some period of time,
// reducing the write pressure when the state is steady.
//
// See also: DiscardCheckOutput
//
// hcl: check_update_interval = "duration"
CheckUpdateInterval time.Duration
// Maximum size for the output of a healtcheck
// hcl check_output_max_size int
// flag: -check_output_max_size int
CheckOutputMaxSize int
// Checks contains the provided check definitions.
//
// hcl: checks = [
// {
// id = string
// name = string
// notes = string
// service_id = string
// token = string
// status = string
// script = string
// args = string
// http = string
// header = map[string][]string
// method = string
// tcp = string
// interval = string
// docker_container_id = string
// shell = string
// tls_skip_verify = (true|false)
// timeout = "duration"
// ttl = "duration"
// deregister_critical_service_after = "duration"
// },
// ...
// ]
Checks []*structs.CheckDefinition
// ClientAddrs contains the list of ip addresses the DNS, HTTP and HTTPS
// endpoints will bind to if the endpoints are enabled (ports > 0) and the
// addresses are not overwritten.
//
// The ip addresses must be provided as a space separated list of ip
// addresses and go-sockaddr templates.
//
// Client addresses cannot contain UNIX socket addresses since a socket
// cannot be shared across multiple endpoints (no ports). To use UNIX
// sockets configure it in 'addresses'.
//
// hcl: client_addr = string
// flag: -client string
ClientAddrs []*net.IPAddr
// ConfigEntryBootstrap contains a list of ConfigEntries to ensure are created
// If entries of the same Kind/Name exist already these will not update them.
ConfigEntryBootstrap []structs.ConfigEntry
// AutoEncryptTLS requires the client to acquire TLS certificates from
// servers.
AutoEncryptTLS bool
// Additional DNS SAN entries that clients request during auto_encrypt
// flow for their certificates.
AutoEncryptDNSSAN []string
// Additional IP SAN entries that clients request during auto_encrypt
// flow for their certificates.
AutoEncryptIPSAN []net.IP
// AutoEncryptAllowTLS enables the server to respond to
// AutoEncrypt.Sign requests.
AutoEncryptAllowTLS bool
// ConnectEnabled opts the agent into connect. It should be set on all clients
// and servers in a cluster for correct connect operation.
ConnectEnabled bool
// ConnectSidecarMinPort is the inclusive start of the range of ports
// allocated to the agent for asigning to sidecar services where no port is
// specified.
ConnectSidecarMinPort int
// ConnectSidecarMaxPort is the inclusive end of the range of ports
// allocated to the agent for asigning to sidecar services where no port is
// specified
ConnectSidecarMaxPort int
// ExposeMinPort is the inclusive start of the range of ports
// allocated to the agent for exposing checks through a proxy
ExposeMinPort int
// ExposeMinPort is the inclusive start of the range of ports
// allocated to the agent for exposing checks through a proxy
ExposeMaxPort int
// ConnectCAProvider is the type of CA provider to use with Connect.
ConnectCAProvider string
// ConnectCAConfig is the config to use for the CA provider.
ConnectCAConfig map[string]interface{}
// ConnectTestCALeafRootChangeSpread is used to control how long the CA leaf
// cache with spread CSRs over when a root change occurs. For now we don't
// expose this in public config intentionally but could later with a rename.
// We only set this from during tests to effectively make CA rotation tests
// deterministic again.
ConnectTestCALeafRootChangeSpread time.Duration
// DNSAddrs contains the list of TCP and UDP addresses the DNS server will
// bind to. If the DNS endpoint is disabled (ports.dns <= 0) the list is
// empty.
//
// The ip addresses are taken from 'addresses.dns' which should contain a
// space separated list of ip addresses and/or go-sockaddr templates.
//
// If 'addresses.dns' was not provided the 'client_addr' addresses are
// used.
//
// The DNS server cannot be bound to UNIX sockets.
//
// hcl: client_addr = string addresses { dns = string } ports { dns = int }
DNSAddrs []net.Addr
// DNSPort is the port the DNS server listens on. The default is 8600.
// Setting this to a value <= 0 disables the endpoint.
//
// hcl: ports { dns = int }
// flags: -dns-port int
DNSPort int
// DNSSOA is the settings applied for DNS SOA
// hcl: soa {}
DNSSOA RuntimeSOAConfig
// DataDir is the path to the directory where the local state is stored.
//
// hcl: data_dir = string
// flag: -data-dir string
DataDir string
// DefaultQueryTime is the amount of time a blocking query will wait before
// Consul will force a response. This value can be overridden by the 'wait'
// query parameter.
//
// hcl: default_query_time = "duration"
// flag: -default-query-time string
DefaultQueryTime time.Duration
// DevMode enables a fast-path mode of operation to bring up an in-memory
// server with minimal configuration. Useful for developing Consul.
//
// flag: -dev
DevMode bool
// DisableAnonymousSignature is used to turn off the anonymous signature
// send with the update check. This is used to deduplicate messages.
//
// hcl: disable_anonymous_signature = (true|false)
DisableAnonymousSignature bool
// DisableCoordinates controls features related to network coordinates.
//
// hcl: disable_coordinates = (true|false)
DisableCoordinates bool
// DisableHostNodeID will prevent Consul from using information from the
// host to generate a node ID, and will cause Consul to generate a
// random ID instead.
//
// hcl: disable_host_node_id = (true|false)
// flag: -disable-host-node-id
DisableHostNodeID bool
// DisableHTTPUnprintableCharFilter will bypass the filter preventing HTTP
// URLs from containing unprintable chars. This filter was added in 1.0.3 as a
// response to a vulnerability report. Disabling this is never recommended in
// general however some users who have keys written in older versions of
// Consul may use this to temporarily disable the filter such that they can
// delete those keys again! We do not recommend leaving it disabled long term.
//
// hcl: disable_http_unprintable_char_filter
DisableHTTPUnprintableCharFilter bool
// DisableKeyringFile disables writing the keyring to a file.
//
// hcl: disable_keyring_file = (true|false)
// flag: -disable-keyring-file
DisableKeyringFile bool
// DisableRemoteExec is used to turn off the remote execution
// feature. This is for security to prevent unknown scripts from running.
//
// hcl: disable_remote_exec = (true|false)
DisableRemoteExec bool
// DisableUpdateCheck is used to turn off the automatic update and
// security bulletin checking.
//
// hcl: disable_update_check = (true|false)
DisableUpdateCheck bool
// DiscardCheckOutput is used to turn off storing and comparing the
// output of health checks. This reduces the write rate on the server
// for checks with highly volatile output. (reloadable)
//
// See also: CheckUpdateInterval
//
// hcl: discard_check_output = (true|false)
DiscardCheckOutput bool
// EnableAgentTLSForChecks is used to apply the agent's TLS settings in
// order to configure the HTTP client used for health checks. Enabling
// this allows HTTP checks to present a client certificate and verify
// the server using the same TLS configuration as the agent (CA, cert,
// and key).
EnableAgentTLSForChecks bool
// EnableCentralServiceConfig controls whether the agent should incorporate
// centralized config such as service-defaults into local service registrations.
//
// hcl: enable_central_service_config = (true|false)
EnableCentralServiceConfig bool
// EnableDebug is used to enable various debugging features.
//
// hcl: enable_debug = (true|false)
EnableDebug bool
// EnableLocalScriptChecks controls whether health checks declared from the local
// config file which execute scripts are enabled. This includes regular script
// checks and Docker checks.
//
// hcl: (enable_script_checks|enable_local_script_checks) = (true|false)
// flag: -enable-script-checks, -enable-local-script-checks
EnableLocalScriptChecks bool
// EnableRemoeScriptChecks controls whether health checks declared from the http API
// which execute scripts are enabled. This includes regular script checks and Docker
// checks.
//
// hcl: enable_script_checks = (true|false)
// flag: -enable-script-checks
EnableRemoteScriptChecks bool
// EnableSyslog is used to also tee all the logs over to syslog. Only supported
// on linux and OSX. Other platforms will generate an error.
//
// hcl: enable_syslog = (true|false)
// flag: -syslog
EnableSyslog bool
// EnableUI enables the statically-compiled assets for the Consul web UI and
// serves them at the default /ui/ endpoint automatically.
//
// hcl: enable_ui = (true|false)
// flag: -ui
EnableUI bool
// EncryptKey contains the encryption key to use for the Serf communication.
//
// hcl: encrypt = string
// flag: -encrypt string
EncryptKey string
// EncryptVerifyIncoming enforces incoming gossip encryption and can be
// used to upshift to encrypted gossip on a running cluster.
//
// hcl: encrypt_verify_incoming = (true|false)
EncryptVerifyIncoming bool
// EncryptVerifyOutgoing enforces outgoing gossip encryption and can be
// used to upshift to encrypted gossip on a running cluster.
//
// hcl: encrypt_verify_outgoing = (true|false)
EncryptVerifyOutgoing bool
// GRPCPort is the port the gRPC server listens on. Currently this only
// exposes the xDS and ext_authz APIs for Envoy and it is disabled by default.
//
// hcl: ports { grpc = int }
// flags: -grpc-port int
GRPCPort int
// GRPCAddrs contains the list of TCP addresses and UNIX sockets the gRPC
// server will bind to. If the gRPC endpoint is disabled (ports.grpc <= 0)
// the list is empty.
//
// The addresses are taken from 'addresses.grpc' which should contain a
// space separated list of ip addresses, UNIX socket paths and/or
// go-sockaddr templates. UNIX socket paths must be written as
// 'unix://<full path>', e.g. 'unix:///var/run/consul-grpc.sock'.
//
// If 'addresses.grpc' was not provided the 'client_addr' addresses are
// used.
//
// hcl: client_addr = string addresses { grpc = string } ports { grpc = int }
GRPCAddrs []net.Addr
// HTTPAddrs contains the list of TCP addresses and UNIX sockets the HTTP
// server will bind to. If the HTTP endpoint is disabled (ports.http <= 0)
// the list is empty.
//
// The addresses are taken from 'addresses.http' which should contain a
// space separated list of ip addresses, UNIX socket paths and/or
// go-sockaddr templates. UNIX socket paths must be written as
// 'unix://<full path>', e.g. 'unix:///var/run/consul-http.sock'.
//
// If 'addresses.http' was not provided the 'client_addr' addresses are
// used.
//
// hcl: client_addr = string addresses { http = string } ports { http = int }
HTTPAddrs []net.Addr
// HTTPPort is the port the HTTP server listens on. The default is 8500.
// Setting this to a value <= 0 disables the endpoint.
//
// hcl: ports { http = int }
// flags: -http-port int
HTTPPort int
// HTTPSAddrs contains the list of TCP addresses and UNIX sockets the HTTPS
// server will bind to. If the HTTPS endpoint is disabled (ports.https <=
// 0) the list is empty.
//
// The addresses are taken from 'addresses.https' which should contain a
// space separated list of ip addresses, UNIX socket paths and/or
// go-sockaddr templates. UNIX socket paths must be written as
// 'unix://<full path>', e.g. 'unix:///var/run/consul-https.sock'.
//
// If 'addresses.https' was not provided the 'client_addr' addresses are
// used.
//
// hcl: client_addr = string addresses { https = string } ports { https = int }
HTTPSAddrs []net.Addr
// HTTPSPort is the port the HTTP server listens on. The default is -1.
// Setting this to a value <= 0 disables the endpoint.
//
// hcl: ports { https = int }
// flags: -https-port int
HTTPSPort int
// KeyFile is used to provide a TLS key that is used for serving TLS
// connections. Must be provided to serve TLS connections.
//
// hcl: key_file = string
KeyFile string
// KVMaxValueSize controls the max allowed value size. If not set defaults
// to raft's suggested max value size.
//
// hcl: limits { kv_max_value_size = uint64 }
KVMaxValueSize uint64
// LeaveDrainTime is used to wait after a server has left the LAN Serf
// pool for RPCs to drain and new requests to be sent to other servers.
//
// hcl: performance { leave_drain_time = "duration" }
LeaveDrainTime time.Duration
// LeaveOnTerm controls if Serf does a graceful leave when receiving
// the TERM signal. Defaults true on clients, false on servers. (reloadable)
//
// hcl: leave_on_terminate = (true|false)
LeaveOnTerm bool
// LogLevel is the level of the logs to write. Defaults to "INFO".
//
// hcl: log_level = string
LogLevel string
// LogFile is the path to the file where the logs get written to. Defaults to empty string.
//
// hcl: log_file = string
// flags: -log-file string
LogFile string
// LogRotateDuration is the time configured to rotate logs based on time
//
// hcl: log_rotate_duration = string
// flags: -log-rotate-duration string
LogRotateDuration time.Duration
// LogRotateBytes is the time configured to rotate logs based on bytes written
//
// hcl: log_rotate_bytes = int
// flags: -log-rotate-bytes int
LogRotateBytes int
// LogRotateMaxFiles is the maximum number of log file archives to keep
//
// hcl: log_rotate_max_files = int
// flags: -log-rotate-max-files int
LogRotateMaxFiles int
// MaxQueryTime is the maximum amount of time a blocking query can wait
// before Consul will force a response. Consul applies jitter to the wait
// time. The jittered time will be capped to MaxQueryTime.
//
// hcl: max_query_time = "duration"
// flags: -max-query-time string
MaxQueryTime time.Duration
// Node ID is a unique ID for this node across space and time. Defaults
// to a randomly-generated ID that persists in the data-dir.
//
// todo(fs): don't we have a requirement for this to be a UUID in a specific format?
//
// hcl: node_id = string
// flag: -node-id string
NodeID types.NodeID
// NodeMeta contains metadata key/value pairs. These are excluded from JSON output
// because they can be reloaded and might be stale when shown from the
// config instead of the local state.
// todo(fs): should the sanitizer omit them from output as well since they could be stale?
//
// hcl: node_meta = map[string]string
// flag: -node-meta "key:value" -node-meta "key:value" ...
NodeMeta map[string]string
// NonVotingServer is whether this server will act as a non-voting member
// of the cluster to help provide read scalability. (Enterprise-only)
//
// hcl: non_voting_server = (true|false)
// flag: -non-voting-server
NonVotingServer bool
// PidFile is the file to store our PID in.
//
// hcl: pid_file = string
PidFile string
// PrimaryDatacenter is the central datacenter that holds authoritative
// ACL records, replicates intentions and holds the root CA for Connect.
// This must be the same for the entire cluster. Off by default.
//
// hcl: primary_datacenter = string
PrimaryDatacenter string
// RPCAdvertiseAddr is the TCP address Consul advertises for its RPC endpoint.
// By default this is the bind address on the default RPC Server port. If the
// advertise address is specified then it is used.
//
// hcl: bind_addr = string advertise_addr = string ports { server = int }
RPCAdvertiseAddr *net.TCPAddr
// RPCBindAddr is the TCP address Consul will bind to for its RPC endpoint.
// By default this is the bind address on the default RPC Server port.
//
// hcl: bind_addr = string ports { server = int }
RPCBindAddr *net.TCPAddr
// 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.
//
// hcl: performance { rpc_hold_timeout = "duration" }
RPCHoldTimeout time.Duration
// RPCRateLimit and RPCMaxBurst control how frequently RPC calls are allowed
// to happen. In any large enough time interval, rate limiter limits the
// rate to RPCRate tokens per second, with a maximum burst size of
// RPCMaxBurst events. As a special case, if RPCRate == Inf (the infinite
// rate), RPCMaxBurst is ignored.
//
// See https://en.wikipedia.org/wiki/Token_bucket for more about token
// buckets.
//
// hcl: limit { rpc_rate = (float64|MaxFloat64) rpc_max_burst = int }
RPCRateLimit rate.Limit
RPCMaxBurst int
// RPCProtocol is the Consul protocol version to use.
//
// hcl: protocol = int
RPCProtocol int
// RaftProtocol sets the Raft protocol version to use on this server.
// Defaults to 3.
//
// hcl: raft_protocol = int
RaftProtocol int
// RaftSnapshotThreshold sets the minimum threshold of raft commits after which
// a snapshot is created. Defaults to 8192
//
// hcl: raft_snapshot_threshold = int
RaftSnapshotThreshold int
// RaftSnapshotInterval sets the interval to use when checking whether to create
// a new snapshot. Defaults to 5 seconds.
// hcl: raft_snapshot_threshold = int
RaftSnapshotInterval time.Duration
// RaftTrailingLogs sets the number of log entries that will be left in the
// log store after a snapshot. This must be large enough that a follower can
// transfer and restore an entire snapshot of the state before this many new
// entries have been appended. In vast majority of cases the default is plenty
// but if there is a sustained high write throughput coupled with a huge
// multi-gigabyte snapshot setting this higher may be necessary to allow
// followers time to reload from snapshot without becoming unhealthy. If it's
// too low then followers are unable to ever recover from a restart and will
// enter a loop of constantly downloading full snapshots and never catching
// up. If you need to change this you should reconsider your usage of Consul
// as it is not designed to store multiple-gigabyte data sets with high write
// throughput. Defaults to 10000.
//
// hcl: raft_trailing_logs = int
RaftTrailingLogs int
// ReconnectTimeoutLAN specifies the amount of time to wait to reconnect with
// another agent before deciding it's permanently gone. This can be used to
// control the time it takes to reap failed nodes from the cluster.
//
// hcl: reconnect_timeout = "duration"
ReconnectTimeoutLAN time.Duration
// ReconnectTimeoutWAN specifies the amount of time to wait to reconnect with
// another agent before deciding it's permanently gone. This can be used to
// control the time it takes to reap failed nodes from the cluster.
//
// hcl: reconnect_timeout = "duration"
ReconnectTimeoutWAN time.Duration
// RejoinAfterLeave controls our interaction with the cluster after leave.
// When set to false (default), a leave causes 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.
//
// hcl: rejoin_after_leave = (true|false)
// flag: -rejoin
RejoinAfterLeave bool
// RetryJoinIntervalLAN specifies the amount of time to wait in between join
// attempts on agent start. The minimum allowed value is 1 second and
// the default is 30s.
//
// hcl: retry_join = "duration"
RetryJoinIntervalLAN time.Duration
// RetryJoinIntervalWAN specifies the amount of time to wait in between join
// attempts on agent start. The minimum allowed value is 1 second and
// the default is 30s.
//
// hcl: retry_join_wan = "duration"
RetryJoinIntervalWAN time.Duration
// RetryJoinLAN is a list of addresses and/or go-discover expressions to
// join with retry enabled. See
// https://www.consul.io/docs/agent/options.html#cloud-auto-joining for
// details.
//
// hcl: retry_join = []string
// flag: -retry-join string -retry-join string
RetryJoinLAN []string
// RetryJoinMaxAttemptsLAN specifies the maximum number of times to retry
// joining a host on startup. This is useful for cases where we know the
// node will be online eventually.
//
// hcl: retry_max = int
// flag: -retry-max int
RetryJoinMaxAttemptsLAN int
// RetryJoinMaxAttemptsWAN specifies the maximum number of times to retry
// joining a host on startup. This is useful for cases where we know the
// node will be online eventually.
//
// hcl: retry_max_wan = int
// flag: -retry-max-wan int
RetryJoinMaxAttemptsWAN int
// RetryJoinWAN is a list of addresses and/or go-discover expressions to
// join -wan with retry enabled. See
// https://www.consul.io/docs/agent/options.html#cloud-auto-joining for
// details.
//
// hcl: retry_join_wan = []string
// flag: -retry-join-wan string -retry-join-wan string
RetryJoinWAN []string
// SegmentName is the network segment for this client to join.
// (Enterprise-only)
//
// hcl: segment = string
SegmentName string
// Segments is the list of network segments for this server to
// initialize.
//
// hcl: segment = [
// {
// # name is the name of the segment
// name = string
//
// # bind is the bind ip address for this segment.
// bind = string
//
// # port is the bind port for this segment.
// port = int
//
// # advertise is the advertise ip address for this segment.
// # Defaults to the bind address if not set.
// advertise = string
//
// # rpc_listener controls whether or not to bind a separate
// # RPC listener to the bind address.
// rpc_listener = (true|false)
// },
// ...
// ]
Segments []structs.NetworkSegment
// SerfAdvertiseAddrLAN is the TCP address which is used for advertising
// the LAN Gossip pool for both client and server. The address is the
// combination of AdvertiseAddrLAN and the SerfPortLAN. If the advertise
// address is not given the bind address is used.
//
// hcl: bind_addr = string advertise_addr = string ports { serf_lan = int }
SerfAdvertiseAddrLAN *net.TCPAddr
// SerfAdvertiseAddrWAN is the TCP address which is used for advertising
// the WAN Gossip pool on the server only. The address is the combination
// of AdvertiseAddrWAN and the SerfPortWAN. If the advertise address is not
// given the bind address is used.
//
// hcl: bind_addr = string advertise_addr_wan = string ports { serf_wan = int }
SerfAdvertiseAddrWAN *net.TCPAddr
// SerfBindAddrLAN is the address to bind the Serf LAN TCP and UDP
// listeners to. The ip address is either the default bind address or the
// 'serf_lan' address which can be either an ip address or a go-sockaddr
// template which resolves to a single ip address.
//
// hcl: bind_addr = string serf_lan = string ports { serf_lan = int }
// flag: -serf-lan string
SerfBindAddrLAN *net.TCPAddr
// SerfBindAddrWAN is the address to bind the Serf WAN TCP and UDP
// listeners to. The ip address is either the default bind address or the
// 'serf_wan' address which can be either an ip address or a go-sockaddr
// template which resolves to a single ip address.
//
// hcl: bind_addr = string serf_wan = string ports { serf_wan = int }
// flag: -serf-wan string
SerfBindAddrWAN *net.TCPAddr
// SerfPortLAN is the port used for the LAN Gossip pool for both client and server.
// The default is 8301.
//
// hcl: ports { serf_lan = int }
SerfPortLAN int
// SerfPortWAN is the port used for the WAN Gossip pool for the server only.
// The default is 8302.
//
// hcl: ports { serf_wan = int }
SerfPortWAN int
// GossipLANGossipInterval is the interval between sending messages that need
// to be gossiped that haven't been able to piggyback on probing messages.
// If this is set to zero, non-piggyback gossip is disabled. By lowering
// this value (more frequent) gossip messages are propagated across
// the cluster more quickly at the expense of increased bandwidth. This
// configuration only applies to LAN gossip communications
//
// The default is: 200ms
//
// hcl: gossip_lan { gossip_interval = duration}
GossipLANGossipInterval time.Duration
// GossipLANGossipNodes is the number of random nodes to send gossip messages to
// per GossipInterval. Increasing this number causes the gossip messages to
// propagate across the cluster more quickly at the expense of increased
// bandwidth. This configuration only applies to LAN gossip communications
//
// The default is: 3
//
// hcl: gossip_lan { gossip_nodes = int }
GossipLANGossipNodes int
// GossipLANProbeInterval is the interval between random node probes. Setting
// this lower (more frequent) will cause the memberlist cluster to detect
// failed nodes more quickly at the expense of increased bandwidth usage.
// This configuration only applies to LAN gossip communications
//
// The default is: 1s
//
// hcl: gossip_lan { probe_interval = duration }
GossipLANProbeInterval time.Duration
// GossipLANProbeTimeout is the timeout to wait for an ack from a probed node
// before assuming it is unhealthy. This should be set to 99-percentile
// of RTT (round-trip time) on your network. This configuration
// only applies to the LAN gossip communications
//
// The default is: 500ms
//
// hcl: gossip_lan { probe_timeout = duration }
GossipLANProbeTimeout time.Duration
// GossipLANSuspicionMult is the multiplier for determining the time an
// inaccessible node is considered suspect before declaring it dead. This
// configuration only applies to LAN gossip communications
//
// The actual timeout is calculated using the formula:
//
// SuspicionTimeout = SuspicionMult * log(N+1) * ProbeInterval
//
// This allows the timeout to scale properly with expected propagation
// delay with a larger cluster size. The higher the multiplier, the longer
// an inaccessible node is considered part of the cluster before declaring
// it dead, giving that suspect node more time to refute if it is indeed
// still alive.
//
// The default is: 4
//
// hcl: gossip_lan { suspicion_mult = int }
GossipLANSuspicionMult int
// GossipLANRetransmitMult is the multiplier for the number of retransmissions
// that are attempted for messages broadcasted over gossip. This
// configuration only applies to LAN gossip communications. The actual
// count of retransmissions is calculated using the formula:
//
// Retransmits = RetransmitMult * log(N+1)
//
// This allows the retransmits to scale properly with cluster size. The
// higher the multiplier, the more likely a failed broadcast is to converge
// at the expense of increased bandwidth.
//
// The default is: 4
//
// hcl: gossip_lan { retransmit_mult = int }
GossipLANRetransmitMult int
// GossipWANGossipInterval is the interval between sending messages that need
// to be gossiped that haven't been able to piggyback on probing messages.
// If this is set to zero, non-piggyback gossip is disabled. By lowering
// this value (more frequent) gossip messages are propagated across
// the cluster more quickly at the expense of increased bandwidth. This
// configuration only applies to WAN gossip communications
//
// The default is: 200ms
//
// hcl: gossip_wan { gossip_interval = duration}
GossipWANGossipInterval time.Duration
// GossipWANGossipNodes is the number of random nodes to send gossip messages to
// per GossipInterval. Increasing this number causes the gossip messages to
// propagate across the cluster more quickly at the expense of increased
// bandwidth. This configuration only applies to WAN gossip communications
//
// The default is: 3
//
// hcl: gossip_wan { gossip_nodes = int }
GossipWANGossipNodes int
// GossipWANProbeInterval is the interval between random node probes. Setting
// this lower (more frequent) will cause the memberlist cluster to detect
// failed nodes more quickly at the expense of increased bandwidth usage.
// This configuration only applies to WAN gossip communications
//
// The default is: 1s
//
// hcl: gossip_wan { probe_interval = duration }
GossipWANProbeInterval time.Duration
// GossipWANProbeTimeout is the timeout to wait for an ack from a probed node
// before assuming it is unhealthy. This should be set to 99-percentile
// of RTT (round-trip time) on your network. This configuration
// only applies to the WAN gossip communications
//
// The default is: 500ms
//
// hcl: gossip_wan { probe_timeout = duration }
GossipWANProbeTimeout time.Duration
// GossipWANSuspicionMult is the multiplier for determining the time an
// inaccessible node is considered suspect before declaring it dead. This
// configuration only applies to WAN gossip communications
//
// The actual timeout is calculated using the formula:
//
// SuspicionTimeout = SuspicionMult * log(N+1) * ProbeInterval
//
// This allows the timeout to scale properly with expected propagation
// delay with a larger cluster size. The higher the multiplier, the longer
// an inaccessible node is considered part of the cluster before declaring
// it dead, giving that suspect node more time to refute if it is indeed
// still alive.
//
// The default is: 4
//
// hcl: gossip_wan { suspicion_mult = int }
GossipWANSuspicionMult int
// GossipWANRetransmitMult is the multiplier for the number of retransmissions
// that are attempted for messages broadcasted over gossip. This
// configuration only applies to WAN gossip communications. The actual
// count of retransmissions is calculated using the formula:
//
// Retransmits = RetransmitMult * log(N+1)
//
// This allows the retransmits to scale properly with cluster size. The
// higher the multiplier, the more likely a failed broadcast is to converge
// at the expense of increased bandwidth.
//
// The default is: 4
//
// hcl: gossip_wan { retransmit_mult = int }
GossipWANRetransmitMult int
// ServerMode controls if this agent acts like a Consul server,
// or merely as a client. Servers have more state, take part
// in leader election, etc.
//
// hcl: server = (true|false)
// flag: -server
ServerMode bool
// ServerName is used with the TLS certificates to ensure the name we
// provide matches the certificate.
//
// hcl: server_name = string
ServerName string
// ServerPort is the port the RPC server will bind to.
// The default is 8300.
//
// hcl: ports { server = int }
ServerPort int
// Services contains the provided service definitions:
//
// hcl: services = [
// {
// id = string
// name = string
// tags = []string
// address = string
// check = { check definition }
// checks = [ { check definition}, ... ]
// token = string
// enable_tag_override = (true|false)
// },
// ...
// ]
Services []*structs.ServiceDefinition
// Minimum Session TTL.
//
// hcl: session_ttl_min = "duration"
SessionTTLMin time.Duration
// SkipLeaveOnInt controls if Serf skips a graceful leave when
// receiving the INT signal. Defaults false on clients, true on
// servers. (reloadable)
//
// hcl: skip_leave_on_interrupt = (true|false)
SkipLeaveOnInt bool
// StartJoinAddrsLAN is a list of addresses to attempt to join -lan when the
// agent starts. If Serf is unable to communicate with any of these
// addresses, then the agent will error and exit.
//
// hcl: start_join = []string
// flag: -join string -join string
StartJoinAddrsLAN []string
// StartJoinWAN is a list of addresses to attempt to join -wan when the
// agent starts. If Serf is unable to communicate with any of these
// addresses, then the agent will error and exit.
//
// hcl: start_join_wan = []string
// flag: -join-wan string -join-wan string
StartJoinAddrsWAN []string
// SyslogFacility is used to control where the syslog messages go
// By default, goes to LOCAL0
//
// hcl: syslog_facility = string
SyslogFacility string
// TLSCipherSuites is used to specify the list of supported ciphersuites.
//
// The values should be a list of the following values:
//
// TLS_ECDHE_RSA_WITH_CHACHA20_POLY1305
// TLS_ECDHE_ECDSA_WITH_CHACHA20_POLY1305
// TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256
// TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256
// TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384
// TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384
// TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256
// TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA
// TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256
// TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA
// TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA
// TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA
// TLS_RSA_WITH_AES_128_GCM_SHA256
// TLS_RSA_WITH_AES_256_GCM_SHA384
// TLS_RSA_WITH_AES_128_CBC_SHA256
// TLS_RSA_WITH_AES_128_CBC_SHA
// TLS_RSA_WITH_AES_256_CBC_SHA
// TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA
// TLS_RSA_WITH_3DES_EDE_CBC_SHA
// TLS_RSA_WITH_RC4_128_SHA
// TLS_ECDHE_RSA_WITH_RC4_128_SHA
// TLS_ECDHE_ECDSA_WITH_RC4_128_SHA
//
// todo(fs): IMHO, we should also support the raw 0xNNNN values from
// todo(fs): https://golang.org/pkg/crypto/tls/#pkg-constants
// todo(fs): since they are standardized by IANA.
//
// hcl: tls_cipher_suites = []string
TLSCipherSuites []uint16
// TLSMinVersion is used to set the minimum TLS version used for TLS
// connections. Should be either "tls10", "tls11", or "tls12".
//
// hcl: tls_min_version = string
TLSMinVersion string
// TLSPreferServerCipherSuites specifies whether to prefer the server's
// cipher suite over the client cipher suites.
//
// hcl: tls_prefer_server_cipher_suites = (true|false)
TLSPreferServerCipherSuites bool
// TaggedAddresses are used to publish a set of addresses for
// for a node, which can be used by the remote agent. We currently
// populate only the "wan" tag based on the SerfWan advertise address,
// but this structure is here for possible future features with other
// user-defined tags. The "wan" tag will be used by remote agents if
// they are configured with TranslateWANAddrs set to true.
//
// hcl: tagged_addresses = map[string]string
TaggedAddresses map[string]string
// TranslateWANAddrs controls whether or not Consul should prefer
// the "wan" tagged address when doing lookups in remote datacenters.
// See TaggedAddresses below for more details.
//
// hcl: translate_wan_addrs = (true|false)
TranslateWANAddrs bool
// UIDir is the directory containing the Web UI resources.
// If provided, the UI endpoints will be enabled.
//
// hcl: ui_dir = string
// flag: -ui-dir string
UIDir string
//UIContentPath is a string that sets the external
// path to a string. Default: /ui/
UIContentPath string
// UnixSocketGroup contains the group of the file permissions when
// Consul binds to UNIX sockets.
//
// hcl: unix_sockets { group = string }
UnixSocketGroup string
// UnixSocketMode contains the mode of the file permissions when
// Consul binds to UNIX sockets.
//
// hcl: unix_sockets { mode = string }
UnixSocketMode string
// UnixSocketUser contains the user of the file permissions when
// Consul binds to UNIX sockets.
//
// hcl: unix_sockets { user = string }
UnixSocketUser string
// 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.
//
// hcl: verify_incoming = (true|false)
VerifyIncoming bool
// VerifyIncomingHTTPS is used to verify the authenticity of incoming HTTPS
// 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.
//
// hcl: verify_incoming_https = (true|false)
VerifyIncomingHTTPS bool
// VerifyIncomingRPC is used to verify the authenticity of incoming RPC
// 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.
//
// hcl: verify_incoming_rpc = (true|false)
VerifyIncomingRPC bool
// VerifyOutgoing is used to verify the authenticity of outgoing
// connections. This means that TLS requests are used. TLS connections must
// match a provided certificate authority. This is used to verify
// authenticity of server nodes.
//
// hcl: verify_outgoing = (true|false)
VerifyOutgoing bool
// VerifyServerHostname is used to enable hostname verification of servers.
// This ensures that the certificate presented is valid for
// server.<datacenter>.<domain>. 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.
//
// hcl: verify_server_hostname = (true|false)
VerifyServerHostname bool
// Watches are used to monitor various endpoints and to invoke a
// handler to act appropriately. These are managed entirely in the
// agent layer using the standard APIs.
//
// See https://www.consul.io/docs/agent/watches.html for details.
//
// hcl: watches = [
// { type=string ... },
// { type=string ... },
// ...
// ]
//
Watches []map[string]interface{}
EnterpriseRuntimeConfig
}
func (c *RuntimeConfig) apiAddresses(maxPerType int) (unixAddrs, httpAddrs, httpsAddrs []string) {
if len(c.HTTPSAddrs) > 0 {
for i, addr := range c.HTTPSAddrs {
if maxPerType < 1 || i < maxPerType {
httpsAddrs = append(httpsAddrs, addr.String())
} else {
break
}
}
}
if len(c.HTTPAddrs) > 0 {
unix_count := 0
http_count := 0
for _, addr := range c.HTTPAddrs {
switch addr.(type) {
case *net.UnixAddr:
if maxPerType < 1 || unix_count < maxPerType {
unixAddrs = append(unixAddrs, addr.String())
unix_count += 1
}
default:
if maxPerType < 1 || http_count < maxPerType {
httpAddrs = append(httpAddrs, addr.String())
http_count += 1
}
}
}
}
return
}
func (c *RuntimeConfig) ClientAddress() (unixAddr, httpAddr, httpsAddr string) {
unixAddrs, httpAddrs, httpsAddrs := c.apiAddresses(0)
if len(unixAddrs) > 0 {
unixAddr = "unix://" + unixAddrs[0]
}
http_any := ""
if len(httpAddrs) > 0 {
for _, addr := range httpAddrs {
host, port, err := net.SplitHostPort(addr)
if err != nil {
continue
}
if host == "0.0.0.0" || host == "::" {
if http_any == "" {
if host == "0.0.0.0" {
http_any = net.JoinHostPort("127.0.0.1", port)
} else {
http_any = net.JoinHostPort("::1", port)
}
}
continue
}
httpAddr = addr
break
}
if httpAddr == "" && http_any != "" {
httpAddr = http_any
}
}
https_any := ""
if len(httpsAddrs) > 0 {
for _, addr := range httpsAddrs {
host, port, err := net.SplitHostPort(addr)
if err != nil {
continue
}
if host == "0.0.0.0" || host == "::" {
if https_any == "" {
if host == "0.0.0.0" {
https_any = net.JoinHostPort("127.0.0.1", port)
} else {
https_any = net.JoinHostPort("::1", port)
}
}
continue
}
httpsAddr = addr
break
}
if httpsAddr == "" && https_any != "" {
httpsAddr = https_any
}
}
return
}
func (c *RuntimeConfig) APIConfig(includeClientCerts bool) (*api.Config, error) {
cfg := &api.Config{
Datacenter: c.Datacenter,
TLSConfig: api.TLSConfig{InsecureSkipVerify: !c.VerifyOutgoing},
}
unixAddr, httpAddr, httpsAddr := c.ClientAddress()
if httpsAddr != "" {
cfg.Address = httpsAddr
cfg.Scheme = "https"
cfg.TLSConfig.CAFile = c.CAFile
cfg.TLSConfig.CAPath = c.CAPath
if includeClientCerts {
cfg.TLSConfig.CertFile = c.CertFile
cfg.TLSConfig.KeyFile = c.KeyFile
}
} else if httpAddr != "" {
cfg.Address = httpAddr
cfg.Scheme = "http"
} else if unixAddr != "" {
cfg.Address = unixAddr
// this should be ignored - however we are still talking http over a unix socket
// so it makes sense to set it like this
cfg.Scheme = "http"
} else {
return nil, fmt.Errorf("No suitable client address can be found")
}
return cfg, nil
}
// Sanitized returns a JSON/HCL compatible representation of the runtime
// configuration where all fields with potential secrets had their
// values replaced by 'hidden'. In addition, network addresses and
// time.Duration values are formatted to improve readability.
func (c *RuntimeConfig) Sanitized() map[string]interface{} {
return sanitize("rt", reflect.ValueOf(c)).Interface().(map[string]interface{})
}
func (c *RuntimeConfig) ToTLSUtilConfig() tlsutil.Config {
return tlsutil.Config{
VerifyIncoming: c.VerifyIncoming,
VerifyIncomingRPC: c.VerifyIncomingRPC,
VerifyIncomingHTTPS: c.VerifyIncomingHTTPS,
VerifyOutgoing: c.VerifyOutgoing,
VerifyServerHostname: c.VerifyServerHostname,
CAFile: c.CAFile,
CAPath: c.CAPath,
CertFile: c.CertFile,
KeyFile: c.KeyFile,
NodeName: c.NodeName,
Domain: c.DNSDomain,
ServerName: c.ServerName,
TLSMinVersion: c.TLSMinVersion,
CipherSuites: c.TLSCipherSuites,
PreferServerCipherSuites: c.TLSPreferServerCipherSuites,
EnableAgentTLSForChecks: c.EnableAgentTLSForChecks,
AutoEncryptTLS: c.AutoEncryptTLS,
}
}
// isSecret determines whether a field name represents a field which
// may contain a secret.
func isSecret(name string) bool {
name = strings.ToLower(name)
return strings.Contains(name, "key") || strings.Contains(name, "token") || strings.Contains(name, "secret")
}
// cleanRetryJoin sanitizes the go-discover config strings key=val key=val...
// by scrubbing the individual key=val combinations.
func cleanRetryJoin(a string) string {
var fields []string
for _, f := range strings.Fields(a) {
if isSecret(f) {
kv := strings.SplitN(f, "=", 2)
fields = append(fields, kv[0]+"=hidden")
} else {
fields = append(fields, f)
}
}
return strings.Join(fields, " ")
}
func sanitize(name string, v reflect.Value) reflect.Value {
typ := v.Type()
switch {
// check before isStruct and isPtr
case isNetAddr(typ):
if v.IsNil() {
return reflect.ValueOf("")
}
switch x := v.Interface().(type) {
case *net.TCPAddr:
return reflect.ValueOf("tcp://" + x.String())
case *net.UDPAddr:
return reflect.ValueOf("udp://" + x.String())
case *net.UnixAddr:
return reflect.ValueOf("unix://" + x.String())
case *net.IPAddr:
return reflect.ValueOf(x.IP.String())
case *net.IPNet:
return reflect.ValueOf(x.String())
default:
return v
}
// check before isNumber
case isDuration(typ):
x := v.Interface().(time.Duration)
return reflect.ValueOf(x.String())
case isString(typ):
if strings.HasPrefix(name, "RetryJoinLAN[") || strings.HasPrefix(name, "RetryJoinWAN[") {
x := v.Interface().(string)
return reflect.ValueOf(cleanRetryJoin(x))
}
if isSecret(name) {
return reflect.ValueOf("hidden")
}
return v
case isNumber(typ) || isBool(typ):
return v
case isPtr(typ):
if v.IsNil() {
return v
}
return sanitize(name, v.Elem())
case isStruct(typ):
m := map[string]interface{}{}
for i := 0; i < typ.NumField(); i++ {
key := typ.Field(i).Name
m[key] = sanitize(key, v.Field(i)).Interface()
}
return reflect.ValueOf(m)
case isArray(typ) || isSlice(typ):
ma := make([]interface{}, 0)
for i := 0; i < v.Len(); i++ {
ma = append(ma, sanitize(fmt.Sprintf("%s[%d]", name, i), v.Index(i)).Interface())
}
return reflect.ValueOf(ma)
case isMap(typ):
m := map[string]interface{}{}
for _, k := range v.MapKeys() {
key := k.String()
m[key] = sanitize(key, v.MapIndex(k)).Interface()
}
return reflect.ValueOf(m)
default:
return v
}
}
func isDuration(t reflect.Type) bool { return t == reflect.TypeOf(time.Second) }
func isMap(t reflect.Type) bool { return t.Kind() == reflect.Map }
func isNetAddr(t reflect.Type) bool { return t.Implements(reflect.TypeOf((*net.Addr)(nil)).Elem()) }
func isPtr(t reflect.Type) bool { return t.Kind() == reflect.Ptr }
func isArray(t reflect.Type) bool { return t.Kind() == reflect.Array }
func isSlice(t reflect.Type) bool { return t.Kind() == reflect.Slice }
func isString(t reflect.Type) bool { return t.Kind() == reflect.String }
func isStruct(t reflect.Type) bool { return t.Kind() == reflect.Struct }
func isBool(t reflect.Type) bool { return t.Kind() == reflect.Bool }
func isNumber(t reflect.Type) bool { return isInt(t) || isUint(t) || isFloat(t) || isComplex(t) }
func isInt(t reflect.Type) bool {
return t.Kind() == reflect.Int ||
t.Kind() == reflect.Int8 ||
t.Kind() == reflect.Int16 ||
t.Kind() == reflect.Int32 ||
t.Kind() == reflect.Int64
}
func isUint(t reflect.Type) bool {
return t.Kind() == reflect.Uint ||
t.Kind() == reflect.Uint8 ||
t.Kind() == reflect.Uint16 ||
t.Kind() == reflect.Uint32 ||
t.Kind() == reflect.Uint64
}
func isFloat(t reflect.Type) bool { return t.Kind() == reflect.Float32 || t.Kind() == reflect.Float64 }
func isComplex(t reflect.Type) bool {
return t.Kind() == reflect.Complex64 || t.Kind() == reflect.Complex128
}