open-consul/agent/consul/server.go

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2013-12-06 23:43:07 +00:00
package consul
import (
"context"
"errors"
2013-12-06 23:43:07 +00:00
"fmt"
Adds support for snapshots and restores. (#2396) * Updates Raft library to get new snapshot/restore API. * Basic backup and restore working, but need some cleanup. * Breaks out a snapshot module and adds a SHA256 integrity check. * Adds snapshot ACL and fills in some missing comments. * Require a consistent read for snapshots. * Make sure snapshot works if ACLs aren't enabled. * Adds a bit of package documentation. * Returns an empty response from restore to avoid EOF errors. * Adds API client support for snapshots. * Makes internal file names match on-disk file snapshots. * Adds DC and token coverage for snapshot API test. * Adds missing documentation. * Adds a unit test for the snapshot client endpoint. * Moves the connection pool out of the client for easier testing. * Fixes an incidental issue in the prepared query unit test. I realized I had two servers in bootstrap mode so this wasn't a good setup. * Adds a half close to the TCP stream and fixes panic on error. * Adds client and endpoint tests for snapshots. * Moves the pool back into the snapshot RPC client. * Adds a TLS test and fixes half-closes for TLS connections. * Tweaks some comments. * Adds a low-level snapshot test. This is independent of Consul so we can pull this out into a library later if we want to. * Cleans up snapshot and archive and completes archive tests. * Sends a clear error for snapshot operations in dev mode. Snapshots require the Raft snapshots to be readable, which isn't supported in dev mode. Send a clear error instead of a deep-down Raft one. * Adds docs for the snapshot endpoint. * Adds a stale mode and index feedback for snapshot saves. This gives folks a way to extract data even if the cluster has no leader. * Changes the internal format of a snapshot from zip to tgz. * Pulls in Raft fix to cancel inflight before a restore. * Pulls in new Raft restore interface. * Adds metadata to snapshot saves and a verify function. * Adds basic save and restore snapshot CLI commands. * Gets rid of tarball extensions and adds restore message. * Fixes an incidental bad link in the KV docs. * Adds documentation for the snapshot CLI commands. * Scuttle any request body when a snapshot is saved. * Fixes archive unit test error message check. * Allows for nil output writers in snapshot RPC handlers. * Renames hash list Decode to DecodeAndVerify. * Closes the client connection for snapshot ops. * Lowers timeout for restore ops. * Updates Raft vendor to get new Restore signature and integrates with Consul. * Bounces the leader's internal state when we do a restore.
2016-10-26 02:20:24 +00:00
"io"
"io/ioutil"
2013-12-07 00:35:13 +00:00
"net"
"net/rpc"
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"os"
"path/filepath"
"reflect"
"strconv"
"strings"
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"sync"
"sync/atomic"
"time"
metrics "github.com/armon/go-metrics"
connlimit "github.com/hashicorp/go-connlimit"
"github.com/hashicorp/go-hclog"
"github.com/hashicorp/go-memdb"
"github.com/hashicorp/memberlist"
"github.com/hashicorp/raft"
raftboltdb "github.com/hashicorp/raft-boltdb"
"github.com/hashicorp/serf/serf"
"golang.org/x/time/rate"
"google.golang.org/grpc"
"github.com/hashicorp/consul/acl"
2018-05-09 22:12:31 +00:00
ca "github.com/hashicorp/consul/agent/connect/ca"
"github.com/hashicorp/consul/agent/consul/authmethod"
"github.com/hashicorp/consul/agent/consul/authmethod/ssoauth"
2017-12-12 00:38:52 +00:00
"github.com/hashicorp/consul/agent/consul/autopilot"
"github.com/hashicorp/consul/agent/consul/fsm"
pkg refactor command/agent/* -> agent/* command/consul/* -> agent/consul/* command/agent/command{,_test}.go -> command/agent{,_test}.go command/base/command.go -> command/base.go command/base/* -> command/* commands.go -> command/commands.go The script which did the refactor is: ( cd $GOPATH/src/github.com/hashicorp/consul git mv command/agent/command.go command/agent.go git mv command/agent/command_test.go command/agent_test.go git mv command/agent/flag_slice_value{,_test}.go command/ git mv command/agent . git mv command/base/command.go command/base.go git mv command/base/config_util{,_test}.go command/ git mv commands.go command/ git mv consul agent rmdir command/base/ gsed -i -e 's|package agent|package command|' command/agent{,_test}.go gsed -i -e 's|package agent|package command|' command/flag_slice_value{,_test}.go gsed -i -e 's|package base|package command|' command/base.go command/config_util{,_test}.go gsed -i -e 's|package main|package command|' command/commands.go gsed -i -e 's|base.Command|BaseCommand|' command/commands.go gsed -i -e 's|agent.Command|AgentCommand|' command/commands.go gsed -i -e 's|\tCommand:|\tBaseCommand:|' command/commands.go gsed -i -e 's|base\.||' command/commands.go gsed -i -e 's|command\.||' command/commands.go gsed -i -e 's|command|c|' main.go gsed -i -e 's|range Commands|range command.Commands|' main.go gsed -i -e 's|Commands: Commands|Commands: command.Commands|' main.go gsed -i -e 's|base\.BoolValue|BoolValue|' command/operator_autopilot_set.go gsed -i -e 's|base\.DurationValue|DurationValue|' command/operator_autopilot_set.go gsed -i -e 's|base\.StringValue|StringValue|' command/operator_autopilot_set.go gsed -i -e 's|base\.UintValue|UintValue|' command/operator_autopilot_set.go gsed -i -e 's|\bCommand\b|BaseCommand|' command/base.go gsed -i -e 's|BaseCommand Options|Command Options|' command/base.go gsed -i -e 's|base.Command|BaseCommand|' command/*.go gsed -i -e 's|c\.Command|c.BaseCommand|g' command/*.go gsed -i -e 's|\tCommand:|\tBaseCommand:|' command/*_test.go gsed -i -e 's|base\.||' command/*_test.go gsed -i -e 's|\bCommand\b|AgentCommand|' command/agent{,_test}.go gsed -i -e 's|cmd.AgentCommand|cmd.BaseCommand|' command/agent.go gsed -i -e 's|cli.AgentCommand = new(Command)|cli.Command = new(AgentCommand)|' command/agent_test.go gsed -i -e 's|exec.AgentCommand|exec.Command|' command/agent_test.go gsed -i -e 's|exec.BaseCommand|exec.Command|' command/agent_test.go gsed -i -e 's|NewTestAgent|agent.NewTestAgent|' command/agent_test.go gsed -i -e 's|= TestConfig|= agent.TestConfig|' command/agent_test.go gsed -i -e 's|: RetryJoin|: agent.RetryJoin|' command/agent_test.go gsed -i -e 's|\.\./\.\./|../|' command/config_util_test.go gsed -i -e 's|\bverifyUniqueListeners|VerifyUniqueListeners|' agent/config{,_test}.go command/agent.go gsed -i -e 's|\bserfLANKeyring\b|SerfLANKeyring|g' agent/{agent,keyring,testagent}.go command/agent.go gsed -i -e 's|\bserfWANKeyring\b|SerfWANKeyring|g' agent/{agent,keyring,testagent}.go command/agent.go gsed -i -e 's|\bNewAgent\b|agent.New|g' command/agent{,_test}.go gsed -i -e 's|\bNewAgent|New|' agent/{acl_test,agent,testagent}.go gsed -i -e 's|\bAgent\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bBool\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bConfig\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bDefaultConfig\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bDevConfig\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bMergeConfig\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bReadConfigPaths\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bParseMetaPair\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bSerfLANKeyring\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|\bSerfWANKeyring\b|agent.&|g' command/agent{,_test}.go gsed -i -e 's|circonus\.agent|circonus|g' command/agent{,_test}.go gsed -i -e 's|logger\.agent|logger|g' command/agent{,_test}.go gsed -i -e 's|metrics\.agent|metrics|g' command/agent{,_test}.go gsed -i -e 's|// agent.Agent|// agent|' command/agent{,_test}.go gsed -i -e 's|a\.agent\.Config|a.Config|' command/agent{,_test}.go gsed -i -e 's|agent\.AppendSliceValue|AppendSliceValue|' command/{configtest,validate}.go gsed -i -e 's|consul/consul|agent/consul|' GNUmakefile gsed -i -e 's|\.\./test|../../test|' agent/consul/server_test.go # fix imports f=$(grep -rl 'github.com/hashicorp/consul/command/agent' * | grep '\.go') gsed -i -e 's|github.com/hashicorp/consul/command/agent|github.com/hashicorp/consul/agent|' $f goimports -w $f f=$(grep -rl 'github.com/hashicorp/consul/consul' * | grep '\.go') gsed -i -e 's|github.com/hashicorp/consul/consul|github.com/hashicorp/consul/agent/consul|' $f goimports -w $f goimports -w command/*.go main.go )
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"github.com/hashicorp/consul/agent/consul/state"
"github.com/hashicorp/consul/agent/consul/usagemetrics"
agentgrpc "github.com/hashicorp/consul/agent/grpc"
"github.com/hashicorp/consul/agent/metadata"
"github.com/hashicorp/consul/agent/pool"
"github.com/hashicorp/consul/agent/router"
"github.com/hashicorp/consul/agent/rpc/subscribe"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/agent/token"
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"github.com/hashicorp/consul/lib"
"github.com/hashicorp/consul/logging"
"github.com/hashicorp/consul/proto/pbsubscribe"
"github.com/hashicorp/consul/tlsutil"
"github.com/hashicorp/consul/types"
2013-12-06 23:43:07 +00:00
)
// These are the protocol versions that Consul can _understand_. These are
// Consul-level protocol versions, that are used to configure the Serf
// protocol versions.
const (
DefaultRPCProtocol = 2
ProtocolVersionMin uint8 = 2
// Version 3 added support for network coordinates but we kept the
// default protocol version at 2 to ease the transition to this new
// feature. A Consul agent speaking version 2 of the protocol will
// attempt to send its coordinates to a server who understands version
// 3 or greater.
ProtocolVersion2Compatible = 2
ProtocolVersionMax = 3
)
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const (
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serfLANSnapshot = "serf/local.snapshot"
serfWANSnapshot = "serf/remote.snapshot"
raftState = "raft/"
snapshotsRetained = 2
// raftLogCacheSize is the maximum number of logs to cache in-memory.
2015-09-11 19:24:54 +00:00
// This is used to reduce disk I/O for the recently committed entries.
raftLogCacheSize = 512
// raftRemoveGracePeriod is how long we wait to allow a RemovePeer
// to replicate to gracefully leave the cluster.
raftRemoveGracePeriod = 5 * time.Second
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// serfEventChSize is the size of the buffered channel to get Serf
// events. If this is exhausted we will block Serf and Memberlist.
serfEventChSize = 2048
// reconcileChSize is the size of the buffered channel reconcile updates
// from Serf with the Catalog. If this is exhausted we will drop updates,
// and wait for a periodic reconcile.
reconcileChSize = 256
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)
const (
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
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legacyACLReplicationRoutineName = "legacy ACL replication"
aclPolicyReplicationRoutineName = "ACL policy replication"
aclRoleReplicationRoutineName = "ACL role replication"
aclTokenReplicationRoutineName = "ACL token replication"
aclTokenReapingRoutineName = "acl token reaping"
aclUpgradeRoutineName = "legacy ACL token upgrade"
caRootPruningRoutineName = "CA root pruning"
configReplicationRoutineName = "config entry replication"
federationStateReplicationRoutineName = "federation state replication"
federationStateAntiEntropyRoutineName = "federation state anti-entropy"
federationStatePruningRoutineName = "federation state pruning"
connect: intentions are now managed as a new config entry kind "service-intentions" (#8834) - Upgrade the ConfigEntry.ListAll RPC to be kind-aware so that older copies of consul will not see new config entries it doesn't understand replicate down. - Add shim conversion code so that the old API/CLI method of interacting with intentions will continue to work so long as none of these are edited via config entry endpoints. Almost all of the read-only APIs will continue to function indefinitely. - Add new APIs that operate on individual intentions without IDs so that the UI doesn't need to implement CAS operations. - Add a new serf feature flag indicating support for intentions-as-config-entries. - The old line-item intentions way of interacting with the state store will transparently flip between the legacy memdb table and the config entry representations so that readers will never see a hiccup during migration where the results are incomplete. It uses a piece of system metadata to control the flip. - The primary datacenter will begin migrating intentions into config entries on startup once all servers in the datacenter are on a version of Consul with the intentions-as-config-entries feature flag. When it is complete the old state store representations will be cleared. We also record a piece of system metadata indicating this has occurred. We use this metadata to skip ALL of this code the next time the leader starts up. - The secondary datacenters continue to run the old intentions replicator until all servers in the secondary DC and primary DC support intentions-as-config-entries (via serf flag). Once this condition it met the old intentions replicator ceases. - The secondary datacenters replicate the new config entries as they are migrated in the primary. When they detect that the primary has zeroed it's old state store table it waits until all config entries up to that point are replicated and then zeroes its own copy of the old state store table. We also record a piece of system metadata indicating this has occurred. We use this metadata to skip ALL of this code the next time the leader starts up.
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intentionMigrationRoutineName = "intention config entry migration"
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
secondaryCARootWatchRoutineName = "secondary CA roots watch"
intermediateCertRenewWatchRoutineName = "intermediate cert renew watch"
)
var (
ErrWANFederationDisabled = fmt.Errorf("WAN Federation is disabled")
)
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// Server is Consul server which manages the service discovery,
// health checking, DC forwarding, Raft, and multiple Serf pools.
type Server struct {
// queriesBlocking is a counter that we incr and decr atomically in
// rpc calls to provide telemetry on how many blocking queries are running.
// We interact with queriesBlocking atomically, do not move without ensuring it is
// correctly 64-byte aligned in the struct layout
queriesBlocking uint64
// aclConfig is the configuration for the ACL system
aclConfig *acl.Config
New ACLs (#4791) This PR is almost a complete rewrite of the ACL system within Consul. It brings the features more in line with other HashiCorp products. Obviously there is quite a bit left to do here but most of it is related docs, testing and finishing the last few commands in the CLI. I will update the PR description and check off the todos as I finish them over the next few days/week. Description At a high level this PR is mainly to split ACL tokens from Policies and to split the concepts of Authorization from Identities. A lot of this PR is mostly just to support CRUD operations on ACLTokens and ACLPolicies. These in and of themselves are not particularly interesting. The bigger conceptual changes are in how tokens get resolved, how backwards compatibility is handled and the separation of policy from identity which could lead the way to allowing for alternative identity providers. On the surface and with a new cluster the ACL system will look very similar to that of Nomads. Both have tokens and policies. Both have local tokens. The ACL management APIs for both are very similar. I even ripped off Nomad's ACL bootstrap resetting procedure. There are a few key differences though. Nomad requires token and policy replication where Consul only requires policy replication with token replication being opt-in. In Consul local tokens only work with token replication being enabled though. All policies in Nomad are globally applicable. In Consul all policies are stored and replicated globally but can be scoped to a subset of the datacenters. This allows for more granular access management. Unlike Nomad, Consul has legacy baggage in the form of the original ACL system. The ramifications of this are: A server running the new system must still support other clients using the legacy system. A client running the new system must be able to use the legacy RPCs when the servers in its datacenter are running the legacy system. The primary ACL DC's servers running in legacy mode needs to be a gate that keeps everything else in the entire multi-DC cluster running in legacy mode. So not only does this PR implement the new ACL system but has a legacy mode built in for when the cluster isn't ready for new ACLs. Also detecting that new ACLs can be used is automatic and requires no configuration on the part of administrators. This process is detailed more in the "Transitioning from Legacy to New ACL Mode" section below.
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// acls is used to resolve tokens to effective policies
acls *ACLResolver
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aclAuthMethodValidators authmethod.Cache
New ACLs (#4791) This PR is almost a complete rewrite of the ACL system within Consul. It brings the features more in line with other HashiCorp products. Obviously there is quite a bit left to do here but most of it is related docs, testing and finishing the last few commands in the CLI. I will update the PR description and check off the todos as I finish them over the next few days/week. Description At a high level this PR is mainly to split ACL tokens from Policies and to split the concepts of Authorization from Identities. A lot of this PR is mostly just to support CRUD operations on ACLTokens and ACLPolicies. These in and of themselves are not particularly interesting. The bigger conceptual changes are in how tokens get resolved, how backwards compatibility is handled and the separation of policy from identity which could lead the way to allowing for alternative identity providers. On the surface and with a new cluster the ACL system will look very similar to that of Nomads. Both have tokens and policies. Both have local tokens. The ACL management APIs for both are very similar. I even ripped off Nomad's ACL bootstrap resetting procedure. There are a few key differences though. Nomad requires token and policy replication where Consul only requires policy replication with token replication being opt-in. In Consul local tokens only work with token replication being enabled though. All policies in Nomad are globally applicable. In Consul all policies are stored and replicated globally but can be scoped to a subset of the datacenters. This allows for more granular access management. Unlike Nomad, Consul has legacy baggage in the form of the original ACL system. The ramifications of this are: A server running the new system must still support other clients using the legacy system. A client running the new system must be able to use the legacy RPCs when the servers in its datacenter are running the legacy system. The primary ACL DC's servers running in legacy mode needs to be a gate that keeps everything else in the entire multi-DC cluster running in legacy mode. So not only does this PR implement the new ACL system but has a legacy mode built in for when the cluster isn't ready for new ACLs. Also detecting that new ACLs can be used is automatic and requires no configuration on the part of administrators. This process is detailed more in the "Transitioning from Legacy to New ACL Mode" section below.
2018-10-19 16:04:07 +00:00
// DEPRECATED (ACL-Legacy-Compat) - only needed while we support both
// useNewACLs is used to determine whether we can use new ACLs or not
useNewACLs int32
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// autopilot is the Autopilot instance for this server.
autopilot *autopilot.Autopilot
// autopilotWaitGroup is used to block until Autopilot shuts down.
autopilotWaitGroup sync.WaitGroup
// caProviderReconfigurationLock guards the provider reconfiguration.
caProviderReconfigurationLock sync.Mutex
// caProvider is the current CA provider in use for Connect. This is
// only non-nil when we are the leader.
caProvider ca.Provider
// caProviderRoot is the CARoot that was stored along with the ca.Provider
// active. It's only updated in lock-step with the caProvider. This prevents
// races between state updates to active roots and the fetch of the provider
// instance.
caProviderRoot *structs.CARoot
caProviderLock sync.RWMutex
// rate limiter to use when signing leaf certificates
caLeafLimiter connectSignRateLimiter
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// Consul configuration
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config *Config
// configReplicator is used to manage the leaders replication routines for
// centralized config
configReplicator *Replicator
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
// federationStateReplicator is used to manage the leaders replication routines for
// federation states
federationStateReplicator *Replicator
// dcSupportsFederationStates is used to determine whether we can
// replicate federation states or not. All servers in the local
// DC must be on a version of Consul supporting federation states
// before this will get enabled.
dcSupportsFederationStates int32
// tokens holds ACL tokens initially from the configuration, but can
// be updated at runtime, so should always be used instead of going to
// the configuration directly.
tokens *token.Store
2013-12-09 20:09:57 +00:00
// Connection pool to other consul servers
connPool *pool.ConnPool
2013-12-09 20:09:57 +00:00
// eventChLAN is used to receive events from the
// serf cluster in the datacenter
eventChLAN chan serf.Event
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// eventChWAN is used to receive events from the
// serf cluster that spans datacenters
eventChWAN chan serf.Event
2013-12-06 23:43:07 +00:00
// fsm is the state machine used with Raft to provide
// strong consistency.
fsm *fsm.FSM
2013-12-06 23:43:07 +00:00
// Logger uses the provided LogOutput
logger hclog.InterceptLogger
loggers *loggerStore
2013-12-06 23:43:07 +00:00
// The raft instance is used among Consul nodes within the DC to protect
// operations that require strong consistency.
// the state directly.
raft *raft.Raft
raftLayer *RaftLayer
2015-01-30 05:55:11 +00:00
raftStore *raftboltdb.BoltStore
raftTransport *raft.NetworkTransport
2015-11-29 04:40:05 +00:00
raftInmem *raft.InmemStore
2013-12-06 23:43:07 +00:00
2017-07-06 14:09:21 +00:00
// raftNotifyCh is set up by setupRaft() and ensures that we get reliable leader
// transition notifications from the Raft layer.
2017-07-06 14:09:21 +00:00
raftNotifyCh <-chan bool
// reconcileCh is used to pass events from the serf handler
// into the leader manager, so that the strong state can be
// updated
reconcileCh chan serf.Member
// readyForConsistentReads is used to track when the leader server is
// ready to serve consistent reads, after it has applied its initial
// barrier. This is updated atomically.
readyForConsistentReads int32
// leaveCh is used to signal that the server is leaving the cluster
// and trying to shed its RPC traffic onto other Consul servers. This
// is only ever closed.
leaveCh chan struct{}
// router is used to map out Consul servers in the WAN and in Consul
// Enterprise user-defined areas.
router *router.Router
2013-12-12 00:24:34 +00:00
// rpcLimiter is used to rate limit the total number of RPCs initiated
// from an agent.
rpcLimiter atomic.Value
// rpcConnLimiter limits the number of RPC connections from a single source IP
rpcConnLimiter connlimit.Limiter
2017-06-25 19:36:03 +00:00
// Listener is used to listen for incoming connections
Listener net.Listener
grpcHandler connHandler
rpcServer *rpc.Server
2013-12-07 00:35:13 +00:00
// insecureRPCServer is a RPC server that is configure with
// IncomingInsecureRPCConfig to allow clients to call AutoEncrypt.Sign
// to request client certificates. At this point a client doesn't have
// a client cert and thus cannot present it. This is the only RPC
// Endpoint that is available at the time of writing.
insecureRPCServer *rpc.Server
// tlsConfigurator holds the agent configuration relevant to TLS and
// configures everything related to it.
tlsConfigurator *tlsutil.Configurator
// serfLAN is the Serf cluster maintained inside the DC
2013-12-06 23:43:07 +00:00
// which contains all the DC nodes
serfLAN *serf.Serf
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// segmentLAN maps segment names to their Serf cluster
segmentLAN map[string]*serf.Serf
// serfWAN is the Serf cluster maintained between DC's
2013-12-06 23:43:07 +00:00
// which SHOULD only consist of Consul servers
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
serfWAN *serf.Serf
memberlistTransportWAN memberlist.IngestionAwareTransport
gatewayLocator *GatewayLocator
2013-12-06 23:43:07 +00:00
// serverLookup tracks server consuls in the local datacenter.
// Used to do leader forwarding and provide fast lookup by server id and address
serverLookup *ServerLookup
// floodLock controls access to floodCh.
floodLock sync.RWMutex
floodCh []chan struct{}
2017-03-15 19:26:54 +00:00
// sessionTimers track the expiration time of each Session that has
// a TTL. On expiration, a SessionDestroy event will occur, and
2015-09-11 19:24:54 +00:00
// destroy the session via standard session destroy processing
sessionTimers *SessionTimers
// statsFetcher is used by autopilot to check the status of the other
// Consul router.
statsFetcher *StatsFetcher
// reassertLeaderCh is used to signal the leader loop should re-run
// leadership actions after a snapshot restore.
reassertLeaderCh chan chan error
2014-12-11 07:49:44 +00:00
// tombstoneGC is used to track the pending GC invocations
// for the KV tombstones
tombstoneGC *state.TombstoneGC
2014-12-11 07:49:44 +00:00
// aclReplicationStatus (and its associated lock) provide information
// about the health of the ACL replication goroutine.
aclReplicationStatus structs.ACLReplicationStatus
aclReplicationStatusLock sync.RWMutex
2016-08-03 05:04:11 +00:00
// shutdown and the associated members here are used in orchestrating
// a clean shutdown. The shutdownCh is never written to, only closed to
2016-08-04 00:01:32 +00:00
// indicate a shutdown has been initiated.
2013-12-06 23:43:07 +00:00
shutdown bool
shutdownCh chan struct{}
shutdownLock sync.Mutex
// State for whether this datacenter is acting as a secondary CA.
actingSecondaryCA bool
actingSecondaryLock sync.RWMutex
connect: intentions are now managed as a new config entry kind "service-intentions" (#8834) - Upgrade the ConfigEntry.ListAll RPC to be kind-aware so that older copies of consul will not see new config entries it doesn't understand replicate down. - Add shim conversion code so that the old API/CLI method of interacting with intentions will continue to work so long as none of these are edited via config entry endpoints. Almost all of the read-only APIs will continue to function indefinitely. - Add new APIs that operate on individual intentions without IDs so that the UI doesn't need to implement CAS operations. - Add a new serf feature flag indicating support for intentions-as-config-entries. - The old line-item intentions way of interacting with the state store will transparently flip between the legacy memdb table and the config entry representations so that readers will never see a hiccup during migration where the results are incomplete. It uses a piece of system metadata to control the flip. - The primary datacenter will begin migrating intentions into config entries on startup once all servers in the datacenter are on a version of Consul with the intentions-as-config-entries feature flag. When it is complete the old state store representations will be cleared. We also record a piece of system metadata indicating this has occurred. We use this metadata to skip ALL of this code the next time the leader starts up. - The secondary datacenters continue to run the old intentions replicator until all servers in the secondary DC and primary DC support intentions-as-config-entries (via serf flag). Once this condition it met the old intentions replicator ceases. - The secondary datacenters replicate the new config entries as they are migrated in the primary. When they detect that the primary has zeroed it's old state store table it waits until all config entries up to that point are replicated and then zeroes its own copy of the old state store table. We also record a piece of system metadata indicating this has occurred. We use this metadata to skip ALL of this code the next time the leader starts up.
2020-10-06 18:24:05 +00:00
// dcSupportsIntentionsAsConfigEntries is used to determine whether we can
// migrate old intentions into service-intentions config entries. All
// servers in the local DC must be on a version of Consul supporting
// service-intentions before this will get enabled.
dcSupportsIntentionsAsConfigEntries int32
// Manager to handle starting/stopping go routines when establishing/revoking raft leadership
leaderRoutineManager *LeaderRoutineManager
// embedded struct to hold all the enterprise specific data
EnterpriseServer
2013-12-06 23:43:07 +00:00
}
type connHandler interface {
Run() error
Handle(conn net.Conn)
Shutdown() error
}
// NewServer is used to construct a new Consul server from the configuration
// and extra options, potentially returning an error.
func NewServer(config *Config, flat Deps) (*Server, error) {
logger := flat.Logger
2017-05-03 19:02:01 +00:00
if err := config.CheckProtocolVersion(); err != nil {
return nil, err
}
2015-11-29 04:40:05 +00:00
if config.DataDir == "" && !config.DevMode {
2013-12-06 23:43:07 +00:00
return nil, fmt.Errorf("Config must provide a DataDir")
}
2014-08-05 22:20:35 +00:00
if err := config.CheckACL(); err != nil {
return nil, err
}
2013-12-06 23:43:07 +00:00
// Check if TLS is enabled
if config.CAFile != "" || config.CAPath != "" {
config.UseTLS = true
}
// Set the primary DC if it wasn't set.
if config.PrimaryDatacenter == "" {
if config.ACLDatacenter != "" {
config.PrimaryDatacenter = config.ACLDatacenter
} else {
config.PrimaryDatacenter = config.Datacenter
}
}
if config.PrimaryDatacenter != "" {
config.ACLDatacenter = config.PrimaryDatacenter
}
2016-08-03 05:04:11 +00:00
// Create the tombstone GC.
gc, err := state.NewTombstoneGC(config.TombstoneTTL, config.TombstoneTTLGranularity)
2014-12-11 07:49:44 +00:00
if err != nil {
return nil, err
}
// Create the shutdown channel - this is closed but never written to.
shutdownCh := make(chan struct{})
serverLogger := flat.Logger.NamedIntercept(logging.ConsulServer)
loggers := newLoggerStore(serverLogger)
2016-08-03 05:04:11 +00:00
// Create server.
2013-12-06 23:43:07 +00:00
s := &Server{
config: config,
tokens: flat.Tokens,
connPool: flat.ConnPool,
eventChLAN: make(chan serf.Event, serfEventChSize),
eventChWAN: make(chan serf.Event, serfEventChSize),
logger: serverLogger,
loggers: loggers,
leaveCh: make(chan struct{}),
reconcileCh: make(chan serf.Member, reconcileChSize),
router: flat.Router,
rpcServer: rpc.NewServer(),
insecureRPCServer: rpc.NewServer(),
tlsConfigurator: flat.TLSConfigurator,
reassertLeaderCh: make(chan chan error),
segmentLAN: make(map[string]*serf.Serf, len(config.Segments)),
sessionTimers: NewSessionTimers(),
tombstoneGC: gc,
serverLookup: NewServerLookup(),
shutdownCh: shutdownCh,
leaderRoutineManager: NewLeaderRoutineManager(logger),
aclAuthMethodValidators: authmethod.NewCache(),
fsm: newFSMFromConfig(flat.Logger, gc, config),
2013-12-06 23:43:07 +00:00
}
2017-03-21 23:36:44 +00:00
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
if s.config.ConnectMeshGatewayWANFederationEnabled {
s.gatewayLocator = NewGatewayLocator(
s.logger,
s,
s.config.Datacenter,
s.config.PrimaryDatacenter,
)
s.connPool.GatewayResolver = s.gatewayLocator.PickGateway
}
// Initialize enterprise specific server functionality
if err := s.initEnterprise(); err != nil {
s.Shutdown()
return nil, err
}
s.rpcLimiter.Store(rate.NewLimiter(config.RPCRate, config.RPCMaxBurst))
configReplicatorConfig := ReplicatorConfig{
Name: logging.ConfigEntry,
Delegate: &FunctionReplicator{ReplicateFn: s.replicateConfig},
Rate: s.config.ConfigReplicationRate,
Burst: s.config.ConfigReplicationBurst,
Logger: s.logger,
}
s.configReplicator, err = NewReplicator(&configReplicatorConfig)
if err != nil {
s.Shutdown()
return nil, err
}
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
federationStateReplicatorConfig := ReplicatorConfig{
Name: logging.FederationState,
Delegate: &IndexReplicator{
agent: handle re-bootstrapping in a secondary datacenter when WAN federation via mesh gateways is configured (#7931) The main fix here is to always union the `primary-gateways` list with the list of mesh gateways in the primary returned from the replicated federation states list. This will allow any replicated (incorrect) state to be supplemented with user-configured (correct) state in the config file. Eventually the game of random selection whack-a-mole will pick a winning entry and re-replicate the latest federation states from the primary. If the user-configured state is actually the incorrect one, then the same eventual correct selection process will work in that case, too. The secondary fix is actually to finish making wanfed-via-mgws actually work as originally designed. Once a secondary datacenter has replicated federation states for the primary AND managed to stand up its own local mesh gateways then all of the RPCs from a secondary to the primary SHOULD go through two sets of mesh gateways to arrive in the consul servers in the primary (one hop for the secondary datacenter's mesh gateway, and one hop through the primary datacenter's mesh gateway). This was neglected in the initial implementation. While everything works, ideally we should treat communications that go around the mesh gateways as just provided for bootstrapping purposes. Now we heuristically use the success/failure history of the federation state replicator goroutine loop to determine if our current mesh gateway route is working as intended. If it is, we try using the local gateways, and if those don't work we fall back on trying the primary via the union of the replicated state and the go-discover configuration flags. This can be improved slightly in the future by possibly initializing the gateway choice to local on startup if we already have replicated state. This PR does not address that improvement. Fixes #7339
2020-05-27 16:31:10 +00:00
Delegate: &FederationStateReplicator{
srv: s,
gatewayLocator: s.gatewayLocator,
},
Logger: s.loggers.Named(logging.Replication).Named(logging.FederationState),
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
},
Rate: s.config.FederationStateReplicationRate,
Burst: s.config.FederationStateReplicationBurst,
Logger: s.logger,
SuppressErrorLog: isErrFederationStatesNotSupported,
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
}
s.federationStateReplicator, err = NewReplicator(&federationStateReplicatorConfig)
if err != nil {
s.Shutdown()
return nil, err
}
// Initialize the stats fetcher that autopilot will use.
s.statsFetcher = NewStatsFetcher(logger, s.connPool, s.config.Datacenter)
s.aclConfig = newACLConfig(logger)
New ACLs (#4791) This PR is almost a complete rewrite of the ACL system within Consul. It brings the features more in line with other HashiCorp products. Obviously there is quite a bit left to do here but most of it is related docs, testing and finishing the last few commands in the CLI. I will update the PR description and check off the todos as I finish them over the next few days/week. Description At a high level this PR is mainly to split ACL tokens from Policies and to split the concepts of Authorization from Identities. A lot of this PR is mostly just to support CRUD operations on ACLTokens and ACLPolicies. These in and of themselves are not particularly interesting. The bigger conceptual changes are in how tokens get resolved, how backwards compatibility is handled and the separation of policy from identity which could lead the way to allowing for alternative identity providers. On the surface and with a new cluster the ACL system will look very similar to that of Nomads. Both have tokens and policies. Both have local tokens. The ACL management APIs for both are very similar. I even ripped off Nomad's ACL bootstrap resetting procedure. There are a few key differences though. Nomad requires token and policy replication where Consul only requires policy replication with token replication being opt-in. In Consul local tokens only work with token replication being enabled though. All policies in Nomad are globally applicable. In Consul all policies are stored and replicated globally but can be scoped to a subset of the datacenters. This allows for more granular access management. Unlike Nomad, Consul has legacy baggage in the form of the original ACL system. The ramifications of this are: A server running the new system must still support other clients using the legacy system. A client running the new system must be able to use the legacy RPCs when the servers in its datacenter are running the legacy system. The primary ACL DC's servers running in legacy mode needs to be a gate that keeps everything else in the entire multi-DC cluster running in legacy mode. So not only does this PR implement the new ACL system but has a legacy mode built in for when the cluster isn't ready for new ACLs. Also detecting that new ACLs can be used is automatic and requires no configuration on the part of administrators. This process is detailed more in the "Transitioning from Legacy to New ACL Mode" section below.
2018-10-19 16:04:07 +00:00
s.useNewACLs = 0
aclConfig := ACLResolverConfig{
Config: config,
Delegate: s,
CacheConfig: serverACLCacheConfig,
AutoDisable: false,
Logger: logger,
ACLConfig: s.aclConfig,
2014-08-08 22:32:43 +00:00
}
New ACLs (#4791) This PR is almost a complete rewrite of the ACL system within Consul. It brings the features more in line with other HashiCorp products. Obviously there is quite a bit left to do here but most of it is related docs, testing and finishing the last few commands in the CLI. I will update the PR description and check off the todos as I finish them over the next few days/week. Description At a high level this PR is mainly to split ACL tokens from Policies and to split the concepts of Authorization from Identities. A lot of this PR is mostly just to support CRUD operations on ACLTokens and ACLPolicies. These in and of themselves are not particularly interesting. The bigger conceptual changes are in how tokens get resolved, how backwards compatibility is handled and the separation of policy from identity which could lead the way to allowing for alternative identity providers. On the surface and with a new cluster the ACL system will look very similar to that of Nomads. Both have tokens and policies. Both have local tokens. The ACL management APIs for both are very similar. I even ripped off Nomad's ACL bootstrap resetting procedure. There are a few key differences though. Nomad requires token and policy replication where Consul only requires policy replication with token replication being opt-in. In Consul local tokens only work with token replication being enabled though. All policies in Nomad are globally applicable. In Consul all policies are stored and replicated globally but can be scoped to a subset of the datacenters. This allows for more granular access management. Unlike Nomad, Consul has legacy baggage in the form of the original ACL system. The ramifications of this are: A server running the new system must still support other clients using the legacy system. A client running the new system must be able to use the legacy RPCs when the servers in its datacenter are running the legacy system. The primary ACL DC's servers running in legacy mode needs to be a gate that keeps everything else in the entire multi-DC cluster running in legacy mode. So not only does this PR implement the new ACL system but has a legacy mode built in for when the cluster isn't ready for new ACLs. Also detecting that new ACLs can be used is automatic and requires no configuration on the part of administrators. This process is detailed more in the "Transitioning from Legacy to New ACL Mode" section below.
2018-10-19 16:04:07 +00:00
// Initialize the ACL resolver.
if s.acls, err = NewACLResolver(&aclConfig); err != nil {
2014-08-08 22:32:43 +00:00
s.Shutdown()
New ACLs (#4791) This PR is almost a complete rewrite of the ACL system within Consul. It brings the features more in line with other HashiCorp products. Obviously there is quite a bit left to do here but most of it is related docs, testing and finishing the last few commands in the CLI. I will update the PR description and check off the todos as I finish them over the next few days/week. Description At a high level this PR is mainly to split ACL tokens from Policies and to split the concepts of Authorization from Identities. A lot of this PR is mostly just to support CRUD operations on ACLTokens and ACLPolicies. These in and of themselves are not particularly interesting. The bigger conceptual changes are in how tokens get resolved, how backwards compatibility is handled and the separation of policy from identity which could lead the way to allowing for alternative identity providers. On the surface and with a new cluster the ACL system will look very similar to that of Nomads. Both have tokens and policies. Both have local tokens. The ACL management APIs for both are very similar. I even ripped off Nomad's ACL bootstrap resetting procedure. There are a few key differences though. Nomad requires token and policy replication where Consul only requires policy replication with token replication being opt-in. In Consul local tokens only work with token replication being enabled though. All policies in Nomad are globally applicable. In Consul all policies are stored and replicated globally but can be scoped to a subset of the datacenters. This allows for more granular access management. Unlike Nomad, Consul has legacy baggage in the form of the original ACL system. The ramifications of this are: A server running the new system must still support other clients using the legacy system. A client running the new system must be able to use the legacy RPCs when the servers in its datacenter are running the legacy system. The primary ACL DC's servers running in legacy mode needs to be a gate that keeps everything else in the entire multi-DC cluster running in legacy mode. So not only does this PR implement the new ACL system but has a legacy mode built in for when the cluster isn't ready for new ACLs. Also detecting that new ACLs can be used is automatic and requires no configuration on the part of administrators. This process is detailed more in the "Transitioning from Legacy to New ACL Mode" section below.
2018-10-19 16:04:07 +00:00
return nil, fmt.Errorf("Failed to create ACL resolver: %v", err)
2014-08-09 00:38:39 +00:00
}
2016-08-03 05:04:11 +00:00
// Initialize the RPC layer.
if err := s.setupRPC(); err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start RPC layer: %v", err)
}
// Initialize any extra RPC listeners for segments.
segmentListeners, err := s.setupSegmentRPC()
if err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start segment RPC layer: %v", err)
}
2016-08-03 05:04:11 +00:00
// Initialize the Raft server.
2013-12-09 23:29:01 +00:00
if err := s.setupRaft(); err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start Raft: %v", err)
}
if s.config.ConnectEnabled && (s.config.AutoEncryptAllowTLS || s.config.AutoConfigAuthzEnabled) {
go s.connectCARootsMonitor(&lib.StopChannelContext{StopCh: s.shutdownCh})
}
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
if s.gatewayLocator != nil {
go s.gatewayLocator.Run(&lib.StopChannelContext{StopCh: s.shutdownCh})
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
}
// Serf and dynamic bind ports
//
// The LAN serf cluster announces the port of the WAN serf cluster
// which creates a race when the WAN cluster is supposed to bind to
// a dynamic port (port 0). The current memberlist implementation will
// update the bind port in the configuration after the memberlist is
// created, so we can pull it out from there reliably, even though it's
// a little gross to be reading the updated config.
// Initialize the WAN Serf if enabled
serfBindPortWAN := -1
if config.SerfWANConfig != nil {
serfBindPortWAN = config.SerfWANConfig.MemberlistConfig.BindPort
s.serfWAN, err = s.setupSerf(config.SerfWANConfig, s.eventChWAN, serfWANSnapshot, true, serfBindPortWAN, "", s.Listener)
if err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start WAN Serf: %v", err)
}
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
// This is always a *memberlist.NetTransport or something which wraps
// it which satisfies this interface.
s.memberlistTransportWAN = config.SerfWANConfig.MemberlistConfig.Transport.(memberlist.IngestionAwareTransport)
// See big comment above why we are doing this.
if serfBindPortWAN == 0 {
serfBindPortWAN = config.SerfWANConfig.MemberlistConfig.BindPort
if serfBindPortWAN == 0 {
return nil, fmt.Errorf("Failed to get dynamic bind port for WAN Serf")
}
s.logger.Info("Serf WAN TCP bound", "port", serfBindPortWAN)
}
}
// Initialize the LAN segments before the default LAN Serf so we have
// updated port information to publish there.
2017-09-01 00:56:43 +00:00
if err := s.setupSegments(config, serfBindPortWAN, segmentListeners); err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to setup network segments: %v", err)
}
// Initialize the LAN Serf for the default network segment.
s.serfLAN, err = s.setupSerf(config.SerfLANConfig, s.eventChLAN, serfLANSnapshot, false, serfBindPortWAN, "", s.Listener)
2013-12-06 23:43:07 +00:00
if err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start LAN Serf: %v", err)
}
if err := s.router.AddArea(types.AreaLAN, s.serfLAN, s.connPool); err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to add LAN serf route: %w", err)
}
go s.lanEventHandler()
// Start the flooders after the LAN event handler is wired up.
s.floodSegments(config)
// Add a "static route" to the WAN Serf and hook it up to Serf events.
if s.serfWAN != nil {
if err := s.router.AddArea(types.AreaWAN, s.serfWAN, s.connPool); err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to add WAN serf route: %v", err)
}
go router.HandleSerfEvents(s.logger, s.router, types.AreaWAN, s.serfWAN.ShutdownCh(), s.eventChWAN)
2013-12-06 23:43:07 +00:00
// Fire up the LAN <-> WAN join flooder.
2020-04-27 08:21:05 +00:00
addrFn := func(s *metadata.Server) (string, error) {
if s.WanJoinPort == 0 {
return "", fmt.Errorf("no wan join port for server: %s", s.Addr.String())
}
2020-04-27 08:21:05 +00:00
addr, _, err := net.SplitHostPort(s.Addr.String())
if err != nil {
return "", err
}
return fmt.Sprintf("%s:%d", addr, s.WanJoinPort), nil
2017-03-15 19:26:54 +00:00
}
2020-04-27 08:21:05 +00:00
go s.Flood(addrFn, s.serfWAN)
}
2018-06-29 21:38:29 +00:00
// Start enterprise specific functionality
if err := s.startEnterprise(); err != nil {
s.Shutdown()
return nil, err
}
reporter, err := usagemetrics.NewUsageMetricsReporter(
new(usagemetrics.Config).
WithStateProvider(s.fsm).
WithLogger(s.logger).
WithDatacenter(s.config.Datacenter).
WithReportingInterval(s.config.MetricsReportingInterval),
)
if err != nil {
s.Shutdown()
return nil, fmt.Errorf("Failed to start usage metrics reporter: %v", err)
}
go reporter.Run(&lib.StopChannelContext{StopCh: s.shutdownCh})
s.grpcHandler = newGRPCHandlerFromConfig(flat, config, s)
// Initialize Autopilot. This must happen before starting leadership monitoring
// as establishing leadership could attempt to use autopilot and cause a panic.
s.initAutopilot(config)
2013-12-06 23:43:07 +00:00
// Start monitoring leadership. This must happen after Serf is set up
// since it can fire events when leadership is obtained.
go s.monitorLeadership()
2016-08-03 05:04:11 +00:00
// Start listening for RPC requests.
go func() {
if err := s.grpcHandler.Run(); err != nil {
s.logger.Error("gRPC server failed", "error", err)
}
}()
go s.listen(s.Listener)
// Start listeners for any segments with separate RPC listeners.
for _, listener := range segmentListeners {
go s.listen(listener)
}
2014-12-19 00:57:49 +00:00
2016-08-03 05:04:11 +00:00
// Start the metrics handlers.
go s.updateMetrics()
2016-08-03 05:04:11 +00:00
2013-12-06 23:43:07 +00:00
return s, nil
}
func newFSMFromConfig(logger hclog.Logger, gc *state.TombstoneGC, config *Config) *fsm.FSM {
deps := fsm.Deps{Logger: logger}
if config.RPCConfig.EnableStreaming {
deps.NewStateStore = func() *state.Store {
return state.NewStateStoreWithEventPublisher(gc)
}
return fsm.NewFromDeps(deps)
}
deps.NewStateStore = func() *state.Store {
return state.NewStateStore(gc)
}
return fsm.NewFromDeps(deps)
}
func newGRPCHandlerFromConfig(deps Deps, config *Config, s *Server) connHandler {
if !config.RPCConfig.EnableStreaming {
return agentgrpc.NoOpHandler{Logger: deps.Logger}
}
register := func(srv *grpc.Server) {
pbsubscribe.RegisterStateChangeSubscriptionServer(srv, subscribe.NewServer(
&subscribeBackend{srv: s, connPool: deps.GRPCConnPool},
deps.Logger.Named("grpc-api.subscription")))
}
return agentgrpc.NewHandler(config.RPCAddr, register)
}
func (s *Server) connectCARootsMonitor(ctx context.Context) {
for {
ws := memdb.NewWatchSet()
state := s.fsm.State()
ws.Add(state.AbandonCh())
_, cas, err := state.CARoots(ws)
if err != nil {
s.logger.Error("Failed to watch AutoEncrypt CARoot", "error", err)
return
}
caPems := []string{}
for _, ca := range cas {
caPems = append(caPems, ca.RootCert)
}
if err := s.tlsConfigurator.UpdateAutoTLSCA(caPems); err != nil {
s.logger.Error("Failed to update AutoEncrypt CAPems", "error", err)
}
if err := ws.WatchCtx(ctx); err == context.Canceled {
s.logger.Info("shutting down Connect CA roots monitor")
return
}
}
}
2013-12-06 23:43:07 +00:00
// setupRaft is used to setup and initialize Raft
func (s *Server) setupRaft() error {
// If we have an unclean exit then attempt to close the Raft store.
defer func() {
if s.raft == nil && s.raftStore != nil {
if err := s.raftStore.Close(); err != nil {
s.logger.Error("failed to close Raft store", "error", err)
}
}
}()
var serverAddressProvider raft.ServerAddressProvider = nil
if s.config.RaftConfig.ProtocolVersion >= 3 { //ServerAddressProvider needs server ids to work correctly, which is only supported in protocol version 3 or higher
serverAddressProvider = s.serverLookup
}
// Create a transport layer.
transConfig := &raft.NetworkTransportConfig{
Stream: s.raftLayer,
MaxPool: 3,
Timeout: 10 * time.Second,
ServerAddressProvider: serverAddressProvider,
Logger: s.loggers.Named(logging.Raft),
}
trans := raft.NewNetworkTransportWithConfig(transConfig)
2015-11-29 04:40:05 +00:00
s.raftTransport = trans
s.config.RaftConfig.Logger = s.loggers.Named(logging.Raft)
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// Versions of the Raft protocol below 3 require the LocalID to match the network
// address of the transport.
s.config.RaftConfig.LocalID = raft.ServerID(trans.LocalAddr())
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if s.config.RaftConfig.ProtocolVersion >= 3 {
s.config.RaftConfig.LocalID = raft.ServerID(s.config.NodeID)
}
// Build an all in-memory setup for dev mode, otherwise prepare a full
// disk-based setup.
2015-11-29 04:40:05 +00:00
var log raft.LogStore
var stable raft.StableStore
var snap raft.SnapshotStore
if s.config.DevMode {
store := raft.NewInmemStore()
s.raftInmem = store
stable = store
log = store
2016-10-31 18:39:47 +00:00
snap = raft.NewInmemSnapshotStore()
2015-11-29 04:40:05 +00:00
} else {
// Create the base raft path.
2015-11-29 04:40:05 +00:00
path := filepath.Join(s.config.DataDir, raftState)
2017-01-18 06:20:11 +00:00
if err := lib.EnsurePath(path, true); err != nil {
2015-11-29 04:40:05 +00:00
return err
}
2013-12-06 23:43:07 +00:00
// Create the backend raft store for logs and stable storage.
2015-11-29 04:40:05 +00:00
store, err := raftboltdb.NewBoltStore(filepath.Join(path, "raft.db"))
if err != nil {
return err
}
s.raftStore = store
stable = store
// Wrap the store in a LogCache to improve performance.
2015-11-29 04:40:05 +00:00
cacheStore, err := raft.NewLogCache(raftLogCacheSize, store)
if err != nil {
return err
}
log = cacheStore
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// Create the snapshot store.
2020-07-29 20:05:51 +00:00
snapshots, err := raft.NewFileSnapshotStoreWithLogger(path, snapshotsRetained, s.logger.Named("snapshot"))
2015-11-29 04:40:05 +00:00
if err != nil {
return err
}
snap = snapshots
2013-12-06 23:43:07 +00:00
// For an existing cluster being upgraded to the new version of
// Raft, we almost never want to run recovery based on the old
// peers.json file. We create a peers.info file with a helpful
// note about where peers.json went, and use that as a sentinel
// to avoid ingesting the old one that first time (if we have to
// create the peers.info file because it's not there, we also
// blow away any existing peers.json file).
peersFile := filepath.Join(path, "peers.json")
peersInfoFile := filepath.Join(path, "peers.info")
if _, err := os.Stat(peersInfoFile); os.IsNotExist(err) {
if err := ioutil.WriteFile(peersInfoFile, []byte(peersInfoContent), 0755); err != nil {
return fmt.Errorf("failed to write peers.info file: %v", err)
}
// Blow away the peers.json file if present, since the
// peers.info sentinel wasn't there.
if _, err := os.Stat(peersFile); err == nil {
if err := os.Remove(peersFile); err != nil {
return fmt.Errorf("failed to delete peers.json, please delete manually (see peers.info for details): %v", err)
}
s.logger.Info("deleted peers.json file (see peers.info for details)")
}
} else if _, err := os.Stat(peersFile); err == nil {
s.logger.Info("found peers.json file, recovering Raft configuration...")
var configuration raft.Configuration
if s.config.RaftConfig.ProtocolVersion < 3 {
configuration, err = raft.ReadPeersJSON(peersFile)
} else {
configuration, err = raft.ReadConfigJSON(peersFile)
}
if err != nil {
return fmt.Errorf("recovery failed to parse peers.json: %v", err)
}
tmpFsm := fsm.NewFromDeps(fsm.Deps{
Logger: s.logger,
NewStateStore: func() *state.Store {
return state.NewStateStore(s.tombstoneGC)
},
})
if err := raft.RecoverCluster(s.config.RaftConfig, tmpFsm,
log, stable, snap, trans, configuration); err != nil {
return fmt.Errorf("recovery failed: %v", err)
}
if err := os.Remove(peersFile); err != nil {
return fmt.Errorf("recovery failed to delete peers.json, please delete manually (see peers.info for details): %v", err)
}
s.logger.Info("deleted peers.json file after successful recovery")
}
2015-11-29 04:40:05 +00:00
}
2013-12-06 23:43:07 +00:00
// If we are in bootstrap or dev mode and the state is clean then we can
// bootstrap now.
if s.config.Bootstrap || s.config.DevMode {
hasState, err := raft.HasExistingState(log, stable, snap)
if err != nil {
return err
}
if !hasState {
configuration := raft.Configuration{
Servers: []raft.Server{
{
2017-02-22 20:53:32 +00:00
ID: s.config.RaftConfig.LocalID,
Address: trans.LocalAddr(),
},
},
}
if err := raft.BootstrapCluster(s.config.RaftConfig,
log, stable, snap, trans, configuration); err != nil {
return err
}
}
}
// Set up a channel for reliable leader notifications.
raftNotifyCh := make(chan bool, 10)
2017-07-06 14:09:21 +00:00
s.config.RaftConfig.NotifyCh = raftNotifyCh
s.raftNotifyCh = raftNotifyCh
// Setup the Raft store.
var err error
s.raft, err = raft.NewRaft(s.config.RaftConfig, s.fsm.ChunkingFSM(), log, stable, snap, trans)
return err
2013-12-06 23:43:07 +00:00
}
// endpointFactory is a function that returns an RPC endpoint bound to the given
// server.
type factory func(s *Server) interface{}
// endpoints is a list of registered RPC endpoint factories.
var endpoints []factory
// registerEndpoint registers a new RPC endpoint factory.
func registerEndpoint(fn factory) {
endpoints = append(endpoints, fn)
}
2013-12-07 00:35:13 +00:00
// setupRPC is used to setup the RPC listener
func (s *Server) setupRPC() error {
s.rpcConnLimiter.SetConfig(connlimit.Config{
MaxConnsPerClientIP: s.config.RPCMaxConnsPerClient,
})
for _, fn := range endpoints {
s.rpcServer.Register(fn(s))
}
2013-12-09 22:49:07 +00:00
// Only register AutoEncrypt on the insecure RPC server. Insecure only
// means that verify incoming is turned off even though it might have
// been configured.
s.insecureRPCServer.Register(&AutoEncrypt{srv: s})
// Setup the AutoConfig JWT Authorizer
var authz AutoConfigAuthorizer
if s.config.AutoConfigAuthzEnabled {
// create the auto config authorizer from the JWT authmethod
validator, err := ssoauth.NewValidator(s.logger, &s.config.AutoConfigAuthzAuthMethod)
if err != nil {
return fmt.Errorf("Failed to initialize JWT Auto Config Authorizer: %w", err)
}
authz = &jwtAuthorizer{
validator: validator,
allowReuse: s.config.AutoConfigAuthzAllowReuse,
claimAssertions: s.config.AutoConfigAuthzClaimAssertions,
}
} else {
// This authorizer always returns that the endpoint is disabled
authz = &disabledAuthorizer{}
}
// now register with the insecure RPC server
s.insecureRPCServer.Register(NewAutoConfig(s.config, s.tlsConfigurator, s, authz))
ln, err := net.ListenTCP("tcp", s.config.RPCAddr)
2013-12-07 00:35:13 +00:00
if err != nil {
return err
}
2017-06-25 19:36:03 +00:00
s.Listener = ln
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
2017-06-25 19:36:03 +00:00
if s.config.NotifyListen != nil {
s.config.NotifyListen()
}
// todo(fs): we should probably guard this
if s.config.RPCAdvertise == nil {
s.config.RPCAdvertise = ln.Addr().(*net.TCPAddr)
}
2013-12-31 22:00:25 +00:00
// Verify that we have a usable advertise address
if s.config.RPCAdvertise.IP.IsUnspecified() {
ln.Close()
return fmt.Errorf("RPC advertise address is not advertisable: %v", s.config.RPCAdvertise)
2013-12-31 22:00:25 +00:00
}
// TODO (hans) switch NewRaftLayer to tlsConfigurator
2015-05-11 22:15:36 +00:00
// Provide a DC specific wrapper. Raft replication is only
// ever done in the same datacenter, so we can provide it as a constant.
wrapper := tlsutil.SpecificDC(s.config.Datacenter, s.tlsConfigurator.OutgoingRPCWrapper())
// Define a callback for determining whether to wrap a connection with TLS
tlsFunc := func(address raft.ServerAddress) bool {
// raft only talks to its own datacenter
return s.tlsConfigurator.UseTLS(s.config.Datacenter)
}
s.raftLayer = NewRaftLayer(s.config.RPCSrcAddr, s.config.RPCAdvertise, wrapper, tlsFunc)
2013-12-07 00:35:13 +00:00
return nil
}
2013-12-06 23:43:07 +00:00
// Shutdown is used to shutdown the server
func (s *Server) Shutdown() error {
s.logger.Info("shutting down server")
2013-12-06 23:43:07 +00:00
s.shutdownLock.Lock()
defer s.shutdownLock.Unlock()
if s.shutdown {
return nil
}
s.shutdown = true
close(s.shutdownCh)
// ensure that any leader routines still running get canceled
if s.leaderRoutineManager != nil {
s.leaderRoutineManager.StopAll()
}
if s.serfLAN != nil {
s.serfLAN.Shutdown()
2013-12-06 23:43:07 +00:00
}
for _, segment := range s.segmentLAN {
segment.Shutdown()
}
if s.serfWAN != nil {
s.serfWAN.Shutdown()
if err := s.router.RemoveArea(types.AreaWAN); err != nil {
s.logger.Warn("error removing WAN area", "error", err)
}
2013-12-06 23:43:07 +00:00
}
s.router.Shutdown()
2013-12-06 23:43:07 +00:00
if s.raft != nil {
s.raftTransport.Close()
s.raftLayer.Close()
future := s.raft.Shutdown()
if err := future.Error(); err != nil {
s.logger.Warn("error shutting down raft", "error", err)
}
2015-11-29 04:40:05 +00:00
if s.raftStore != nil {
s.raftStore.Close()
}
2013-12-06 23:43:07 +00:00
}
2013-12-07 00:35:13 +00:00
2017-06-25 19:36:03 +00:00
if s.Listener != nil {
s.Listener.Close()
2013-12-07 00:35:13 +00:00
}
if s.grpcHandler != nil {
if err := s.grpcHandler.Shutdown(); err != nil {
s.logger.Warn("failed to stop gRPC server", "error", err)
}
}
2013-12-09 20:09:57 +00:00
// Close the connection pool
if s.connPool != nil {
s.connPool.Shutdown()
}
2013-12-09 20:09:57 +00:00
if s.acls != nil {
s.acls.Close()
}
if s.fsm != nil {
s.fsm.State().Abandon()
}
2013-12-06 23:43:07 +00:00
return nil
}
2013-12-07 01:18:09 +00:00
2013-12-09 20:10:27 +00:00
// Leave is used to prepare for a graceful shutdown of the server
func (s *Server) Leave() error {
s.logger.Info("server starting leave")
2013-12-09 20:10:27 +00:00
// Check the number of known peers
numPeers, err := s.numPeers()
if err != nil {
s.logger.Error("failed to check raft peers", "error", err)
return err
}
addr := s.raftTransport.LocalAddr()
// If we are the current leader, and we have any other peers (cluster has multiple
// servers), we should do a RemoveServer/RemovePeer to safely reduce the quorum size.
// If we are not the leader, then we should issue our leave intention and wait to be
// removed for some sane period of time.
isLeader := s.IsLeader()
if isLeader && numPeers > 1 {
2017-12-12 00:38:52 +00:00
minRaftProtocol, err := s.autopilot.MinRaftProtocol()
if err != nil {
return err
}
if minRaftProtocol >= 2 && s.config.RaftConfig.ProtocolVersion >= 3 {
future := s.raft.RemoveServer(raft.ServerID(s.config.NodeID), 0, 0)
if err := future.Error(); err != nil {
s.logger.Error("failed to remove ourself as raft peer", "error", err)
}
} else {
future := s.raft.RemovePeer(addr)
if err := future.Error(); err != nil {
s.logger.Error("failed to remove ourself as raft peer", "error", err)
}
}
}
2013-12-09 20:10:27 +00:00
// Leave the WAN pool
if s.serfWAN != nil {
if err := s.serfWAN.Leave(); err != nil {
s.logger.Error("failed to leave WAN Serf cluster", "error", err)
2013-12-09 20:10:27 +00:00
}
}
// Leave the LAN pool
if s.serfLAN != nil {
if err := s.serfLAN.Leave(); err != nil {
s.logger.Error("failed to leave LAN Serf cluster", "error", err)
2013-12-09 20:10:27 +00:00
}
}
2019-09-11 09:01:37 +00:00
// Leave everything enterprise related as well
s.handleEnterpriseLeave()
// Start refusing RPCs now that we've left the LAN pool. It's important
// to do this *after* we've left the LAN pool so that clients will know
// to shift onto another server if they perform a retry. We also wake up
// all queries in the RPC retry state.
s.logger.Info("Waiting to drain RPC traffic", "drain_time", s.config.LeaveDrainTime)
close(s.leaveCh)
time.Sleep(s.config.LeaveDrainTime)
// If we were not leader, wait to be safely removed from the cluster. We
// must wait to allow the raft replication to take place, otherwise an
// immediate shutdown could cause a loss of quorum.
if !isLeader {
left := false
limit := time.Now().Add(raftRemoveGracePeriod)
for !left && time.Now().Before(limit) {
// Sleep a while before we check.
time.Sleep(50 * time.Millisecond)
// Get the latest configuration.
future := s.raft.GetConfiguration()
if err := future.Error(); err != nil {
s.logger.Error("failed to get raft configuration", "error", err)
break
}
// See if we are no longer included.
left = true
for _, server := range future.Configuration().Servers {
if server.Address == addr {
left = false
break
}
}
}
// TODO (slackpad) With the old Raft library we used to force the
// peers set to empty when a graceful leave occurred. This would
// keep voting spam down if the server was restarted, but it was
// dangerous because the peers was inconsistent with the logs and
// snapshots, so it wasn't really safe in all cases for the server
// to become leader. This is now safe, but the log spam is noisy.
// The next new version of the library will have a "you are not a
// peer stop it" behavior that should address this. We will have
// to evaluate during the RC period if this interim situation is
// not too confusing for operators.
// TODO (slackpad) When we take a later new version of the Raft
// library it won't try to complete replication, so this peer
// may not realize that it has been removed. Need to revisit this
// and the warning here.
if !left {
s.logger.Warn("failed to leave raft configuration gracefully, timeout")
}
}
2013-12-09 20:10:27 +00:00
return nil
}
// numPeers is used to check on the number of known peers, including potentially
// the local node. We count only voters, since others can't actually become
// leader, so aren't considered peers.
func (s *Server) numPeers() (int, error) {
future := s.raft.GetConfiguration()
if err := future.Error(); err != nil {
return 0, err
}
return autopilot.NumPeers(future.Configuration()), nil
}
2013-12-07 01:18:09 +00:00
// JoinLAN is used to have Consul join the inner-DC pool
// The target address should be another node inside the DC
// listening on the Serf LAN address
func (s *Server) JoinLAN(addrs []string) (int, error) {
return s.serfLAN.Join(addrs, true)
2013-12-07 01:18:09 +00:00
}
// JoinWAN is used to have Consul join the cross-WAN Consul ring
// The target address should be another node listening on the
// Serf WAN address
func (s *Server) JoinWAN(addrs []string) (int, error) {
if s.serfWAN == nil {
return 0, ErrWANFederationDisabled
}
return s.serfWAN.Join(addrs, true)
2013-12-07 01:18:09 +00:00
}
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
// PrimaryMeshGatewayAddressesReadyCh returns a channel that will be closed
// when federation state replication ships back at least one primary mesh
// gateway (not via fallback config).
func (s *Server) PrimaryMeshGatewayAddressesReadyCh() <-chan struct{} {
if s.gatewayLocator == nil {
return nil
}
return s.gatewayLocator.PrimaryMeshGatewayAddressesReadyCh()
}
// PickRandomMeshGatewaySuitableForDialing is a convenience function used for writing tests.
func (s *Server) PickRandomMeshGatewaySuitableForDialing(dc string) string {
if s.gatewayLocator == nil {
return ""
}
return s.gatewayLocator.PickGateway(dc)
}
// RefreshPrimaryGatewayFallbackAddresses is used to update the list of current
// fallback addresses for locating mesh gateways in the primary datacenter.
func (s *Server) RefreshPrimaryGatewayFallbackAddresses(addrs []string) {
if s.gatewayLocator != nil {
s.gatewayLocator.RefreshPrimaryGatewayFallbackAddresses(addrs)
}
}
// PrimaryGatewayFallbackAddresses returns the current set of discovered
// fallback addresses for the mesh gateways in the primary datacenter.
func (s *Server) PrimaryGatewayFallbackAddresses() []string {
if s.gatewayLocator == nil {
return nil
}
return s.gatewayLocator.PrimaryGatewayFallbackAddresses()
}
// LocalMember is used to return the local node
func (s *Server) LocalMember() serf.Member {
return s.serfLAN.LocalMember()
}
// LANMembers is used to return the members of the LAN cluster
func (s *Server) LANMembers() []serf.Member {
return s.serfLAN.Members()
}
// WANMembers is used to return the members of the LAN cluster
func (s *Server) WANMembers() []serf.Member {
if s.serfWAN == nil {
return nil
}
return s.serfWAN.Members()
}
// RemoveFailedNode is used to remove a failed node from the cluster
func (s *Server) RemoveFailedNode(node string, prune bool) error {
var removeFn func(*serf.Serf, string) error
if prune {
removeFn = (*serf.Serf).RemoveFailedNodePrune
} else {
removeFn = (*serf.Serf).RemoveFailedNode
}
if err := removeFn(s.serfLAN, node); err != nil {
return err
}
// The Serf WAN pool stores members as node.datacenter
// so the dc is appended if not present
if !strings.HasSuffix(node, "."+s.config.Datacenter) {
node = node + "." + s.config.Datacenter
}
if s.serfWAN != nil {
if err := removeFn(s.serfWAN, node); err != nil {
return err
}
}
return nil
}
// IsLeader checks if this server is the cluster leader
func (s *Server) IsLeader() bool {
return s.raft.State() == raft.Leader
}
wan federation via mesh gateways (#6884) This is like a Möbius strip of code due to the fact that low-level components (serf/memberlist) are connected to high-level components (the catalog and mesh-gateways) in a twisty maze of references which make it hard to dive into. With that in mind here's a high level summary of what you'll find in the patch: There are several distinct chunks of code that are affected: * new flags and config options for the server * retry join WAN is slightly different * retry join code is shared to discover primary mesh gateways from secondary datacenters * because retry join logic runs in the *agent* and the results of that operation for primary mesh gateways are needed in the *server* there are some methods like `RefreshPrimaryGatewayFallbackAddresses` that must occur at multiple layers of abstraction just to pass the data down to the right layer. * new cache type `FederationStateListMeshGatewaysName` for use in `proxycfg/xds` layers * the function signature for RPC dialing picked up a new required field (the node name of the destination) * several new RPCs for manipulating a FederationState object: `FederationState:{Apply,Get,List,ListMeshGateways}` * 3 read-only internal APIs for debugging use to invoke those RPCs from curl * raft and fsm changes to persist these FederationStates * replication for FederationStates as they are canonically stored in the Primary and replicated to the Secondaries. * a special derivative of anti-entropy that runs in secondaries to snapshot their local mesh gateway `CheckServiceNodes` and sync them into their upstream FederationState in the primary (this works in conjunction with the replication to distribute addresses for all mesh gateways in all DCs to all other DCs) * a "gateway locator" convenience object to make use of this data to choose the addresses of gateways to use for any given RPC or gossip operation to a remote DC. This gets data from the "retry join" logic in the agent and also directly calls into the FSM. * RPC (`:8300`) on the server sniffs the first byte of a new connection to determine if it's actually doing native TLS. If so it checks the ALPN header for protocol determination (just like how the existing system uses the type-byte marker). * 2 new kinds of protocols are exclusively decoded via this native TLS mechanism: one for ferrying "packet" operations (udp-like) from the gossip layer and one for "stream" operations (tcp-like). The packet operations re-use sockets (using length-prefixing) to cut down on TLS re-negotiation overhead. * the server instances specially wrap the `memberlist.NetTransport` when running with gateway federation enabled (in a `wanfed.Transport`). The general gist is that if it tries to dial a node in the SAME datacenter (deduced by looking at the suffix of the node name) there is no change. If dialing a DIFFERENT datacenter it is wrapped up in a TLS+ALPN blob and sent through some mesh gateways to eventually end up in a server's :8300 port. * a new flag when launching a mesh gateway via `consul connect envoy` to indicate that the servers are to be exposed. This sets a special service meta when registering the gateway into the catalog. * `proxycfg/xds` notice this metadata blob to activate additional watches for the FederationState objects as well as the location of all of the consul servers in that datacenter. * `xds:` if the extra metadata is in place additional clusters are defined in a DC to bulk sink all traffic to another DC's gateways. For the current datacenter we listen on a wildcard name (`server.<dc>.consul`) that load balances all servers as well as one mini-cluster per node (`<node>.server.<dc>.consul`) * the `consul tls cert create` command got a new flag (`-node`) to help create an additional SAN in certs that can be used with this flavor of federation.
2020-03-09 20:59:02 +00:00
// LeaderLastContact returns the time of last contact by a leader.
// This only makes sense if we are currently a follower.
func (s *Server) LeaderLastContact() time.Time {
return s.raft.LastContact()
}
// KeyManagerLAN returns the LAN Serf keyring manager
func (s *Server) KeyManagerLAN() *serf.KeyManager {
return s.serfLAN.KeyManager()
}
// KeyManagerWAN returns the WAN Serf keyring manager
func (s *Server) KeyManagerWAN() *serf.KeyManager {
return s.serfWAN.KeyManager()
}
// LANSegments returns a map of LAN segments by name
func (s *Server) LANSegments() map[string]*serf.Serf {
segments := make(map[string]*serf.Serf, len(s.segmentLAN)+1)
segments[""] = s.serfLAN
for name, segment := range s.segmentLAN {
segments[name] = segment
}
return segments
}
// inmemCodec is used to do an RPC call without going over a network
type inmemCodec struct {
method string
args interface{}
reply interface{}
err error
}
func (i *inmemCodec) ReadRequestHeader(req *rpc.Request) error {
req.ServiceMethod = i.method
return nil
}
func (i *inmemCodec) ReadRequestBody(args interface{}) error {
sourceValue := reflect.Indirect(reflect.Indirect(reflect.ValueOf(i.args)))
dst := reflect.Indirect(reflect.Indirect(reflect.ValueOf(args)))
dst.Set(sourceValue)
return nil
}
func (i *inmemCodec) WriteResponse(resp *rpc.Response, reply interface{}) error {
if resp.Error != "" {
i.err = errors.New(resp.Error)
return nil
}
sourceValue := reflect.Indirect(reflect.Indirect(reflect.ValueOf(reply)))
dst := reflect.Indirect(reflect.Indirect(reflect.ValueOf(i.reply)))
dst.Set(sourceValue)
return nil
}
func (i *inmemCodec) Close() error {
return nil
}
// RPC is used to make a local RPC call
func (s *Server) RPC(method string, args interface{}, reply interface{}) error {
codec := &inmemCodec{
method: method,
args: args,
reply: reply,
}
// Enforce the RPC limit.
//
// "client" metric path because the internal client API is calling to the
// internal server API. It's odd that the same request directed to a server is
// recorded differently. On the other hand this possibly masks the different
// between regular client requests that traverse the network and these which
// don't (unless forwarded). This still seems most sane.
metrics.IncrCounter([]string{"client", "rpc"}, 1)
if !s.rpcLimiter.Load().(*rate.Limiter).Allow() {
metrics.IncrCounter([]string{"client", "rpc", "exceeded"}, 1)
return structs.ErrRPCRateExceeded
}
if err := s.rpcServer.ServeRequest(codec); err != nil {
return err
}
return codec.err
}
Adds support for snapshots and restores. (#2396) * Updates Raft library to get new snapshot/restore API. * Basic backup and restore working, but need some cleanup. * Breaks out a snapshot module and adds a SHA256 integrity check. * Adds snapshot ACL and fills in some missing comments. * Require a consistent read for snapshots. * Make sure snapshot works if ACLs aren't enabled. * Adds a bit of package documentation. * Returns an empty response from restore to avoid EOF errors. * Adds API client support for snapshots. * Makes internal file names match on-disk file snapshots. * Adds DC and token coverage for snapshot API test. * Adds missing documentation. * Adds a unit test for the snapshot client endpoint. * Moves the connection pool out of the client for easier testing. * Fixes an incidental issue in the prepared query unit test. I realized I had two servers in bootstrap mode so this wasn't a good setup. * Adds a half close to the TCP stream and fixes panic on error. * Adds client and endpoint tests for snapshots. * Moves the pool back into the snapshot RPC client. * Adds a TLS test and fixes half-closes for TLS connections. * Tweaks some comments. * Adds a low-level snapshot test. This is independent of Consul so we can pull this out into a library later if we want to. * Cleans up snapshot and archive and completes archive tests. * Sends a clear error for snapshot operations in dev mode. Snapshots require the Raft snapshots to be readable, which isn't supported in dev mode. Send a clear error instead of a deep-down Raft one. * Adds docs for the snapshot endpoint. * Adds a stale mode and index feedback for snapshot saves. This gives folks a way to extract data even if the cluster has no leader. * Changes the internal format of a snapshot from zip to tgz. * Pulls in Raft fix to cancel inflight before a restore. * Pulls in new Raft restore interface. * Adds metadata to snapshot saves and a verify function. * Adds basic save and restore snapshot CLI commands. * Gets rid of tarball extensions and adds restore message. * Fixes an incidental bad link in the KV docs. * Adds documentation for the snapshot CLI commands. * Scuttle any request body when a snapshot is saved. * Fixes archive unit test error message check. * Allows for nil output writers in snapshot RPC handlers. * Renames hash list Decode to DecodeAndVerify. * Closes the client connection for snapshot ops. * Lowers timeout for restore ops. * Updates Raft vendor to get new Restore signature and integrates with Consul. * Bounces the leader's internal state when we do a restore.
2016-10-26 02:20:24 +00:00
// SnapshotRPC dispatches the given snapshot request, reading from the streaming
// input and writing to the streaming output depending on the operation.
func (s *Server) SnapshotRPC(args *structs.SnapshotRequest, in io.Reader, out io.Writer,
replyFn structs.SnapshotReplyFn) error {
Adds support for snapshots and restores. (#2396) * Updates Raft library to get new snapshot/restore API. * Basic backup and restore working, but need some cleanup. * Breaks out a snapshot module and adds a SHA256 integrity check. * Adds snapshot ACL and fills in some missing comments. * Require a consistent read for snapshots. * Make sure snapshot works if ACLs aren't enabled. * Adds a bit of package documentation. * Returns an empty response from restore to avoid EOF errors. * Adds API client support for snapshots. * Makes internal file names match on-disk file snapshots. * Adds DC and token coverage for snapshot API test. * Adds missing documentation. * Adds a unit test for the snapshot client endpoint. * Moves the connection pool out of the client for easier testing. * Fixes an incidental issue in the prepared query unit test. I realized I had two servers in bootstrap mode so this wasn't a good setup. * Adds a half close to the TCP stream and fixes panic on error. * Adds client and endpoint tests for snapshots. * Moves the pool back into the snapshot RPC client. * Adds a TLS test and fixes half-closes for TLS connections. * Tweaks some comments. * Adds a low-level snapshot test. This is independent of Consul so we can pull this out into a library later if we want to. * Cleans up snapshot and archive and completes archive tests. * Sends a clear error for snapshot operations in dev mode. Snapshots require the Raft snapshots to be readable, which isn't supported in dev mode. Send a clear error instead of a deep-down Raft one. * Adds docs for the snapshot endpoint. * Adds a stale mode and index feedback for snapshot saves. This gives folks a way to extract data even if the cluster has no leader. * Changes the internal format of a snapshot from zip to tgz. * Pulls in Raft fix to cancel inflight before a restore. * Pulls in new Raft restore interface. * Adds metadata to snapshot saves and a verify function. * Adds basic save and restore snapshot CLI commands. * Gets rid of tarball extensions and adds restore message. * Fixes an incidental bad link in the KV docs. * Adds documentation for the snapshot CLI commands. * Scuttle any request body when a snapshot is saved. * Fixes archive unit test error message check. * Allows for nil output writers in snapshot RPC handlers. * Renames hash list Decode to DecodeAndVerify. * Closes the client connection for snapshot ops. * Lowers timeout for restore ops. * Updates Raft vendor to get new Restore signature and integrates with Consul. * Bounces the leader's internal state when we do a restore.
2016-10-26 02:20:24 +00:00
// Enforce the RPC limit.
//
// "client" metric path because the internal client API is calling to the
// internal server API. It's odd that the same request directed to a server is
// recorded differently. On the other hand this possibly masks the different
// between regular client requests that traverse the network and these which
// don't (unless forwarded). This still seems most sane.
metrics.IncrCounter([]string{"client", "rpc"}, 1)
if !s.rpcLimiter.Load().(*rate.Limiter).Allow() {
metrics.IncrCounter([]string{"client", "rpc", "exceeded"}, 1)
return structs.ErrRPCRateExceeded
}
Adds support for snapshots and restores. (#2396) * Updates Raft library to get new snapshot/restore API. * Basic backup and restore working, but need some cleanup. * Breaks out a snapshot module and adds a SHA256 integrity check. * Adds snapshot ACL and fills in some missing comments. * Require a consistent read for snapshots. * Make sure snapshot works if ACLs aren't enabled. * Adds a bit of package documentation. * Returns an empty response from restore to avoid EOF errors. * Adds API client support for snapshots. * Makes internal file names match on-disk file snapshots. * Adds DC and token coverage for snapshot API test. * Adds missing documentation. * Adds a unit test for the snapshot client endpoint. * Moves the connection pool out of the client for easier testing. * Fixes an incidental issue in the prepared query unit test. I realized I had two servers in bootstrap mode so this wasn't a good setup. * Adds a half close to the TCP stream and fixes panic on error. * Adds client and endpoint tests for snapshots. * Moves the pool back into the snapshot RPC client. * Adds a TLS test and fixes half-closes for TLS connections. * Tweaks some comments. * Adds a low-level snapshot test. This is independent of Consul so we can pull this out into a library later if we want to. * Cleans up snapshot and archive and completes archive tests. * Sends a clear error for snapshot operations in dev mode. Snapshots require the Raft snapshots to be readable, which isn't supported in dev mode. Send a clear error instead of a deep-down Raft one. * Adds docs for the snapshot endpoint. * Adds a stale mode and index feedback for snapshot saves. This gives folks a way to extract data even if the cluster has no leader. * Changes the internal format of a snapshot from zip to tgz. * Pulls in Raft fix to cancel inflight before a restore. * Pulls in new Raft restore interface. * Adds metadata to snapshot saves and a verify function. * Adds basic save and restore snapshot CLI commands. * Gets rid of tarball extensions and adds restore message. * Fixes an incidental bad link in the KV docs. * Adds documentation for the snapshot CLI commands. * Scuttle any request body when a snapshot is saved. * Fixes archive unit test error message check. * Allows for nil output writers in snapshot RPC handlers. * Renames hash list Decode to DecodeAndVerify. * Closes the client connection for snapshot ops. * Lowers timeout for restore ops. * Updates Raft vendor to get new Restore signature and integrates with Consul. * Bounces the leader's internal state when we do a restore.
2016-10-26 02:20:24 +00:00
// Perform the operation.
var reply structs.SnapshotResponse
snap, err := s.dispatchSnapshotRequest(args, in, &reply)
if err != nil {
return err
}
defer func() {
if err := snap.Close(); err != nil {
s.logger.Error("Failed to close snapshot", "error", err)
Adds support for snapshots and restores. (#2396) * Updates Raft library to get new snapshot/restore API. * Basic backup and restore working, but need some cleanup. * Breaks out a snapshot module and adds a SHA256 integrity check. * Adds snapshot ACL and fills in some missing comments. * Require a consistent read for snapshots. * Make sure snapshot works if ACLs aren't enabled. * Adds a bit of package documentation. * Returns an empty response from restore to avoid EOF errors. * Adds API client support for snapshots. * Makes internal file names match on-disk file snapshots. * Adds DC and token coverage for snapshot API test. * Adds missing documentation. * Adds a unit test for the snapshot client endpoint. * Moves the connection pool out of the client for easier testing. * Fixes an incidental issue in the prepared query unit test. I realized I had two servers in bootstrap mode so this wasn't a good setup. * Adds a half close to the TCP stream and fixes panic on error. * Adds client and endpoint tests for snapshots. * Moves the pool back into the snapshot RPC client. * Adds a TLS test and fixes half-closes for TLS connections. * Tweaks some comments. * Adds a low-level snapshot test. This is independent of Consul so we can pull this out into a library later if we want to. * Cleans up snapshot and archive and completes archive tests. * Sends a clear error for snapshot operations in dev mode. Snapshots require the Raft snapshots to be readable, which isn't supported in dev mode. Send a clear error instead of a deep-down Raft one. * Adds docs for the snapshot endpoint. * Adds a stale mode and index feedback for snapshot saves. This gives folks a way to extract data even if the cluster has no leader. * Changes the internal format of a snapshot from zip to tgz. * Pulls in Raft fix to cancel inflight before a restore. * Pulls in new Raft restore interface. * Adds metadata to snapshot saves and a verify function. * Adds basic save and restore snapshot CLI commands. * Gets rid of tarball extensions and adds restore message. * Fixes an incidental bad link in the KV docs. * Adds documentation for the snapshot CLI commands. * Scuttle any request body when a snapshot is saved. * Fixes archive unit test error message check. * Allows for nil output writers in snapshot RPC handlers. * Renames hash list Decode to DecodeAndVerify. * Closes the client connection for snapshot ops. * Lowers timeout for restore ops. * Updates Raft vendor to get new Restore signature and integrates with Consul. * Bounces the leader's internal state when we do a restore.
2016-10-26 02:20:24 +00:00
}
}()
// Let the caller peek at the reply.
if replyFn != nil {
if err := replyFn(&reply); err != nil {
return nil
}
}
// Stream the snapshot.
if out != nil {
if _, err := io.Copy(out, snap); err != nil {
return fmt.Errorf("failed to stream snapshot: %v", err)
}
}
return nil
}
// RegisterEndpoint is used to substitute an endpoint for testing.
func (s *Server) RegisterEndpoint(name string, handler interface{}) error {
s.logger.Warn("endpoint injected; this should only be used for testing")
return s.rpcServer.RegisterName(name, handler)
}
// Stats is used to return statistics for debugging and insight
// for various sub-systems
func (s *Server) Stats() map[string]map[string]string {
toString := func(v uint64) string {
return strconv.FormatUint(v, 10)
}
numKnownDCs := len(s.router.GetDatacenters())
stats := map[string]map[string]string{
"consul": {
2014-02-24 02:08:58 +00:00
"server": "true",
"leader": fmt.Sprintf("%v", s.IsLeader()),
"leader_addr": string(s.raft.Leader()),
2014-02-24 02:08:58 +00:00
"bootstrap": fmt.Sprintf("%v", s.config.Bootstrap),
"known_datacenters": toString(uint64(numKnownDCs)),
},
2014-02-24 02:08:58 +00:00
"raft": s.raft.Stats(),
"serf_lan": s.serfLAN.Stats(),
"runtime": runtimeStats(),
}
if s.config.ACLsEnabled {
if s.UseLegacyACLs() {
stats["consul"]["acl"] = "legacy"
} else {
stats["consul"]["acl"] = "enabled"
}
} else {
stats["consul"]["acl"] = "disabled"
}
if s.serfWAN != nil {
stats["serf_wan"] = s.serfWAN.Stats()
}
for outerKey, outerValue := range s.enterpriseStats() {
if _, ok := stats[outerKey]; ok {
for innerKey, innerValue := range outerValue {
stats[outerKey][innerKey] = innerValue
}
} else {
stats[outerKey] = outerValue
}
}
return stats
}
2015-04-15 23:12:45 +00:00
// GetLANCoordinate returns the coordinate of the server in the LAN gossip pool.
func (s *Server) GetLANCoordinate() (lib.CoordinateSet, error) {
lan, err := s.serfLAN.GetCoordinate()
if err != nil {
return nil, err
}
cs := lib.CoordinateSet{"": lan}
for name, segment := range s.segmentLAN {
c, err := segment.GetCoordinate()
if err != nil {
return nil, err
}
cs[name] = c
}
return cs, nil
2015-04-15 23:12:45 +00:00
}
2015-05-08 08:31:34 +00:00
// ReloadConfig is used to have the Server do an online reload of
// relevant configuration information
func (s *Server) ReloadConfig(config *Config) error {
s.rpcLimiter.Store(rate.NewLimiter(config.RPCRate, config.RPCMaxBurst))
s.rpcConnLimiter.SetConfig(connlimit.Config{
MaxConnsPerClientIP: config.RPCMaxConnsPerClient,
})
if s.IsLeader() {
// only bootstrap the config entries if we are the leader
// this will error if we lose leadership while bootstrapping here.
return s.bootstrapConfigEntries(config.ConfigEntryBootstrap)
}
return nil
}
// Atomically sets a readiness state flag when leadership is obtained, to indicate that server is past its barrier write
func (s *Server) setConsistentReadReady() {
atomic.StoreInt32(&s.readyForConsistentReads, 1)
}
// Atomically reset readiness state flag on leadership revoke
func (s *Server) resetConsistentReadReady() {
atomic.StoreInt32(&s.readyForConsistentReads, 0)
}
// Returns true if this server is ready to serve consistent reads
func (s *Server) isReadyForConsistentReads() bool {
2017-06-21 00:43:07 +00:00
return atomic.LoadInt32(&s.readyForConsistentReads) == 1
}
// CreateACLToken will create an ACL token from the given template
func (s *Server) CreateACLToken(template *structs.ACLToken) (*structs.ACLToken, error) {
// we have to require local tokens or else it would require having these servers use a token with acl:write to make a
// token create RPC to the servers in the primary DC.
if !s.LocalTokensEnabled() {
return nil, fmt.Errorf("Agent Auto Configuration requires local token usage to be enabled in this datacenter: %s", s.config.Datacenter)
}
newToken := *template
// generate the accessor id
if newToken.AccessorID == "" {
accessor, err := lib.GenerateUUID(s.checkTokenUUID)
if err != nil {
return nil, err
}
newToken.AccessorID = accessor
}
// generate the secret id
if newToken.SecretID == "" {
secret, err := lib.GenerateUUID(s.checkTokenUUID)
if err != nil {
return nil, err
}
newToken.SecretID = secret
}
newToken.CreateTime = time.Now()
req := structs.ACLTokenBatchSetRequest{
Tokens: structs.ACLTokens{&newToken},
CAS: false,
}
// perform the request to mint the new token
if _, err := s.raftApplyMsgpack(structs.ACLTokenSetRequestType, &req); err != nil {
return nil, err
}
// return the full token definition from the FSM
_, token, err := s.fsm.State().ACLTokenGetByAccessor(nil, newToken.AccessorID, &newToken.EnterpriseMeta)
return token, err
}
// DatacenterJoinAddresses will return all the strings suitable for usage in
// retry join operations to connect to the the LAN or LAN segment gossip pool.
func (s *Server) DatacenterJoinAddresses(segment string) ([]string, error) {
members, err := s.LANSegmentMembers(segment)
if err != nil {
return nil, fmt.Errorf("Failed to retrieve members for segment %s - %w", segment, err)
}
var joinAddrs []string
for _, m := range members {
if ok, _ := metadata.IsConsulServer(m); ok {
serfAddr := net.TCPAddr{IP: m.Addr, Port: int(m.Port)}
joinAddrs = append(joinAddrs, serfAddr.String())
}
}
return joinAddrs, nil
}
// peersInfoContent is used to help operators understand what happened to the
// peers.json file. This is written to a file called peers.info in the same
// location.
const peersInfoContent = `
As of Consul 0.7.0, the peers.json file is only used for recovery
after an outage. The format of this file depends on what the server has
configured for its Raft protocol version. Please see the agent configuration
page at https://www.consul.io/docs/agent/options.html#_raft_protocol for more
details about this parameter.
For Raft protocol version 2 and earlier, this should be formatted as a JSON
array containing the address and port of each Consul server in the cluster, like
this:
[
"10.1.0.1:8300",
"10.1.0.2:8300",
"10.1.0.3:8300"
]
For Raft protocol version 3 and later, this should be formatted as a JSON
array containing the node ID, address:port, and suffrage information of each
Consul server in the cluster, like this:
[
{
"id": "adf4238a-882b-9ddc-4a9d-5b6758e4159e",
"address": "10.1.0.1:8300",
"non_voter": false
},
{
"id": "8b6dda82-3103-11e7-93ae-92361f002671",
"address": "10.1.0.2:8300",
"non_voter": false
},
{
"id": "97e17742-3103-11e7-93ae-92361f002671",
"address": "10.1.0.3:8300",
"non_voter": false
}
]
The "id" field is the node ID of the server. This can be found in the logs when
the server starts up, or in the "node-id" file inside the server's data
directory.
The "address" field is the address and port of the server.
The "non_voter" field controls whether the server is a non-voter, which is used
in some advanced Autopilot configurations, please see
https://www.consul.io/docs/guides/autopilot.html for more information. If
"non_voter" is omitted it will default to false, which is typical for most
clusters.
Under normal operation, the peers.json file will not be present.
When Consul starts for the first time, it will create this peers.info file and
delete any existing peers.json file so that recovery doesn't occur on the first
startup.
Once this peers.info file is present, any peers.json file will be ingested at
startup, and will set the Raft peer configuration manually to recover from an
outage. It's crucial that all servers in the cluster are shut down before
creating the peers.json file, and that all servers receive the same
configuration. Once the peers.json file is successfully ingested and applied, it
will be deleted.
Please see https://www.consul.io/docs/guides/outage.html for more information.
`