package api
import (
"context"
"fmt"
"time"
)
// PeeringState enumerates all the states a peering can be in
type PeeringState string
const (
// PeeringStateUndefined represents an unset value for PeeringState during
// writes.
PeeringStateUndefined PeeringState = "UNDEFINED"
// PeeringStatePending means the peering was created by generating a peering token.
// Peerings stay in a pending state until the peer uses the token to dial
// the local cluster.
PeeringStatePending PeeringState = "PENDING"
// PeeringStateEstablishing means the peering is being established from a peering token.
// This is the initial state for dialing peers.
PeeringStateEstablishing PeeringState = "ESTABLISHING"
// PeeringStateActive means that the peering connection is active and
// healthy.
PeeringStateActive PeeringState = "ACTIVE"
// PeeringStateFailing means the peering connection has been interrupted
// but has not yet been terminated.
PeeringStateFailing PeeringState = "FAILING"
// PeeringStateDeleting means a peering was marked for deletion and is in the process
// of being deleted.
PeeringStateDeleting PeeringState = "DELETING"
// PeeringStateTerminated means the peering relationship has been removed.
PeeringStateTerminated PeeringState = "TERMINATED"
)
type Peering struct {
// ID is a datacenter-scoped UUID for the peering.
ID string
// Name is the local alias for the peering relationship.
Name string
// Partition is the local partition connecting to the peer.
Partition string ` json:",omitempty" `
// DeletedAt is the time when the Peering was marked for deletion
DeletedAt * time . Time ` json:",omitempty" alias:"deleted_at" `
// Meta is a mapping of some string value to any other string value
Meta map [ string ] string ` json:",omitempty" `
// State is one of the valid PeeringState values to represent the status of
// peering relationship.
State PeeringState
// PeerID is the ID that our peer assigned to this peering. This ID is to
// be used when dialing the peer, so that it can know who dialed it.
PeerID string ` json:",omitempty" `
// PeerCAPems contains all the CA certificates for the remote peer.
PeerCAPems [ ] string ` json:",omitempty" `
// PeerServerName is the name of the remote server as it relates to TLS.
PeerServerName string ` json:",omitempty" `
// PeerServerAddresses contains all the connection addresses for the remote peer.
PeerServerAddresses [ ] string ` json:",omitempty" `
// ImportedServiceCount is the count of how many services are imported from this peering.
ImportedServiceCount uint64
// ExportedServiceCount is the count of how many services are exported to this peering.
ExportedServiceCount uint64
// CreateIndex is the Raft index at which the Peering was created.
CreateIndex uint64
// ModifyIndex is the latest Raft index at which the Peering. was modified.
ModifyIndex uint64
}
type PeeringReadResponse struct {
Peering * Peering
}
type PeeringGenerateTokenRequest struct {
// PeerName is the name of the remote peer.
PeerName string
// Partition to be peered.
Partition string ` json:",omitempty" `
Datacenter string ` json:",omitempty" `
Token string ` json:",omitempty" `
// Meta is a mapping of some string value to any other string value.
Meta map [ string ] string ` json:",omitempty" `
// ServerExternalAddresses is a list of addresses to put into the generated token. This could be used to specify
// load balancer(s) or external IPs to reach the servers from the dialing side, and will override any server
// addresses obtained from the "consul" service.
ServerExternalAddresses [ ] string ` json:",omitempty" `
}
type PeeringGenerateTokenResponse struct {
// PeeringToken is an opaque string provided to the remote peer for it to complete
// the peering initialization handshake.
PeeringToken string
}
type PeeringEstablishRequest struct {
// Name of the remote peer.
PeerName string
// The peering token returned from the peer's GenerateToken endpoint.
PeeringToken string ` json:",omitempty" `
// Partition to be peered.
Partition string ` json:",omitempty" `
Datacenter string ` json:",omitempty" `
Token string ` json:",omitempty" `
// Meta is a mapping of some string value to any other string value
Meta map [ string ] string ` json:",omitempty" `
}
type PeeringEstablishResponse struct {
}
type PeeringListRequest struct {
// future proofing in case we extend List functionality
}
type Peerings struct {
c * Client
}
// Peerings returns a handle to the operator endpoints.
func ( c * Client ) Peerings ( ) * Peerings {
return & Peerings { c : c }
}
func ( p * Peerings ) Read ( ctx context . Context , name string , q * QueryOptions ) ( * Peering , * QueryMeta , error ) {
if name == "" {
return nil , nil , fmt . Errorf ( "peering name cannot be empty" )
}
req := p . c . newRequest ( "GET" , fmt . Sprintf ( "/v1/peering/%s" , name ) )
req . setQueryOptions ( q )
req . ctx = ctx
rtt , resp , err := p . c . doRequest ( req )
if err != nil {
return nil , nil , err
}
defer closeResponseBody ( resp )
found , resp , err := requireNotFoundOrOK ( resp )
if err != nil {
return nil , nil , err
}
qm := & QueryMeta { }
parseQueryMeta ( resp , qm )
qm . RequestTime = rtt
if ! found {
return nil , qm , nil
}
var out Peering
if err := decodeBody ( resp , & out ) ; err != nil {
return nil , nil , err
}
return & out , qm , nil
}
func ( p * Peerings ) Delete ( ctx context . Context , name string , q * WriteOptions ) ( * WriteMeta , error ) {
if name == "" {
return nil , fmt . Errorf ( "peering name cannot be empty" )
}
req := p . c . newRequest ( "DELETE" , fmt . Sprintf ( "/v1/peering/%s" , name ) )
req . setWriteOptions ( q )
req . ctx = ctx
rtt , resp , err := p . c . doRequest ( req )
if err != nil {
return nil , err
}
defer closeResponseBody ( resp )
if err := requireOK ( resp ) ; err != nil {
return nil , err
}
wm := & WriteMeta { RequestTime : rtt }
return wm , nil
}
// TODO(peering): verify this is the ultimate signature we want
func ( p * Peerings ) GenerateToken ( ctx context . Context , g PeeringGenerateTokenRequest , wq * WriteOptions ) ( * PeeringGenerateTokenResponse , * WriteMeta , error ) {
if g . PeerName == "" {
return nil , nil , fmt . Errorf ( "peer name cannot be empty" )
}
req := p . c . newRequest ( "POST" , fmt . Sprint ( "/v1/peering/token" ) )
req . setWriteOptions ( wq )
req . ctx = ctx
req . obj = g
rtt , resp , err := p . c . doRequest ( req )
if err != nil {
return nil , nil , err
}
defer closeResponseBody ( resp )
if err := requireOK ( resp ) ; err != nil {
return nil , nil , err
}
wm := & WriteMeta { RequestTime : rtt }
var out PeeringGenerateTokenResponse
if err := decodeBody ( resp , & out ) ; err != nil {
return nil , nil , err
}
return & out , wm , nil
}
// TODO(peering): verify this is the ultimate signature we want
func ( p * Peerings ) Establish ( ctx context . Context , i PeeringEstablishRequest , wq * WriteOptions ) ( * PeeringEstablishResponse , * WriteMeta , error ) {
req := p . c . newRequest ( "POST" , fmt . Sprint ( "/v1/peering/establish" ) )
req . setWriteOptions ( wq )
req . ctx = ctx
req . obj = i
rtt , resp , err := p . c . doRequest ( req )
if err != nil {
return nil , nil , err
}
defer closeResponseBody ( resp )
if err := requireOK ( resp ) ; err != nil {
return nil , nil , err
}
wm := & WriteMeta { RequestTime : rtt }
var out PeeringEstablishResponse
if err := decodeBody ( resp , & out ) ; err != nil {
return nil , nil , err
}
return & out , wm , nil
}
func ( p * Peerings ) List ( ctx context . Context , q * QueryOptions ) ( [ ] * Peering , * QueryMeta , error ) {
req := p . c . newRequest ( "GET" , "/v1/peerings" )
req . setQueryOptions ( q )
req . ctx = ctx
rtt , resp , err := p . c . doRequest ( req )
if err != nil {
return nil , nil , err
}
defer closeResponseBody ( resp )
if err := requireOK ( resp ) ; err != nil {
return nil , nil , err
}
qm := & QueryMeta { }
parseQueryMeta ( resp , qm )
qm . RequestTime = rtt
var out [ ] * Peering
if err := decodeBody ( resp , & out ) ; err != nil {
return nil , nil , err
}
return out , qm , nil
}