open-consul/agent/consul/internal_endpoint.go

570 lines
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package consul
import (
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"fmt"
bexpr "github.com/hashicorp/go-bexpr"
"github.com/hashicorp/go-hclog"
"github.com/hashicorp/go-memdb"
"github.com/hashicorp/serf/serf"
server: suppress spurious blocking query returns where multiple config entries are involved (#12362) Starting from and extending the mechanism introduced in #12110 we can specially handle the 3 main special Consul RPC endpoints that react to many config entries in a single blocking query in Connect: - `DiscoveryChain.Get` - `ConfigEntry.ResolveServiceConfig` - `Intentions.Match` All of these will internally watch for many config entries, and at least one of those will likely be not found in any given query. Because these are blends of multiple reads the exact solution from #12110 isn't perfectly aligned, but we can tweak the approach slightly and regain the utility of that mechanism. ### No Config Entries Found In this case, despite looking for many config entries none may be found at all. Unlike #12110 in this scenario we do not return an empty reply to the caller, but instead synthesize a struct from default values to return. This can be handled nearly identically to #12110 with the first 1-2 replies being non-empty payloads followed by the standard spurious wakeup suppression mechanism from #12110. ### No Change Since Last Wakeup Once a blocking query loop on the server has completed and slept at least once, there is a further optimization we can make here to detect if any of the config entries that were present at specific versions for the prior execution of the loop are identical for the loop we just woke up for. In that scenario we can return a slightly different internal sentinel error and basically externally handle it similar to #12110. This would mean that even if 20 discovery chain read RPC handling goroutines wakeup due to the creation of an unrelated config entry, the only ones that will terminate and reply with a blob of data are those that genuinely have new data to report. ### Extra Endpoints Since this pattern is pretty reusable, other key config-entry-adjacent endpoints used by `agent/proxycfg` also were updated: - `ConfigEntry.List` - `Internal.IntentionUpstreams` (tproxy)
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hashstructure_v2 "github.com/mitchellh/hashstructure/v2"
"github.com/hashicorp/consul/acl"
"github.com/hashicorp/consul/agent/consul/state"
"github.com/hashicorp/consul/agent/structs"
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)
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// Internal endpoint is used to query the miscellaneous info that
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// does not necessarily fit into the other systems. It is also
// used to hold undocumented APIs that users should not rely on.
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type Internal struct {
srv *Server
logger hclog.Logger
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}
// NodeInfo is used to retrieve information about a specific node.
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func (m *Internal) NodeInfo(args *structs.NodeSpecificRequest,
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reply *structs.IndexedNodeDump) error {
if done, err := m.srv.ForwardRPC("Internal.NodeInfo", args, reply); done {
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return err
}
_, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, nil)
if err != nil {
return err
}
return m.srv.blockingQuery(
&args.QueryOptions,
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&reply.QueryMeta,
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func(ws memdb.WatchSet, state *state.Store) error {
index, dump, err := state.NodeInfo(ws, args.Node, &args.EnterpriseMeta)
if err != nil {
return err
}
reply.Index, reply.Dump = index, dump
return m.srv.filterACL(args.Token, reply)
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})
}
// NodeDump is used to generate information about all of the nodes.
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func (m *Internal) NodeDump(args *structs.DCSpecificRequest,
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reply *structs.IndexedNodeDump) error {
if done, err := m.srv.ForwardRPC("Internal.NodeDump", args, reply); done {
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return err
}
_, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, nil)
if err != nil {
return err
}
filter, err := bexpr.CreateFilter(args.Filter, nil, reply.Dump)
if err != nil {
return err
}
return m.srv.blockingQuery(
&args.QueryOptions,
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&reply.QueryMeta,
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func(ws memdb.WatchSet, state *state.Store) error {
index, dump, err := state.NodeDump(ws, &args.EnterpriseMeta)
if err != nil {
return err
}
reply.Index, reply.Dump = index, dump
raw, err := filter.Execute(reply.Dump)
if err != nil {
return err
}
reply.Dump = raw.(structs.NodeDump)
// Note: we filter the results with ACLs *after* applying the user-supplied
// bexpr filter, to ensure QueryMeta.ResultsFilteredByACLs does not include
// results that would be filtered out even if the user did have permission.
if err := m.srv.filterACL(args.Token, reply); err != nil {
return err
}
return nil
})
}
func (m *Internal) ServiceDump(args *structs.ServiceDumpRequest, reply *structs.IndexedNodesWithGateways) error {
if done, err := m.srv.ForwardRPC("Internal.ServiceDump", args, reply); done {
return err
}
_, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, nil)
if err != nil {
return err
}
filter, err := bexpr.CreateFilter(args.Filter, nil, reply.Nodes)
if err != nil {
return err
}
return m.srv.blockingQuery(
&args.QueryOptions,
&reply.QueryMeta,
func(ws memdb.WatchSet, state *state.Store) error {
// Get, store, and filter nodes
maxIdx, nodes, err := state.ServiceDump(ws, args.ServiceKind, args.UseServiceKind, &args.EnterpriseMeta)
if err != nil {
return err
}
reply.Nodes = nodes
// Get, store, and filter gateway services
idx, gatewayServices, err := state.DumpGatewayServices(ws)
if err != nil {
return err
}
reply.Gateways = gatewayServices
if idx > maxIdx {
maxIdx = idx
}
reply.Index = maxIdx
raw, err := filter.Execute(reply.Nodes)
if err != nil {
return err
}
reply.Nodes = raw.(structs.CheckServiceNodes)
// Note: we filter the results with ACLs *after* applying the user-supplied
// bexpr filter, to ensure QueryMeta.ResultsFilteredByACLs does not include
// results that would be filtered out even if the user did have permission.
if err := m.srv.filterACL(args.Token, reply); err != nil {
return err
}
return nil
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})
}
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func (m *Internal) ServiceTopology(args *structs.ServiceSpecificRequest, reply *structs.IndexedServiceTopology) error {
if done, err := m.srv.ForwardRPC("Internal.ServiceTopology", args, reply); done {
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return err
}
if args.ServiceName == "" {
return fmt.Errorf("Must provide a service name")
}
var authzContext acl.AuthorizerContext
authz, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, &authzContext)
if err != nil {
return err
}
if err := m.srv.validateEnterpriseRequest(&args.EnterpriseMeta, false); err != nil {
return err
}
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if authz.ServiceRead(args.ServiceName, &authzContext) != acl.Allow {
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return acl.ErrPermissionDenied
}
return m.srv.blockingQuery(
&args.QueryOptions,
&reply.QueryMeta,
func(ws memdb.WatchSet, state *state.Store) error {
defaultAllow := authz.IntentionDefaultAllow(nil)
index, topology, err := state.ServiceTopology(ws, args.Datacenter, args.ServiceName, args.ServiceKind, defaultAllow, &args.EnterpriseMeta)
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if err != nil {
return err
}
reply.Index = index
reply.ServiceTopology = topology
if err := m.srv.filterACL(args.Token, reply); err != nil {
return err
}
return nil
})
}
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// IntentionUpstreams returns the upstreams of a service. Upstreams are inferred from intentions.
// If intentions allow a connection from the target to some candidate service, the candidate service is considered
// an upstream of the target.
func (m *Internal) IntentionUpstreams(args *structs.ServiceSpecificRequest, reply *structs.IndexedServiceList) error {
// Exit early if Connect hasn't been enabled.
if !m.srv.config.ConnectEnabled {
return ErrConnectNotEnabled
}
if args.ServiceName == "" {
return fmt.Errorf("Must provide a service name")
}
if done, err := m.srv.ForwardRPC("Internal.IntentionUpstreams", args, reply); done {
return err
}
authz, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, nil)
if err != nil {
return err
}
if err := m.srv.validateEnterpriseRequest(&args.EnterpriseMeta, false); err != nil {
return err
}
server: suppress spurious blocking query returns where multiple config entries are involved (#12362) Starting from and extending the mechanism introduced in #12110 we can specially handle the 3 main special Consul RPC endpoints that react to many config entries in a single blocking query in Connect: - `DiscoveryChain.Get` - `ConfigEntry.ResolveServiceConfig` - `Intentions.Match` All of these will internally watch for many config entries, and at least one of those will likely be not found in any given query. Because these are blends of multiple reads the exact solution from #12110 isn't perfectly aligned, but we can tweak the approach slightly and regain the utility of that mechanism. ### No Config Entries Found In this case, despite looking for many config entries none may be found at all. Unlike #12110 in this scenario we do not return an empty reply to the caller, but instead synthesize a struct from default values to return. This can be handled nearly identically to #12110 with the first 1-2 replies being non-empty payloads followed by the standard spurious wakeup suppression mechanism from #12110. ### No Change Since Last Wakeup Once a blocking query loop on the server has completed and slept at least once, there is a further optimization we can make here to detect if any of the config entries that were present at specific versions for the prior execution of the loop are identical for the loop we just woke up for. In that scenario we can return a slightly different internal sentinel error and basically externally handle it similar to #12110. This would mean that even if 20 discovery chain read RPC handling goroutines wakeup due to the creation of an unrelated config entry, the only ones that will terminate and reply with a blob of data are those that genuinely have new data to report. ### Extra Endpoints Since this pattern is pretty reusable, other key config-entry-adjacent endpoints used by `agent/proxycfg` also were updated: - `ConfigEntry.List` - `Internal.IntentionUpstreams` (tproxy)
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var (
priorHash uint64
ranOnce bool
)
return m.srv.blockingQuery(
&args.QueryOptions,
&reply.QueryMeta,
func(ws memdb.WatchSet, state *state.Store) error {
defaultDecision := authz.IntentionDefaultAllow(nil)
sn := structs.NewServiceName(args.ServiceName, &args.EnterpriseMeta)
index, services, err := state.IntentionTopology(ws, sn, false, defaultDecision)
if err != nil {
return err
}
reply.Index, reply.Services = index, services
m.srv.filterACLWithAuthorizer(authz, reply)
server: suppress spurious blocking query returns where multiple config entries are involved (#12362) Starting from and extending the mechanism introduced in #12110 we can specially handle the 3 main special Consul RPC endpoints that react to many config entries in a single blocking query in Connect: - `DiscoveryChain.Get` - `ConfigEntry.ResolveServiceConfig` - `Intentions.Match` All of these will internally watch for many config entries, and at least one of those will likely be not found in any given query. Because these are blends of multiple reads the exact solution from #12110 isn't perfectly aligned, but we can tweak the approach slightly and regain the utility of that mechanism. ### No Config Entries Found In this case, despite looking for many config entries none may be found at all. Unlike #12110 in this scenario we do not return an empty reply to the caller, but instead synthesize a struct from default values to return. This can be handled nearly identically to #12110 with the first 1-2 replies being non-empty payloads followed by the standard spurious wakeup suppression mechanism from #12110. ### No Change Since Last Wakeup Once a blocking query loop on the server has completed and slept at least once, there is a further optimization we can make here to detect if any of the config entries that were present at specific versions for the prior execution of the loop are identical for the loop we just woke up for. In that scenario we can return a slightly different internal sentinel error and basically externally handle it similar to #12110. This would mean that even if 20 discovery chain read RPC handling goroutines wakeup due to the creation of an unrelated config entry, the only ones that will terminate and reply with a blob of data are those that genuinely have new data to report. ### Extra Endpoints Since this pattern is pretty reusable, other key config-entry-adjacent endpoints used by `agent/proxycfg` also were updated: - `ConfigEntry.List` - `Internal.IntentionUpstreams` (tproxy)
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// Generate a hash of the intentions content driving this response.
// Use it to determine if the response is identical to a prior
// wakeup.
newHash, err := hashstructure_v2.Hash(services, hashstructure_v2.FormatV2, nil)
if err != nil {
return fmt.Errorf("error hashing reply for spurious wakeup suppression: %w", err)
}
if ranOnce && priorHash == newHash {
priorHash = newHash
return errNotChanged
} else {
priorHash = newHash
ranOnce = true
}
return nil
})
}
// GatewayServiceNodes returns all the nodes for services associated with a gateway along with their gateway config
func (m *Internal) GatewayServiceDump(args *structs.ServiceSpecificRequest, reply *structs.IndexedServiceDump) error {
if done, err := m.srv.ForwardRPC("Internal.GatewayServiceDump", args, reply); done {
return err
}
// Verify the arguments
if args.ServiceName == "" {
return fmt.Errorf("Must provide gateway name")
}
var authzContext acl.AuthorizerContext
authz, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &args.EnterpriseMeta, &authzContext)
if err != nil {
return err
}
if err := m.srv.validateEnterpriseRequest(&args.EnterpriseMeta, false); err != nil {
return err
}
// We need read access to the gateway we're trying to find services for, so check that first.
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if authz.ServiceRead(args.ServiceName, &authzContext) != acl.Allow {
return acl.ErrPermissionDenied
}
err = m.srv.blockingQuery(
&args.QueryOptions,
&reply.QueryMeta,
func(ws memdb.WatchSet, state *state.Store) error {
var maxIdx uint64
idx, gatewayServices, err := state.GatewayServices(ws, args.ServiceName, &args.EnterpriseMeta)
if err != nil {
return err
}
if idx > maxIdx {
maxIdx = idx
}
// Loop over the gateway <-> serviceName mappings and fetch all service instances for each
var result structs.ServiceDump
for _, gs := range gatewayServices {
idx, instances, err := state.CheckServiceNodes(ws, gs.Service.Name, &gs.Service.EnterpriseMeta)
if err != nil {
return err
}
if idx > maxIdx {
maxIdx = idx
}
for _, n := range instances {
svc := structs.ServiceInfo{
Node: n.Node,
Service: n.Service,
Checks: n.Checks,
GatewayService: gs,
}
result = append(result, &svc)
}
// Ensure we store the gateway <-> service mapping even if there are no instances of the service
if len(instances) == 0 {
svc := structs.ServiceInfo{
GatewayService: gs,
}
result = append(result, &svc)
}
}
reply.Index, reply.Dump = maxIdx, result
if err := m.srv.filterACL(args.Token, reply); err != nil {
return err
}
return nil
})
return err
}
// Match returns the set of intentions that match the given source/destination.
func (m *Internal) GatewayIntentions(args *structs.IntentionQueryRequest, reply *structs.IndexedIntentions) error {
// Forward if necessary
if done, err := m.srv.ForwardRPC("Internal.GatewayIntentions", args, reply); done {
return err
}
if len(args.Match.Entries) > 1 {
return fmt.Errorf("Expected 1 gateway name, got %d", len(args.Match.Entries))
}
// Get the ACL token for the request for the checks below.
var entMeta structs.EnterpriseMeta
var authzContext acl.AuthorizerContext
authz, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, &entMeta, &authzContext)
if err != nil {
return err
}
if args.Match.Entries[0].Namespace == "" {
args.Match.Entries[0].Namespace = entMeta.NamespaceOrDefault()
}
if err := m.srv.validateEnterpriseIntentionNamespace(args.Match.Entries[0].Namespace, true); err != nil {
return fmt.Errorf("Invalid match entry namespace %q: %v", args.Match.Entries[0].Namespace, err)
}
// We need read access to the gateway we're trying to find intentions for, so check that first.
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if authz.ServiceRead(args.Match.Entries[0].Name, &authzContext) != acl.Allow {
return acl.ErrPermissionDenied
}
return m.srv.blockingQuery(
&args.QueryOptions,
&reply.QueryMeta,
func(ws memdb.WatchSet, state *state.Store) error {
var maxIdx uint64
idx, gatewayServices, err := state.GatewayServices(ws, args.Match.Entries[0].Name, &entMeta)
if err != nil {
return err
}
if idx > maxIdx {
maxIdx = idx
}
// Loop over the gateway <-> serviceName mappings and fetch all intentions for each
seen := make(map[string]bool)
result := make(structs.Intentions, 0)
for _, gs := range gatewayServices {
entry := structs.IntentionMatchEntry{
Namespace: gs.Service.NamespaceOrDefault(),
Partition: gs.Service.PartitionOrDefault(),
Name: gs.Service.Name,
}
idx, intentions, err := state.IntentionMatchOne(ws, entry, structs.IntentionMatchDestination)
if err != nil {
return err
}
if idx > maxIdx {
maxIdx = idx
}
// Deduplicate wildcard intentions
for _, ixn := range intentions {
if !seen[ixn.ID] {
result = append(result, ixn)
seen[ixn.ID] = true
}
}
}
reply.Index, reply.Intentions = maxIdx, result
if reply.Intentions == nil {
reply.Intentions = make(structs.Intentions, 0)
}
if err := m.srv.filterACL(args.Token, reply); err != nil {
return err
}
return nil
},
)
}
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// EventFire is a bit of an odd endpoint, but it allows for a cross-DC RPC
// call to fire an event. The primary use case is to enable user events being
// triggered in a remote DC.
func (m *Internal) EventFire(args *structs.EventFireRequest,
reply *structs.EventFireResponse) error {
if done, err := m.srv.ForwardRPC("Internal.EventFire", args, reply); done {
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return err
}
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// Check ACLs
authz, err := m.srv.ResolveTokenAndDefaultMeta(args.Token, nil, nil)
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if err != nil {
return err
}
if authz.EventWrite(args.Name, nil) != acl.Allow {
accessorID := authz.AccessorID()
m.logger.Warn("user event blocked by ACLs", "event", args.Name, "accessorID", accessorID)
return acl.ErrPermissionDenied
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}
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// Set the query meta data
m.srv.setQueryMeta(&reply.QueryMeta, args.Token)
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// Add the consul prefix to the event name
eventName := userEventName(args.Name)
// Fire the event on all LAN segments
return m.srv.LANSendUserEvent(eventName, args.Payload, false)
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}
// KeyringOperation will query the WAN and LAN gossip keyrings of all nodes.
func (m *Internal) KeyringOperation(
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args *structs.KeyringRequest,
reply *structs.KeyringResponses) error {
// Error aggressively to be clear about LocalOnly behavior
if args.LocalOnly && args.Operation != structs.KeyringList {
return fmt.Errorf("argument error: LocalOnly can only be used for List operations")
}
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// Check ACLs
authz, err := m.srv.ACLResolver.ResolveToken(args.Token)
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if err != nil {
return err
}
if err := m.srv.validateEnterpriseToken(authz.Identity()); err != nil {
return err
}
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switch args.Operation {
case structs.KeyringList:
if authz.KeyringRead(nil) != acl.Allow {
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return fmt.Errorf("Reading keyring denied by ACLs")
}
case structs.KeyringInstall:
fallthrough
case structs.KeyringUse:
fallthrough
case structs.KeyringRemove:
if authz.KeyringWrite(nil) != acl.Allow {
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return fmt.Errorf("Modifying keyring denied due to ACLs")
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}
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default:
panic("Invalid keyring operation")
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}
if args.LocalOnly || args.Forwarded || m.srv.serfWAN == nil {
// Handle operations that are localOnly, already forwarded or
// there is no serfWAN. If any of this is the case this
// operation shouldn't go out to other dcs or WAN pool.
reply.Responses = append(reply.Responses, m.executeKeyringOpLAN(args)...)
} else {
// Handle not already forwarded, non-local operations.
// Marking this as forwarded because this is what we are about
// to do. Prevents the same message from being fowarded by
// other servers.
args.Forwarded = true
reply.Responses = append(reply.Responses, m.executeKeyringOpWAN(args))
reply.Responses = append(reply.Responses, m.executeKeyringOpLAN(args)...)
dcs := m.srv.router.GetRemoteDatacenters(m.srv.config.Datacenter)
responses, err := m.srv.keyringRPCs("Internal.KeyringOperation", args, dcs)
if err != nil {
return err
}
reply.Add(responses)
}
return nil
}
func (m *Internal) executeKeyringOpLAN(args *structs.KeyringRequest) []*structs.KeyringResponse {
responses := []*structs.KeyringResponse{}
_ = m.srv.DoWithLANSerfs(func(poolName, poolKind string, pool *serf.Serf) error {
mgr := pool.KeyManager()
serfResp, err := m.executeKeyringOpMgr(mgr, args)
resp := translateKeyResponseToKeyringResponse(serfResp, m.srv.config.Datacenter, err)
if poolKind == PoolKindSegment {
resp.Segment = poolName
} else {
resp.Partition = poolName
}
responses = append(responses, &resp)
return nil
}, nil)
return responses
}
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func (m *Internal) executeKeyringOpWAN(args *structs.KeyringRequest) *structs.KeyringResponse {
mgr := m.srv.KeyManagerWAN()
serfResp, err := m.executeKeyringOpMgr(mgr, args)
resp := translateKeyResponseToKeyringResponse(serfResp, m.srv.config.Datacenter, err)
resp.WAN = true
return &resp
}
func translateKeyResponseToKeyringResponse(keyresponse *serf.KeyResponse, datacenter string, err error) structs.KeyringResponse {
resp := structs.KeyringResponse{
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Datacenter: datacenter,
Messages: keyresponse.Messages,
Keys: keyresponse.Keys,
PrimaryKeys: keyresponse.PrimaryKeys,
NumNodes: keyresponse.NumNodes,
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}
if err != nil {
resp.Error = err.Error()
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}
return resp
}
// executeKeyringOpMgr executes the appropriate keyring-related function based on
// the type of keyring operation in the request. It takes the KeyManager as an
// argument, so it can handle any operation for either LAN or WAN pools.
func (m *Internal) executeKeyringOpMgr(
mgr *serf.KeyManager,
args *structs.KeyringRequest,
) (*serf.KeyResponse, error) {
var serfResp *serf.KeyResponse
var err error
opts := &serf.KeyRequestOptions{RelayFactor: args.RelayFactor}
switch args.Operation {
case structs.KeyringList:
serfResp, err = mgr.ListKeysWithOptions(opts)
case structs.KeyringInstall:
serfResp, err = mgr.InstallKeyWithOptions(args.Key, opts)
case structs.KeyringUse:
serfResp, err = mgr.UseKeyWithOptions(args.Key, opts)
case structs.KeyringRemove:
serfResp, err = mgr.RemoveKeyWithOptions(args.Key, opts)
}
return serfResp, err
}