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cluster.go
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cluster.go
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// Copyright 2022 Molecula Corp. (DBA FeatureBase).
// SPDX-License-Identifier: Apache-2.0
package pilosa
import (
"context"
"encoding/json"
"fmt"
"log"
"sync"
"time"
"github.com/featurebasedb/featurebase/v3/dax"
"github.com/featurebasedb/featurebase/v3/dax/computer"
"github.com/featurebasedb/featurebase/v3/dax/storage"
"github.com/featurebasedb/featurebase/v3/disco"
"github.com/featurebasedb/featurebase/v3/logger"
"github.com/featurebasedb/featurebase/v3/roaring"
"github.com/pkg/errors"
"golang.org/x/sync/errgroup"
)
const (
defaultConfirmDownRetries = 10
defaultConfirmDownSleep = 1 * time.Second
)
// cluster represents a collection of nodes.
type cluster struct { //nolint: maligned
noder disco.Noder
id string
Node *disco.Node
// Hashing algorithm used to assign partitions to nodes.
Hasher disco.Hasher
// The number of partitions in the cluster.
partitionN int
// The number of replicas a partition has.
ReplicaN int
// Human-readable name of the cluster.
Name string
// Maximum number of Set() or Clear() commands per request.
maxWritesPerRequest int
// Data directory path.
Path string
// Distributed Consensus
disCo disco.DisCo
sharder disco.Sharder
holder *Holder
broadcaster broadcaster
translationSyncer TranslationSyncer
mu sync.RWMutex
// Close management
wg sync.WaitGroup
closing chan struct{}
logger logger.Logger
InternalClient *InternalClient
confirmDownRetries int
confirmDownSleep time.Duration
partitionAssigner string
serverlessStorage *storage.ResourceManager
// isComputeNode is set to true if this node is running as a DAX compute
// node.
isComputeNode bool
}
// newCluster returns a new instance of Cluster with defaults.
func newCluster() *cluster {
return &cluster{
Hasher: &disco.Jmphasher{},
partitionN: disco.DefaultPartitionN,
ReplicaN: 1,
closing: make(chan struct{}),
translationSyncer: NopTranslationSyncer,
InternalClient: &InternalClient{}, // TODO might have to fill this out a bit
logger: logger.NopLogger,
confirmDownRetries: defaultConfirmDownRetries,
confirmDownSleep: defaultConfirmDownSleep,
disCo: disco.NopDisCo,
noder: disco.NewEmptyLocalNoder(),
}
}
func (c *cluster) primaryNode() *disco.Node {
return c.unprotectedPrimaryNode()
}
// unprotectedPrimaryNode returns the primary node.
func (c *cluster) unprotectedPrimaryNode() *disco.Node {
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
return snap.PrimaryFieldTranslationNode()
}
// nodeIDs returns the list of IDs in the cluster.
func (c *cluster) nodeIDs() []string {
return disco.Nodes(c.Nodes()).IDs()
}
func (c *cluster) State() (disco.ClusterState, error) {
return c.noder.ClusterState(context.Background())
}
func (c *cluster) nodeByID(id string) *disco.Node {
c.mu.RLock()
defer c.mu.RUnlock()
return c.unprotectedNodeByID(id)
}
// unprotectedNodeByID returns a node reference by ID.
func (c *cluster) unprotectedNodeByID(id string) *disco.Node {
for _, n := range c.noder.Nodes() {
if n.ID == id {
return n
}
}
return nil
}
// nodePositionByID returns the position of the node in slice c.Nodes.
func (c *cluster) nodePositionByID(nodeID string) int {
for i, n := range c.noder.Nodes() {
if n.ID == nodeID {
return i
}
}
return -1
}
// Nodes returns a copy of the slice of nodes in the cluster. Safe for
// concurrent use, result may be modified.
func (c *cluster) Nodes() []*disco.Node {
nodes := c.noder.Nodes()
// duplicate the nodes since we're going to be altering them
copiedNodes := make([]disco.Node, len(nodes))
result := make([]*disco.Node, len(nodes))
primary := disco.PrimaryNode(nodes, c.Hasher)
// Set node states and IsPrimary.
for i, node := range nodes {
copiedNodes[i] = *node
result[i] = &copiedNodes[i]
if node == primary {
copiedNodes[i].IsPrimary = true
}
}
return result
}
// shardDistributionByIndex returns a map of [nodeID][primaryOrReplica][]uint64,
// where the int slices are lists of shards.
func (c *cluster) shardDistributionByIndex(indexName string) map[string]map[string][]uint64 {
dist := make(map[string]map[string][]uint64)
for _, node := range c.noder.Nodes() {
nodeDist := make(map[string][]uint64)
nodeDist["primary-shards"] = make([]uint64, 0)
nodeDist["replica-shards"] = make([]uint64, 0)
dist[node.ID] = nodeDist
}
index := c.holder.Index(indexName)
available := index.AvailableShards(includeRemote).Slice()
c.mu.RLock()
defer c.mu.RUnlock()
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
for _, shard := range available {
p := snap.ShardToShardPartition(indexName, shard)
nodes := snap.PartitionNodes(p)
dist[nodes[0].ID]["primary-shards"] = append(dist[nodes[0].ID]["primary-shards"], shard)
for k := 1; k < len(nodes); k++ {
dist[nodes[k].ID]["replica-shards"] = append(dist[nodes[k].ID]["replica-shards"], shard)
}
}
return dist
}
func (c *cluster) close() error {
// Notify goroutines of closing and wait for completion.
close(c.closing)
c.wg.Wait()
return nil
}
// PrimaryReplicaNode returns the node listed before the current node in c.Nodes.
// This is different than "previous node" as the first node always returns nil.
func (c *cluster) PrimaryReplicaNode() *disco.Node {
c.mu.RLock()
defer c.mu.RUnlock()
return c.unprotectedPrimaryReplicaNode()
}
func (c *cluster) unprotectedPrimaryReplicaNode() *disco.Node {
pos := c.nodePositionByID(c.Node.ID)
if pos <= 0 {
return nil
}
cNodes := c.noder.Nodes()
return cNodes[pos-1]
}
// TODO: remove this when it is no longer used
func (c *cluster) translateFieldKeys(ctx context.Context, field *Field, keys []string, writable bool) ([]uint64, error) {
var trans map[string]uint64
var err error
if writable {
trans, err = c.createFieldKeys(ctx, field, keys...)
} else {
trans, err = c.findFieldKeys(ctx, field, keys...)
}
if err != nil {
return nil, err
}
ids := make([]uint64, len(keys))
for i, key := range keys {
id, ok := trans[key]
if !ok {
return nil, ErrTranslatingKeyNotFound
}
ids[i] = id
}
return ids, nil
}
func (c *cluster) findFieldKeys(ctx context.Context, field *Field, keys ...string) (map[string]uint64, error) {
if idx := field.ForeignIndex(); idx != "" {
// The field uses foreign index keys.
// Therefore, the field keys are actually column keys on a different index.
return c.findIndexKeys(ctx, idx, keys...)
}
if !field.Keys() {
return nil, errors.Errorf("cannot find keys on unkeyed field %q", field.Name())
}
// Attempt to find the keys locally.
localTranslations, err := field.TranslateStore().FindKeys(keys...)
if err != nil {
return nil, errors.Wrapf(err, "translating field(%s/%s) keys(%v) locally", field.Index(), field.Name(), keys)
}
// Check for missing keys.
var missing []string
if len(keys) > len(localTranslations) {
// There are either duplicate keys or missing keys.
// This should work either way.
missing = make([]string, 0, len(keys)-len(localTranslations))
for _, k := range keys {
_, found := localTranslations[k]
if !found {
missing = append(missing, k)
}
}
} else if len(localTranslations) > len(keys) {
panic(fmt.Sprintf("more translations than keys! translation count=%v, key count=%v", len(localTranslations), len(keys)))
}
if len(missing) == 0 {
// All keys were available locally.
return localTranslations, nil
}
// It is possible that the missing keys exist, but have not been synced to the local replica.
primary := c.primaryNode()
if primary == nil {
return nil, errors.Errorf("translating field(%s/%s) keys(%v) - cannot find primary node", field.Index(), field.Name(), keys)
}
if c.Node.ID == primary.ID {
// The local copy is the authoritative copy.
return localTranslations, nil
}
// Forward the missing keys to the primary.
// The primary has the authoritative copy.
remoteTranslations, err := c.InternalClient.FindFieldKeysNode(ctx, &primary.URI, field.Index(), field.Name(), missing...)
if err != nil {
return nil, errors.Wrapf(err, "translating field(%s/%s) keys(%v) remotely", field.Index(), field.Name(), keys)
}
// Merge the remote translations into the local translations.
translations := localTranslations
for key, id := range remoteTranslations {
translations[key] = id
}
return translations, nil
}
func (c *cluster) appendFieldKeysWriteLog(ctx context.Context, qtid dax.QualifiedTableID, fieldName dax.FieldName, translations map[string]uint64) error {
// TODO move marshaling somewhere more centralized and less... explicitly json-y
msg := computer.FieldKeyMap{
TableKey: qtid.Key(),
Field: fieldName,
StringToID: translations,
}
b, err := json.Marshal(msg)
if err != nil {
return errors.Wrap(err, "marshalling field key map to json")
}
resource := c.serverlessStorage.GetFieldKeyResource(qtid, fieldName)
err = resource.Append(b)
if err != nil {
return errors.Wrap(err, "appending field keys")
}
return nil
}
func (c *cluster) appendTableKeysWriteLog(ctx context.Context, qtid dax.QualifiedTableID, partition dax.PartitionNum, translations map[string]uint64) error {
msg := computer.PartitionKeyMap{
TableKey: qtid.Key(),
Partition: partition,
StringToID: translations,
}
b, err := json.Marshal(msg)
if err != nil {
return errors.Wrap(err, "marshalling partition key map to json")
}
resource := c.serverlessStorage.GetTableKeyResource(qtid, partition)
return errors.Wrap(resource.Append(b), "appending table keys")
}
func (c *cluster) createFieldKeys(ctx context.Context, field *Field, keys ...string) (map[string]uint64, error) {
if idx := field.ForeignIndex(); idx != "" {
// The field uses foreign index keys.
// Therefore, the field keys are actually column keys on a different index.
return c.createIndexKeys(ctx, idx, keys...)
}
if !field.Keys() {
return nil, errors.Errorf("cannot create keys on unkeyed field %q", field.Name())
}
// The primary is the only node that can create field keys, since it owns the authoritative copy.
primary := c.primaryNode()
if primary == nil {
return nil, errors.Errorf("translating field(%s/%s) keys(%v) - cannot find primary node", field.Index(), field.Name(), keys)
}
if c.Node.ID == primary.ID {
translations, err := field.TranslateStore().CreateKeys(keys...)
if err != nil {
return nil, errors.Errorf("creating field(%s/%s) keys(%v)", field.Index(), field.Name(), keys)
}
// If this is not a DAX compute node, bail early; there's no need to
// send data to the write log.
if !c.isComputeNode {
return translations, nil
}
// Send to write log.
tkey := dax.TableKey(field.Index())
qtid := tkey.QualifiedTableID()
fieldName := dax.FieldName(field.Name())
err = c.appendFieldKeysWriteLog(ctx, qtid, fieldName, translations)
if err != nil {
return nil, errors.Wrap(err, "appending to write log")
}
return translations, nil
}
// Attempt to find the keys locally.
// They cannot be created locally, but skipping keys that exist can reduce network usage.
localTranslations, err := field.TranslateStore().FindKeys(keys...)
if err != nil {
return nil, errors.Wrapf(err, "translating field(%s/%s) keys(%v) locally", field.Index(), field.Name(), keys)
}
// Check for missing keys.
var missing []string
if len(keys) > len(localTranslations) {
// There are either duplicate keys or missing keys.
// This should work either way.
missing = make([]string, 0, len(keys)-len(localTranslations))
for _, k := range keys {
_, found := localTranslations[k]
if !found {
missing = append(missing, k)
}
}
} else if len(localTranslations) > len(keys) {
panic(fmt.Sprintf("more translations than keys! translation count=%v, key count=%v", len(localTranslations), len(keys)))
}
if len(missing) == 0 {
// All keys exist locally.
// There is no need to create anything.
return localTranslations, nil
}
// Forward the missing keys to the primary to be created.
remoteTranslations, err := c.InternalClient.CreateFieldKeysNode(ctx, &primary.URI, field.Index(), field.Name(), missing...)
if err != nil {
return nil, errors.Wrapf(err, "translating field(%s/%s) keys(%v) remotely", field.Index(), field.Name(), keys)
}
// Merge the remote translations into the local translations.
translations := localTranslations
for key, id := range remoteTranslations {
translations[key] = id
}
return translations, nil
}
func (c *cluster) matchField(ctx context.Context, field *Field, like string) ([]uint64, error) {
// The primary is the only node that can match field keys, since it is the only node with all of the keys.
primary := c.primaryNode()
if primary == nil {
return nil, errors.Errorf("matching field(%s/%s) like %q - cannot find primary node", field.Index(), field.Name(), like)
}
if c.Node.ID == primary.ID {
// The local copy is the authoritative copy.
plan := planLike(like)
store := field.TranslateStore()
if store == nil {
return nil, ErrTranslateStoreNotFound
}
return field.TranslateStore().Match(func(key []byte) bool {
return matchLike(key, plan...)
})
}
// Forward the request to the primary.
return c.InternalClient.MatchFieldKeysNode(ctx, &primary.URI, field.Index(), field.Name(), like)
}
func (c *cluster) translateFieldIDs(ctx context.Context, field *Field, ids map[uint64]struct{}) (map[uint64]string, error) {
idList := make([]uint64, len(ids))
{
i := 0
for id := range ids {
idList[i] = id
i++
}
}
keyList, err := c.translateFieldListIDs(ctx, field, idList)
if err != nil {
return nil, err
}
mapped := make(map[uint64]string, len(idList))
for i, key := range keyList {
mapped[idList[i]] = key
}
return mapped, nil
}
func (c *cluster) translateFieldListIDs(ctx context.Context, field *Field, ids []uint64) (keys []string, err error) {
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
primary := snap.PrimaryFieldTranslationNode()
if primary == nil {
return nil, errors.Errorf("translating field(%s/%s) ids(%v) - cannot find primary node", field.Index(), field.Name(), ids)
}
if c.Node.ID == primary.ID {
store := field.TranslateStore()
if store == nil {
return nil, ErrTranslateStoreNotFound
}
keys, err = field.TranslateStore().TranslateIDs(ids)
} else {
keys, err = c.InternalClient.TranslateIDsNode(ctx, &primary.URI, field.Index(), field.Name(), ids)
}
if err != nil {
return nil, errors.Wrapf(err, "translating field(%s/%s) ids(%v)", field.Index(), field.Name(), ids)
}
return keys, err
}
// TODO: remove this when it is no longer used
func (c *cluster) translateIndexKey(ctx context.Context, indexName string, key string, writable bool) (uint64, error) {
keyMap, err := c.translateIndexKeySet(ctx, indexName, map[string]struct{}{key: {}}, writable)
if err != nil {
return 0, err
}
return keyMap[key], nil
}
// TODO: remove this when it is no longer used
func (c *cluster) translateIndexKeys(ctx context.Context, indexName string, keys []string, writable bool) ([]uint64, error) {
var trans map[string]uint64
var err error
if writable {
trans, err = c.createIndexKeys(ctx, indexName, keys...)
} else {
trans, err = c.findIndexKeys(ctx, indexName, keys...)
}
if err != nil {
return nil, err
}
ids := make([]uint64, len(keys))
for i, key := range keys {
id, ok := trans[key]
if !ok {
return nil, ErrTranslatingKeyNotFound
}
ids[i] = id
}
return ids, nil
}
// TODO: remove this when it is no longer used
func (c *cluster) translateIndexKeySet(ctx context.Context, indexName string, keySet map[string]struct{}, writable bool) (map[string]uint64, error) {
keys := make([]string, 0, len(keySet))
for key := range keySet {
keys = append(keys, key)
}
if writable {
return c.createIndexKeys(ctx, indexName, keys...)
}
trans, err := c.findIndexKeys(ctx, indexName, keys...)
if err != nil {
return nil, err
}
if len(trans) != len(keys) {
return nil, ErrTranslatingKeyNotFound
}
return trans, nil
}
func (c *cluster) findIndexKeys(ctx context.Context, indexName string, keys ...string) (map[string]uint64, error) {
done := ctx.Done()
idx := c.holder.Index(indexName)
if idx == nil {
return nil, ErrIndexNotFound
}
if !idx.Keys() {
return nil, errors.Errorf("cannot find keys on unkeyed index %q", indexName)
}
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
// Split keys by partition.
keysByPartition := make(map[int][]string, c.partitionN)
for _, key := range keys {
partitionID := snap.KeyToKeyPartition(indexName, key)
keysByPartition[partitionID] = append(keysByPartition[partitionID], key)
// This node only handles keys for the partition(s) that it owns.
if c.isComputeNode {
if !intInPartitions(partitionID, idx.translatePartitions) {
return nil, errors.Errorf("cannot find key on this partition: %s, %d", key, partitionID)
}
}
}
// TODO: use local replicas to short-circuit network traffic
// Group keys by node.
keysByNode := make(map[*disco.Node][]string)
for partitionID, keys := range keysByPartition {
// Find the primary node for this partition.
primary := snap.PrimaryPartitionNode(partitionID)
if primary == nil {
return nil, errors.Errorf("translating index(%s) keys(%v) on partition(%d) - cannot find primary node", indexName, keys, partitionID)
}
if c.Node.ID == primary.ID {
// The partition is local.
continue
}
// Group the partition to be processed remotely.
keysByNode[primary] = append(keysByNode[primary], keys...)
// Delete remote keys from the by-partition map so that it can be used for local translation.
delete(keysByPartition, partitionID)
}
// Start translating keys remotely.
// On child calls, there are no remote results since we were only sent the keys that we own.
remoteResults := make(chan map[string]uint64, len(keysByNode))
var g errgroup.Group
defer g.Wait() //nolint:errcheck
for node, keys := range keysByNode {
node, keys := node, keys
g.Go(func() error {
translations, err := c.InternalClient.FindIndexKeysNode(ctx, &node.URI, indexName, keys...)
if err != nil {
return errors.Wrapf(err, "translating index(%s) keys(%v) on node %s", indexName, keys, node.ID)
}
remoteResults <- translations
return nil
})
}
// Translate local keys.
translations := make(map[string]uint64)
for partitionID, keys := range keysByPartition {
// Handle cancellation.
select {
case <-done:
return nil, ctx.Err()
default:
}
// Find the keys within the partition.
t, err := idx.TranslateStore(partitionID).FindKeys(keys...)
if err != nil {
return nil, errors.Wrapf(err, "translating index(%s) keys(%v) on partition(%d)", idx.Name(), keys, partitionID)
}
// Merge the translations from this partition.
for key, id := range t {
translations[key] = id
}
}
// Wait for remote key sets.
if err := g.Wait(); err != nil {
return nil, err
}
// Merge the translations.
// All data should have been written to here while we waited.
// Closing the channel prevents the range from blocking.
close(remoteResults)
for t := range remoteResults {
for key, id := range t {
translations[key] = id
}
}
return translations, nil
}
func (c *cluster) createIndexKeys(ctx context.Context, indexName string, keys ...string) (map[string]uint64, error) {
// Check for early cancellation.
done := ctx.Done()
select {
case <-done:
return nil, ctx.Err()
default:
}
idx := c.holder.Index(indexName)
if idx == nil {
return nil, ErrIndexNotFound
}
if !idx.keys {
return nil, errors.Errorf("cannot create keys on unkeyed index %q", indexName)
}
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
// Split keys by partition.
keysByPartition := make(map[int][]string, c.partitionN)
for _, key := range keys {
partitionID := snap.KeyToKeyPartition(indexName, key)
keysByPartition[partitionID] = append(keysByPartition[partitionID], key)
// This node only handles keys for the partition(s) that it owns.
if c.isComputeNode {
if !intInPartitions(partitionID, idx.translatePartitions) {
log.Printf("cannot create key on this partition: %s, %d", key, partitionID)
return nil, errors.Errorf("cannot create key on this partition: %s, %d", key, partitionID)
}
}
}
// TODO: use local replicas to short-circuit network traffic
// Group keys by node.
// Delete remote keys from the by-partition map so that it can be used for local translation.
keysByNode := make(map[*disco.Node][]string)
for partitionID, keys := range keysByPartition {
// Find the primary node for this partition.
primary := snap.PrimaryPartitionNode(partitionID)
if primary == nil {
return nil, errors.Errorf("translating index(%s) keys(%v) on partition(%d) - cannot find primary node", indexName, keys, partitionID)
}
if c.Node.ID == primary.ID {
// The partition is local.
continue
}
// Group the partition to be processed remotely.
keysByNode[primary] = append(keysByNode[primary], keys...)
delete(keysByPartition, partitionID)
}
translateResults := make(chan map[string]uint64, len(keysByNode)+len(keysByPartition))
var g errgroup.Group
defer g.Wait() //nolint:errcheck
// Start translating keys remotely.
// On child calls, there are no remote results since we were only sent the keys that we own.
for node, keys := range keysByNode {
node, keys := node, keys
g.Go(func() error {
translations, err := c.InternalClient.CreateIndexKeysNode(ctx, &node.URI, indexName, keys...)
if err != nil {
return errors.Wrapf(err, "translating index(%s) keys(%v) on node %s", indexName, keys, node.ID)
}
translateResults <- translations
return nil
})
}
// Translate local keys.
// TODO: make this less horrible (why fsync why?????)
// This is kinda terrible because each goroutine does an fsync, thus locking up an entire OS thread.
// AHHHHHHHHHHHHHHHHHH
for partitionID, keys := range keysByPartition {
partitionID, keys := partitionID, keys
g.Go(func() error {
// Handle cancellation.
select {
case <-done:
return ctx.Err()
default:
}
translations, err := idx.TranslateStore(partitionID).CreateKeys(keys...)
if err != nil {
return errors.Wrapf(err, "translating index(%s) keys(%v) on partition(%d)", idx.Name(), keys, partitionID)
}
translateResults <- translations
// If this is not a DAX compute node, bail early; there's no need to
// send data to the write log.
if !c.isComputeNode {
return nil
}
// Send to write log.
tkey := dax.TableKey(idx.Name())
qtid := tkey.QualifiedTableID()
partitionNum := dax.PartitionNum(partitionID)
return c.appendTableKeysWriteLog(ctx, qtid, partitionNum, translations)
})
}
// Wait for remote key sets.
if err := g.Wait(); err != nil {
return nil, err
}
// Merge the translations.
// All data should have been written to here while we waited.
// Closing the channel prevents the range from blocking.
translations := make(map[string]uint64, len(keys))
close(translateResults)
for t := range translateResults {
for key, id := range t {
translations[key] = id
}
}
return translations, nil
}
func (c *cluster) translateIndexIDs(ctx context.Context, indexName string, ids []uint64) ([]string, error) {
idSet := make(map[uint64]struct{})
for _, id := range ids {
idSet[id] = struct{}{}
}
idMap, err := c.translateIndexIDSet(ctx, indexName, idSet)
if err != nil {
return nil, err
}
keys := make([]string, len(ids))
for i := range ids {
keys[i] = idMap[ids[i]]
}
return keys, nil
}
func (c *cluster) translateIndexIDSet(ctx context.Context, indexName string, idSet map[uint64]struct{}) (map[uint64]string, error) {
idMap := make(map[uint64]string, len(idSet))
index := c.holder.Index(indexName)
if index == nil {
return nil, newNotFoundError(ErrIndexNotFound, indexName)
}
// Create a snapshot of the cluster to use for node/partition calculations.
snap := c.NewSnapshot()
// Split ids by partition.
idsByPartition := make(map[int][]uint64, c.partitionN)
for id := range idSet {
partitionID := snap.IDToShardPartition(indexName, id)
// This node only handles keys for the partition(s) that it owns.
if c.isComputeNode {
if !intInPartitions(partitionID, index.translatePartitions) {
return nil, errors.Errorf("cannot find id on this partition: %d, %d", id, partitionID)
}
}
idsByPartition[partitionID] = append(idsByPartition[partitionID], id)
}
// Translate ids by partition.
var g errgroup.Group
var mu sync.Mutex
for partitionID := range idsByPartition {
partitionID := partitionID
ids := idsByPartition[partitionID]
g.Go(func() (err error) {
var keys []string
primary := snap.PrimaryPartitionNode(partitionID)
if primary == nil {
return errors.Errorf("translating index(%s) ids(%v) on partition(%d) - cannot find primary node", indexName, ids, partitionID)
}
if c.Node.ID == primary.ID {
keys, err = index.TranslateStore(partitionID).TranslateIDs(ids)
} else {
keys, err = c.InternalClient.TranslateIDsNode(ctx, &primary.URI, indexName, "", ids)
}
if err != nil {
return errors.Wrapf(err, "translating index(%s) ids(%v) on partition(%d)", indexName, ids, partitionID)
}
mu.Lock()
for i, id := range ids {
idMap[id] = keys[i]
}
mu.Unlock()
return nil
})
}
if err := g.Wait(); err != nil {
return nil, err
}
return idMap, nil
}
func (c *cluster) NewSnapshot() *disco.ClusterSnapshot {
return disco.NewClusterSnapshot(c.noder, c.Hasher, c.partitionAssigner, c.ReplicaN)
}
// ClusterStatus describes the status of the cluster including its
// state and node topology.
type ClusterStatus struct {
ClusterID string
State string
Nodes []*disco.Node
Schema *Schema
}
// Schema contains information about indexes and their configuration.
type Schema struct {
Indexes []*IndexInfo `json:"indexes"`
}
// CreateShardMessage is an internal message indicating shard creation.
type CreateShardMessage struct {
Index string
Field string
Shard uint64
}
// CreateIndexMessage is an internal message indicating index creation.
type CreateIndexMessage struct {
Index string
CreatedAt int64
Owner string
Meta IndexOptions
}
// DeleteIndexMessage is an internal message indicating index deletion.
type DeleteIndexMessage struct {
Index string
}
// CreateFieldMessage is an internal message indicating field creation.
type CreateFieldMessage struct {
Index string
Field string
CreatedAt int64
Owner string
Meta *FieldOptions
}
// UpdateFieldMessage represents a change to an existing field. The
// CreateFieldMessage holds the changed field, while the update shows
// the change that was made.
type UpdateFieldMessage struct {
CreateFieldMessage CreateFieldMessage
Update FieldUpdate
}
// DeleteFieldMessage is an internal message indicating field deletion.
type DeleteFieldMessage struct {
Index string
Field string
}
// DeleteAvailableShardMessage is an internal message indicating available shard deletion.
type DeleteAvailableShardMessage struct {
Index string
Field string
ShardID uint64
}
// CreateViewMessage is an internal message indicating view creation.
type CreateViewMessage struct {
Index string
Field string
View string
}
// DeleteViewMessage is an internal message indicating view deletion.
type DeleteViewMessage struct {
Index string
Field string
View string
}
// NodeStateMessage is an internal message for broadcasting a node's state.
type NodeStateMessage struct {
NodeID string `protobuf:"bytes,1,opt,name=NodeID,proto3" json:"NodeID,omitempty"`
State string `protobuf:"bytes,2,opt,name=State,proto3" json:"State,omitempty"`
}
// NodeStatus is an internal message representing the contents of a node.
type NodeStatus struct {
Node *disco.Node
Indexes []*IndexStatus
Schema *Schema
}
// IndexStatus is an internal message representing the contents of an index.
type IndexStatus struct {
Name string
CreatedAt int64
Fields []*FieldStatus
}
// FieldStatus is an internal message representing the contents of a field.
type FieldStatus struct {
Name string
CreatedAt int64
AvailableShards *roaring.Bitmap
}
// RecalculateCaches is an internal message for recalculating all caches