dendrite/userapi/internal/device_list_update.go

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// Copyright 2020 The Matrix.org Foundation C.I.C.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package internal
import (
"context"
"encoding/json"
"errors"
"fmt"
"hash/fnv"
"net"
"strconv"
"sync"
"time"
rsapi "github.com/matrix-org/dendrite/roomserver/api"
"github.com/matrix-org/gomatrixserverlib/fclient"
"github.com/matrix-org/gomatrixserverlib/spec"
"github.com/matrix-org/gomatrix"
"github.com/matrix-org/gomatrixserverlib"
"github.com/matrix-org/util"
"github.com/prometheus/client_golang/prometheus"
"github.com/sirupsen/logrus"
fedsenderapi "github.com/matrix-org/dendrite/federationapi/api"
"github.com/matrix-org/dendrite/setup/process"
"github.com/matrix-org/dendrite/userapi/api"
)
var (
deviceListUpdateCount = prometheus.NewCounterVec(
prometheus.CounterOpts{
Namespace: "dendrite",
Subsystem: "keyserver",
Name: "device_list_update",
Help: "Number of times we have attempted to update device lists from this server",
},
[]string{"server"},
)
)
const requestTimeout = time.Second * 30
func init() {
prometheus.MustRegister(
deviceListUpdateCount,
)
}
// DeviceListUpdater handles device list updates from remote servers.
//
// In the case where we have the prev_id for an update, the updater just stores the update (after acquiring a per-user lock).
// In the case where we do not have the prev_id for an update, the updater marks the user_id as stale and notifies
// a worker to get the latest device list for this user. Note: stream IDs are scoped per user so missing a prev_id
// for a (user, device) does not mean that DEVICE is outdated as the previous ID could be for a different device:
// we have to invalidate all devices for that user. Once the list has been fetched, the per-user lock is acquired and the
// updater stores the latest list along with the latest stream ID.
//
// On startup, the updater spins up N workers which are responsible for querying device keys from remote servers.
// Workers are scoped by homeserver domain, with one worker responsible for many domains, determined by hashing
// mod N the server name. Work is sent via a channel which just serves to "poke" the worker as the data is retrieved
// from the database (which allows us to batch requests to the same server). This has a number of desirable properties:
// - We guarantee only 1 in-flight /keys/query request per server at any time as there is exactly 1 worker responsible
// for that domain.
// - We don't have unbounded growth in proportion to the number of servers (this is more important in a P2P world where
// we have many many servers)
// - We can adjust concurrency (at the cost of memory usage) by tuning N, to accommodate mobile devices vs servers.
//
// The downsides are that:
// - Query requests can get queued behind other servers if they hash to the same worker, even if there are other free
// workers elsewhere. Whilst suboptimal, provided we cap how long a single request can last (e.g using context timeouts)
// we guarantee we will get around to it. Also, more users on a given server does not increase the number of requests
// (as /keys/query allows multiple users to be specified) so being stuck behind matrix.org won't materially be any worse
// than being stuck behind foo.bar
//
// In the event that the query fails, a lock is acquired and the server name along with the time to wait before retrying is
// set in a map. A restarter goroutine periodically probes this map and injects servers which are ready to be retried.
type DeviceListUpdater struct {
process *process.ProcessContext
// A map from user_id to a mutex. Used when we are missing prev IDs so we don't make more than 1
// request to the remote server and race.
// TODO: Put in an LRU cache to bound growth
userIDToMutex map[string]*sync.Mutex
mu *sync.Mutex // protects UserIDToMutex
db DeviceListUpdaterDatabase
api DeviceListUpdaterAPI
producer KeyChangeProducer
fedClient fedsenderapi.KeyserverFederationAPI
workerChans []chan spec.ServerName
thisServer spec.ServerName
// When device lists are stale for a user, they get inserted into this map with a channel which `Update` will
// block on or timeout via a select.
userIDToChan map[string]chan bool
userIDToChanMu *sync.Mutex
rsAPI rsapi.KeyserverRoomserverAPI
}
// DeviceListUpdaterDatabase is the subset of functionality from storage.Database required for the updater.
// Useful for testing.
type DeviceListUpdaterDatabase interface {
// StaleDeviceLists returns a list of user IDs ending with the domains provided who have stale device lists.
// If no domains are given, all user IDs with stale device lists are returned.
StaleDeviceLists(ctx context.Context, domains []spec.ServerName) ([]string, error)
// MarkDeviceListStale sets the stale bit for this user to isStale.
MarkDeviceListStale(ctx context.Context, userID string, isStale bool) error
// StoreRemoteDeviceKeys persists the given keys. Keys with the same user ID and device ID will be replaced. An empty KeyJSON removes the key
// for this (user, device). Does not modify the stream ID for keys. User IDs in `clearUserIDs` will have all their device keys deleted prior
// to insertion - use this when you have a complete snapshot of a user's keys in order to track device deletions correctly.
StoreRemoteDeviceKeys(ctx context.Context, keys []api.DeviceMessage, clearUserIDs []string) error
// PrevIDsExists returns true if all prev IDs exist for this user.
PrevIDsExists(ctx context.Context, userID string, prevIDs []int64) (bool, error)
// DeviceKeysJSON populates the KeyJSON for the given keys. If any proided `keys` have a `KeyJSON` or `StreamID` already then it will be replaced.
DeviceKeysJSON(ctx context.Context, keys []api.DeviceMessage) error
DeleteStaleDeviceLists(ctx context.Context, userIDs []string) error
}
type DeviceListUpdaterAPI interface {
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PerformUploadDeviceKeys(ctx context.Context, req *api.PerformUploadDeviceKeysRequest, res *api.PerformUploadDeviceKeysResponse)
}
// KeyChangeProducer is the interface for producers.KeyChange useful for testing.
type KeyChangeProducer interface {
ProduceKeyChanges(keys []api.DeviceMessage) error
}
var deviceListUpdaterBackpressure = prometheus.NewGaugeVec(
prometheus.GaugeOpts{
Namespace: "dendrite",
Subsystem: "keyserver",
Name: "worker_backpressure",
Help: "How many device list updater requests are queued",
},
[]string{"worker_id"},
)
var deviceListUpdaterServersRetrying = prometheus.NewGaugeVec(
prometheus.GaugeOpts{
Namespace: "dendrite",
Subsystem: "keyserver",
Name: "worker_servers_retrying",
Help: "How many servers are queued for retry",
},
[]string{"worker_id"},
)
// NewDeviceListUpdater creates a new updater which fetches fresh device lists when they go stale.
func NewDeviceListUpdater(
process *process.ProcessContext, db DeviceListUpdaterDatabase,
api DeviceListUpdaterAPI, producer KeyChangeProducer,
fedClient fedsenderapi.KeyserverFederationAPI, numWorkers int,
rsAPI rsapi.KeyserverRoomserverAPI, thisServer spec.ServerName,
enableMetrics bool,
) *DeviceListUpdater {
if enableMetrics {
prometheus.MustRegister(deviceListUpdaterBackpressure, deviceListUpdaterServersRetrying)
}
return &DeviceListUpdater{
process: process,
userIDToMutex: make(map[string]*sync.Mutex),
mu: &sync.Mutex{},
db: db,
api: api,
producer: producer,
fedClient: fedClient,
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thisServer: thisServer,
workerChans: make([]chan spec.ServerName, numWorkers),
userIDToChan: make(map[string]chan bool),
userIDToChanMu: &sync.Mutex{},
rsAPI: rsAPI,
}
}
// Start the device list updater, which will try to refresh any stale device lists.
func (u *DeviceListUpdater) Start() error {
for i := 0; i < len(u.workerChans); i++ {
// Allocate a small buffer per channel.
// If the buffer limit is reached, backpressure will cause the processing of EDUs
// to stop (in this transaction) until key requests can be made.
ch := make(chan spec.ServerName, 10)
u.workerChans[i] = ch
go u.worker(ch, i)
}
staleLists, err := u.db.StaleDeviceLists(u.process.Context(), []spec.ServerName{})
if err != nil {
return err
}
newStaleLists := dedupeStaleLists(staleLists)
offset, step := time.Second*10, time.Second
if max := len(newStaleLists); max > 120 {
step = (time.Second * 120) / time.Duration(max)
}
for _, userID := range newStaleLists {
userID := userID // otherwise we are only sending the last entry
time.AfterFunc(offset, func() {
u.notifyWorkers(userID)
})
offset += step
}
return nil
}
// CleanUp removes stale device entries for users we don't share a room with anymore
func (u *DeviceListUpdater) CleanUp() error {
staleUsers, err := u.db.StaleDeviceLists(u.process.Context(), []spec.ServerName{})
if err != nil {
return err
}
res := rsapi.QueryLeftUsersResponse{}
if err = u.rsAPI.QueryLeftUsers(u.process.Context(), &rsapi.QueryLeftUsersRequest{StaleDeviceListUsers: staleUsers}, &res); err != nil {
return err
}
if len(res.LeftUsers) == 0 {
return nil
}
logrus.Debugf("Deleting %d stale device list entries", len(res.LeftUsers))
return u.db.DeleteStaleDeviceLists(u.process.Context(), res.LeftUsers)
}
func (u *DeviceListUpdater) mutex(userID string) *sync.Mutex {
u.mu.Lock()
defer u.mu.Unlock()
if u.userIDToMutex[userID] == nil {
u.userIDToMutex[userID] = &sync.Mutex{}
}
return u.userIDToMutex[userID]
}
// ManualUpdate invalidates the device list for the given user and fetches the latest and tracks it.
// Blocks until the device list is synced or the timeout is reached.
func (u *DeviceListUpdater) ManualUpdate(ctx context.Context, serverName spec.ServerName, userID string) error {
mu := u.mutex(userID)
mu.Lock()
err := u.db.MarkDeviceListStale(ctx, userID, true)
mu.Unlock()
if err != nil {
return fmt.Errorf("ManualUpdate: failed to mark device list for %s as stale: %w", userID, err)
}
u.notifyWorkers(userID)
return nil
}
// Update blocks until the update has been stored in the database. It blocks primarily for satisfying sytest,
// which assumes when /send 200 OKs that the device lists have been updated.
func (u *DeviceListUpdater) Update(ctx context.Context, event gomatrixserverlib.DeviceListUpdateEvent) error {
isDeviceListStale, err := u.update(ctx, event)
if err != nil {
return err
}
if isDeviceListStale {
// poke workers to handle stale device lists
u.notifyWorkers(event.UserID)
}
return nil
}
func (u *DeviceListUpdater) update(ctx context.Context, event gomatrixserverlib.DeviceListUpdateEvent) (bool, error) {
mu := u.mutex(event.UserID)
mu.Lock()
defer mu.Unlock()
// check if we have the prev IDs
exists, err := u.db.PrevIDsExists(ctx, event.UserID, event.PrevID)
if err != nil {
return false, fmt.Errorf("failed to check prev IDs exist for %s (%s): %w", event.UserID, event.DeviceID, err)
}
// if this is the first time we're hearing about this user, sync the device list manually.
if len(event.PrevID) == 0 {
exists = false
}
util.GetLogger(ctx).WithFields(logrus.Fields{
"prev_ids_exist": exists,
"user_id": event.UserID,
"device_id": event.DeviceID,
"stream_id": event.StreamID,
"prev_ids": event.PrevID,
"display_name": event.DeviceDisplayName,
"deleted": event.Deleted,
}).Trace("DeviceListUpdater.Update")
// if we haven't missed anything update the database and notify users
if exists || event.Deleted {
k := event.Keys
if event.Deleted {
k = nil
}
keys := []api.DeviceMessage{
{
Type: api.TypeDeviceKeyUpdate,
DeviceKeys: &api.DeviceKeys{
DeviceID: event.DeviceID,
DisplayName: event.DeviceDisplayName,
KeyJSON: k,
UserID: event.UserID,
},
StreamID: event.StreamID,
},
}
// DeviceKeysJSON will side-effect modify this, so it needs
// to be a copy, not sharing any pointers with the above.
deviceKeysCopy := *keys[0].DeviceKeys
deviceKeysCopy.KeyJSON = nil
existingKeys := []api.DeviceMessage{
{
Type: keys[0].Type,
DeviceKeys: &deviceKeysCopy,
StreamID: keys[0].StreamID,
},
}
// fetch what keys we had already and only emit changes
if err = u.db.DeviceKeysJSON(ctx, existingKeys); err != nil {
// non-fatal, log and continue
util.GetLogger(ctx).WithError(err).WithField("user_id", event.UserID).Errorf(
"failed to query device keys json for calculating diffs",
)
}
err = u.db.StoreRemoteDeviceKeys(ctx, keys, nil)
if err != nil {
return false, fmt.Errorf("failed to store remote device keys for %s (%s): %w", event.UserID, event.DeviceID, err)
}
if err = emitDeviceKeyChanges(u.producer, existingKeys, keys, false); err != nil {
return false, fmt.Errorf("failed to produce device key changes for %s (%s): %w", event.UserID, event.DeviceID, err)
}
return false, nil
}
err = u.db.MarkDeviceListStale(ctx, event.UserID, true)
if err != nil {
return false, fmt.Errorf("failed to mark device list for %s as stale: %w", event.UserID, err)
}
return true, nil
}
func (u *DeviceListUpdater) notifyWorkers(userID string) {
_, remoteServer, err := gomatrixserverlib.SplitID('@', userID)
if err != nil {
return
}
hash := fnv.New32a()
_, _ = hash.Write([]byte(remoteServer))
index := int(int64(hash.Sum32()) % int64(len(u.workerChans)))
ch := u.assignChannel(userID)
deviceListUpdaterBackpressure.With(prometheus.Labels{"worker_id": strconv.Itoa(index)}).Inc()
defer deviceListUpdaterBackpressure.With(prometheus.Labels{"worker_id": strconv.Itoa(index)}).Dec()
u.workerChans[index] <- remoteServer
select {
case <-ch:
case <-time.After(10 * time.Second):
// we don't return an error in this case as it's not a failure condition.
// we mainly block for the benefit of sytest anyway
}
}
func (u *DeviceListUpdater) assignChannel(userID string) chan bool {
u.userIDToChanMu.Lock()
defer u.userIDToChanMu.Unlock()
if ch, ok := u.userIDToChan[userID]; ok {
return ch
}
ch := make(chan bool)
u.userIDToChan[userID] = ch
return ch
}
func (u *DeviceListUpdater) clearChannel(userID string) {
u.userIDToChanMu.Lock()
defer u.userIDToChanMu.Unlock()
if ch, ok := u.userIDToChan[userID]; ok {
close(ch)
delete(u.userIDToChan, userID)
}
}
func (u *DeviceListUpdater) worker(ch chan spec.ServerName, workerID int) {
retries := make(map[spec.ServerName]time.Time)
retriesMu := &sync.Mutex{}
// restarter goroutine which will inject failed servers into ch when it is time
go func() {
var serversToRetry []spec.ServerName
for {
serversToRetry = serversToRetry[:0] // reuse memory
time.Sleep(time.Second)
retriesMu.Lock()
now := time.Now()
for srv, retryAt := range retries {
if now.After(retryAt) {
serversToRetry = append(serversToRetry, srv)
}
}
for _, srv := range serversToRetry {
delete(retries, srv)
}
deviceListUpdaterServersRetrying.With(prometheus.Labels{"worker_id": strconv.Itoa(workerID)}).Set(float64(len(retries)))
retriesMu.Unlock()
for _, srv := range serversToRetry {
deviceListUpdaterBackpressure.With(prometheus.Labels{"worker_id": strconv.Itoa(workerID)}).Inc()
ch <- srv
deviceListUpdaterBackpressure.With(prometheus.Labels{"worker_id": strconv.Itoa(workerID)}).Dec()
}
}
}()
for serverName := range ch {
retriesMu.Lock()
_, exists := retries[serverName]
retriesMu.Unlock()
if exists {
// Don't retry a server that we're already waiting for.
continue
}
waitTime, shouldRetry := u.processServer(serverName)
if shouldRetry {
retriesMu.Lock()
if _, exists = retries[serverName]; !exists {
retries[serverName] = time.Now().Add(waitTime)
}
retriesMu.Unlock()
}
}
}
func (u *DeviceListUpdater) processServer(serverName spec.ServerName) (time.Duration, bool) {
ctx := u.process.Context()
// If the process.Context is canceled, there is no need to go further.
// This avoids spamming the logs when shutting down
if errors.Is(ctx.Err(), context.Canceled) {
return defaultWaitTime, false
}
logger := util.GetLogger(ctx).WithField("server_name", serverName)
deviceListUpdateCount.WithLabelValues(string(serverName)).Inc()
waitTime := defaultWaitTime // How long should we wait to try again?
successCount := 0 // How many user requests failed?
userIDs, err := u.db.StaleDeviceLists(ctx, []spec.ServerName{serverName})
if err != nil {
logger.WithError(err).Error("Failed to load stale device lists")
return waitTime, true
}
for _, userID := range userIDs {
userWait, err := u.processServerUser(ctx, serverName, userID)
if err != nil {
if userWait > waitTime {
waitTime = userWait
}
break
}
successCount++
}
allUsersSucceeded := successCount == len(userIDs)
if !allUsersSucceeded {
logger.WithFields(logrus.Fields{
"total": len(userIDs),
"succeeded": successCount,
"failed": len(userIDs) - successCount,
"wait_time": waitTime,
}).Debug("Failed to query device keys for some users")
}
return waitTime, !allUsersSucceeded
}
func (u *DeviceListUpdater) processServerUser(ctx context.Context, serverName spec.ServerName, userID string) (time.Duration, error) {
ctx, cancel := context.WithTimeout(ctx, requestTimeout)
defer cancel()
// If we are processing more than one user per server, this unblocks further calls to Update
// immediately instead of just after **all** users have been processed.
defer u.clearChannel(userID)
logger := util.GetLogger(ctx).WithFields(logrus.Fields{
"server_name": serverName,
"user_id": userID,
})
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res, err := u.fedClient.GetUserDevices(ctx, u.thisServer, serverName, userID)
if err != nil {
if errors.Is(err, context.DeadlineExceeded) {
return time.Minute * 10, err
}
switch e := err.(type) {
case *json.UnmarshalTypeError, *json.SyntaxError:
logger.WithError(err).Debugf("Device list update for %q contained invalid JSON", userID)
return defaultWaitTime, nil
case *fedsenderapi.FederationClientError:
if e.RetryAfter > 0 {
return e.RetryAfter, err
} else if e.Blacklisted {
return time.Hour * 8, err
}
case net.Error:
// Use the default waitTime, if it's a timeout.
// It probably doesn't make sense to try further users.
if !e.Timeout() {
logger.WithError(e).Debug("GetUserDevices returned net.Error")
return time.Minute * 10, err
}
case gomatrix.HTTPError:
// The remote server returned an error, give it some time to recover.
// This is to avoid spamming remote servers, which may not be Matrix servers anymore.
if e.Code >= 300 {
logger.WithError(e).Debug("GetUserDevices returned gomatrix.HTTPError")
return hourWaitTime, err
}
default:
// Something else failed
logger.WithError(err).Debugf("GetUserDevices returned unknown error type: %T", err)
return time.Minute * 10, err
}
}
if res.UserID != userID {
logger.WithError(err).Debugf("User ID %q in device list update response doesn't match expected %q", res.UserID, userID)
return defaultWaitTime, nil
}
if res.MasterKey != nil || res.SelfSigningKey != nil {
uploadReq := &api.PerformUploadDeviceKeysRequest{
UserID: userID,
}
uploadRes := &api.PerformUploadDeviceKeysResponse{}
if res.MasterKey != nil {
if err = sanityCheckKey(*res.MasterKey, userID, fclient.CrossSigningKeyPurposeMaster); err == nil {
uploadReq.MasterKey = *res.MasterKey
}
}
if res.SelfSigningKey != nil {
if err = sanityCheckKey(*res.SelfSigningKey, userID, fclient.CrossSigningKeyPurposeSelfSigning); err == nil {
uploadReq.SelfSigningKey = *res.SelfSigningKey
}
}
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u.api.PerformUploadDeviceKeys(ctx, uploadReq, uploadRes)
}
err = u.updateDeviceList(&res)
if err != nil {
logger.WithError(err).Error("Fetched device list but failed to store/emit it")
return defaultWaitTime, err
}
return defaultWaitTime, nil
}
func (u *DeviceListUpdater) updateDeviceList(res *fclient.RespUserDevices) error {
ctx := context.Background() // we've got the keys, don't time out when persisting them to the database.
keys := make([]api.DeviceMessage, len(res.Devices))
existingKeys := make([]api.DeviceMessage, len(res.Devices))
for i, device := range res.Devices {
keyJSON, err := json.Marshal(device.Keys)
if err != nil {
util.GetLogger(ctx).WithField("keys", device.Keys).Error("failed to marshal keys, skipping device")
continue
}
keys[i] = api.DeviceMessage{
Type: api.TypeDeviceKeyUpdate,
StreamID: res.StreamID,
DeviceKeys: &api.DeviceKeys{
DeviceID: device.DeviceID,
DisplayName: device.DisplayName,
UserID: res.UserID,
KeyJSON: keyJSON,
},
}
existingKeys[i] = api.DeviceMessage{
Type: api.TypeDeviceKeyUpdate,
DeviceKeys: &api.DeviceKeys{
UserID: res.UserID,
DeviceID: device.DeviceID,
},
}
}
// fetch what keys we had already and only emit changes
if err := u.db.DeviceKeysJSON(ctx, existingKeys); err != nil {
// non-fatal, log and continue
util.GetLogger(ctx).WithError(err).WithField("user_id", res.UserID).Errorf(
"failed to query device keys json for calculating diffs",
)
}
err := u.db.StoreRemoteDeviceKeys(ctx, keys, []string{res.UserID})
if err != nil {
return fmt.Errorf("failed to store remote device keys: %w", err)
}
err = u.db.MarkDeviceListStale(ctx, res.UserID, false)
if err != nil {
return fmt.Errorf("failed to mark device list as fresh: %w", err)
}
err = emitDeviceKeyChanges(u.producer, existingKeys, keys, false)
if err != nil {
return fmt.Errorf("failed to emit key changes for fresh device list: %w", err)
}
return nil
}
// dedupeStaleLists de-duplicates the stateList entries using the domain.
// This is used on startup, processServer is getting all users anyway, so
// there is no need to send every user to the workers.
func dedupeStaleLists(staleLists []string) []string {
seenDomains := make(map[spec.ServerName]struct{})
newStaleLists := make([]string, 0, len(staleLists))
for _, userID := range staleLists {
_, domain, err := gomatrixserverlib.SplitID('@', userID)
if err != nil {
// non-fatal and should not block starting up
continue
}
if _, ok := seenDomains[domain]; ok {
continue
}
newStaleLists = append(newStaleLists, userID)
seenDomains[domain] = struct{}{}
}
return newStaleLists
}