mirror of https://github.com/hashicorp/consul
557 lines
17 KiB
Go
557 lines
17 KiB
Go
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package leafcert
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import (
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"context"
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"errors"
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"fmt"
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"sync"
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"time"
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"github.com/armon/go-metrics"
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"github.com/hashicorp/go-hclog"
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"golang.org/x/sync/singleflight"
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"golang.org/x/time/rate"
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"github.com/hashicorp/consul/agent/cache"
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"github.com/hashicorp/consul/agent/structs"
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"github.com/hashicorp/consul/lib/ttlcache"
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)
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const (
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DefaultLastGetTTL = 72 * time.Hour // reasonable default is days
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// DefaultLeafCertRefreshRate is the default rate at which certs can be refreshed.
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// This defaults to not being limited
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DefaultLeafCertRefreshRate = rate.Inf
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// DefaultLeafCertRefreshMaxBurst is the number of cache entry fetches that can
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// occur in a burst.
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DefaultLeafCertRefreshMaxBurst = 2
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DefaultLeafCertRefreshBackoffMin = 3 // 3 attempts before backing off
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DefaultLeafCertRefreshMaxWait = 1 * time.Minute // maximum backoff wait time
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DefaultQueryTimeout = 10 * time.Minute
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)
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type Config struct {
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// LastGetTTL is the time that the certs returned by this type remain in
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// the cache after the last get operation. If a cert isn't accessed within
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// this duration, the certs is purged and background refreshing will cease.
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LastGetTTL time.Duration
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// LeafCertRefreshMaxBurst max burst size of RateLimit for a single cache entry
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LeafCertRefreshMaxBurst int
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// LeafCertRefreshRate represents the max calls/sec for a single cache entry
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LeafCertRefreshRate rate.Limit
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// LeafCertRefreshBackoffMin is the number of attempts to wait before
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// backing off.
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//
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// Mostly configurable just for testing.
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LeafCertRefreshBackoffMin uint
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// LeafCertRefreshMaxWait is the maximum backoff wait time.
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//
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// Mostly configurable just for testing.
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LeafCertRefreshMaxWait time.Duration
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// TestOverrideCAChangeInitialDelay allows overriding the random jitter
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// after a root change with a fixed delay. So far ths is only done in
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// tests. If it's zero the caChangeInitialSpreadDefault maximum jitter will
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// be used but if set, it overrides and provides a fixed delay. To
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// essentially disable the delay in tests they can set it to 1 nanosecond.
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// We may separately allow configuring the jitter limit by users later but
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// this is different and for tests only since we need to set a
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// deterministic time delay in order to test the behavior here fully and
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// determinstically.
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TestOverrideCAChangeInitialDelay time.Duration
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}
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func (c Config) withDefaults() Config {
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if c.LastGetTTL <= 0 {
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c.LastGetTTL = DefaultLastGetTTL
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}
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if c.LeafCertRefreshRate == 0.0 {
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c.LeafCertRefreshRate = DefaultLeafCertRefreshRate
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}
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if c.LeafCertRefreshMaxBurst == 0 {
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c.LeafCertRefreshMaxBurst = DefaultLeafCertRefreshMaxBurst
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}
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if c.LeafCertRefreshBackoffMin == 0 {
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c.LeafCertRefreshBackoffMin = DefaultLeafCertRefreshBackoffMin
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}
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if c.LeafCertRefreshMaxWait == 0 {
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c.LeafCertRefreshMaxWait = DefaultLeafCertRefreshMaxWait
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}
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return c
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}
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type Deps struct {
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Config Config
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Logger hclog.Logger
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// RootsReader is an interface to access connect CA roots.
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RootsReader RootsReader
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// CertSigner is an interface to remotely sign certificates.
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CertSigner CertSigner
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}
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type RootsReader interface {
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Get() (*structs.IndexedCARoots, error)
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Notify(ctx context.Context, correlationID string, ch chan<- cache.UpdateEvent) error
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}
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type CertSigner interface {
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SignCert(ctx context.Context, args *structs.CASignRequest) (*structs.IssuedCert, error)
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}
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func NewManager(deps Deps) *Manager {
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deps.Config = deps.Config.withDefaults()
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if deps.Logger == nil {
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deps.Logger = hclog.NewNullLogger()
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}
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if deps.RootsReader == nil {
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panic("RootsReader is required")
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}
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if deps.CertSigner == nil {
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panic("CertSigner is required")
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}
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m := &Manager{
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config: deps.Config,
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logger: deps.Logger,
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certSigner: deps.CertSigner,
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rootsReader: deps.RootsReader,
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//
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certs: make(map[string]*certData),
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certsExpiryHeap: ttlcache.NewExpiryHeap(),
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}
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m.ctx, m.ctxCancel = context.WithCancel(context.Background())
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m.rootWatcher = &rootWatcher{
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ctx: m.ctx,
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rootsReader: m.rootsReader,
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}
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// Start the expiry watcher
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go m.runExpiryLoop()
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return m
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}
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type Manager struct {
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logger hclog.Logger
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// config contains agent configuration necessary for the cert manager to operate.
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config Config
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// rootsReader is an interface to access connect CA roots.
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rootsReader RootsReader
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// certSigner is an interface to remotely sign certificates.
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certSigner CertSigner
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// rootWatcher helps let multiple requests for leaf certs to coordinate
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// sharing a single long-lived watch for the root certs. This allows the
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// leaf cert requests to notice when the roots rotate and trigger their
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// reissuance.
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rootWatcher *rootWatcher
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// This is the "top-level" internal context. This is used to cancel
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// background operations.
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ctx context.Context
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ctxCancel context.CancelFunc
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// lock guards access to certs and certsExpiryHeap
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lock sync.RWMutex
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certs map[string]*certData
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certsExpiryHeap *ttlcache.ExpiryHeap
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// certGroup is a singleflight group keyed identically to the certs map.
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// When the leaf cert itself needs replacement requests will coalesce
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// together through this chokepoint.
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certGroup singleflight.Group
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}
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func (m *Manager) getCertData(key string) *certData {
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m.lock.RLock()
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cd, ok := m.certs[key]
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m.lock.RUnlock()
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if ok {
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return cd
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}
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m.lock.Lock()
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defer m.lock.Unlock()
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cd, ok = m.certs[key]
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if !ok {
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cd = &certData{
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expiry: m.certsExpiryHeap.Add(key, m.config.LastGetTTL),
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refreshRateLimiter: rate.NewLimiter(
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m.config.LeafCertRefreshRate,
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m.config.LeafCertRefreshMaxBurst,
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),
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}
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m.certs[key] = cd
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metrics.SetGauge([]string{"leaf-certs", "entries_count"}, float32(len(m.certs)))
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}
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return cd
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}
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// Stop stops any background work and frees all resources for the manager.
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// Current fetch requests are allowed to continue to completion and callers may
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// still access the current leaf cert values so coordination isn't needed with
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// callers, however no background activity will continue. It's intended to
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// close the manager at agent shutdown so no further requests should be made,
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// however concurrent or in-flight ones won't break.
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func (m *Manager) Stop() {
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if m.ctxCancel != nil {
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m.ctxCancel()
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m.ctxCancel = nil
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}
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}
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// Get returns the leaf cert for the request. If data satisfying the
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// minimum index is present, it is returned immediately. Otherwise,
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// this will block until the cert is refreshed or the request timeout is
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// reached.
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//
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// Multiple Get calls for the same logical request will block on a single
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// network request.
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//
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// The timeout specified by the request will be the timeout on the cache
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// Get, and does not correspond to the timeout of any background data
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// fetching. If the timeout is reached before data satisfying the minimum
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// index is retrieved, the last known value (maybe nil) is returned. No
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// error is returned on timeout. This matches the behavior of Consul blocking
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// queries.
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func (m *Manager) Get(ctx context.Context, req *ConnectCALeafRequest) (*structs.IssuedCert, cache.ResultMeta, error) {
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// Lightweight copy this object so that manipulating req doesn't race.
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dup := *req
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req = &dup
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// We don't want non-blocking queries to return expired leaf certs
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// or leaf certs not valid under the current CA. So always revalidate
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// the leaf cert on non-blocking queries (ie when MinQueryIndex == 0)
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//
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// NOTE: This conditional was formerly only in the API endpoint.
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if req.MinQueryIndex == 0 {
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req.MustRevalidate = true
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}
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return m.internalGet(ctx, req)
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}
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func (m *Manager) internalGet(ctx context.Context, req *ConnectCALeafRequest) (*structs.IssuedCert, cache.ResultMeta, error) {
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key := req.Key()
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if key == "" {
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return nil, cache.ResultMeta{}, fmt.Errorf("a key is required")
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}
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if req.MaxQueryTime <= 0 {
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req.MaxQueryTime = DefaultQueryTimeout
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}
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timeoutTimer := time.NewTimer(req.MaxQueryTime)
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defer timeoutTimer.Stop()
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// First time through
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first := true
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for {
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// Get the current value
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cd := m.getCertData(key)
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cd.lock.Lock()
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var (
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existing = cd.value
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existingIndex = cd.index
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refreshing = cd.refreshing
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fetchedAt = cd.fetchedAt
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lastFetchErr = cd.lastFetchErr
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expiry = cd.expiry
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)
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cd.lock.Unlock()
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shouldReplaceCert := certNeedsUpdate(req, existingIndex, existing, refreshing)
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if expiry != nil {
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// The entry already exists in the TTL heap, touch it to keep it alive since
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// this Get is still interested in the value. Note that we used to only do
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// this in the `entryValid` block below but that means that a cache entry
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// will expire after it's TTL regardless of how many callers are waiting for
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// updates in this method in a couple of cases:
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//
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// 1. If the agent is disconnected from servers for the TTL then the client
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// will be in backoff getting errors on each call to Get and since an
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// errored cache entry has Valid = false it won't be touching the TTL.
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//
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// 2. If the value is just not changing then the client's current index
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// will be equal to the entry index and entryValid will be false. This
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// is a common case!
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//
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// But regardless of the state of the entry, assuming it's already in the
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// TTL heap, we should touch it every time around here since this caller at
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// least still cares about the value!
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m.lock.Lock()
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m.certsExpiryHeap.Update(expiry.Index(), m.config.LastGetTTL)
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m.lock.Unlock()
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}
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if !shouldReplaceCert {
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meta := cache.ResultMeta{
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Index: existingIndex,
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}
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if first {
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meta.Hit = true
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}
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// For non-background refresh types, the age is just how long since we
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// fetched it last.
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if !fetchedAt.IsZero() {
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meta.Age = time.Since(fetchedAt)
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}
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// We purposely do not return an error here since the cache only works with
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// fetching values that either have a value or have an error, but not both.
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// The Error may be non-nil in the entry in the case that an error has
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// occurred _since_ the last good value, but we still want to return the
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// good value to clients that are not requesting a specific version. The
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// effect of this is that blocking clients will all see an error immediately
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// without waiting a whole timeout to see it, but clients that just look up
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// cache with an older index than the last valid result will still see the
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// result and not the error here. I.e. the error is not "cached" without a
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// new fetch attempt occurring, but the last good value can still be fetched
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// from cache.
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return existing, meta, nil
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}
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// If this isn't our first time through and our last value has an error, then
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// we return the error. This has the behavior that we don't sit in a retry
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// loop getting the same error for the entire duration of the timeout.
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// Instead, we make one effort to fetch a new value, and if there was an
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// error, we return. Note that the invariant is that if both entry.Value AND
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// entry.Error are non-nil, the error _must_ be more recent than the Value. In
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// other words valid fetches should reset the error. See
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// https://github.com/hashicorp/consul/issues/4480.
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if !first && lastFetchErr != nil {
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return existing, cache.ResultMeta{Index: existingIndex}, lastFetchErr
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}
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notifyCh := m.triggerCertRefreshInGroup(req, cd)
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// No longer our first time through
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first = false
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select {
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case <-ctx.Done():
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return nil, cache.ResultMeta{}, ctx.Err()
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case <-notifyCh:
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// Our fetch returned, retry the get from the cache.
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req.MustRevalidate = false
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case <-timeoutTimer.C:
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// Timeout on the cache read, just return whatever we have.
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return existing, cache.ResultMeta{Index: existingIndex}, nil
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}
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}
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}
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func certNeedsUpdate(req *ConnectCALeafRequest, index uint64, value *structs.IssuedCert, refreshing bool) bool {
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if value == nil {
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return true
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}
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if req.MinQueryIndex > 0 && req.MinQueryIndex >= index {
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// MinIndex was given and matches or is higher than current value so we
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// ignore the cache and fallthrough to blocking on a new value.
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return true
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}
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// Check if re-validate is requested. If so the first time round the
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// loop is not a hit but subsequent ones should be treated normally.
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if req.MustRevalidate {
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// It is important to note that this block ONLY applies when we are not
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// in indefinite refresh mode (where the underlying goroutine will
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// continue to re-query for data).
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//
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// In this mode goroutines have a 1:1 relationship to RPCs that get
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// executed, and importantly they DO NOT SLEEP after executing.
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//
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// This means that a running goroutine for this cache entry extremely
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// strongly implies that the RPC has not yet completed, which is why
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// this check works for the revalidation-avoidance optimization here.
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if refreshing {
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// There is an active goroutine performing a blocking query for
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// this data, which has not returned.
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//
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// We can logically deduce that the contents of the cache are
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// actually current, and we can simply return this while leaving
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// the blocking query alone.
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return false
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} else {
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return true
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}
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}
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return false
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}
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func (m *Manager) triggerCertRefreshInGroup(req *ConnectCALeafRequest, cd *certData) <-chan singleflight.Result {
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// Lightweight copy this object so that manipulating req doesn't race.
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dup := *req
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req = &dup
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if req.MaxQueryTime == 0 {
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req.MaxQueryTime = DefaultQueryTimeout
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}
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// At this point, we know we either don't have a cert at all or the
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// cert we have is too old. We need to mint a new one.
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//
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// We use a singleflight group to coordinate only one request driving
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// the async update to the key at once.
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//
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// NOTE: this anonymous function only has one goroutine in it per key at all times
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return m.certGroup.DoChan(req.Key(), func() (any, error) {
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cd.lock.Lock()
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var (
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shouldReplaceCert = certNeedsUpdate(req, cd.index, cd.value, cd.refreshing)
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rateLimiter = cd.refreshRateLimiter
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lastIndex = cd.index
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)
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cd.lock.Unlock()
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if !shouldReplaceCert {
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// This handles the case where a fetch succeeded after checking for
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// its existence in Get. This ensures that we don't miss updates
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||
|
// since we don't hold the lock between the read and then the
|
||
|
// refresh trigger.
|
||
|
return nil, nil
|
||
|
}
|
||
|
|
||
|
if err := rateLimiter.Wait(m.ctx); err != nil {
|
||
|
// NOTE: this can only happen when the entire cache is being
|
||
|
// shutdown and isn't something that can happen normally.
|
||
|
return nil, nil
|
||
|
}
|
||
|
|
||
|
cd.MarkRefreshing(true)
|
||
|
defer cd.MarkRefreshing(false)
|
||
|
|
||
|
req.MinQueryIndex = lastIndex
|
||
|
|
||
|
// Start building the new entry by blocking on the fetch.
|
||
|
m.refreshLeafAndUpdate(req, cd)
|
||
|
|
||
|
return nil, nil
|
||
|
})
|
||
|
}
|
||
|
|
||
|
// testGet is a way for the test code to do a get but from the middle of the
|
||
|
// logic stack, skipping some of the caching logic.
|
||
|
func (m *Manager) testGet(req *ConnectCALeafRequest) (uint64, *structs.IssuedCert, error) {
|
||
|
cd := m.getCertData(req.Key())
|
||
|
|
||
|
m.refreshLeafAndUpdate(req, cd)
|
||
|
|
||
|
cd.lock.Lock()
|
||
|
var (
|
||
|
index = cd.index
|
||
|
cert = cd.value
|
||
|
err = cd.lastFetchErr
|
||
|
)
|
||
|
cd.lock.Unlock()
|
||
|
|
||
|
if err != nil {
|
||
|
return 0, nil, err
|
||
|
}
|
||
|
|
||
|
return index, cert, nil
|
||
|
}
|
||
|
|
||
|
// refreshLeafAndUpdate will try to refresh the leaf and persist the updated
|
||
|
// data back to the in-memory store.
|
||
|
//
|
||
|
// NOTE: this function only has one goroutine in it per key at all times
|
||
|
func (m *Manager) refreshLeafAndUpdate(req *ConnectCALeafRequest, cd *certData) {
|
||
|
existing, state := cd.GetValueAndState()
|
||
|
newCert, updatedState, err := m.attemptLeafRefresh(req, existing, state)
|
||
|
cd.Update(newCert, updatedState, err)
|
||
|
}
|
||
|
|
||
|
// Prepopulate puts a cert in manually. This is useful when the correct initial
|
||
|
// value is known and the cache shouldn't refetch the same thing on startup. It
|
||
|
// is used to set AgentLeafCert when AutoEncrypt.TLS is turned on. The manager
|
||
|
// itself cannot fetch that the first time because it requires a special
|
||
|
// RPCType. Subsequent runs are fine though.
|
||
|
func (m *Manager) Prepopulate(
|
||
|
ctx context.Context,
|
||
|
key string,
|
||
|
index uint64,
|
||
|
value *structs.IssuedCert,
|
||
|
authorityKeyID string,
|
||
|
) error {
|
||
|
if value == nil {
|
||
|
return errors.New("value is required")
|
||
|
}
|
||
|
cd := m.getCertData(key)
|
||
|
|
||
|
cd.lock.Lock()
|
||
|
defer cd.lock.Unlock()
|
||
|
|
||
|
cd.index = index
|
||
|
cd.value = value
|
||
|
cd.state = fetchState{
|
||
|
authorityKeyID: authorityKeyID,
|
||
|
forceExpireAfter: time.Time{},
|
||
|
consecutiveRateLimitErrs: 0,
|
||
|
activeRootRotationStart: time.Time{},
|
||
|
}
|
||
|
|
||
|
return nil
|
||
|
}
|
||
|
|
||
|
// runExpiryLoop is a blocking function that watches the expiration
|
||
|
// heap and invalidates cert entries that have expired.
|
||
|
func (m *Manager) runExpiryLoop() {
|
||
|
for {
|
||
|
m.lock.RLock()
|
||
|
timer := m.certsExpiryHeap.Next()
|
||
|
m.lock.RUnlock()
|
||
|
|
||
|
select {
|
||
|
case <-m.ctx.Done():
|
||
|
timer.Stop()
|
||
|
return
|
||
|
case <-m.certsExpiryHeap.NotifyCh:
|
||
|
timer.Stop()
|
||
|
continue
|
||
|
|
||
|
case <-timer.Wait():
|
||
|
m.lock.Lock()
|
||
|
|
||
|
entry := timer.Entry
|
||
|
|
||
|
// Entry expired! Remove it.
|
||
|
delete(m.certs, entry.Key())
|
||
|
m.certsExpiryHeap.Remove(entry.Index())
|
||
|
|
||
|
// Set some metrics
|
||
|
metrics.IncrCounter([]string{"leaf-certs", "evict_expired"}, 1)
|
||
|
metrics.SetGauge([]string{"leaf-certs", "entries_count"}, float32(len(m.certs)))
|
||
|
|
||
|
m.lock.Unlock()
|
||
|
}
|
||
|
}
|
||
|
}
|