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forgejo/vendor/github.com/caddyserver/certmagic/cache.go

364 lines
12 KiB
Go
Vendored

// Copyright 2015 Matthew Holt
//
// 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 certmagic
import (
"fmt"
weakrand "math/rand" // seeded elsewhere
"strings"
"sync"
"time"
"go.uber.org/zap"
)
// Cache is a structure that stores certificates in memory.
// A Cache indexes certificates by name for quick access
// during TLS handshakes, and avoids duplicating certificates
// in memory. Generally, there should only be one per process.
// However, that is not a strict requirement; but using more
// than one is a code smell, and may indicate an
// over-engineered design.
//
// An empty cache is INVALID and must not be used. Be sure
// to call NewCache to get a valid value.
//
// These should be very long-lived values and must not be
// copied. Before all references leave scope to be garbage
// collected, ensure you call Stop() to stop maintenance on
// the certificates stored in this cache and release locks.
//
// Caches are not usually manipulated directly; create a
// Config value with a pointer to a Cache, and then use
// the Config to interact with the cache. Caches are
// agnostic of any particular storage or ACME config,
// since each certificate may be managed and stored
// differently.
type Cache struct {
// User configuration of the cache
options CacheOptions
// The cache is keyed by certificate hash
cache map[string]Certificate
// cacheIndex is a map of SAN to cache key (cert hash)
cacheIndex map[string][]string
// Protects the cache and index maps
mu sync.RWMutex
// Close this channel to cancel asset maintenance
stopChan chan struct{}
// Used to signal when stopping is completed
doneChan chan struct{}
logger *zap.Logger
}
// NewCache returns a new, valid Cache for efficiently
// accessing certificates in memory. It also begins a
// maintenance goroutine to tend to the certificates
// in the cache. Call Stop() when you are done with the
// cache so it can clean up locks and stuff.
//
// Most users of this package will not need to call this
// because a default certificate cache is created for you.
// Only advanced use cases require creating a new cache.
//
// This function panics if opts.GetConfigForCert is not
// set. The reason is that a cache absolutely needs to
// be able to get a Config with which to manage TLS
// assets, and it is not safe to assume that the Default
// config is always the correct one, since you have
// created the cache yourself.
//
// See the godoc for Cache to use it properly. When
// no longer needed, caches should be stopped with
// Stop() to clean up resources even if the process
// is being terminated, so that it can clean up
// any locks for other processes to unblock!
func NewCache(opts CacheOptions) *Cache {
// assume default options if necessary
if opts.OCSPCheckInterval <= 0 {
opts.OCSPCheckInterval = DefaultOCSPCheckInterval
}
if opts.RenewCheckInterval <= 0 {
opts.RenewCheckInterval = DefaultRenewCheckInterval
}
if opts.Capacity < 0 {
opts.Capacity = 0
}
// this must be set, because we cannot not
// safely assume that the Default Config
// is always the correct one to use
if opts.GetConfigForCert == nil {
panic("cache must be initialized with a GetConfigForCert callback")
}
c := &Cache{
options: opts,
cache: make(map[string]Certificate),
cacheIndex: make(map[string][]string),
stopChan: make(chan struct{}),
doneChan: make(chan struct{}),
logger: opts.Logger,
}
go c.maintainAssets(0)
return c
}
// Stop stops the maintenance goroutine for
// certificates in certCache. It blocks until
// stopping is complete. Once a cache is
// stopped, it cannot be reused.
func (certCache *Cache) Stop() {
close(certCache.stopChan) // signal to stop
<-certCache.doneChan // wait for stop to complete
}
// CacheOptions is used to configure certificate caches.
// Once a cache has been created with certain options,
// those settings cannot be changed.
type CacheOptions struct {
// REQUIRED. A function that returns a configuration
// used for managing a certificate, or for accessing
// that certificate's asset storage (e.g. for
// OCSP staples, etc). The returned Config MUST
// be associated with the same Cache as the caller.
//
// The reason this is a callback function, dynamically
// returning a Config (instead of attaching a static
// pointer to a Config on each certificate) is because
// the config for how to manage a domain's certificate
// might change from maintenance to maintenance. The
// cache is so long-lived, we cannot assume that the
// host's situation will always be the same; e.g. the
// certificate might switch DNS providers, so the DNS
// challenge (if used) would need to be adjusted from
// the last time it was run ~8 weeks ago.
GetConfigForCert ConfigGetter
// How often to check certificates for renewal;
// if unset, DefaultOCSPCheckInterval will be used.
OCSPCheckInterval time.Duration
// How often to check certificates for renewal;
// if unset, DefaultRenewCheckInterval will be used.
RenewCheckInterval time.Duration
// Maximum number of certificates to allow in the cache.
// If reached, certificates will be randomly evicted to
// make room for new ones. 0 means unlimited.
Capacity int
// Set a logger to enable logging
Logger *zap.Logger
}
// ConfigGetter is a function that returns a prepared,
// valid config that should be used when managing the
// given certificate or its assets.
type ConfigGetter func(Certificate) (*Config, error)
// cacheCertificate calls unsyncedCacheCertificate with a write lock.
//
// This function is safe for concurrent use.
func (certCache *Cache) cacheCertificate(cert Certificate) {
certCache.mu.Lock()
certCache.unsyncedCacheCertificate(cert)
certCache.mu.Unlock()
}
// unsyncedCacheCertificate adds cert to the in-memory cache unless
// it already exists in the cache (according to cert.Hash). It
// updates the name index.
//
// This function is NOT safe for concurrent use. Callers MUST acquire
// a write lock on certCache.mu first.
func (certCache *Cache) unsyncedCacheCertificate(cert Certificate) {
// no-op if this certificate already exists in the cache
if _, ok := certCache.cache[cert.hash]; ok {
if certCache.logger != nil {
certCache.logger.Debug("certificate already cached",
zap.Strings("subjects", cert.Names),
zap.Time("expiration", cert.Leaf.NotAfter),
zap.Bool("managed", cert.managed),
zap.String("issuer_key", cert.issuerKey),
zap.String("hash", cert.hash))
}
return
}
// if the cache is at capacity, make room for new cert
cacheSize := len(certCache.cache)
if certCache.options.Capacity > 0 && cacheSize >= certCache.options.Capacity {
// Go maps are "nondeterministic" but not actually random,
// so although we could just chop off the "front" of the
// map with less code, that is a heavily skewed eviction
// strategy; generating random numbers is cheap and
// ensures a much better distribution.
rnd := weakrand.Intn(cacheSize)
i := 0
for _, randomCert := range certCache.cache {
if i == rnd {
if certCache.logger != nil {
certCache.logger.Debug("cache full; evicting random certificate",
zap.Strings("removing_subjects", randomCert.Names),
zap.String("removing_hash", randomCert.hash),
zap.Strings("inserting_subjects", cert.Names),
zap.String("inserting_hash", cert.hash))
}
certCache.removeCertificate(randomCert)
break
}
i++
}
}
// store the certificate
certCache.cache[cert.hash] = cert
// update the index so we can access it by name
for _, name := range cert.Names {
certCache.cacheIndex[name] = append(certCache.cacheIndex[name], cert.hash)
}
if certCache.logger != nil {
certCache.logger.Debug("added certificate to cache",
zap.Strings("subjects", cert.Names),
zap.Time("expiration", cert.Leaf.NotAfter),
zap.Bool("managed", cert.managed),
zap.String("issuer_key", cert.issuerKey),
zap.String("hash", cert.hash),
zap.Int("cache_size", len(certCache.cache)),
zap.Int("cache_capacity", certCache.options.Capacity))
}
}
// removeCertificate removes cert from the cache.
//
// This function is NOT safe for concurrent use; callers
// MUST first acquire a write lock on certCache.mu.
func (certCache *Cache) removeCertificate(cert Certificate) {
// delete all mentions of this cert from the name index
for _, name := range cert.Names {
keyList := certCache.cacheIndex[name]
for i := 0; i < len(keyList); i++ {
if keyList[i] == cert.hash {
keyList = append(keyList[:i], keyList[i+1:]...)
i--
}
}
if len(keyList) == 0 {
delete(certCache.cacheIndex, name)
} else {
certCache.cacheIndex[name] = keyList
}
}
// delete the actual cert from the cache
delete(certCache.cache, cert.hash)
if certCache.logger != nil {
certCache.logger.Debug("removed certificate from cache",
zap.Strings("subjects", cert.Names),
zap.Time("expiration", cert.Leaf.NotAfter),
zap.Bool("managed", cert.managed),
zap.String("issuer_key", cert.issuerKey),
zap.String("hash", cert.hash),
zap.Int("cache_size", len(certCache.cache)),
zap.Int("cache_capacity", certCache.options.Capacity))
}
}
// replaceCertificate atomically replaces oldCert with newCert in
// the cache.
//
// This method is safe for concurrent use.
func (certCache *Cache) replaceCertificate(oldCert, newCert Certificate) {
certCache.mu.Lock()
certCache.removeCertificate(oldCert)
certCache.unsyncedCacheCertificate(newCert)
certCache.mu.Unlock()
if certCache.logger != nil {
certCache.logger.Info("replaced certificate in cache",
zap.Strings("subjects", newCert.Names),
zap.Time("new_expiration", newCert.Leaf.NotAfter))
}
}
func (certCache *Cache) getAllMatchingCerts(name string) []Certificate {
certCache.mu.RLock()
defer certCache.mu.RUnlock()
allCertKeys := certCache.cacheIndex[name]
certs := make([]Certificate, len(allCertKeys))
for i := range allCertKeys {
certs[i] = certCache.cache[allCertKeys[i]]
}
return certs
}
func (certCache *Cache) getAllCerts() []Certificate {
certCache.mu.RLock()
defer certCache.mu.RUnlock()
certs := make([]Certificate, 0, len(certCache.cache))
for _, cert := range certCache.cache {
certs = append(certs, cert)
}
return certs
}
func (certCache *Cache) getConfig(cert Certificate) (*Config, error) {
cfg, err := certCache.options.GetConfigForCert(cert)
if err != nil {
return nil, err
}
if cfg.certCache != nil && cfg.certCache != certCache {
return nil, fmt.Errorf("config returned for certificate %v is not nil and points to different cache; got %p, expected %p (this one)",
cert.Names, cfg.certCache, certCache)
}
return cfg, nil
}
// AllMatchingCertificates returns a list of all certificates that could
// be used to serve the given SNI name, including exact SAN matches and
// wildcard matches.
func (certCache *Cache) AllMatchingCertificates(name string) []Certificate {
// get exact matches first
certs := certCache.getAllMatchingCerts(name)
// then look for wildcard matches by replacing each
// label of the domain name with wildcards
labels := strings.Split(name, ".")
for i := range labels {
labels[i] = "*"
candidate := strings.Join(labels, ".")
certs = append(certs, certCache.getAllMatchingCerts(candidate)...)
}
return certs
}
var (
defaultCache *Cache
defaultCacheMu sync.Mutex
)