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consul/agent/leafcert/generate.go

363 lines
14 KiB

package leafcert
import (
"context"
"errors"
"fmt"
"net"
"time"
"github.com/hashicorp/consul/agent/connect"
"github.com/hashicorp/consul/agent/consul"
"github.com/hashicorp/consul/agent/structs"
"github.com/hashicorp/consul/lib"
)
// caChangeJitterWindow is the time over which we spread each round of retries
// when attempting to get a new certificate following a root rotation. It's
// selected to be a trade-off between not making rotation unnecessarily slow on
// a tiny cluster while not hammering the servers on a huge cluster
// unnecessarily hard. Servers rate limit to protect themselves from the
// expensive crypto work, but in practice have 10k+ RPCs all in the same second
// will cause a major disruption even on large servers due to downloading the
// payloads, parsing msgpack etc. Instead we pick a window that for now is fixed
// but later might be either user configurable (not nice since it would become
// another hard-to-tune value) or set dynamically by the server based on it's
// knowledge of how many certs need to be rotated. Currently the server doesn't
// know that so we pick something that is reasonable. We err on the side of
// being slower that we need in trivial cases but gentler for large deployments.
// 30s means that even with a cluster of 10k service instances, the server only
// has to cope with ~333 RPCs a second which shouldn't be too bad if it's rate
// limiting the actual expensive crypto work.
//
// The actual backoff strategy when we are rate limited is to have each cert
// only retry once with each window of this size, at a point in the window
// selected at random. This performs much better than exponential backoff in
// terms of getting things rotated quickly with more predictable load and so
// fewer rate limited requests. See the full simulation this is based on at
// https://github.com/banks/sim-rate-limit-backoff/blob/master/README.md for
// more detail.
const caChangeJitterWindow = 30 * time.Second
// NOTE: this function only has one goroutine in it per key at all times
func (m *Manager) attemptLeafRefresh(
req *ConnectCALeafRequest,
existing *structs.IssuedCert,
state fetchState,
) (*structs.IssuedCert, fetchState, error) {
if req.MaxQueryTime <= 0 {
req.MaxQueryTime = DefaultQueryTimeout
}
// Handle brand new request first as it's simplest.
if existing == nil {
return m.generateNewLeaf(req, state, true)
}
// We have a certificate in cache already. Check it's still valid.
now := time.Now()
minExpire, maxExpire := calculateSoftExpiry(now, existing)
expiresAt := minExpire.Add(lib.RandomStagger(maxExpire.Sub(minExpire)))
// Check if we have been force-expired by a root update that jittered beyond
// the timeout of the query it was running.
if !state.forceExpireAfter.IsZero() && state.forceExpireAfter.Before(expiresAt) {
expiresAt = state.forceExpireAfter
}
if expiresAt.Equal(now) || expiresAt.Before(now) {
// Already expired, just make a new one right away
return m.generateNewLeaf(req, state, false)
}
// If we called Get() with MustRevalidate then this call came from a non-blocking query.
// Any prior CA rotations should've already expired the cert.
// All we need to do is check whether the current CA is the one that signed the leaf. If not, generate a new leaf.
// This is not a perfect solution (as a CA rotation update can be missed) but it should take care of instances like
// see https://github.com/hashicorp/consul/issues/10871, https://github.com/hashicorp/consul/issues/9862
// This seems to me like a hack, so maybe we can revisit the caching/ fetching logic in this case
if req.MustRevalidate {
roots, err := m.rootsReader.Get()
if err != nil {
return nil, state, err
} else if roots == nil {
return nil, state, errors.New("no CA roots")
}
if activeRootHasKey(roots, state.authorityKeyID) {
return nil, state, nil
}
// if we reach here then the current leaf was not signed by the same CAs, just regen
return m.generateNewLeaf(req, state, false)
}
// We are about to block and wait for a change or timeout.
// Make a chan we can be notified of changes to CA roots on. It must be
// buffered so we don't miss broadcasts from rootsWatch. It is an edge trigger
// so a single buffer element is sufficient regardless of whether we consume
// the updates fast enough since as soon as we see an element in it, we will
// reload latest CA from cache.
rootUpdateCh := make(chan struct{}, 1)
// The roots may have changed in between blocking calls. We need to verify
// that the existing cert was signed by the current root. If it was we still
// want to do the whole jitter thing. We could code that again here but it's
// identical to the select case below so we just trigger our own update chan
// and let the logic below handle checking if the CA actually changed in the
// common case where it didn't it is a no-op anyway.
rootUpdateCh <- struct{}{}
// Subscribe our chan to get root update notification.
m.rootWatcher.Subscribe(rootUpdateCh)
defer m.rootWatcher.Unsubscribe(rootUpdateCh)
// Setup the timeout chan outside the loop so we don't keep bumping the timeout
// later if we loop around.
timeoutTimer := time.NewTimer(req.MaxQueryTime)
defer timeoutTimer.Stop()
// Setup initial expiry chan. We may change this if root update occurs in the
// loop below.
expiresTimer := time.NewTimer(expiresAt.Sub(now))
defer func() {
// Resolve the timer reference at defer time, so we use the latest one each time.
expiresTimer.Stop()
}()
// Current cert is valid so just wait until it expires or we time out.
for {
select {
case <-timeoutTimer.C:
// We timed out the request with same cert.
return nil, state, nil
case <-expiresTimer.C:
// Cert expired or was force-expired by a root change.
return m.generateNewLeaf(req, state, false)
case <-rootUpdateCh:
// A root cache change occurred, reload roots from cache.
roots, err := m.rootsReader.Get()
if err != nil {
return nil, state, err
} else if roots == nil {
return nil, state, errors.New("no CA roots")
}
// Handle _possibly_ changed roots. We still need to verify the new active
// root is not the same as the one our current cert was signed by since we
// can be notified spuriously if we are the first request since the
// rootsWatcher didn't know about the CA we were signed by. We also rely
// on this on every request to do the initial check that the current roots
// are the same ones the current cert was signed by.
if activeRootHasKey(roots, state.authorityKeyID) {
// Current active CA is the same one that signed our current cert so
// keep waiting for a change.
continue
}
state.activeRootRotationStart = time.Now()
// CA root changed. We add some jitter here to avoid a thundering herd.
// See docs on caChangeJitterWindow const.
delay := m.getJitteredCAChangeDelay()
// Force the cert to be expired after the jitter - the delay above might
// be longer than we have left on our timeout. We set forceExpireAfter in
// the cache state so the next request will notice we still need to renew
// and do it at the right time. This is cleared once a new cert is
// returned by generateNewLeaf.
state.forceExpireAfter = state.activeRootRotationStart.Add(delay)
// If the delay time is within the current timeout, we want to renew the
// as soon as it's up. We change the expire time and chan so that when we
// loop back around, we'll wait at most delay until generating a new cert.
if state.forceExpireAfter.Before(expiresAt) {
expiresAt = state.forceExpireAfter
// Stop the former one and create a new one.
expiresTimer.Stop()
expiresTimer = time.NewTimer(delay)
}
continue
}
}
}
func (m *Manager) getJitteredCAChangeDelay() time.Duration {
if m.config.TestOverrideCAChangeInitialDelay > 0 {
return m.config.TestOverrideCAChangeInitialDelay
}
// CA root changed. We add some jitter here to avoid a thundering herd.
// See docs on caChangeJitterWindow const.
return lib.RandomStagger(caChangeJitterWindow)
}
func activeRootHasKey(roots *structs.IndexedCARoots, currentSigningKeyID string) bool {
for _, ca := range roots.Roots {
if ca.Active {
return ca.SigningKeyID == currentSigningKeyID
}
}
// Shouldn't be possible since at least one root should be active.
return false
}
// generateNewLeaf does the actual work of creating a new private key,
// generating a CSR and getting it signed by the servers.
//
// NOTE: do not hold the lock while doing the RPC/blocking stuff
func (m *Manager) generateNewLeaf(
req *ConnectCALeafRequest,
newState fetchState,
firstTime bool,
) (*structs.IssuedCert, fetchState, error) {
// Need to lookup RootCAs response to discover trust domain. This should be a
// cache hit.
roots, err := m.rootsReader.Get()
if err != nil {
return nil, newState, err
} else if roots == nil {
return nil, newState, errors.New("no CA roots")
}
if roots.TrustDomain == "" {
return nil, newState, errors.New("cluster has no CA bootstrapped yet")
}
// Build the cert uri
var id connect.CertURI
var dnsNames []string
var ipAddresses []net.IP
switch {
case req.Service != "":
id = &connect.SpiffeIDService{
Host: roots.TrustDomain,
Datacenter: req.Datacenter,
Partition: req.TargetPartition(),
Namespace: req.TargetNamespace(),
Service: req.Service,
}
dnsNames = append(dnsNames, req.DNSSAN...)
case req.Agent != "":
id = &connect.SpiffeIDAgent{
Host: roots.TrustDomain,
Datacenter: req.Datacenter,
Partition: req.TargetPartition(),
Agent: req.Agent,
}
dnsNames = append([]string{"localhost"}, req.DNSSAN...)
ipAddresses = append([]net.IP{net.ParseIP("127.0.0.1"), net.ParseIP("::1")}, req.IPSAN...)
case req.Kind == structs.ServiceKindMeshGateway:
id = &connect.SpiffeIDMeshGateway{
Host: roots.TrustDomain,
Datacenter: req.Datacenter,
Partition: req.TargetPartition(),
}
dnsNames = append(dnsNames, req.DNSSAN...)
case req.Kind != "":
return nil, newState, fmt.Errorf("unsupported kind: %s", req.Kind)
case req.Server:
if req.Datacenter == "" {
return nil, newState, errors.New("datacenter name must be specified")
}
id = &connect.SpiffeIDServer{
Host: roots.TrustDomain,
Datacenter: req.Datacenter,
}
dnsNames = append(dnsNames, connect.PeeringServerSAN(req.Datacenter, roots.TrustDomain))
default:
return nil, newState, errors.New("URI must be either service, agent, server, or kind")
}
// Create a new private key
// TODO: for now we always generate EC keys on clients regardless of the key
// type being used by the active CA. This is fine and allowed in TLS1.2 and
// signing EC CSRs with an RSA key is supported by all current CA providers so
// it's OK. IFF we ever need to support a CA provider that refuses to sign a
// CSR with a different signature algorithm, or if we have compatibility
// issues with external PKI systems that require EC certs be signed with ECDSA
// from the CA (this was required in TLS1.1 but not in 1.2) then we can
// instead intelligently pick the key type we generate here based on the key
// type of the active signing CA. We already have that loaded since we need
// the trust domain.
pk, pkPEM, err := connect.GeneratePrivateKey()
if err != nil {
return nil, newState, err
}
// Create a CSR.
csr, err := connect.CreateCSR(id, pk, dnsNames, ipAddresses)
if err != nil {
return nil, newState, err
}
// Request signing
args := structs.CASignRequest{
WriteRequest: structs.WriteRequest{Token: req.Token},
Datacenter: req.Datacenter,
CSR: csr,
}
reply, err := m.certSigner.SignCert(context.Background(), &args)
if err != nil {
if err.Error() == consul.ErrRateLimited.Error() {
if firstTime {
// This was a first fetch - we have no good value in cache. In this case
// we just return the error to the caller rather than rely on surprising
// semi-blocking until the rate limit is appeased or we timeout
// behavior. It's likely the caller isn't expecting this to block since
// it's an initial fetch. This also massively simplifies this edge case.
return nil, newState, err
}
if newState.activeRootRotationStart.IsZero() {
// We hit a rate limit error by chance - for example a cert expired
// before the root rotation was observed (not triggered by rotation) but
// while server is working through high load from a recent rotation.
// Just pretend there is a rotation and the retry logic here will start
// jittering and retrying in the same way from now.
newState.activeRootRotationStart = time.Now()
}
// Increment the errors in the state
newState.consecutiveRateLimitErrs++
delay := m.getJitteredCAChangeDelay()
// Find the start of the next window we can retry in. See comment on
// caChangeJitterWindow for details of why we use this strategy.
windowStart := newState.activeRootRotationStart.Add(
time.Duration(newState.consecutiveRateLimitErrs) * delay)
// Pick a random time in that window
newState.forceExpireAfter = windowStart.Add(delay)
// Return a result with the existing cert but the new state - the cache
// will see this as no change. Note that we always have an existing result
// here due to the nil value check above.
return nil, newState, nil
}
return nil, newState, err
}
reply.PrivateKeyPEM = pkPEM
// Reset rotation state
newState.forceExpireAfter = time.Time{}
newState.consecutiveRateLimitErrs = 0
newState.activeRootRotationStart = time.Time{}
cert, err := connect.ParseCert(reply.CertPEM)
if err != nil {
return nil, newState, err
}
// Set the CA key ID so we can easily tell when a active root has changed.
newState.authorityKeyID = connect.EncodeSigningKeyID(cert.AuthorityKeyId)
return reply, newState, nil
}