// 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 (
"context"
"crypto/tls"
"encoding/json"
"fmt"
"log"
"net"
"net/http"
"path"
"runtime"
"strings"
"sync"
"sync/atomic"
"time"
"github.com/libdns/libdns"
"github.com/mholt/acmez"
"github.com/mholt/acmez/acme"
"github.com/miekg/dns"
)
// httpSolver solves the HTTP challenge. It must be
// associated with a config and an address to use
// for solving the challenge. If multiple httpSolvers
// are initialized concurrently, the first one to
// begin will start the server, and the last one to
// finish will stop the server. This solver must be
// wrapped by a distributedSolver to work properly,
// because the only way the HTTP challenge handler
// can access the keyAuth material is by loading it
// from storage, which is done by distributedSolver.
type httpSolver struct {
closed int32 // accessed atomically
acmeManager * ACMEManager
address string
}
// Present starts an HTTP server if none is already listening on s.address.
func ( s * httpSolver ) Present ( ctx context . Context , _ acme . Challenge ) error {
solversMu . Lock ( )
defer solversMu . Unlock ( )
si := getSolverInfo ( s . address )
si . count ++
if si . listener != nil {
return nil // already be served by us
}
// notice the unusual error handling here; we
// only continue to start a challenge server if
// we got a listener; in all other cases return
ln , err := robustTryListen ( s . address )
if ln == nil {
return err
}
// successfully bound socket, so save listener and start key auth HTTP server
si . listener = ln
go s . serve ( si )
return nil
}
// serve is an HTTP server that serves only HTTP challenge responses.
func ( s * httpSolver ) serve ( si * solverInfo ) {
defer func ( ) {
if err := recover ( ) ; err != nil {
buf := make ( [ ] byte , stackTraceBufferSize )
buf = buf [ : runtime . Stack ( buf , false ) ]
log . Printf ( "panic: http solver server: %v\n%s" , err , buf )
}
} ( )
defer close ( si . done )
httpServer := & http . Server { Handler : s . acmeManager . HTTPChallengeHandler ( http . NewServeMux ( ) ) }
httpServer . SetKeepAlivesEnabled ( false )
err := httpServer . Serve ( si . listener )
if err != nil && atomic . LoadInt32 ( & s . closed ) != 1 {
log . Printf ( "[ERROR] key auth HTTP server: %v" , err )
}
}
// CleanUp cleans up the HTTP server if it is the last one to finish.
func ( s * httpSolver ) CleanUp ( ctx context . Context , _ acme . Challenge ) error {
solversMu . Lock ( )
defer solversMu . Unlock ( )
si := getSolverInfo ( s . address )
si . count --
if si . count == 0 {
// last one out turns off the lights
atomic . StoreInt32 ( & s . closed , 1 )
if si . listener != nil {
si . listener . Close ( )
<- si . done
}
delete ( solvers , s . address )
}
return nil
}
// tlsALPNSolver is a type that can solve TLS-ALPN challenges.
// It must have an associated config and address on which to
// serve the challenge.
type tlsALPNSolver struct {
config * Config
address string
}
// Present adds the certificate to the certificate cache and, if
// needed, starts a TLS server for answering TLS-ALPN challenges.
func ( s * tlsALPNSolver ) Present ( ctx context . Context , chal acme . Challenge ) error {
// we pre-generate the certificate for efficiency with multi-perspective
// validation, so it only has to be done once (at least, by this instance;
// distributed solving does not have that luxury, oh well) - update the
// challenge data in memory to be the generated certificate
cert , err := acmez . TLSALPN01ChallengeCert ( chal )
if err != nil {
return err
}
key := challengeKey ( chal )
activeChallengesMu . Lock ( )
chalData := activeChallenges [ key ]
chalData . data = cert
activeChallenges [ key ] = chalData
activeChallengesMu . Unlock ( )
// the rest of this function increments the
// challenge count for the solver at this
// listener address, and if necessary, starts
// a simple TLS server
solversMu . Lock ( )
defer solversMu . Unlock ( )
si := getSolverInfo ( s . address )
si . count ++
if si . listener != nil {
return nil // already be served by us
}
// notice the unusual error handling here; we
// only continue to start a challenge server if
// we got a listener; in all other cases return
ln , err := robustTryListen ( s . address )
if ln == nil {
return err
}
// we were able to bind the socket, so make it into a TLS
// listener, store it with the solverInfo, and start the
// challenge server
si . listener = tls . NewListener ( ln , s . config . TLSConfig ( ) )
go func ( ) {
defer func ( ) {
if err := recover ( ) ; err != nil {
buf := make ( [ ] byte , stackTraceBufferSize )
buf = buf [ : runtime . Stack ( buf , false ) ]
log . Printf ( "panic: tls-alpn solver server: %v\n%s" , err , buf )
}
} ( )
defer close ( si . done )
for {
conn , err := si . listener . Accept ( )
if err != nil {
if atomic . LoadInt32 ( & si . closed ) == 1 {
return
}
log . Printf ( "[ERROR] TLS-ALPN challenge server: accept: %v" , err )
continue
}
go s . handleConn ( conn )
}
} ( )
return nil
}
// handleConn completes the TLS handshake and then closes conn.
func ( * tlsALPNSolver ) handleConn ( conn net . Conn ) {
defer func ( ) {
if err := recover ( ) ; err != nil {
buf := make ( [ ] byte , stackTraceBufferSize )
buf = buf [ : runtime . Stack ( buf , false ) ]
log . Printf ( "panic: tls-alpn solver handler: %v\n%s" , err , buf )
}
} ( )
defer conn . Close ( )
tlsConn , ok := conn . ( * tls . Conn )
if ! ok {
log . Printf ( "[ERROR] TLS-ALPN challenge server: expected tls.Conn but got %T: %#v" , conn , conn )
return
}
err := tlsConn . Handshake ( )
if err != nil {
log . Printf ( "[ERROR] TLS-ALPN challenge server: handshake: %v" , err )
return
}
}
// CleanUp removes the challenge certificate from the cache, and if
// it is the last one to finish, stops the TLS server.
func ( s * tlsALPNSolver ) CleanUp ( ctx context . Context , chal acme . Challenge ) error {
solversMu . Lock ( )
defer solversMu . Unlock ( )
si := getSolverInfo ( s . address )
si . count --
if si . count == 0 {
// last one out turns off the lights
atomic . StoreInt32 ( & si . closed , 1 )
if si . listener != nil {
si . listener . Close ( )
<- si . done
}
delete ( solvers , s . address )
}
return nil
}
// DNS01Solver is a type that makes libdns providers usable
// as ACME dns-01 challenge solvers.
// See https://github.com/libdns/libdns
type DNS01Solver struct {
// The implementation that interacts with the DNS
// provider to set or delete records. (REQUIRED)
DNSProvider ACMEDNSProvider
// The TTL for the temporary challenge records.
TTL time . Duration
// Maximum time to wait for temporary record to appear.
PropagationTimeout time . Duration
// Preferred DNS resolver(s) to use when doing DNS lookups.
Resolvers [ ] string
txtRecords map [ string ] dnsPresentMemory // keyed by domain name
txtRecordsMu sync . Mutex
}
// Present creates the DNS TXT record for the given ACME challenge.
func ( s * DNS01Solver ) Present ( ctx context . Context , challenge acme . Challenge ) error {
dnsName := challenge . DNS01TXTRecordName ( )
keyAuth := challenge . DNS01KeyAuthorization ( )
// multiple identifiers can have the same ACME challenge
// domain (e.g. example.com and *.example.com) so we need
// to ensure that we don't solve those concurrently and
// step on each challenges' metaphorical toes; see
// https://github.com/caddyserver/caddy/issues/3474
activeDNSChallenges . Lock ( dnsName )
zone , err := findZoneByFQDN ( dnsName , recursiveNameservers ( s . Resolvers ) )
if err != nil {
return fmt . Errorf ( "could not determine zone for domain %q: %v" , dnsName , err )
}
rec := libdns . Record {
Type : "TXT" ,
Name : libdns . RelativeName ( dnsName + "." , zone ) ,
Value : keyAuth ,
TTL : s . TTL ,
}
results , err := s . DNSProvider . AppendRecords ( ctx , zone , [ ] libdns . Record { rec } )
if err != nil {
return fmt . Errorf ( "adding temporary record for zone %s: %w" , zone , err )
}
if len ( results ) != 1 {
return fmt . Errorf ( "expected one record, got %d: %v" , len ( results ) , results )
}
// remember the record and zone we got so we can clean up more efficiently
s . txtRecordsMu . Lock ( )
if s . txtRecords == nil {
s . txtRecords = make ( map [ string ] dnsPresentMemory )
}
s . txtRecords [ dnsName ] = dnsPresentMemory { dnsZone : zone , rec : results [ 0 ] }
s . txtRecordsMu . Unlock ( )
return nil
}
// Wait blocks until the TXT record created in Present() appears in
// authoritative lookups, i.e. until it has propagated, or until
// timeout, whichever is first.
func ( s * DNS01Solver ) Wait ( ctx context . Context , challenge acme . Challenge ) error {
dnsName := challenge . DNS01TXTRecordName ( )
keyAuth := challenge . DNS01KeyAuthorization ( )
timeout := s . PropagationTimeout
if timeout == 0 {
timeout = 2 * time . Minute
}
const interval = 2 * time . Second
resolvers := recursiveNameservers ( s . Resolvers )
var err error
start := time . Now ( )
for time . Since ( start ) < timeout {
select {
case <- time . After ( interval ) :
case <- ctx . Done ( ) :
return ctx . Err ( )
}
var ready bool
ready , err = checkDNSPropagation ( dnsName , keyAuth , resolvers )
if err != nil {
return fmt . Errorf ( "checking DNS propagation of %s: %w" , dnsName , err )
}
if ready {
return nil
}
}
return fmt . Errorf ( "timed out waiting for record to fully propagate; verify DNS provider configuration is correct - last error: %v" , err )
}
// CleanUp deletes the DNS TXT record created in Present().
func ( s * DNS01Solver ) CleanUp ( ctx context . Context , challenge acme . Challenge ) error {
dnsName := challenge . DNS01TXTRecordName ( )
defer func ( ) {
// always forget about it so we don't leak memory
s . txtRecordsMu . Lock ( )
delete ( s . txtRecords , dnsName )
s . txtRecordsMu . Unlock ( )
// always do this last - but always do it!
activeDNSChallenges . Unlock ( dnsName )
} ( )
// recall the record we created and zone we looked up
s . txtRecordsMu . Lock ( )
memory , ok := s . txtRecords [ dnsName ]
if ! ok {
s . txtRecordsMu . Unlock ( )
return fmt . Errorf ( "no memory of presenting a DNS record for %s (probably OK if presenting failed)" , challenge . Identifier . Value )
}
s . txtRecordsMu . Unlock ( )
// clean up the record
_ , err := s . DNSProvider . DeleteRecords ( ctx , memory . dnsZone , [ ] libdns . Record { memory . rec } )
if err != nil {
return fmt . Errorf ( "deleting temporary record for zone %s: %w" , memory . dnsZone , err )
}
return nil
}
type dnsPresentMemory struct {
dnsZone string
rec libdns . Record
}
// ACMEDNSProvider defines the set of operations required for
// ACME challenges. A DNS provider must be able to append and
// delete records in order to solve ACME challenges. Find one
// you can use at https://github.com/libdns. If your provider
// isn't implemented yet, feel free to contribute!
type ACMEDNSProvider interface {
libdns . RecordAppender
libdns . RecordDeleter
}
// activeDNSChallenges synchronizes DNS challenges for
// names to ensure that challenges for the same ACME
// DNS name do not overlap; for example, the TXT record
// to make for both example.com and *.example.com are
// the same; thus we cannot solve them concurrently.
var activeDNSChallenges = newMapMutex ( )
// mapMutex implements named mutexes.
type mapMutex struct {
cond * sync . Cond
set map [ interface { } ] struct { }
}
func newMapMutex ( ) * mapMutex {
return & mapMutex {
cond : sync . NewCond ( new ( sync . Mutex ) ) ,
set : make ( map [ interface { } ] struct { } ) ,
}
}
func ( mmu * mapMutex ) Lock ( key interface { } ) {
mmu . cond . L . Lock ( )
defer mmu . cond . L . Unlock ( )
for mmu . locked ( key ) {
mmu . cond . Wait ( )
}
mmu . set [ key ] = struct { } { }
}
func ( mmu * mapMutex ) Unlock ( key interface { } ) {
mmu . cond . L . Lock ( )
defer mmu . cond . L . Unlock ( )
delete ( mmu . set , key )
mmu . cond . Broadcast ( )
}
func ( mmu * mapMutex ) locked ( key interface { } ) ( ok bool ) {
_ , ok = mmu . set [ key ]
return
}
// distributedSolver allows the ACME HTTP-01 and TLS-ALPN challenges
// to be solved by an instance other than the one which initiated it.
// This is useful behind load balancers or in other cluster/fleet
// configurations. The only requirement is that the instance which
// initiates the challenge shares the same storage and locker with
// the others in the cluster. The storage backing the certificate
// cache in distributedSolver.config is crucial.
//
// Obviously, the instance which completes the challenge must be
// serving on the HTTPChallengePort for the HTTP-01 challenge or the
// TLSALPNChallengePort for the TLS-ALPN-01 challenge (or have all
// the packets port-forwarded) to receive and handle the request. The
// server which receives the challenge must handle it by checking to
// see if the challenge token exists in storage, and if so, decode it
// and use it to serve up the correct response. HTTPChallengeHandler
// in this package as well as the GetCertificate method implemented
// by a Config support and even require this behavior.
//
// In short: the only two requirements for cluster operation are
// sharing sync and storage, and using the facilities provided by
// this package for solving the challenges.
type distributedSolver struct {
// The storage backing the distributed solver. It must be
// the same storage configuration as what is solving the
// challenge in order to be effective.
storage Storage
// The storage key prefix, associated with the issuer
// that is solving the challenge.
storageKeyIssuerPrefix string
// Since the distributedSolver is only a
// wrapper over an actual solver, place
// the actual solver here.
solver acmez . Solver
}
// Present invokes the underlying solver's Present method
// and also stores domain, token, and keyAuth to the storage
// backing the certificate cache of dhs.acmeManager.
func ( dhs distributedSolver ) Present ( ctx context . Context , chal acme . Challenge ) error {
infoBytes , err := json . Marshal ( chal )
if err != nil {
return err
}
err = dhs . storage . Store ( dhs . challengeTokensKey ( challengeKey ( chal ) ) , infoBytes )
if err != nil {
return err
}
err = dhs . solver . Present ( ctx , chal )
if err != nil {
return fmt . Errorf ( "presenting with embedded solver: %v" , err )
}
return nil
}
// Wait wraps the underlying solver's Wait() method, if any. Implements acmez.Waiter.
func ( dhs distributedSolver ) Wait ( ctx context . Context , challenge acme . Challenge ) error {
if waiter , ok := dhs . solver . ( acmez . Waiter ) ; ok {
return waiter . Wait ( ctx , challenge )
}
return nil
}
// CleanUp invokes the underlying solver's CleanUp method
// and also cleans up any assets saved to storage.
func ( dhs distributedSolver ) CleanUp ( ctx context . Context , chal acme . Challenge ) error {
err := dhs . storage . Delete ( dhs . challengeTokensKey ( challengeKey ( chal ) ) )
if err != nil {
return err
}
err = dhs . solver . CleanUp ( ctx , chal )
if err != nil {
return fmt . Errorf ( "cleaning up embedded provider: %v" , err )
}
return nil
}
// challengeTokensPrefix returns the key prefix for challenge info.
func ( dhs distributedSolver ) challengeTokensPrefix ( ) string {
return path . Join ( dhs . storageKeyIssuerPrefix , "challenge_tokens" )
}
// challengeTokensKey returns the key to use to store and access
// challenge info for domain.
func ( dhs distributedSolver ) challengeTokensKey ( domain string ) string {
return path . Join ( dhs . challengeTokensPrefix ( ) , StorageKeys . Safe ( domain ) + ".json" )
}
// solverInfo associates a listener with the
// number of challenges currently using it.
type solverInfo struct {
closed int32 // accessed atomically
count int
listener net . Listener
done chan struct { } // used to signal when our own solver server is done
}
// getSolverInfo gets a valid solverInfo struct for address.
func getSolverInfo ( address string ) * solverInfo {
si , ok := solvers [ address ]
if ! ok {
si = & solverInfo { done : make ( chan struct { } ) }
solvers [ address ] = si
}
return si
}
// robustTryListen calls net.Listen for a TCP socket at addr.
// This function may return both a nil listener and a nil error!
// If it was able to bind the socket, it returns the listener
// and no error. If it wasn't able to bind the socket because
// the socket is already in use, then it returns a nil listener
// and nil error. If it had any other error, it returns the
// error. The intended error handling logic for this function
// is to proceed if the returned listener is not nil; otherwise
// return err (which may also be nil). In other words, this
// function ignores errors if the socket is already in use,
// which is useful for our challenge servers, where we assume
// that whatever is already listening can solve the challenges.
func robustTryListen ( addr string ) ( net . Listener , error ) {
var listenErr error
for i := 0 ; i < 2 ; i ++ {
// doesn't hurt to sleep briefly before the second
// attempt in case the OS has timing issues
if i > 0 {
time . Sleep ( 100 * time . Millisecond )
}
// if we can bind the socket right away, great!
var ln net . Listener
ln , listenErr = net . Listen ( "tcp" , addr )
if listenErr == nil {
return ln , nil
}
// if it failed just because the socket is already in use, we
// have no choice but to assume that whatever is using the socket
// can answer the challenge already, so we ignore the error
connectErr := dialTCPSocket ( addr )
if connectErr == nil {
return nil , nil
}
// hmm, we couldn't connect to the socket, so something else must
// be wrong, right? wrong!! we've had reports across multiple OSes
// now that sometimes connections fail even though the OS told us
// that the address was already in use; either the listener is
// fluctuating between open and closed very, very quickly, or the
// OS is inconsistent and contradicting itself; I have been unable
// to reproduce this, so I'm now resorting to hard-coding substring
// matching in error messages as a really hacky and unreliable
// safeguard against this, until we can idenify exactly what was
// happening; see the following threads for more info:
// https://caddy.community/t/caddy-retry-error/7317
// https://caddy.community/t/v2-upgrade-to-caddy2-failing-with-errors/7423
if strings . Contains ( listenErr . Error ( ) , "address already in use" ) ||
strings . Contains ( listenErr . Error ( ) , "one usage of each socket address" ) {
log . Printf ( "[WARNING] OS reports a contradiction: %v - but we cannot connect to it, with this error: %v; continuing anyway 🤞 (I don't know what causes this... if you do, please help?)" , listenErr , connectErr )
return nil , nil
}
}
return nil , fmt . Errorf ( "could not start listener for challenge server at %s: %v" , addr , listenErr )
}
// dialTCPSocket connects to a TCP address just for the sake of
// seeing if it is open. It returns a nil error if a TCP connection
// can successfully be made to addr within a short timeout.
func dialTCPSocket ( addr string ) error {
conn , err := net . DialTimeout ( "tcp" , addr , 250 * time . Millisecond )
if err == nil {
conn . Close ( )
}
return err
}
// GetACMEChallenge returns an active ACME challenge for the given identifier,
// or false if no active challenge for that identifier is known.
func GetACMEChallenge ( identifier string ) ( Challenge , bool ) {
activeChallengesMu . Lock ( )
chalData , ok := activeChallenges [ identifier ]
activeChallengesMu . Unlock ( )
return chalData , ok
}
// The active challenge solvers, keyed by listener address,
// and protected by a mutex. Note that the creation of
// solver listeners and the incrementing of their counts
// are atomic operations guarded by this mutex.
var (
solvers = make ( map [ string ] * solverInfo )
solversMu sync . Mutex
)
// activeChallenges holds information about all known, currently-active
// ACME challenges, keyed by identifier. CertMagic guarantees that
// challenges for the same identifier do not overlap, by its locking
// mechanisms; thus if a challenge comes in for a certain identifier,
// we can be confident that if this process initiated the challenge,
// the correct information to solve it is in this map. (It may have
// alternatively been initiated by another instance in a cluster, in
// which case the distributed solver will take care of that.)
var (
activeChallenges = make ( map [ string ] Challenge )
activeChallengesMu sync . Mutex
)
// Challenge is an ACME challenge, but optionally paired with
// data that can make it easier or more efficient to solve.
type Challenge struct {
acme . Challenge
data interface { }
}
// challengeKey returns the map key for a given challenge; it is the identifier
// unless it is an IP address using the TLS-ALPN challenge.
func challengeKey ( chal acme . Challenge ) string {
if chal . Type == acme . ChallengeTypeTLSALPN01 && chal . Identifier . Type == "ip" {
reversed , err := dns . ReverseAddr ( chal . Identifier . Value )
if err == nil {
return reversed [ : len ( reversed ) - 1 ] // strip off '.'
}
}
return chal . Identifier . Value
}
// solverWrapper should be used to wrap all challenge solvers so that
// we can add the challenge info to memory; this makes challenges globally
// solvable by a single HTTP or TLS server even if multiple servers with
// different configurations/scopes need to get certificates.
type solverWrapper struct { acmez . Solver }
func ( sw solverWrapper ) Present ( ctx context . Context , chal acme . Challenge ) error {
activeChallengesMu . Lock ( )
activeChallenges [ challengeKey ( chal ) ] = Challenge { Challenge : chal }
activeChallengesMu . Unlock ( )
return sw . Solver . Present ( ctx , chal )
}
func ( sw solverWrapper ) Wait ( ctx context . Context , chal acme . Challenge ) error {
if waiter , ok := sw . Solver . ( acmez . Waiter ) ; ok {
return waiter . Wait ( ctx , chal )
}
return nil
}
func ( sw solverWrapper ) CleanUp ( ctx context . Context , chal acme . Challenge ) error {
activeChallengesMu . Lock ( )
delete ( activeChallenges , challengeKey ( chal ) )
activeChallengesMu . Unlock ( )
return sw . Solver . CleanUp ( ctx , chal )
}
// Interface guards
var (
_ acmez . Solver = ( * solverWrapper ) ( nil )
_ acmez . Waiter = ( * solverWrapper ) ( nil )
_ acmez . Waiter = ( * distributedSolver ) ( nil )
)