mirror of
https://github.com/caddyserver/caddy.git
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ac4fa2c3a9
These changes span work from the last ~4 months in an effort to make Caddy more extensible, reduce the coupling between its components, and lay a more robust foundation of code going forward into 1.0. A bunch of new features have been added, too, with even higher future potential. The most significant design change is an overall inversion of dependencies. Instead of the caddy package knowing about the server and the notion of middleware and config, the caddy package exposes an interface that other components plug into. This does introduce more indirection when reading the code, but every piece is very modular and pluggable. Even the HTTP server is pluggable. The caddy package has been moved to the top level, and main has been pushed into a subfolder called caddy. The actual logic of the main file has been pushed even further into caddy/caddymain/run.go so that custom builds of Caddy can be 'go get'able. The HTTPS logic was surgically separated into two parts to divide the TLS-specific code and the HTTPS-specific code. The caddytls package can now be used by any type of server that needs TLS, not just HTTP. I also added the ability to customize nearly every aspect of TLS at the site level rather than all sites sharing the same TLS configuration. Not all of this flexibility is exposed in the Caddyfile yet, but it may be in the future. Caddy can also generate self-signed certificates in memory for the convenience of a developer working on localhost who wants HTTPS. And Caddy now supports the DNS challenge, assuming at least one DNS provider is plugged in. Dozens, if not hundreds, of other minor changes swept through the code base as I literally started from an empty main function, copying over functions or files as needed, then adjusting them to fit in the new design. Most tests have been restored and adapted to the new API, but more work is needed there. A lot of what was "impossible" before is now possible, or can be made possible with minimal disruption of the code. For example, it's fairly easy to make plugins hook into another part of the code via callbacks. Plugins can do more than just be directives; we now have plugins that customize how the Caddyfile is loaded (useful when you need to get your configuration from a remote store). Site addresses no longer need be just a host and port. They can have a path, allowing you to scope a configuration to a specific path. There is no inheretance, however; each site configuration is distinct. Thanks to amazing work by Lucas Clemente, this commit adds experimental QUIC support. Turn it on using the -quic flag; your browser may have to be configured to enable it. Almost everything is here, but you will notice that most of the middle- ware are missing. After those are transferred over, we'll be ready for beta tests. I'm very excited to get this out. Thanks for everyone's help and patience these last few months. I hope you like it!!
259 lines
7.4 KiB
Go
259 lines
7.4 KiB
Go
package caddytls
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import (
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"bytes"
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"crypto"
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"crypto/ecdsa"
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"crypto/elliptic"
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"crypto/rand"
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"crypto/rsa"
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"crypto/tls"
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"crypto/x509"
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"crypto/x509/pkix"
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"encoding/pem"
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"errors"
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"fmt"
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"io"
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"io/ioutil"
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"math/big"
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"net"
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"os"
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"time"
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"github.com/xenolf/lego/acme"
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)
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// loadPrivateKey loads a PEM-encoded ECC/RSA private key from file.
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func loadPrivateKey(file string) (crypto.PrivateKey, error) {
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keyBytes, err := ioutil.ReadFile(file)
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if err != nil {
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return nil, err
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}
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keyBlock, _ := pem.Decode(keyBytes)
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switch keyBlock.Type {
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case "RSA PRIVATE KEY":
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return x509.ParsePKCS1PrivateKey(keyBlock.Bytes)
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case "EC PRIVATE KEY":
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return x509.ParseECPrivateKey(keyBlock.Bytes)
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}
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return nil, errors.New("unknown private key type")
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}
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// savePrivateKey saves a PEM-encoded ECC/RSA private key to file.
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func savePrivateKey(key crypto.PrivateKey, file string) error {
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var pemType string
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var keyBytes []byte
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switch key := key.(type) {
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case *ecdsa.PrivateKey:
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var err error
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pemType = "EC"
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keyBytes, err = x509.MarshalECPrivateKey(key)
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if err != nil {
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return err
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}
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case *rsa.PrivateKey:
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pemType = "RSA"
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keyBytes = x509.MarshalPKCS1PrivateKey(key)
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}
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pemKey := pem.Block{Type: pemType + " PRIVATE KEY", Bytes: keyBytes}
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keyOut, err := os.Create(file)
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if err != nil {
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return err
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}
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keyOut.Chmod(0600)
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defer keyOut.Close()
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return pem.Encode(keyOut, &pemKey)
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}
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// stapleOCSP staples OCSP information to cert for hostname name.
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// If you have it handy, you should pass in the PEM-encoded certificate
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// bundle; otherwise the DER-encoded cert will have to be PEM-encoded.
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// If you don't have the PEM blocks handy, just pass in nil.
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//
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// Errors here are not necessarily fatal, it could just be that the
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// certificate doesn't have an issuer URL.
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func stapleOCSP(cert *Certificate, pemBundle []byte) error {
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if pemBundle == nil {
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// The function in the acme package that gets OCSP requires a PEM-encoded cert
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bundle := new(bytes.Buffer)
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for _, derBytes := range cert.Certificate.Certificate {
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pem.Encode(bundle, &pem.Block{Type: "CERTIFICATE", Bytes: derBytes})
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}
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pemBundle = bundle.Bytes()
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}
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ocspBytes, ocspResp, err := acme.GetOCSPForCert(pemBundle)
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if err != nil {
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return err
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}
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cert.Certificate.OCSPStaple = ocspBytes
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cert.OCSP = ocspResp
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return nil
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}
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// makeSelfSignedCert makes a self-signed certificate according
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// to the parameters in config. It then caches the certificate
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// in our cache.
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func makeSelfSignedCert(config *Config) error {
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// start by generating private key
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var privKey interface{}
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var err error
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switch config.KeyType {
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case "", acme.EC256:
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privKey, err = ecdsa.GenerateKey(elliptic.P256(), rand.Reader)
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case acme.EC384:
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privKey, err = ecdsa.GenerateKey(elliptic.P384(), rand.Reader)
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case acme.RSA2048:
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privKey, err = rsa.GenerateKey(rand.Reader, 2048)
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case acme.RSA4096:
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privKey, err = rsa.GenerateKey(rand.Reader, 4096)
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case acme.RSA8192:
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privKey, err = rsa.GenerateKey(rand.Reader, 8192)
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default:
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return fmt.Errorf("cannot generate private key; unknown key type %v", config.KeyType)
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}
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if err != nil {
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return fmt.Errorf("failed to generate private key: %v", err)
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}
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// create certificate structure with proper values
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notBefore := time.Now()
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notAfter := notBefore.Add(24 * time.Hour * 7)
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serialNumberLimit := new(big.Int).Lsh(big.NewInt(1), 128)
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serialNumber, err := rand.Int(rand.Reader, serialNumberLimit)
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if err != nil {
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return fmt.Errorf("failed to generate serial number: %v", err)
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}
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cert := &x509.Certificate{
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SerialNumber: serialNumber,
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Subject: pkix.Name{Organization: []string{"Caddy Self-Signed"}},
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NotBefore: notBefore,
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NotAfter: notAfter,
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KeyUsage: x509.KeyUsageKeyEncipherment | x509.KeyUsageDigitalSignature,
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ExtKeyUsage: []x509.ExtKeyUsage{x509.ExtKeyUsageServerAuth},
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}
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if ip := net.ParseIP(config.Hostname); ip != nil {
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cert.IPAddresses = append(cert.IPAddresses, ip)
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} else {
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cert.DNSNames = append(cert.DNSNames, config.Hostname)
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}
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publicKey := func(privKey interface{}) interface{} {
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switch k := privKey.(type) {
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case *rsa.PrivateKey:
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return &k.PublicKey
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case *ecdsa.PrivateKey:
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return &k.PublicKey
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default:
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return errors.New("unknown key type")
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}
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}
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derBytes, err := x509.CreateCertificate(rand.Reader, cert, cert, publicKey(privKey), privKey)
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if err != nil {
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return fmt.Errorf("could not create certificate: %v", err)
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}
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cacheCertificate(Certificate{
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Certificate: tls.Certificate{
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Certificate: [][]byte{derBytes},
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PrivateKey: privKey,
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Leaf: cert,
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},
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Names: cert.DNSNames,
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NotAfter: cert.NotAfter,
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Config: config,
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})
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return nil
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}
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// RotateSessionTicketKeys rotates the TLS session ticket keys
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// on cfg every TicketRotateInterval. It spawns a new goroutine so
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// this function does NOT block. It returns a channel you should
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// close when you are ready to stop the key rotation, like when the
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// server using cfg is no longer running.
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func RotateSessionTicketKeys(cfg *tls.Config) chan struct{} {
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ch := make(chan struct{})
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ticker := time.NewTicker(TicketRotateInterval)
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go runTLSTicketKeyRotation(cfg, ticker, ch)
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return ch
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}
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// Functions that may be swapped out for testing
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var (
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runTLSTicketKeyRotation = standaloneTLSTicketKeyRotation
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setSessionTicketKeysTestHook = func(keys [][32]byte) [][32]byte { return keys }
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)
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// standaloneTLSTicketKeyRotation governs over the array of TLS ticket keys used to de/crypt TLS tickets.
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// It periodically sets a new ticket key as the first one, used to encrypt (and decrypt),
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// pushing any old ticket keys to the back, where they are considered for decryption only.
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//
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// Lack of entropy for the very first ticket key results in the feature being disabled (as does Go),
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// later lack of entropy temporarily disables ticket key rotation.
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// Old ticket keys are still phased out, though.
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//
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// Stops the ticker when returning.
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func standaloneTLSTicketKeyRotation(c *tls.Config, ticker *time.Ticker, exitChan chan struct{}) {
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defer ticker.Stop()
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// The entire page should be marked as sticky, but Go cannot do that
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// without resorting to syscall#Mlock. And, we don't have madvise (for NODUMP), too. ☹
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keys := make([][32]byte, 1, NumTickets)
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rng := c.Rand
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if rng == nil {
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rng = rand.Reader
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}
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if _, err := io.ReadFull(rng, keys[0][:]); err != nil {
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c.SessionTicketsDisabled = true // bail if we don't have the entropy for the first one
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return
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}
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c.SessionTicketKey = keys[0] // SetSessionTicketKeys doesn't set a 'tls.keysAlreadySet'
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c.SetSessionTicketKeys(setSessionTicketKeysTestHook(keys))
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for {
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select {
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case _, isOpen := <-exitChan:
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if !isOpen {
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return
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}
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case <-ticker.C:
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rng = c.Rand // could've changed since the start
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if rng == nil {
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rng = rand.Reader
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}
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var newTicketKey [32]byte
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_, err := io.ReadFull(rng, newTicketKey[:])
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if len(keys) < NumTickets {
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keys = append(keys, keys[0]) // manipulates the internal length
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}
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for idx := len(keys) - 1; idx >= 1; idx-- {
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keys[idx] = keys[idx-1] // yes, this makes copies
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}
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if err == nil {
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keys[0] = newTicketKey
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}
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// pushes the last key out, doesn't matter that we don't have a new one
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c.SetSessionTicketKeys(setSessionTicketKeysTestHook(keys))
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}
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}
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}
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const (
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// NumTickets is how many tickets to hold and consider
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// to decrypt TLS sessions.
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NumTickets = 4
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// TicketRotateInterval is how often to generate
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// new ticket for TLS PFS encryption
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TicketRotateInterval = 10 * time.Hour
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)
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