222 lines
6.1 KiB
Go
222 lines
6.1 KiB
Go
package connect
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import (
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"crypto"
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"crypto/ecdsa"
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"crypto/rsa"
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"crypto/sha1"
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"crypto/sha256"
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"crypto/x509"
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"encoding/hex"
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"encoding/pem"
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"fmt"
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"math/big"
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"strings"
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)
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// ParseCert parses the x509 certificate from a PEM-encoded value.
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func ParseCert(pemValue string) (*x509.Certificate, error) {
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// The _ result below is not an error but the remaining PEM bytes.
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block, _ := pem.Decode([]byte(pemValue))
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if block == nil {
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return nil, fmt.Errorf("no PEM-encoded data found")
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}
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if block.Type != "CERTIFICATE" {
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return nil, fmt.Errorf("first PEM-block should be CERTIFICATE type")
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}
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return x509.ParseCertificate(block.Bytes)
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}
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// ParseLeafCerts parses all of the x509 certificates from a PEM-encoded value
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// under the assumption that the first cert is a leaf (non-CA) cert and the
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// rest are intermediate CA certs.
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//
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// If no certificates are found this returns an error.
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func ParseLeafCerts(pemValue string) (*x509.Certificate, *x509.CertPool, error) {
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certs, err := parseCerts(pemValue)
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if err != nil {
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return nil, nil, err
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}
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leaf := certs[0]
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if leaf.IsCA {
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return nil, nil, fmt.Errorf("first PEM-block should be a leaf cert")
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}
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intermediates := x509.NewCertPool()
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for _, cert := range certs[1:] {
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if !cert.IsCA {
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return nil, nil, fmt.Errorf("found an unexpected leaf cert after the first PEM-block")
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}
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intermediates.AddCert(cert)
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}
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return leaf, intermediates, nil
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}
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// ParseCerts parses the all x509 certificates from a PEM-encoded value.
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// The first returned cert is a leaf cert and any other ones are intermediates.
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//
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// If no certificates are found this returns an error.
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func parseCerts(pemValue string) ([]*x509.Certificate, error) {
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var out []*x509.Certificate
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rest := []byte(pemValue)
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for {
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// The _ result below is not an error but the remaining PEM bytes.
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block, remaining := pem.Decode(rest)
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if block == nil {
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break
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}
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rest = remaining
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if block.Type != "CERTIFICATE" {
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return nil, fmt.Errorf("PEM-block should be CERTIFICATE type")
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}
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cert, err := x509.ParseCertificate(block.Bytes)
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if err != nil {
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return nil, err
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}
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out = append(out, cert)
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}
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if len(out) == 0 {
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return nil, fmt.Errorf("no PEM-encoded data found")
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}
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return out, nil
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}
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// CalculateCertFingerprint parses the x509 certificate from a PEM-encoded value
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// and calculates the SHA-1 fingerprint.
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func CalculateCertFingerprint(pemValue string) (string, error) {
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// The _ result below is not an error but the remaining PEM bytes.
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block, _ := pem.Decode([]byte(pemValue))
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if block == nil {
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return "", fmt.Errorf("no PEM-encoded data found")
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}
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if block.Type != "CERTIFICATE" {
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return "", fmt.Errorf("first PEM-block should be CERTIFICATE type")
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}
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hash := sha1.Sum(block.Bytes)
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return HexString(hash[:]), nil
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}
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// ParseSigner parses a crypto.Signer from a PEM-encoded key. The private key
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// is expected to be the first block in the PEM value.
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func ParseSigner(pemValue string) (crypto.Signer, error) {
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// The _ result below is not an error but the remaining PEM bytes.
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block, _ := pem.Decode([]byte(pemValue))
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if block == nil {
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return nil, fmt.Errorf("no PEM-encoded data found")
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}
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switch block.Type {
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case "EC PRIVATE KEY":
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return x509.ParseECPrivateKey(block.Bytes)
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case "RSA PRIVATE KEY":
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return x509.ParsePKCS1PrivateKey(block.Bytes)
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case "PRIVATE KEY":
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signer, err := x509.ParsePKCS8PrivateKey(block.Bytes)
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if err != nil {
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return nil, err
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}
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pk, ok := signer.(crypto.Signer)
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if !ok {
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return nil, fmt.Errorf("private key is not a valid format")
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}
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return pk, nil
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default:
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return nil, fmt.Errorf("unknown PEM block type for signing key: %s", block.Type)
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}
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}
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// ParseCSR parses a CSR from a PEM-encoded value. The certificate request
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// must be the the first block in the PEM value.
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func ParseCSR(pemValue string) (*x509.CertificateRequest, error) {
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// The _ result below is not an error but the remaining PEM bytes.
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block, _ := pem.Decode([]byte(pemValue))
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if block == nil {
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return nil, fmt.Errorf("no PEM-encoded data found")
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}
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if block.Type != "CERTIFICATE REQUEST" {
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return nil, fmt.Errorf("first PEM-block should be CERTIFICATE REQUEST type")
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}
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return x509.ParseCertificateRequest(block.Bytes)
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}
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// KeyId returns a x509 KeyId from the given signing key. The key must be
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// an *ecdsa.PublicKey currently, but may support more types in the future.
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func KeyId(raw interface{}) ([]byte, error) {
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switch raw.(type) {
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case *ecdsa.PublicKey:
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case *rsa.PublicKey:
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default:
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return nil, fmt.Errorf("invalid key type: %T", raw)
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}
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// This is not standard; RFC allows any unique identifier as long as they
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// match in subject/authority chains but suggests specific hashing of DER
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// bytes of public key including DER tags.
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bs, err := x509.MarshalPKIXPublicKey(raw)
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if err != nil {
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return nil, err
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}
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kID := sha256.Sum256(bs)
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return kID[:], nil
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}
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// EncodeSerialNumber encodes the given serial number as a colon-hex encoded
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// string.
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func EncodeSerialNumber(serial *big.Int) string {
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return HexString(serial.Bytes())
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}
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// EncodeSigningKeyID encodes the given AuthorityKeyId or SubjectKeyId into a
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// colon-hex encoded string suitable for using as a SigningKeyID value.
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func EncodeSigningKeyID(keyID []byte) string { return HexString(keyID) }
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// HexString returns a standard colon-separated hex value for the input
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// byte slice. This should be used with cert serial numbers and so on.
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func HexString(input []byte) string {
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return strings.Replace(fmt.Sprintf("% x", input), " ", ":", -1)
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}
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// IsHexString returns true if the input is the output of HexString(). Meant
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// for use in tests.
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func IsHexString(input []byte) bool {
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s := string(input)
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if strings.Count(s, ":") < 5 { // 5 is arbitrary
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return false
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}
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s = strings.ReplaceAll(s, ":", "")
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_, err := hex.DecodeString(s)
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return err == nil
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}
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// KeyInfoFromCert returns the key type and key bit length for the key used by
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// the certificate.
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func KeyInfoFromCert(cert *x509.Certificate) (keyType string, keyBits int, err error) {
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switch k := cert.PublicKey.(type) {
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case *ecdsa.PublicKey:
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return "ec", k.Curve.Params().BitSize, nil
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case *rsa.PublicKey:
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return "rsa", k.N.BitLen(), nil
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default:
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return "", 0, fmt.Errorf("unsupported key type")
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}
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}
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