open-vault/helper/certutil/helpers.go

181 lines
5.3 KiB
Go

package certutil
import (
"bytes"
"crypto"
"crypto/sha1"
"crypto/x509"
"encoding/json"
"encoding/pem"
"fmt"
"strconv"
"strings"
"github.com/mitchellh/mapstructure"
)
// GetOctalFormatted returns the byte buffer formatted in octal with
// the specified separator between bytes.
// FIXME: where did I originally copy this code from? This ain't octal, it's hex.
func GetOctalFormatted(buf []byte, sep string) string {
var ret bytes.Buffer
for _, cur := range buf {
if ret.Len() > 0 {
fmt.Fprintf(&ret, sep)
}
fmt.Fprintf(&ret, "%02x", cur)
}
return ret.String()
}
func ParseHexFormatted(in, sep string) []byte {
var ret bytes.Buffer
var err error
var inBits int64
inBytes := strings.Split(in, sep)
for _, inByte := range inBytes {
if inBits, err = strconv.ParseInt(inByte, 16, 8); err != nil {
return nil
} else {
ret.WriteByte(byte(inBits))
}
}
return ret.Bytes()
}
// GetSubjKeyID returns the subject key ID, e.g. the SHA1 sum
// of the marshaled public key
func GetSubjKeyID(privateKey crypto.Signer) ([]byte, error) {
if privateKey == nil {
return nil, InternalError{"Passed-in private key is nil"}
}
marshaledKey, err := x509.MarshalPKIXPublicKey(privateKey.Public())
if err != nil {
return nil, InternalError{fmt.Sprintf("Error marshalling public key: %s", err)}
}
subjKeyID := sha1.Sum(marshaledKey)
return subjKeyID[:], nil
}
// ParsePKIMap takes a map (for instance, the Secret.Data
// returned from the PKI backend) and returns a ParsedCertBundle.
func ParsePKIMap(data map[string]interface{}) (*ParsedCertBundle, error) {
result := &CertBundle{}
err := mapstructure.Decode(data, result)
if err != nil {
return nil, UserError{err.Error()}
}
return result.ToParsedCertBundle()
}
// ParsePKIJSON takes a JSON-encoded string and returns a CertBundle
// ParsedCertBundle.
//
// This can be either the output of an
// issue call from the PKI backend or just its data member; or,
// JSON not coming from the PKI backend.
func ParsePKIJSON(input []byte) (*ParsedCertBundle, error) {
result := &CertBundle{}
err := json.Unmarshal(input, &result)
if err == nil {
return result.ToParsedCertBundle()
}
var secret Secret
err = json.Unmarshal(input, &secret)
if err == nil {
return ParsePKIMap(secret.Data)
}
return nil, UserError{"Unable to parse out of either secret data or a secret object"}
}
// ParsePEMBundle takes a string of concatenated PEM-format certificate
// and private key values and decodes/parses them, checking validity along
// the way. There must be at max two certificates (a certificate and its
// issuing certificate) and one private key.
func ParsePEMBundle(pemBundle string) (*ParsedCertBundle, error) {
if len(pemBundle) == 0 {
return nil, UserError{"Empty PEM bundle"}
}
pemBytes := []byte(pemBundle)
var pemBlock *pem.Block
parsedBundle := &ParsedCertBundle{}
for {
pemBlock, pemBytes = pem.Decode(pemBytes)
if pemBlock == nil {
return nil, UserError{"No data found"}
}
if signer, err := x509.ParseECPrivateKey(pemBlock.Bytes); err == nil {
if parsedBundle.PrivateKeyType != UnknownPrivateKey {
return nil, UserError{"More than one private key given; provide only one private key in the bundle"}
}
parsedBundle.PrivateKeyType = ECPrivateKey
parsedBundle.PrivateKeyBytes = pemBlock.Bytes
parsedBundle.PrivateKey = signer
} else if signer, err := x509.ParsePKCS1PrivateKey(pemBlock.Bytes); err == nil {
if parsedBundle.PrivateKeyType != UnknownPrivateKey {
return nil, UserError{"More than one private key given; provide only one private key in the bundle"}
}
parsedBundle.PrivateKeyType = RSAPrivateKey
parsedBundle.PrivateKeyBytes = pemBlock.Bytes
parsedBundle.PrivateKey = signer
} else if certificates, err := x509.ParseCertificates(pemBlock.Bytes); err == nil {
switch len(certificates) {
case 0:
return nil, UserError{"PEM block cannot be decoded to a private key or certificate"}
case 1:
if parsedBundle.Certificate != nil {
switch {
// We just found the issuing CA
case bytes.Equal(parsedBundle.Certificate.AuthorityKeyId, certificates[0].SubjectKeyId) && certificates[0].IsCA:
parsedBundle.IssuingCABytes = pemBlock.Bytes
parsedBundle.IssuingCA = certificates[0]
// Our saved certificate is actually the issuing CA
case bytes.Equal(parsedBundle.Certificate.SubjectKeyId, certificates[0].AuthorityKeyId) && parsedBundle.Certificate.IsCA:
parsedBundle.IssuingCA = parsedBundle.Certificate
parsedBundle.IssuingCABytes = parsedBundle.CertificateBytes
parsedBundle.CertificateBytes = pemBlock.Bytes
parsedBundle.Certificate = certificates[0]
}
} else {
switch {
// If this case isn't correct, the caller needs to assign
// the values to Certificate/CertificateBytes; assumptions
// made here will not be valid for all cases.
case certificates[0].IsCA:
parsedBundle.IssuingCABytes = pemBlock.Bytes
parsedBundle.IssuingCA = certificates[0]
default:
parsedBundle.CertificateBytes = pemBlock.Bytes
parsedBundle.Certificate = certificates[0]
}
}
default:
return nil, UserError{"Too many certificates given; provide a maximum of two certificates in the bundle"}
}
}
if len(pemBytes) == 0 {
break
}
}
return parsedBundle, nil
}