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// SPDX-License-Identifier: BSD-3-Clause
// Copyright (c) 1999-2010 Brian Wellington ([email protected])
package com.couchbase.client.core.deps.org.xbill.DNS;
import java.io.IOException;
import java.math.BigInteger;
import java.security.GeneralSecurityException;
import java.security.KeyFactory;
import java.security.MessageDigest;
import java.security.NoSuchAlgorithmException;
import java.security.PrivateKey;
import java.security.PublicKey;
import java.security.Signature;
import java.security.interfaces.DSAPublicKey;
import java.security.interfaces.ECPublicKey;
import java.security.interfaces.RSAPublicKey;
import java.security.spec.DSAPublicKeySpec;
import java.security.spec.ECFieldFp;
import java.security.spec.ECParameterSpec;
import java.security.spec.ECPoint;
import java.security.spec.ECPublicKeySpec;
import java.security.spec.EllipticCurve;
import java.security.spec.RSAPublicKeySpec;
import java.security.spec.X509EncodedKeySpec;
import java.time.Instant;
import java.util.Arrays;
import java.util.Date;
/**
* Constants and methods relating to DNSSEC.
*
* DNSSEC provides authentication for DNS information.
*
* @see RRSIGRecord
* @see DNSKEYRecord
* @see RRset
* @author Brian Wellington
*/
public class DNSSEC {
/** Domain Name System Security (DNSSEC) Algorithm Numbers. */
public static class Algorithm {
private Algorithm() {}
/**
* Delete DS record in parent zone, RFC8078.
*
* @since 3.5
*/
public static final int DELETE = 0;
/** RSA/MD5 public key (deprecated) */
public static final int RSAMD5 = 1;
/** Diffie Hellman key */
public static final int DH = 2;
/** DSA public key */
public static final int DSA = 3;
/** RSA/SHA1 public key */
public static final int RSASHA1 = 5;
/** DSA/SHA1, NSEC3-aware public key */
public static final int DSA_NSEC3_SHA1 = 6;
/** RSA/SHA1, NSEC3-aware public key */
public static final int RSA_NSEC3_SHA1 = 7;
/** RSA/SHA256 public key */
public static final int RSASHA256 = 8;
/** RSA/SHA512 public key */
public static final int RSASHA512 = 10;
/** GOST R 34.10-2001. This requires an external cryptography provider, such as BouncyCastle. */
public static final int ECC_GOST = 12;
/** ECDSA Curve P-256 with SHA-256 public key * */
public static final int ECDSAP256SHA256 = 13;
/** ECDSA Curve P-384 with SHA-384 public key * */
public static final int ECDSAP384SHA384 = 14;
/** Edwards-Curve Digital Security Algorithm (EdDSA) for DNSSEC, RFC8080 */
public static final int ED25519 = 15;
/** Edwards-Curve Digital Security Algorithm (EdDSA) for DNSSEC, RFC8080 */
public static final int ED448 = 16;
/** Indirect keys; the actual key is elsewhere. */
public static final int INDIRECT = 252;
/** Private algorithm, specified by domain name */
public static final int PRIVATEDNS = 253;
/** Private algorithm, specified by OID */
public static final int PRIVATEOID = 254;
private static final Mnemonic algs = new Mnemonic("DNSSEC algorithm", Mnemonic.CASE_UPPER);
static {
algs.setMaximum(0xFF);
algs.setNumericAllowed(true);
algs.add(DELETE, "DELETE");
algs.add(RSAMD5, "RSAMD5");
algs.add(DH, "DH");
algs.add(DSA, "DSA");
algs.add(RSASHA1, "RSASHA1");
algs.add(DSA_NSEC3_SHA1, "DSA-NSEC3-SHA1");
algs.add(RSA_NSEC3_SHA1, "RSA-NSEC3-SHA1");
algs.add(RSASHA256, "RSASHA256");
algs.add(RSASHA512, "RSASHA512");
algs.add(ECC_GOST, "ECC-GOST");
algs.add(ECDSAP256SHA256, "ECDSAP256SHA256");
algs.add(ECDSAP384SHA384, "ECDSAP384SHA384");
algs.add(ED25519, "ED25519");
algs.add(ED448, "ED448");
algs.add(INDIRECT, "INDIRECT");
algs.add(PRIVATEDNS, "PRIVATEDNS");
algs.add(PRIVATEOID, "PRIVATEOID");
}
/** Converts an algorithm into its textual representation */
public static String string(int alg) {
return algs.getText(alg);
}
/**
* Converts a textual representation of an algorithm into its numeric code. Integers in the
* range 0..255 are also accepted.
*
* @param s The textual representation of the algorithm
* @return The algorithm code, or -1 on error.
*/
public static int value(String s) {
return algs.getValue(s);
}
}
/**
* DNSSEC Delegation Signer (DS) Resource Record (RR) Type Digest Algorithms.
*
* @since 3.5
*/
public static class Digest {
private Digest() {}
/** SHA-1, RFC3658. */
public static final int SHA1 = 1;
/** SHA-256, RFC4509. */
public static final int SHA256 = 2;
/** GOST R 34.11-94, RFC5933. */
public static final int GOST3411 = 3;
/** SHA-384, RFC6605. */
public static final int SHA384 = 4;
private static final Mnemonic algs =
new Mnemonic("DNSSEC Digest Algorithm", Mnemonic.CASE_UPPER);
static {
algs.setMaximum(0xFF);
algs.setNumericAllowed(true);
algs.add(SHA1, "SHA-1");
algs.add(SHA256, "SHA-256");
algs.add(GOST3411, "GOST R 34.11-94");
algs.add(SHA384, "SHA-384");
}
/** Converts an algorithm into its textual representation */
public static String string(int alg) {
return algs.getText(alg);
}
/**
* Converts a textual representation of an algorithm into its numeric code. Integers in the
* range 0..255 are also accepted.
*
* @param s The textual representation of the algorithm
* @return The algorithm code, or -1 on error.
*/
public static int value(String s) {
return algs.getValue(s);
}
}
private DNSSEC() {}
private static void digestSIG(DNSOutput out, SIGBase sig) {
out.writeU16(sig.getTypeCovered());
out.writeU8(sig.getAlgorithm());
out.writeU8(sig.getLabels());
out.writeU32(sig.getOrigTTL());
out.writeU32(sig.getExpire().getEpochSecond());
out.writeU32(sig.getTimeSigned().getEpochSecond());
out.writeU16(sig.getFootprint());
sig.getSigner().toWireCanonical(out);
}
/**
* Creates a byte array containing the concatenation of the fields of the SIG record and the
* RRsets to be signed/verified. This does not perform a cryptographic digest.
*
* @param rrsig The RRSIG record used to sign/verify the rrset.
* @param rrset The data to be signed/verified.
* @return The data to be cryptographically signed or verified.
*/
public static byte[] digestRRset(RRSIGRecord rrsig, RRset rrset) {
DNSOutput out = new DNSOutput();
digestSIG(out, rrsig);
Name name = rrset.getName();
Name wild = null;
int sigLabels = rrsig.getLabels() + 1; // Add the root label back.
if (name.labels() > sigLabels) {
wild = name.wild(name.labels() - sigLabels);
}
DNSOutput header = new DNSOutput();
if (wild != null) {
wild.toWireCanonical(header);
} else {
name.toWireCanonical(header);
}
header.writeU16(rrset.getType());
header.writeU16(rrset.getDClass());
header.writeU32(rrsig.getOrigTTL());
rrset.rrs(false).stream()
.sorted()
.forEachOrdered(
r -> {
out.writeByteArray(header.toByteArray());
int lengthPosition = out.current();
out.writeU16(0);
r.rrToWire(out, null, true);
int rrlength = out.current() - lengthPosition - 2;
out.save();
out.jump(lengthPosition);
out.writeU16(rrlength);
out.restore();
});
return out.toByteArray();
}
/**
* Creates a byte array containing the concatenation of the fields of the SIG(0) record and the
* message to be signed. This does not perform a cryptographic digest.
*
* @param sig The SIG record used to sign the rrset.
* @param msg The message to be signed.
* @param previous If this is a response, the signature from the query.
* @return The data to be cryptographically signed.
*/
public static byte[] digestMessage(SIGRecord sig, Message msg, byte[] previous) {
DNSOutput out = new DNSOutput();
digestSIG(out, sig);
if (previous != null) {
out.writeByteArray(previous);
}
msg.toWire(out);
return out.toByteArray();
}
/** A DNSSEC exception. */
public static class DNSSECException extends Exception {
DNSSECException(String message, Throwable cause) {
super(message, cause);
}
DNSSECException(Throwable cause) {
super(cause);
}
DNSSECException(String message) {
super(message);
}
}
/** An algorithm is unsupported by this DNSSEC implementation. */
public static class UnsupportedAlgorithmException extends DNSSECException {
UnsupportedAlgorithmException(int alg) {
super("Unsupported algorithm: " + alg);
}
}
/** The cryptographic data in a DNSSEC key is malformed. */
public static class MalformedKeyException extends DNSSECException {
MalformedKeyException(String message) {
super(message);
}
MalformedKeyException(Record rec, Throwable cause) {
super("Invalid key data: " + rec.rdataToString(), cause);
}
}
/** A DNSSEC verification failed because fields in the DNSKEY and RRSIG records do not match. */
public static class KeyMismatchException extends DNSSECException {
KeyMismatchException(KEYBase key, SIGBase sig) {
super(
"key "
+ key.getName()
+ "/"
+ DNSSEC.Algorithm.string(key.getAlgorithm())
+ "/"
+ key.getFootprint()
+ " "
+ "does not match signature "
+ sig.getSigner()
+ "/"
+ DNSSEC.Algorithm.string(sig.getAlgorithm())
+ "/"
+ sig.getFootprint());
}
}
/** A DNSSEC verification failed because the signature has expired. */
public static class SignatureExpiredException extends DNSSECException {
private final Instant when;
private final Instant now;
SignatureExpiredException(Instant when, Instant now) {
super("signature expired");
this.when = when;
this.now = now;
}
/** @return When the signature expired */
public Instant getExpiration() {
return when;
}
/** @return When the verification was attempted */
public Instant getVerifyTime() {
return now;
}
}
/** A DNSSEC verification failed because the signature has not yet become valid. */
public static class SignatureNotYetValidException extends DNSSECException {
private final Instant when;
private final Instant now;
SignatureNotYetValidException(Instant when, Instant now) {
super("signature is not yet valid");
this.when = when;
this.now = now;
}
/** @return When the signature will become valid */
public Instant getExpiration() {
return when;
}
/** @return When the verification was attempted */
public Instant getVerifyTime() {
return now;
}
}
/** A DNSSEC verification failed because the cryptographic signature verification failed. */
public static class SignatureVerificationException extends DNSSECException {
SignatureVerificationException() {
super("signature verification failed");
}
}
/** The key data provided is inconsistent. */
public static class IncompatibleKeyException extends IllegalArgumentException {
IncompatibleKeyException() {
super("incompatible keys");
}
}
/** No signature was found. */
public static class NoSignatureException extends DNSSECException {
NoSignatureException() {
super("no signature found");
}
}
private static int bigIntegerLength(BigInteger i) {
return (i.bitLength() + 7) / 8;
}
private static BigInteger readBigInteger(DNSInput in, int len) throws IOException {
byte[] b = in.readByteArray(len);
return new BigInteger(1, b);
}
private static BigInteger readBigInteger(DNSInput in) {
byte[] b = in.readByteArray();
return new BigInteger(1, b);
}
private static byte[] trimByteArray(byte[] array) {
if (array[0] == 0) {
byte[] trimmedArray = new byte[array.length - 1];
System.arraycopy(array, 1, trimmedArray, 0, array.length - 1);
return trimmedArray;
} else {
return array;
}
}
private static void reverseByteArray(byte[] array) {
for (int i = 0; i < array.length / 2; i++) {
int j = array.length - i - 1;
byte tmp = array[i];
array[i] = array[j];
array[j] = tmp;
}
}
private static BigInteger readBigIntegerLittleEndian(DNSInput in, int len) throws IOException {
byte[] b = in.readByteArray(len);
reverseByteArray(b);
return new BigInteger(1, b);
}
private static void writeBigInteger(DNSOutput out, BigInteger val) {
byte[] b = trimByteArray(val.toByteArray());
out.writeByteArray(b);
}
private static void writePaddedBigInteger(DNSOutput out, BigInteger val, int len) {
byte[] b = trimByteArray(val.toByteArray());
if (b.length > len) {
throw new IllegalArgumentException();
}
if (b.length < len) {
byte[] pad = new byte[len - b.length];
out.writeByteArray(pad);
}
out.writeByteArray(b);
}
private static void writePaddedBigIntegerLittleEndian(DNSOutput out, BigInteger val, int len) {
byte[] b = trimByteArray(val.toByteArray());
if (b.length > len) {
throw new IllegalArgumentException();
}
reverseByteArray(b);
out.writeByteArray(b);
if (b.length < len) {
byte[] pad = new byte[len - b.length];
out.writeByteArray(pad);
}
}
private static PublicKey toRSAPublicKey(byte[] key) throws IOException, GeneralSecurityException {
DNSInput in = new DNSInput(key);
int exponentLength = in.readU8();
if (exponentLength == 0) {
exponentLength = in.readU16();
}
BigInteger exponent = readBigInteger(in, exponentLength);
BigInteger modulus = readBigInteger(in);
KeyFactory factory = KeyFactory.getInstance("RSA");
return factory.generatePublic(new RSAPublicKeySpec(modulus, exponent));
}
private static PublicKey toDSAPublicKey(byte[] key)
throws IOException, GeneralSecurityException, MalformedKeyException {
DNSInput in = new DNSInput(key);
int t = in.readU8();
if (t > 8) {
throw new MalformedKeyException("t is too large");
}
BigInteger q = readBigInteger(in, 20);
BigInteger p = readBigInteger(in, 64 + t * 8);
BigInteger g = readBigInteger(in, 64 + t * 8);
BigInteger y = readBigInteger(in, 64 + t * 8);
KeyFactory factory = KeyFactory.getInstance("DSA");
return factory.generatePublic(new DSAPublicKeySpec(y, p, q, g));
}
private static class ECKeyInfo {
int length;
EllipticCurve curve;
ECParameterSpec spec;
ECKeyInfo(int length, String p, String a, String b, String gx, String gy, String n) {
this.length = length;
BigInteger pi = new BigInteger(p, 16);
BigInteger ai = new BigInteger(a, 16);
BigInteger bi = new BigInteger(b, 16);
BigInteger gxi = new BigInteger(gx, 16);
BigInteger gyi = new BigInteger(gy, 16);
BigInteger ni = new BigInteger(n, 16);
curve = new EllipticCurve(new ECFieldFp(pi), ai, bi);
spec = new ECParameterSpec(curve, new ECPoint(gxi, gyi), ni, 1);
}
}
// RFC 4357 Section 11.4
private static final ECKeyInfo GOST =
new ECKeyInfo(
32,
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFD97",
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFD94",
"A6",
"1",
"8D91E471E0989CDA27DF505A453F2B7635294F2DDF23E3B122ACC99C9E9F1E14",
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF6C611070995AD10045841B09B761B893");
// RFC 5114 Section 2.6
private static final ECKeyInfo ECDSA_P256 =
new ECKeyInfo(
32,
"FFFFFFFF00000001000000000000000000000000FFFFFFFFFFFFFFFFFFFFFFFF",
"FFFFFFFF00000001000000000000000000000000FFFFFFFFFFFFFFFFFFFFFFFC",
"5AC635D8AA3A93E7B3EBBD55769886BC651D06B0CC53B0F63BCE3C3E27D2604B",
"6B17D1F2E12C4247F8BCE6E563A440F277037D812DEB33A0F4A13945D898C296",
"4FE342E2FE1A7F9B8EE7EB4A7C0F9E162BCE33576B315ECECBB6406837BF51F5",
"FFFFFFFF00000000FFFFFFFFFFFFFFFFBCE6FAADA7179E84F3B9CAC2FC632551");
// RFC 5114 Section 2.7
private static final ECKeyInfo ECDSA_P384 =
new ECKeyInfo(
48,
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFFFF0000000000000000FFFFFFFF",
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFFFF0000000000000000FFFFFFFC",
"B3312FA7E23EE7E4988E056BE3F82D19181D9C6EFE8141120314088F5013875AC656398D8A2ED19D2A85C8EDD3EC2AEF",
"AA87CA22BE8B05378EB1C71EF320AD746E1D3B628BA79B9859F741E082542A385502F25DBF55296C3A545E3872760AB7",
"3617DE4A96262C6F5D9E98BF9292DC29F8F41DBD289A147CE9DA3113B5F0B8C00A60B1CE1D7E819D7A431D7C90EA0E5F",
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFC7634D81F4372DDF581A0DB248B0A77AECEC196ACCC52973");
private static PublicKey toECGOSTPublicKey(byte[] key, ECKeyInfo keyinfo)
throws IOException, GeneralSecurityException {
DNSInput in = new DNSInput(key);
BigInteger x = readBigIntegerLittleEndian(in, keyinfo.length);
BigInteger y = readBigIntegerLittleEndian(in, keyinfo.length);
ECPoint q = new ECPoint(x, y);
KeyFactory factory = KeyFactory.getInstance("ECGOST3410");
return factory.generatePublic(new ECPublicKeySpec(q, keyinfo.spec));
}
private static PublicKey toECDSAPublicKey(byte[] key, ECKeyInfo keyinfo)
throws IOException, GeneralSecurityException {
DNSInput in = new DNSInput(key);
// RFC 6605 Section 4
BigInteger x = readBigInteger(in, keyinfo.length);
BigInteger y = readBigInteger(in, keyinfo.length);
ECPoint q = new ECPoint(x, y);
KeyFactory factory = KeyFactory.getInstance("EC");
return factory.generatePublic(new ECPublicKeySpec(q, keyinfo.spec));
}
private static PublicKey toEdDSAPublicKey(byte[] key, byte algId)
throws GeneralSecurityException {
// Key is encoded as plain octets, rfc8080#section-3
// wrap it in ASN.1 format so we can use X509EncodedKeySpec to read it as JCA
byte[] encoded = new byte[12 + key.length];
encoded[0] = ASN1_SEQ;
encoded[1] = (byte) (10 + key.length); // length
encoded[2] = ASN1_SEQ;
encoded[3] = 5; // length
encoded[4] = ASN1_OID; // OID
encoded[5] = 3; // length
encoded[6] = 0x2b; // iso.org
encoded[7] = 0x65; // 101 thawte
encoded[8] = algId;
encoded[9] = ASN1_BITSTRING; // sequence
encoded[10] = (byte) (key.length + 1); // length
System.arraycopy(key, 0, encoded, 12, key.length);
X509EncodedKeySpec keySpec = new X509EncodedKeySpec(encoded);
KeyFactory keyFactory = KeyFactory.getInstance("EdDSA");
return keyFactory.generatePublic(keySpec);
}
/** Converts a KEY/DNSKEY record into a PublicKey */
static PublicKey toPublicKey(KEYBase r) throws DNSSECException {
return toPublicKey(r.getAlgorithm(), r.getKey(), r);
}
/** Converts a KEY/DNSKEY record into a PublicKey */
static PublicKey toPublicKey(int alg, byte[] key, Record r) throws DNSSECException {
try {
switch (alg) {
case Algorithm.RSAMD5:
case Algorithm.RSASHA1:
case Algorithm.RSA_NSEC3_SHA1:
case Algorithm.RSASHA256:
case Algorithm.RSASHA512:
return toRSAPublicKey(key);
case Algorithm.DSA:
case Algorithm.DSA_NSEC3_SHA1:
return toDSAPublicKey(key);
case Algorithm.ECC_GOST:
return toECGOSTPublicKey(key, GOST);
case Algorithm.ECDSAP256SHA256:
return toECDSAPublicKey(key, ECDSA_P256);
case Algorithm.ECDSAP384SHA384:
return toECDSAPublicKey(key, ECDSA_P384);
case Algorithm.ED25519:
return toEdDSAPublicKey(key, (byte) 112);
case Algorithm.ED448:
return toEdDSAPublicKey(key, (byte) 113);
default:
throw new UnsupportedAlgorithmException(alg);
}
} catch (IOException e) {
throw new MalformedKeyException(r, e);
} catch (GeneralSecurityException e) {
throw new DNSSECException(e);
}
}
private static byte[] fromRSAPublicKey(RSAPublicKey key) {
DNSOutput out = new DNSOutput();
BigInteger exponent = key.getPublicExponent();
BigInteger modulus = key.getModulus();
int exponentLength = bigIntegerLength(exponent);
if (exponentLength < 256) {
out.writeU8(exponentLength);
} else {
out.writeU8(0);
out.writeU16(exponentLength);
}
writeBigInteger(out, exponent);
writeBigInteger(out, modulus);
return out.toByteArray();
}
private static byte[] fromDSAPublicKey(DSAPublicKey key) {
DNSOutput out = new DNSOutput();
BigInteger q = key.getParams().getQ();
BigInteger p = key.getParams().getP();
BigInteger g = key.getParams().getG();
BigInteger y = key.getY();
int t = (p.toByteArray().length - 64) / 8;
out.writeU8(t);
writeBigInteger(out, q);
writeBigInteger(out, p);
writePaddedBigInteger(out, g, 8 * t + 64);
writePaddedBigInteger(out, y, 8 * t + 64);
return out.toByteArray();
}
private static byte[] fromECGOSTPublicKey(ECPublicKey key, ECKeyInfo keyinfo) {
DNSOutput out = new DNSOutput();
BigInteger x = key.getW().getAffineX();
BigInteger y = key.getW().getAffineY();
writePaddedBigIntegerLittleEndian(out, x, keyinfo.length);
writePaddedBigIntegerLittleEndian(out, y, keyinfo.length);
return out.toByteArray();
}
private static byte[] fromECDSAPublicKey(ECPublicKey key, ECKeyInfo keyinfo) {
DNSOutput out = new DNSOutput();
BigInteger x = key.getW().getAffineX();
BigInteger y = key.getW().getAffineY();
writePaddedBigInteger(out, x, keyinfo.length);
writePaddedBigInteger(out, y, keyinfo.length);
return out.toByteArray();
}
private static byte[] fromEdDSAPublicKey(PublicKey key) {
// The key is a signed DER BitString, starting at index 10. Drop the leading zero if necessary
byte[] encoded = key.getEncoded();
return Arrays.copyOfRange(encoded, 12, encoded.length);
}
/** Builds a DNSKEY record from a PublicKey */
static byte[] fromPublicKey(PublicKey key, int alg) throws DNSSECException {
switch (alg) {
case Algorithm.RSAMD5:
case Algorithm.RSASHA1:
case Algorithm.RSA_NSEC3_SHA1:
case Algorithm.RSASHA256:
case Algorithm.RSASHA512:
if (!(key instanceof RSAPublicKey)) {
throw new IncompatibleKeyException();
}
return fromRSAPublicKey((RSAPublicKey) key);
case Algorithm.DSA:
case Algorithm.DSA_NSEC3_SHA1:
if (!(key instanceof DSAPublicKey)) {
throw new IncompatibleKeyException();
}
return fromDSAPublicKey((DSAPublicKey) key);
case Algorithm.ECC_GOST:
if (!(key instanceof ECPublicKey)) {
throw new IncompatibleKeyException();
}
return fromECGOSTPublicKey((ECPublicKey) key, GOST);
case Algorithm.ECDSAP256SHA256:
if (!(key instanceof ECPublicKey)) {
throw new IncompatibleKeyException();
}
return fromECDSAPublicKey((ECPublicKey) key, ECDSA_P256);
case Algorithm.ECDSAP384SHA384:
if (!(key instanceof ECPublicKey)) {
throw new IncompatibleKeyException();
}
return fromECDSAPublicKey((ECPublicKey) key, ECDSA_P384);
case Algorithm.ED25519:
case Algorithm.ED448:
if (!key.getFormat().equalsIgnoreCase("X.509")) {
throw new IncompatibleKeyException();
}
return fromEdDSAPublicKey(key);
default:
throw new UnsupportedAlgorithmException(alg);
}
}
/**
* Convert an algorithm number to the corresponding JCA string.
*
* @param alg The algorithm number.
* @throws UnsupportedAlgorithmException The algorithm is unknown.
*/
public static String algString(int alg) throws UnsupportedAlgorithmException {
switch (alg) {
case Algorithm.RSAMD5:
return "MD5withRSA";
case Algorithm.DSA:
case Algorithm.DSA_NSEC3_SHA1:
return "SHA1withDSA";
case Algorithm.RSASHA1:
case Algorithm.RSA_NSEC3_SHA1:
return "SHA1withRSA";
case Algorithm.RSASHA256:
return "SHA256withRSA";
case Algorithm.RSASHA512:
return "SHA512withRSA";
case Algorithm.ECC_GOST:
return "GOST3411withECGOST3410";
case Algorithm.ECDSAP256SHA256:
return "SHA256withECDSA";
case Algorithm.ECDSAP384SHA384:
return "SHA384withECDSA";
case Algorithm.ED25519:
return "Ed25519";
case Algorithm.ED448:
return "Ed448";
default:
throw new UnsupportedAlgorithmException(alg);
}
}
static final int ASN1_SEQ = 0x30;
static final int ASN1_INT = 0x2;
static final int ASN1_BITSTRING = 0x3;
static final int ASN1_OID = 0x6;
private static final int DSA_LEN = 20;
private static IOException asn1ParseException(Object expected, Object actual) {
return new IOException("Invalid ASN.1 data, expected " + expected + " got " + actual);
}
private static byte[] dsaSignatureFromDNS(byte[] signature, int keyLength, boolean skipT)
throws DNSSECException, IOException {
if (signature.length != keyLength * 2 + (skipT ? 1 : 0)) {
throw new SignatureVerificationException();
}
DNSInput in = new DNSInput(signature);
DNSOutput out = new DNSOutput();
if (skipT) {
// rfc2536#section-3, this applies to DSA only, not ECDSA
in.readU8();
}
byte[] r = in.readByteArray(keyLength);
int rlen = getDsaIntLen(r, keyLength);
byte[] s = in.readByteArray(keyLength);
int slen = getDsaIntLen(s, keyLength);
out.writeU8(ASN1_SEQ);
out.writeU8(rlen + slen + 4);
writeAsn1Int(keyLength, out, r, rlen);
writeAsn1Int(keyLength, out, s, slen);
return out.toByteArray();
}
private static int getDsaIntLen(byte[] bigint, int dsaLen) {
int len = dsaLen;
if (bigint[0] < 0) {
len++;
} else {
for (int i = 0; i < dsaLen - 1 && bigint[i] == 0 && bigint[i + 1] >= 0; i++) {
len--;
}
}
return len;
}
private static void writeAsn1Int(int keyLength, DNSOutput out, byte[] bigint, int bigintLen) {
out.writeU8(ASN1_INT);
out.writeU8(bigintLen);
if (bigintLen > keyLength) {
out.writeU8(0);
}
if (bigintLen >= keyLength) {
out.writeByteArray(bigint);
} else {
out.writeByteArray(bigint, keyLength - bigintLen, bigintLen);
}
}
private static byte[] dsaSignatureToDNS(byte[] signature, int rsLen, int t) throws IOException {
DNSInput in = new DNSInput(signature);
DNSOutput out = new DNSOutput();
if (t > -1) {
out.writeU8(t);
}
int tmp = in.readU8();
if (tmp != ASN1_SEQ) {
throw asn1ParseException(ASN1_SEQ, tmp);
}
/*int seqlen =*/ in.readU8();
transformAns1IntToDns(rsLen, in, out);
transformAns1IntToDns(rsLen, in, out);
return out.toByteArray();
}
private static void transformAns1IntToDns(int rsLen, DNSInput in, DNSOutput out)
throws IOException {
int tmp = in.readU8();
if (tmp != ASN1_INT) {
throw asn1ParseException(ASN1_INT, tmp);
}
// the int must be of rsLen or +1 if it has a leading zero for negative
// ASN.1 integers
int len = in.readU8();
if (len == rsLen + 1 && in.readU8() == 0) {
--len;
} else if (len <= rsLen) {
// pad with leading zeros, rfc2536#section-3
for (int i = 0; i < rsLen - len; i++) {
out.writeU8(0);
}
} else {
throw new IOException("Invalid r/s-value in ASN.1 DER encoded signature: " + len);
}
out.writeByteArray(in.readByteArray(len));
}
private static void verify(PublicKey key, int alg, byte[] data, byte[] signature)
throws DNSSECException {
if (key instanceof DSAPublicKey) {
try {
signature = dsaSignatureFromDNS(signature, DSA_LEN, true);
} catch (IOException e) {
throw new IllegalStateException();
}
} else if (key instanceof ECPublicKey) {
try {
switch (alg) {
case Algorithm.ECC_GOST:
// Wire format is equal to the engine input
if (signature.length != GOST.length * 2) {
throw new SignatureVerificationException();
}
break;
case Algorithm.ECDSAP256SHA256:
signature = dsaSignatureFromDNS(signature, ECDSA_P256.length, false);
break;
case Algorithm.ECDSAP384SHA384:
signature = dsaSignatureFromDNS(signature, ECDSA_P384.length, false);
break;
default:
throw new UnsupportedAlgorithmException(alg);
}
} catch (IOException e) {
throw new IllegalStateException();
}
}
try {
Signature s = Signature.getInstance(algString(alg));
s.initVerify(key);
s.update(data);
if (!s.verify(signature)) {
throw new SignatureVerificationException();
}
} catch (GeneralSecurityException e) {
throw new DNSSECException(e);
}
}
private static boolean matches(SIGBase sig, KEYBase key) {
return key.getAlgorithm() == sig.getAlgorithm()
&& key.getFootprint() == sig.getFootprint()
&& key.getName().equals(sig.getSigner());
}
/**
* Verify a DNSSEC signature.
*
* @param rrset The data to be verified.
* @param rrsig The RRSIG record containing the signature.
* @param key The DNSKEY record to verify the signature with.
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws KeyMismatchException The key and signature do not match
* @throws SignatureExpiredException The signature has expired
* @throws SignatureNotYetValidException The signature is not yet valid
* @throws SignatureVerificationException The signature does not verify.
* @throws DNSSECException Some other error occurred.
*/
public static void verify(RRset rrset, RRSIGRecord rrsig, DNSKEYRecord key)
throws DNSSECException {
verify(rrset, rrsig, key, Instant.now());
}
/**
* Verify a DNSSEC signature.
*
* @param rrset The data to be verified.
* @param rrsig The RRSIG record containing the signature.
* @param key The DNSKEY record to verify the signature with.
* @param date The date against which the signature is verified.
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws KeyMismatchException The key and signature do not match
* @throws SignatureExpiredException The signature has expired
* @throws SignatureNotYetValidException The signature is not yet valid
* @throws SignatureVerificationException The signature does not verify.
* @throws DNSSECException Some other error occurred.
* @deprecated use {@link #verify(RRset, RRSIGRecord, DNSKEYRecord, Instant)}
*/
@Deprecated
public static void verify(RRset rrset, RRSIGRecord rrsig, DNSKEYRecord key, Date date)
throws DNSSECException {
verify(rrset, rrsig, key, date.toInstant());
}
/**
* Verify a DNSSEC signature.
*
* @param rrset The data to be verified.
* @param rrsig The RRSIG record containing the signature.
* @param key The DNSKEY record to verify the signature with.
* @param date The date against which the signature is verified.
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws KeyMismatchException The key and signature do not match
* @throws SignatureExpiredException The signature has expired
* @throws SignatureNotYetValidException The signature is not yet valid
* @throws SignatureVerificationException The signature does not verify.
* @throws DNSSECException Some other error occurred.
*/
public static void verify(RRset rrset, RRSIGRecord rrsig, DNSKEYRecord key, Instant date)
throws DNSSECException {
if (!matches(rrsig, key)) {
throw new KeyMismatchException(key, rrsig);
}
if (date.compareTo(rrsig.getExpire()) > 0) {
throw new SignatureExpiredException(rrsig.getExpire(), date);
}
if (date.compareTo(rrsig.getTimeSigned()) < 0) {
throw new SignatureNotYetValidException(rrsig.getTimeSigned(), date);
}
verify(
key.getPublicKey(), rrsig.getAlgorithm(),
digestRRset(rrsig, rrset), rrsig.getSignature());
}
static byte[] sign(PrivateKey privkey, PublicKey pubkey, int alg, byte[] data, String provider)
throws DNSSECException {
byte[] signature;
try {
Signature s;
if (provider != null) {
s = Signature.getInstance(algString(alg), provider);
} else {
s = Signature.getInstance(algString(alg));
}
s.initSign(privkey);
s.update(data);
signature = s.sign();
} catch (GeneralSecurityException e) {
throw new DNSSECException(e);
}
if (pubkey instanceof DSAPublicKey) {
try {
DSAPublicKey dsa = (DSAPublicKey) pubkey;
BigInteger p = dsa.getParams().getP();
int t = (bigIntegerLength(p) - 64) / 8;
signature = dsaSignatureToDNS(signature, DSA_LEN, t);
} catch (IOException e) {
throw new IllegalStateException(e);
}
} else if (pubkey instanceof ECPublicKey) {
try {
switch (alg) {
case Algorithm.ECC_GOST:
// Wire format is equal to the engine output
break;
case Algorithm.ECDSAP256SHA256:
signature = dsaSignatureToDNS(signature, ECDSA_P256.length, -1);
break;
case Algorithm.ECDSAP384SHA384:
signature = dsaSignatureToDNS(signature, ECDSA_P384.length, -1);
break;
default:
throw new UnsupportedAlgorithmException(alg);
}
} catch (IOException e) {
throw new IllegalStateException(e);
}
}
return signature;
}
static void checkAlgorithm(PrivateKey key, int alg) throws UnsupportedAlgorithmException {
switch (alg) {
case Algorithm.RSAMD5:
case Algorithm.RSASHA1:
case Algorithm.RSA_NSEC3_SHA1:
case Algorithm.RSASHA256:
case Algorithm.RSASHA512:
if (!"RSA".equals(key.getAlgorithm())) {
throw new IncompatibleKeyException();
}
break;
case Algorithm.DSA:
case Algorithm.DSA_NSEC3_SHA1:
if (!"DSA".equals(key.getAlgorithm())) {
throw new IncompatibleKeyException();
}
break;
case Algorithm.ECC_GOST:
case Algorithm.ECDSAP256SHA256:
case Algorithm.ECDSAP384SHA384:
if (!"EC".equals(key.getAlgorithm()) && !"ECDSA".equals(key.getAlgorithm())) {
throw new IncompatibleKeyException();
}
break;
case Algorithm.ED25519:
if (!"Ed25519".equals(key.getAlgorithm()) && !"EdDSA".equals(key.getAlgorithm())) {
throw new IncompatibleKeyException();
}
break;
case Algorithm.ED448:
if (!"Ed448".equals(key.getAlgorithm()) && !"EdDSA".equals(key.getAlgorithm())) {
throw new IncompatibleKeyException();
}
break;
default:
throw new UnsupportedAlgorithmException(alg);
}
}
/**
* Generate a DNSSEC signature. key and privateKey must refer to the same underlying cryptographic
* key.
*
* @param rrset The data to be signed
* @param key The DNSKEY record to use as part of signing
* @param privkey The PrivateKey to use when signing
* @param inception The time at which the signatures should become valid
* @param expiration The time at which the signatures should expire
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws DNSSECException Some other error occurred.
* @return The generated signature
* @deprecated use {@link #sign(RRset, DNSKEYRecord, PrivateKey, Instant, Instant)}
*/
@Deprecated
public static RRSIGRecord sign(
RRset rrset, DNSKEYRecord key, PrivateKey privkey, Date inception, Date expiration)
throws DNSSECException {
return sign(rrset, key, privkey, inception.toInstant(), expiration.toInstant(), null);
}
/**
* Generate a DNSSEC signature. key and privateKey must refer to the same underlying cryptographic
* key.
*
* @param rrset The data to be signed
* @param key The DNSKEY record to use as part of signing
* @param privkey The PrivateKey to use when signing
* @param inception The time at which the signatures should become valid
* @param expiration The time at which the signatures should expire
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws DNSSECException Some other error occurred.
* @return The generated signature
* @deprecated use {@link #sign(RRset, DNSKEYRecord, PrivateKey, Instant, Instant, String)}
*/
@Deprecated
public static RRSIGRecord sign(
RRset rrset,
DNSKEYRecord key,
PrivateKey privkey,
Date inception,
Date expiration,
String provider)
throws DNSSECException {
return sign(rrset, key, privkey, inception.toInstant(), expiration.toInstant(), provider);
}
/**
* Generate a DNSSEC signature. key and privateKey must refer to the same underlying cryptographic
* key.
*
* @param rrset The data to be signed
* @param key The DNSKEY record to use as part of signing
* @param privkey The PrivateKey to use when signing
* @param inception The time at which the signatures should become valid
* @param expiration The time at which the signatures should expire
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws DNSSECException Some other error occurred.
* @return The generated signature
*/
public static RRSIGRecord sign(
RRset rrset, DNSKEYRecord key, PrivateKey privkey, Instant inception, Instant expiration)
throws DNSSECException {
return sign(rrset, key, privkey, inception, expiration, null);
}
/**
* Generate a DNSSEC signature. key and privateKey must refer to the same underlying cryptographic
* key.
*
* @param rrset The data to be signed
* @param key The DNSKEY record to use as part of signing
* @param privkey The PrivateKey to use when signing
* @param inception The time at which the signatures should become valid
* @param expiration The time at which the signatures should expire
* @param provider The name of the JCA provider. If non-null, it will be passed to JCA
* getInstance() methods.
* @throws UnsupportedAlgorithmException The algorithm is unknown
* @throws MalformedKeyException The key is malformed
* @throws DNSSECException Some other error occurred.
* @return The generated signature
*/
public static RRSIGRecord sign(
RRset rrset,
DNSKEYRecord key,
PrivateKey privkey,
Instant inception,
Instant expiration,
String provider)
throws DNSSECException {
int alg = key.getAlgorithm();
checkAlgorithm(privkey, alg);
RRSIGRecord rrsig =
new RRSIGRecord(
rrset.getName(),
rrset.getDClass(),
rrset.getTTL(),
rrset.getType(),
alg,
rrset.getTTL(),
expiration,
inception,
key.getFootprint(),
key.getName(),
null);
rrsig.setSignature(sign(privkey, key.getPublicKey(), alg, digestRRset(rrsig, rrset), provider));
return rrsig;
}
static SIGRecord signMessage(
Message message,
SIGRecord previous,
KEYRecord key,
PrivateKey privkey,
Instant inception,
Instant expiration)
throws DNSSECException {
int alg = key.getAlgorithm();
checkAlgorithm(privkey, alg);
SIGRecord sig =
new SIGRecord(
Name.root,
DClass.ANY,
0,
0,
alg,
0,
expiration,
inception,
key.getFootprint(),
key.getName(),
null);
DNSOutput out = new DNSOutput();
digestSIG(out, sig);
if (previous != null) {
out.writeByteArray(previous.getSignature());
}
out.writeByteArray(message.toWire());
sig.setSignature(sign(privkey, key.getPublicKey(), alg, out.toByteArray(), null));
return sig;
}
static void verifyMessage(
Message message, byte[] bytes, SIGRecord sig, SIGRecord previous, KEYRecord key, Instant now)
throws DNSSECException {
if (message.sig0start == 0) {
throw new NoSignatureException();
}
if (!matches(sig, key)) {
throw new KeyMismatchException(key, sig);
}
if (now.compareTo(sig.getExpire()) > 0) {
throw new SignatureExpiredException(sig.getExpire(), now);
}
if (now.compareTo(sig.getTimeSigned()) < 0) {
throw new SignatureNotYetValidException(sig.getTimeSigned(), now);
}
DNSOutput out = new DNSOutput();
digestSIG(out, sig);
if (previous != null) {
out.writeByteArray(previous.getSignature());
}
Header header = message.getHeader().clone();
header.decCount(Section.ADDITIONAL);
out.writeByteArray(header.toWire());
out.writeByteArray(bytes, Header.LENGTH, message.sig0start - Header.LENGTH);
verify(
key.getPublicKey(), sig.getAlgorithm(),
out.toByteArray(), sig.getSignature());
}
/**
* Generate the digest value for a DS key
*
* @param key Which is covered by the DS record
* @param digestid The type of digest
* @return The digest value as an array of bytes
*/
static byte[] generateDSDigest(DNSKEYRecord key, int digestid) {
MessageDigest digest;
try {
switch (digestid) {
case Digest.SHA1:
digest = MessageDigest.getInstance("sha-1");
break;
case Digest.SHA256:
digest = MessageDigest.getInstance("sha-256");
break;
case Digest.GOST3411:
digest = MessageDigest.getInstance("GOST3411");
break;
case Digest.SHA384:
digest = MessageDigest.getInstance("sha-384");
break;
default:
throw new IllegalArgumentException("unknown DS digest type " + digestid);
}
} catch (NoSuchAlgorithmException e) {
throw new IllegalStateException("no message digest support");
}
digest.update(key.getName().toWireCanonical());
digest.update(key.rdataToWireCanonical());
return digest.digest();
}
}