test/parallel/test-crypto-dh-curves.js - external/github.com/v8/node - Git at Google

 'use strict';
 const common = require('../common');
 if (!common.hasCrypto)
   common.skip('missing crypto');

 const assert = require('assert');
 const crypto = require('crypto');

 // Second OAKLEY group, see
 // https://github.com/nodejs/node-v0.x-archive/issues/2338 and
 // https://xml2rfc.tools.ietf.org/public/rfc/html/rfc2412.html#anchor49
 const p = 'FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E088A67CC74' +
           '020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B302B0A6DF25F1437' +
           '4FE1356D6D51C245E485B576625E7EC6F44C42E9A637ED6B0BFF5CB6F406B7ED' +
           'EE386BFB5A899FA5AE9F24117C4B1FE649286651ECE65381FFFFFFFFFFFFFFFF';
 crypto.createDiffieHellman(p, 'hex');

 // Confirm DH_check() results are exposed for optional examination.
 const bad_dh = crypto.createDiffieHellman('02', 'hex');
 assert.notStrictEqual(bad_dh.verifyError, 0);

 const availableCurves = new Set(crypto.getCurves());
 const availableHashes = new Set(crypto.getHashes());

 // Oakley curves do not clean up ERR stack, it was causing unexpected failure
 // when accessing other OpenSSL APIs afterwards.
 if (availableCurves.has('Oakley-EC2N-3')) {
   crypto.createECDH('Oakley-EC2N-3');
   crypto.createHash('sha256');
 }

 // Test ECDH
 if (availableCurves.has('prime256v1') && availableCurves.has('secp256k1')) {
   const ecdh1 = crypto.createECDH('prime256v1');
   const ecdh2 = crypto.createECDH('prime256v1');
   const key1 = ecdh1.generateKeys();
   const key2 = ecdh2.generateKeys('hex');
   const secret1 = ecdh1.computeSecret(key2, 'hex', 'base64');
   const secret2 = ecdh2.computeSecret(key1, 'latin1', 'buffer');

   assert.strictEqual(secret1, secret2.toString('base64'));

   // Point formats
   assert.strictEqual(ecdh1.getPublicKey('buffer', 'uncompressed')[0], 4);
   let firstByte = ecdh1.getPublicKey('buffer', 'compressed')[0];
   assert(firstByte === 2 || firstByte === 3);
   firstByte = ecdh1.getPublicKey('buffer', 'hybrid')[0];
   assert(firstByte === 6 || firstByte === 7);
   // Format value should be string

   assert.throws(
     () => ecdh1.getPublicKey('buffer', 10),
     {
       code: 'ERR_CRYPTO_ECDH_INVALID_FORMAT',
       name: 'TypeError',
       message: 'Invalid ECDH format: 10'
     });

   // ECDH should check that point is on curve
   const ecdh3 = crypto.createECDH('secp256k1');
   const key3 = ecdh3.generateKeys();

   assert.throws(
     () => ecdh2.computeSecret(key3, 'latin1', 'buffer'),
     {
       code: 'ERR_CRYPTO_ECDH_INVALID_PUBLIC_KEY',
       name: 'Error',
       message: 'Public key is not valid for specified curve'
     });

   // ECDH should allow .setPrivateKey()/.setPublicKey()
   const ecdh4 = crypto.createECDH('prime256v1');

   ecdh4.setPrivateKey(ecdh1.getPrivateKey());
   ecdh4.setPublicKey(ecdh1.getPublicKey());

   assert.throws(() => {
     ecdh4.setPublicKey(ecdh3.getPublicKey());
   }, { message: 'Failed to convert Buffer to EC_POINT' });

   // Verify that we can use ECDH without having to use newly generated keys.
   const ecdh5 = crypto.createECDH('secp256k1');

   // Verify errors are thrown when retrieving keys from an uninitialized object.
   assert.throws(() => {
     ecdh5.getPublicKey();
   }, /^Error: Failed to get ECDH public key$/);

   assert.throws(() => {
     ecdh5.getPrivateKey();
   }, /^Error: Failed to get ECDH private key$/);

   // A valid private key for the secp256k1 curve.
   const cafebabeKey = 'cafebabe'.repeat(8);
   // Associated compressed and uncompressed public keys (points).
   const cafebabePubPtComp =
   '03672a31bfc59d3f04548ec9b7daeeba2f61814e8ccc40448045007f5479f693a3';
   const cafebabePubPtUnComp =
   '04672a31bfc59d3f04548ec9b7daeeba2f61814e8ccc40448045007f5479f693a3' +
   '2e02c7f93d13dc2732b760ca377a5897b9dd41a1c1b29dc0442fdce6d0a04d1d';
   ecdh5.setPrivateKey(cafebabeKey, 'hex');
   assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
   // Show that the public point (key) is generated while setting the
   // private key.
   assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);

   // Compressed and uncompressed public points/keys for other party's
   // private key.
   // 0xDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEF
   const peerPubPtComp =
   '02c6b754b20826eb925e052ee2c25285b162b51fdca732bcf67e39d647fb6830ae';
   const peerPubPtUnComp =
   '04c6b754b20826eb925e052ee2c25285b162b51fdca732bcf67e39d647fb6830ae' +
   'b651944a574a362082a77e3f2b5d9223eb54d7f2f76846522bf75f3bedb8178e';

   const sharedSecret =
   '1da220b5329bbe8bfd19ceef5a5898593f411a6f12ea40f2a8eead9a5cf59970';

   assert.strictEqual(ecdh5.computeSecret(peerPubPtComp, 'hex', 'hex'),
                      sharedSecret);
   assert.strictEqual(ecdh5.computeSecret(peerPubPtUnComp, 'hex', 'hex'),
                      sharedSecret);

   // Verify that we still have the same key pair as before the computation.
   assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
   assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);

   // Verify setting and getting compressed and non-compressed serializations.
   ecdh5.setPublicKey(cafebabePubPtComp, 'hex');
   assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);
   assert.strictEqual(
     ecdh5.getPublicKey('hex', 'compressed'),
     cafebabePubPtComp
   );
   ecdh5.setPublicKey(cafebabePubPtUnComp, 'hex');
   assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);
   assert.strictEqual(
     ecdh5.getPublicKey('hex', 'compressed'),
     cafebabePubPtComp
   );

   // Show why allowing the public key to be set on this type
   // does not make sense.
   ecdh5.setPublicKey(peerPubPtComp, 'hex');
   assert.strictEqual(ecdh5.getPublicKey('hex'), peerPubPtUnComp);
   assert.throws(() => {
     // Error because the public key does not match the private key anymore.
     ecdh5.computeSecret(peerPubPtComp, 'hex', 'hex');
   }, /Invalid key pair/);

   // Set to a valid key to show that later attempts to set an invalid key are
   // rejected.
   ecdh5.setPrivateKey(cafebabeKey, 'hex');

   // Some invalid private keys for the secp256k1 curve.
   const errMessage = /Private key is not valid for specified curve/;
   ['0000000000000000000000000000000000000000000000000000000000000000',
    'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141',
    'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF',
   ].forEach((element) => {
     assert.throws(() => {
       ecdh5.setPrivateKey(element, 'hex');
     }, errMessage);
     // Verify object state did not change.
     assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
   });
 }

 // Use of invalid keys was not cleaning up ERR stack, and was causing
 // unexpected failure in subsequent signing operations.
 if (availableCurves.has('prime256v1') && availableHashes.has('sha256')) {
   const curve = crypto.createECDH('prime256v1');
   const invalidKey = Buffer.alloc(65);
   invalidKey.fill('\0');
   curve.generateKeys();
   assert.throws(
     () => curve.computeSecret(invalidKey),
     {
       code: 'ERR_CRYPTO_ECDH_INVALID_PUBLIC_KEY',
       name: 'Error',
       message: 'Public key is not valid for specified curve'
     });
   // Check that signing operations are not impacted by the above error.
   const ecPrivateKey =
     '-----BEGIN EC PRIVATE KEY-----\n' +
     'MHcCAQEEIF+jnWY1D5kbVYDNvxxo/Y+ku2uJPDwS0r/VuPZQrjjVoAoGCCqGSM49\n' +
     'AwEHoUQDQgAEurOxfSxmqIRYzJVagdZfMMSjRNNhB8i3mXyIMq704m2m52FdfKZ2\n' +
     'pQhByd5eyj3lgZ7m7jbchtdgyOF8Io/1ng==\n' +
     '-----END EC PRIVATE KEY-----';
   crypto.createSign('SHA256').sign(ecPrivateKey);
 }
	'use strict';
	const common = require('../common');
	if (!common.hasCrypto)
	common.skip('missing crypto');

	const assert = require('assert');
	const crypto = require('crypto');

	// Second OAKLEY group, see
	// https://github.com/nodejs/node-v0.x-archive/issues/2338 and
	// https://xml2rfc.tools.ietf.org/public/rfc/html/rfc2412.html#anchor49
	const p = 'FFFFFFFFFFFFFFFFC90FDAA22168C234C4C6628B80DC1CD129024E088A67CC74' +
	'020BBEA63B139B22514A08798E3404DDEF9519B3CD3A431B302B0A6DF25F1437' +
	'4FE1356D6D51C245E485B576625E7EC6F44C42E9A637ED6B0BFF5CB6F406B7ED' +
	'EE386BFB5A899FA5AE9F24117C4B1FE649286651ECE65381FFFFFFFFFFFFFFFF';
	crypto.createDiffieHellman(p, 'hex');

	// Confirm DH_check() results are exposed for optional examination.
	const bad_dh = crypto.createDiffieHellman('02', 'hex');
	assert.notStrictEqual(bad_dh.verifyError, 0);

	const availableCurves = new Set(crypto.getCurves());
	const availableHashes = new Set(crypto.getHashes());

	// Oakley curves do not clean up ERR stack, it was causing unexpected failure
	// when accessing other OpenSSL APIs afterwards.
	if (availableCurves.has('Oakley-EC2N-3')) {
	crypto.createECDH('Oakley-EC2N-3');
	crypto.createHash('sha256');
	}

	// Test ECDH
	if (availableCurves.has('prime256v1') && availableCurves.has('secp256k1')) {
	const ecdh1 = crypto.createECDH('prime256v1');
	const ecdh2 = crypto.createECDH('prime256v1');
	const key1 = ecdh1.generateKeys();
	const key2 = ecdh2.generateKeys('hex');
	const secret1 = ecdh1.computeSecret(key2, 'hex', 'base64');
	const secret2 = ecdh2.computeSecret(key1, 'latin1', 'buffer');

	assert.strictEqual(secret1, secret2.toString('base64'));

	// Point formats
	assert.strictEqual(ecdh1.getPublicKey('buffer', 'uncompressed')[0], 4);
	let firstByte = ecdh1.getPublicKey('buffer', 'compressed')[0];
	assert(firstByte === 2 \|\| firstByte === 3);
	firstByte = ecdh1.getPublicKey('buffer', 'hybrid')[0];
	assert(firstByte === 6 \|\| firstByte === 7);
	// Format value should be string

	assert.throws(
	() => ecdh1.getPublicKey('buffer', 10),
	{
	code: 'ERR_CRYPTO_ECDH_INVALID_FORMAT',
	name: 'TypeError',
	message: 'Invalid ECDH format: 10'
	});

	// ECDH should check that point is on curve
	const ecdh3 = crypto.createECDH('secp256k1');
	const key3 = ecdh3.generateKeys();

	assert.throws(
	() => ecdh2.computeSecret(key3, 'latin1', 'buffer'),
	{
	code: 'ERR_CRYPTO_ECDH_INVALID_PUBLIC_KEY',
	name: 'Error',
	message: 'Public key is not valid for specified curve'
	});

	// ECDH should allow .setPrivateKey()/.setPublicKey()
	const ecdh4 = crypto.createECDH('prime256v1');

	ecdh4.setPrivateKey(ecdh1.getPrivateKey());
	ecdh4.setPublicKey(ecdh1.getPublicKey());

	assert.throws(() => {
	ecdh4.setPublicKey(ecdh3.getPublicKey());
	}, { message: 'Failed to convert Buffer to EC_POINT' });

	// Verify that we can use ECDH without having to use newly generated keys.
	const ecdh5 = crypto.createECDH('secp256k1');

	// Verify errors are thrown when retrieving keys from an uninitialized object.
	assert.throws(() => {
	ecdh5.getPublicKey();
	}, /^Error: Failed to get ECDH public key$/);

	assert.throws(() => {
	ecdh5.getPrivateKey();
	}, /^Error: Failed to get ECDH private key$/);

	// A valid private key for the secp256k1 curve.
	const cafebabeKey = 'cafebabe'.repeat(8);
	// Associated compressed and uncompressed public keys (points).
	const cafebabePubPtComp =
	'03672a31bfc59d3f04548ec9b7daeeba2f61814e8ccc40448045007f5479f693a3';
	const cafebabePubPtUnComp =
	'04672a31bfc59d3f04548ec9b7daeeba2f61814e8ccc40448045007f5479f693a3' +
	'2e02c7f93d13dc2732b760ca377a5897b9dd41a1c1b29dc0442fdce6d0a04d1d';
	ecdh5.setPrivateKey(cafebabeKey, 'hex');
	assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
	// Show that the public point (key) is generated while setting the
	// private key.
	assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);

	// Compressed and uncompressed public points/keys for other party's
	// private key.
	// 0xDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEFDEADBEEF
	const peerPubPtComp =
	'02c6b754b20826eb925e052ee2c25285b162b51fdca732bcf67e39d647fb6830ae';
	const peerPubPtUnComp =
	'04c6b754b20826eb925e052ee2c25285b162b51fdca732bcf67e39d647fb6830ae' +
	'b651944a574a362082a77e3f2b5d9223eb54d7f2f76846522bf75f3bedb8178e';

	const sharedSecret =
	'1da220b5329bbe8bfd19ceef5a5898593f411a6f12ea40f2a8eead9a5cf59970';

	assert.strictEqual(ecdh5.computeSecret(peerPubPtComp, 'hex', 'hex'),
	sharedSecret);
	assert.strictEqual(ecdh5.computeSecret(peerPubPtUnComp, 'hex', 'hex'),
	sharedSecret);

	// Verify that we still have the same key pair as before the computation.
	assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
	assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);

	// Verify setting and getting compressed and non-compressed serializations.
	ecdh5.setPublicKey(cafebabePubPtComp, 'hex');
	assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);
	assert.strictEqual(
	ecdh5.getPublicKey('hex', 'compressed'),
	cafebabePubPtComp
	);
	ecdh5.setPublicKey(cafebabePubPtUnComp, 'hex');
	assert.strictEqual(ecdh5.getPublicKey('hex'), cafebabePubPtUnComp);
	assert.strictEqual(
	ecdh5.getPublicKey('hex', 'compressed'),
	cafebabePubPtComp
	);

	// Show why allowing the public key to be set on this type
	// does not make sense.
	ecdh5.setPublicKey(peerPubPtComp, 'hex');
	assert.strictEqual(ecdh5.getPublicKey('hex'), peerPubPtUnComp);
	assert.throws(() => {
	// Error because the public key does not match the private key anymore.
	ecdh5.computeSecret(peerPubPtComp, 'hex', 'hex');
	}, /Invalid key pair/);

	// Set to a valid key to show that later attempts to set an invalid key are
	// rejected.
	ecdh5.setPrivateKey(cafebabeKey, 'hex');

	// Some invalid private keys for the secp256k1 curve.
	const errMessage = /Private key is not valid for specified curve/;
	['0000000000000000000000000000000000000000000000000000000000000000',
	'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141',
	'FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF',
	].forEach((element) => {
	assert.throws(() => {
	ecdh5.setPrivateKey(element, 'hex');
	}, errMessage);
	// Verify object state did not change.
	assert.strictEqual(ecdh5.getPrivateKey('hex'), cafebabeKey);
	});
	}

	// Use of invalid keys was not cleaning up ERR stack, and was causing
	// unexpected failure in subsequent signing operations.
	if (availableCurves.has('prime256v1') && availableHashes.has('sha256')) {
	const curve = crypto.createECDH('prime256v1');
	const invalidKey = Buffer.alloc(65);
	invalidKey.fill('\0');
	curve.generateKeys();
	assert.throws(
	() => curve.computeSecret(invalidKey),
	{
	code: 'ERR_CRYPTO_ECDH_INVALID_PUBLIC_KEY',
	name: 'Error',
	message: 'Public key is not valid for specified curve'
	});
	// Check that signing operations are not impacted by the above error.
	const ecPrivateKey =
	'-----BEGIN EC PRIVATE KEY-----\n' +
	'MHcCAQEEIF+jnWY1D5kbVYDNvxxo/Y+ku2uJPDwS0r/VuPZQrjjVoAoGCCqGSM49\n' +
	'AwEHoUQDQgAEurOxfSxmqIRYzJVagdZfMMSjRNNhB8i3mXyIMq704m2m52FdfKZ2\n' +
	'pQhByd5eyj3lgZ7m7jbchtdgyOF8Io/1ng==\n' +
	'-----END EC PRIVATE KEY-----';
	crypto.createSign('SHA256').sign(ecPrivateKey);
	}