I'm using the following example for signing + verifying in Node.js: https://github.com/nodejs/node-v0.x-archive/issues/6904. The verification succeeds in Node.js but fails in WebCrypto. Similarly, a message signed using WebCrypto fails to verify in Node.js.
Here's the code I used to verify a signature produced from the Node.js script using WebCrypto - https://jsfiddle.net/aj49e8sj/. Tested in both Chrome 54.0.2840.27 and Firefox 48.0.2
// From https://github.com/nodejs/node-v0.x-archive/issues/6904
var keys = {
priv: '-----BEGIN EC PRIVATE KEY-----\n' +
'MHcCAQEEIF+jnWY1D5kbVYDNvxxo/Y+ku2uJPDwS0r/VuPZQrjjVoAoGCCqGSM49\n' +
'AwEHoUQDQgAEurOxfSxmqIRYzJVagdZfMMSjRNNhB8i3mXyIMq704m2m52FdfKZ2\n' +
'pQhByd5eyj3lgZ7m7jbchtdgyOF8Io/1ng==\n' +
'-----END EC PRIVATE KEY-----\n',
pub: '-----BEGIN PUBLIC KEY-----\n' +
'MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEurOxfSxmqIRYzJVagdZfMMSjRNNh\n' +
'B8i3mXyIMq704m2m52FdfKZ2pQhByd5eyj3lgZ7m7jbchtdgyOF8Io/1ng==\n' +
'-----END PUBLIC KEY-----\n'
};
var message = (new TextEncoder('UTF-8')).encode('hello');
// Algorithm used in Node.js script is ecdsa-with-SHA1, key generated with prime256v1
var algorithm = {
name: 'ECDSA',
namedCurve: 'P-256',
hash: {
name: 'SHA-1'
}
};
// Signature from obtained via above Node.js script
var sig64 = 'MEUCIQDkAtiomagyHFi7dNfxMrzx/U0Gk/ZhmwCqaL3TimvlswIgPgeDqgZNqfR5/FZZASYsczUAhGSXjuycLhWnvk20qKc=';
// Decode base64 string into ArrayBuffer
var b64Decode = (str) => Uint8Array.from(atob(str), x => x.charCodeAt(0));
// Get base64 string from public key
const key64 = keys.pub.split('\n')
.filter(x => x.length > 0 && !x.startsWith('-----'))
.join('');
// Convert to buffers
var sig = b64Decode(sig64);
var keySpki = b64Decode(key64);
// Import and verify
// Want 'Verification result: true' but will get 'false'
var importKey = crypto.subtle.importKey('spki', keySpki, algorithm, true, ['verify'])
.then(key => crypto.subtle.verify(algorithm, key, sig, message))
.then(result => console.log('Verification result: ' + result));
Related question with a similar issue using SHA-256 instead of SHA-1: Generating ECDSA signature with Node.js/crypto
Things I've checked:
- I decoded the Node.js keys and verified they have the same OID as keys generated via WebCrypto. This tells me I'm using the correct curves.
- SHA-1 is explicitly identified as the hash to use in both locations.
- ECDSA is explicitly identified in both Node.js and WebCrypto.
How can I successfully verify the signature received from Node.js and vice versa - verify a signature in Node.js produced from WebCrypto? Or are the implementations of the standard subtly different in such a way that makes them incompatible?
Edit:
- WebCrypto signature (64 bytes): uTaUWTfF+AjN3aPj0b5Z2d1HybUEpV/phv/P9RtfKaGXtcYnbgfO43IRg46rznG3/WnWwJ2sV6mPOEnEPR0vWw==
- Node.js signature (71 bytes): MEUCIQDkAtiomagyHFi7dNfxMrzx/U0Gk/ZhmwCqaL3TimvlswIgPgeDqgZNqfR5/FZZASYsczUAhGSXjuycLhWnvk20qKc=
Verified Node.js signature is DER encoded and WebCrypto signature is not.
Having not used either of these libraries I can't say for certain, but one possibility is that they don't use the same encoding type for the signature. For DSA/ECDSA there are two main formats, IEEE P1363 (used by Windows) and DER (used by OpenSSL).
The "Windows" format is to have a preset size (determined by Q for DSA and P for ECDSA (Windows doesn't support Char-2, but if it did it'd probably be M for Char-2 ECDSA)). Then both r
and s
are left-padded with 0
until they meet that length.
In the too small to be legal example of r = 0x305
and s = 0x810522
with sizeof(Q) being 3 bytes:
// r
000305
// s
810522
For the "OpenSSL" format it is encoded under the rules of DER as SEQUENCE(INTEGER(r), INTEGER(s)), which looks like
// SEQUENCE
30
// (length of payload)
0A
// INTEGER(r)
02
// (length of payload)
02
// note the leading 0x00 is omitted
0305
// INTEGER(s)
02
// (length of payload)
04
// Since INTEGER is a signed type, but this represented a positive number,
// a 0x00 has to be inserted to keep the sign bit clear.
00810522
or, compactly:
- Windows:
000305810522
- OpenSSL:
300A02020305020400810522
The "Windows" format is always even, always the same length. The "OpenSSL" format is usually about 6 bytes bigger, but can gain or lose a byte in the middle; so it's sometimes even, sometimes odd.
Base64-decoding your sig64
value shows that it is using the DER encoding. Generate a couple signatures with WebCrypto; if any don't start with 0x30
then you have the IEEE/DER problem.
After many hours finally find a solution with zero dependences!!
In browser:
// Tip: Copy & Paste in the console for test.
// Text to sign:
var source = 'test';
// Auxs
function length(hex) {
return ('00' + (hex.length / 2).toString(16)).slice(-2).toString();
}
function pubKeyToPEM(key) {
var pem = '-----BEGIN PUBLIC KEY-----\n',
keydata = '',
bytes = new Uint8Array( key );
for (var i = 0; i < bytes.byteLength; i++) {
keydata += String.fromCharCode( bytes[ i ] );
}
keydata = window.btoa(keydata);
while(keydata.length > 0) {
pem += keydata.substring(0, 64) + '\n';
keydata = keydata.substring(64);
}
pem = pem + "-----END PUBLIC KEY-----";
return pem;
}
// Generate new keypair.
window.crypto.subtle.generateKey({ name: "ECDSA", namedCurve: "P-384" }, true, ["sign", "verify"])
.then(function(keypair) {
// Encode as UTF-8
var enc = new TextEncoder('UTF-8'),
digest = enc.encode(source);
// Sign with subtle
window.crypto.subtle.sign({ name: "ECDSA", hash: {name: "SHA-1"} }, keypair.privateKey, digest)
.then(function(signature) {
signature = new Uint8Array(signature);
// Extract r & s and format it in ASN1 format.
var signHex = Array.prototype.map.call(signature, function(x) { return ('00' + x.toString(16)).slice(-2); }).join(''),
r = signHex.substring(0, 96),
s = signHex.substring(96),
rPre = true,
sPre = true;
while(r.indexOf('00') === 0) {
r = r.substring(2);
rPre = false;
}
if (rPre && parseInt(r.substring(0, 2), 16) > 127) {
r = '00' + r;
}
while(s.indexOf('00') === 0) {
s = s.substring(2);
sPre = false;
}
if(sPre && parseInt(s.substring(0, 2), 16) > 127) {
s = '00' + s;
}
var payload = '02' + length(r) + r +
'02' + length(s) + s,
der = '30' + length(payload) + payload;
// Export public key un PEM format (needed by node)
window.crypto.subtle.exportKey('spki', keypair.publicKey)
.then(function(key) {
var pubKey = pubKeyToPEM(key);
console.log('This is pubKey -> ', pubKey);
console.log('This is signature -> ', der);
});
// For test, we verify the signature, nothing, anecdotal.
window.crypto.subtle.verify({ name: "ECDSA", hash: {name: "SHA-1"} }, keypair.publicKey, signature, digest)
.then(console.log);
});
});
In node:
const crypto = require('crypto');
// ----------------------------------------------------------------------------
// Paste from browser!
var puKeyPem = '-----BEGIN PUBLIC KEY-----\n' +
'MHYwEAYHKoZIzj0CAQYFK4EEACIDYgAEmDubwJuORpMMoMnvv59W8tU8PxPChh75\n' +
'vjlfVB2+tPY5KDy1I0ohz2US+2K1T/ROcDCSRAjyONRzzwVBm9S6bqbk3KuaT2KG\n' +
'ikoe0KLfTeQtdEUyq8J0aEOKRXoCJLZq\n' +
'-----END PUBLIC KEY-----';
var hexSign = '306402305df22aa5f4e7200b7c264c891cd3a8c5b4622c25872020832d5bb3d251773592020249a46a8349754dc58c47c4cbb7c9023053b929a98f5c8cccf2c1a4746d82fc751e044b1f76dffdf9ef73f73bee1499c5e20aadddda41e3373760b8b0f3c1bbb2';
// ----------------------------------------------------------------------------
var verifier = crypto.createVerify('sha1'),
digest = 'test';
verifier.update(digest);
verifier.end();
console.log(verifier.verify(puKeyPem, hexSign, 'hex'));
// ----------------------------------------------------------------------------