/
mac.js
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mac.js
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'use strict';
const {
ArrayFrom,
SafeSet,
} = primordials;
const {
HmacJob,
KeyObjectHandle,
kCryptoJobAsync,
kSignJobModeSign,
kSignJobModeVerify,
} = internalBinding('crypto');
const {
getBlockSize,
hasAnyNotIn,
jobPromise,
normalizeHashName,
validateBitLength,
validateKeyOps,
kHandle,
kKeyObject,
} = require('internal/crypto/util');
const {
lazyDOMException,
promisify,
} = require('internal/util');
const {
codes: {
ERR_MISSING_OPTION,
}
} = require('internal/errors');
const {
generateKey: _generateKey,
} = require('internal/crypto/keygen');
const {
InternalCryptoKey,
SecretKeyObject,
createSecretKey,
} = require('internal/crypto/keys');
const generateKey = promisify(_generateKey);
async function hmacGenerateKey(algorithm, extractable, keyUsages) {
const { hash, name } = algorithm;
let { length } = algorithm;
if (hash === undefined)
throw new ERR_MISSING_OPTION('algorithm.hash');
if (length === undefined)
length = getBlockSize(hash.name);
validateBitLength(length, 'algorithm.length', true);
const usageSet = new SafeSet(keyUsages);
if (hasAnyNotIn(usageSet, ['sign', 'verify'])) {
throw lazyDOMException(
'Unsupported key usage for an HMAC key',
'SyntaxError');
}
const key = await generateKey('hmac', { length }).catch((err) => {
// TODO(@panva): add err as cause to DOMException
throw lazyDOMException(
'The operation failed for an operation-specific reason',
'OperationError');
});
return new InternalCryptoKey(
key,
{ name, length, hash: { name: hash.name } },
ArrayFrom(usageSet),
extractable);
}
async function hmacImportKey(
format,
keyData,
algorithm,
extractable,
keyUsages) {
const { hash } = algorithm;
if (hash === undefined)
throw new ERR_MISSING_OPTION('algorithm.hash');
const usagesSet = new SafeSet(keyUsages);
if (hasAnyNotIn(usagesSet, ['sign', 'verify'])) {
throw lazyDOMException(
'Unsupported key usage for an HMAC key',
'SyntaxError');
}
let keyObject;
switch (format) {
case 'raw': {
const checkLength = keyData.byteLength * 8;
if (checkLength === 0 || algorithm.length === 0)
throw lazyDOMException('Zero-length key is not supported', 'DataError');
// The Web Crypto spec allows for key lengths that are not multiples of
// 8. We don't. Our check here is stricter than that defined by the spec
// in that we require that algorithm.length match keyData.length * 8 if
// algorithm.length is specified.
if (algorithm.length !== undefined &&
algorithm.length !== checkLength) {
throw lazyDOMException('Invalid key length', 'DataError');
}
keyObject = createSecretKey(keyData);
break;
}
case 'jwk': {
if (keyData == null || typeof keyData !== 'object')
throw lazyDOMException('Invalid JWK keyData', 'DataError');
if (keyData.kty !== 'oct')
throw lazyDOMException('Invalid key type', 'DataError');
if (usagesSet.size > 0 &&
keyData.use !== undefined &&
keyData.use !== 'sig') {
throw lazyDOMException('Invalid use type', 'DataError');
}
validateKeyOps(keyData.key_ops, usagesSet);
if (keyData.ext !== undefined &&
keyData.ext === false &&
extractable === true) {
throw lazyDOMException('JWK is not extractable', 'DataError');
}
if (keyData.alg !== undefined) {
if (typeof keyData.alg !== 'string')
throw lazyDOMException('Invalid alg', 'DataError');
switch (keyData.alg) {
case 'HS1':
if (algorithm.hash.name !== 'SHA-1')
throw lazyDOMException('Digest algorithm mismatch', 'DataError');
break;
case 'HS256':
if (algorithm.hash.name !== 'SHA-256')
throw lazyDOMException('Digest algorithm mismatch', 'DataError');
break;
case 'HS384':
if (algorithm.hash.name !== 'SHA-384')
throw lazyDOMException('Digest algorithm mismatch', 'DataError');
break;
case 'HS512':
if (algorithm.hash.name !== 'SHA-512')
throw lazyDOMException('Digest algorithm mismatch', 'DataError');
break;
default:
throw lazyDOMException('Unsupported digest algorithm', 'DataError');
}
}
const handle = new KeyObjectHandle();
handle.initJwk(keyData);
keyObject = new SecretKeyObject(handle);
break;
}
default:
throw lazyDOMException(`Unable to import HMAC key with format ${format}`);
}
const { length } = keyObject[kHandle].keyDetail({});
return new InternalCryptoKey(
keyObject, {
name: 'HMAC',
hash: algorithm.hash,
length,
},
keyUsages,
extractable);
}
function hmacSignVerify(key, data, algorithm, signature) {
const mode = signature === undefined ? kSignJobModeSign : kSignJobModeVerify;
return jobPromise(new HmacJob(
kCryptoJobAsync,
mode,
normalizeHashName(key.algorithm.hash.name),
key[kKeyObject][kHandle],
data,
signature));
}
module.exports = {
hmacImportKey,
hmacGenerateKey,
hmacSignVerify,
};