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denoland-deno/ext/crypto/00_crypto.js
Divy Srivastava 39a2034967
feat(ext/crypto): X448 support (#26043)
Signed-off-by: Divy Srivastava <dj.srivastava23@gmail.com>
2024-10-07 12:04:40 +01:00

5690 lines
138 KiB
JavaScript

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
// @ts-check
/// <reference path="../../core/internal.d.ts" />
/// <reference path="../../core/lib.deno_core.d.ts" />
/// <reference path="../webidl/internal.d.ts" />
/// <reference path="../web/lib.deno_web.d.ts" />
import { core, primordials } from "ext:core/mod.js";
const {
isArrayBuffer,
isTypedArray,
isDataView,
} = core;
import {
op_crypto_base64url_decode,
op_crypto_base64url_encode,
op_crypto_decrypt,
op_crypto_derive_bits,
op_crypto_derive_bits_x25519,
op_crypto_derive_bits_x448,
op_crypto_encrypt,
op_crypto_export_key,
op_crypto_export_pkcs8_ed25519,
op_crypto_export_pkcs8_x25519,
op_crypto_export_pkcs8_x448,
op_crypto_export_spki_ed25519,
op_crypto_export_spki_x25519,
op_crypto_export_spki_x448,
op_crypto_generate_ed25519_keypair,
op_crypto_generate_key,
op_crypto_generate_x25519_keypair,
op_crypto_generate_x448_keypair,
op_crypto_get_random_values,
op_crypto_import_key,
op_crypto_import_pkcs8_ed25519,
op_crypto_import_pkcs8_x25519,
op_crypto_import_pkcs8_x448,
op_crypto_import_spki_ed25519,
op_crypto_import_spki_x25519,
op_crypto_import_spki_x448,
op_crypto_jwk_x_ed25519,
op_crypto_random_uuid,
op_crypto_sign_ed25519,
op_crypto_sign_key,
op_crypto_subtle_digest,
op_crypto_unwrap_key,
op_crypto_verify_ed25519,
op_crypto_verify_key,
op_crypto_wrap_key,
} from "ext:core/ops";
const {
ArrayBufferIsView,
ArrayBufferPrototypeGetByteLength,
ArrayBufferPrototypeSlice,
ArrayPrototypeEvery,
ArrayPrototypeFilter,
ArrayPrototypeFind,
ArrayPrototypeIncludes,
DataViewPrototypeGetBuffer,
DataViewPrototypeGetByteLength,
DataViewPrototypeGetByteOffset,
JSONParse,
JSONStringify,
MathCeil,
ObjectAssign,
ObjectHasOwn,
ObjectPrototypeIsPrototypeOf,
SafeArrayIterator,
SafeWeakMap,
StringFromCharCode,
StringPrototypeCharCodeAt,
StringPrototypeToLowerCase,
StringPrototypeToUpperCase,
Symbol,
SymbolFor,
SyntaxError,
TypeError,
TypedArrayPrototypeGetBuffer,
TypedArrayPrototypeGetByteLength,
TypedArrayPrototypeGetByteOffset,
TypedArrayPrototypeGetSymbolToStringTag,
TypedArrayPrototypeSlice,
Uint8Array,
WeakMapPrototypeGet,
WeakMapPrototypeSet,
} = primordials;
import * as webidl from "ext:deno_webidl/00_webidl.js";
import { createFilteredInspectProxy } from "ext:deno_console/01_console.js";
import { DOMException } from "ext:deno_web/01_dom_exception.js";
const supportedNamedCurves = ["P-256", "P-384", "P-521"];
const recognisedUsages = [
"encrypt",
"decrypt",
"sign",
"verify",
"deriveKey",
"deriveBits",
"wrapKey",
"unwrapKey",
];
const simpleAlgorithmDictionaries = {
AesGcmParams: { iv: "BufferSource", additionalData: "BufferSource" },
RsaHashedKeyGenParams: { hash: "HashAlgorithmIdentifier" },
EcKeyGenParams: {},
HmacKeyGenParams: { hash: "HashAlgorithmIdentifier" },
RsaPssParams: {},
EcdsaParams: { hash: "HashAlgorithmIdentifier" },
HmacImportParams: { hash: "HashAlgorithmIdentifier" },
HkdfParams: {
hash: "HashAlgorithmIdentifier",
salt: "BufferSource",
info: "BufferSource",
},
Pbkdf2Params: { hash: "HashAlgorithmIdentifier", salt: "BufferSource" },
RsaOaepParams: { label: "BufferSource" },
RsaHashedImportParams: { hash: "HashAlgorithmIdentifier" },
EcKeyImportParams: {},
};
const supportedAlgorithms = {
"digest": {
"SHA-1": null,
"SHA-256": null,
"SHA-384": null,
"SHA-512": null,
},
"generateKey": {
"RSASSA-PKCS1-v1_5": "RsaHashedKeyGenParams",
"RSA-PSS": "RsaHashedKeyGenParams",
"RSA-OAEP": "RsaHashedKeyGenParams",
"ECDSA": "EcKeyGenParams",
"ECDH": "EcKeyGenParams",
"AES-CTR": "AesKeyGenParams",
"AES-CBC": "AesKeyGenParams",
"AES-GCM": "AesKeyGenParams",
"AES-KW": "AesKeyGenParams",
"HMAC": "HmacKeyGenParams",
"X25519": null,
"X448": null,
"Ed25519": null,
},
"sign": {
"RSASSA-PKCS1-v1_5": null,
"RSA-PSS": "RsaPssParams",
"ECDSA": "EcdsaParams",
"HMAC": null,
"Ed25519": null,
},
"verify": {
"RSASSA-PKCS1-v1_5": null,
"RSA-PSS": "RsaPssParams",
"ECDSA": "EcdsaParams",
"HMAC": null,
"Ed25519": null,
},
"importKey": {
"RSASSA-PKCS1-v1_5": "RsaHashedImportParams",
"RSA-PSS": "RsaHashedImportParams",
"RSA-OAEP": "RsaHashedImportParams",
"ECDSA": "EcKeyImportParams",
"ECDH": "EcKeyImportParams",
"HMAC": "HmacImportParams",
"HKDF": null,
"PBKDF2": null,
"AES-CTR": null,
"AES-CBC": null,
"AES-GCM": null,
"AES-KW": null,
"Ed25519": null,
"X25519": null,
"X448": null,
},
"deriveBits": {
"HKDF": "HkdfParams",
"PBKDF2": "Pbkdf2Params",
"ECDH": "EcdhKeyDeriveParams",
"X25519": "EcdhKeyDeriveParams",
"X448": "EcdhKeyDeriveParams",
},
"encrypt": {
"RSA-OAEP": "RsaOaepParams",
"AES-CBC": "AesCbcParams",
"AES-GCM": "AesGcmParams",
"AES-CTR": "AesCtrParams",
},
"decrypt": {
"RSA-OAEP": "RsaOaepParams",
"AES-CBC": "AesCbcParams",
"AES-GCM": "AesGcmParams",
"AES-CTR": "AesCtrParams",
},
"get key length": {
"AES-CBC": "AesDerivedKeyParams",
"AES-CTR": "AesDerivedKeyParams",
"AES-GCM": "AesDerivedKeyParams",
"AES-KW": "AesDerivedKeyParams",
"HMAC": "HmacImportParams",
"HKDF": null,
"PBKDF2": null,
},
"wrapKey": {
"AES-KW": null,
},
"unwrapKey": {
"AES-KW": null,
},
};
const aesJwkAlg = {
"AES-CTR": {
128: "A128CTR",
192: "A192CTR",
256: "A256CTR",
},
"AES-CBC": {
128: "A128CBC",
192: "A192CBC",
256: "A256CBC",
},
"AES-GCM": {
128: "A128GCM",
192: "A192GCM",
256: "A256GCM",
},
"AES-KW": {
128: "A128KW",
192: "A192KW",
256: "A256KW",
},
};
// See https://www.w3.org/TR/WebCryptoAPI/#dfn-normalize-an-algorithm
// 18.4.4
function normalizeAlgorithm(algorithm, op) {
if (typeof algorithm == "string") {
return normalizeAlgorithm({ name: algorithm }, op);
}
// 1.
const registeredAlgorithms = supportedAlgorithms[op];
// 2. 3.
const initialAlg = webidl.converters.Algorithm(
algorithm,
"Failed to normalize algorithm",
"passed algorithm",
);
// 4.
let algName = initialAlg.name;
// 5.
let desiredType = undefined;
for (const key in registeredAlgorithms) {
if (!ObjectHasOwn(registeredAlgorithms, key)) {
continue;
}
if (
StringPrototypeToUpperCase(key) === StringPrototypeToUpperCase(algName)
) {
algName = key;
desiredType = registeredAlgorithms[key];
}
}
if (desiredType === undefined) {
throw new DOMException(
"Unrecognized algorithm name",
"NotSupportedError",
);
}
// Fast path everything below if the registered dictionary is "None".
if (desiredType === null) {
return { name: algName };
}
// 6.
const normalizedAlgorithm = webidl.converters[desiredType](
algorithm,
"Failed to normalize algorithm",
"passed algorithm",
);
// 7.
normalizedAlgorithm.name = algName;
// 9.
const dict = simpleAlgorithmDictionaries[desiredType];
// 10.
for (const member in dict) {
if (!ObjectHasOwn(dict, member)) {
continue;
}
const idlType = dict[member];
const idlValue = normalizedAlgorithm[member];
// 3.
if (idlType === "BufferSource" && idlValue) {
normalizedAlgorithm[member] = copyBuffer(idlValue);
} else if (idlType === "HashAlgorithmIdentifier") {
normalizedAlgorithm[member] = normalizeAlgorithm(idlValue, "digest");
} else if (idlType === "AlgorithmIdentifier") {
// TODO(lucacasonato): implement
throw new TypeError("Unimplemented");
}
}
return normalizedAlgorithm;
}
/**
* @param {ArrayBufferView | ArrayBuffer} input
* @returns {Uint8Array}
*/
function copyBuffer(input) {
if (isTypedArray(input)) {
return TypedArrayPrototypeSlice(
new Uint8Array(
TypedArrayPrototypeGetBuffer(/** @type {Uint8Array} */ (input)),
TypedArrayPrototypeGetByteOffset(/** @type {Uint8Array} */ (input)),
TypedArrayPrototypeGetByteLength(/** @type {Uint8Array} */ (input)),
),
);
} else if (isDataView(input)) {
return TypedArrayPrototypeSlice(
new Uint8Array(
DataViewPrototypeGetBuffer(/** @type {DataView} */ (input)),
DataViewPrototypeGetByteOffset(/** @type {DataView} */ (input)),
DataViewPrototypeGetByteLength(/** @type {DataView} */ (input)),
),
);
}
// ArrayBuffer
return TypedArrayPrototypeSlice(
new Uint8Array(
input,
0,
ArrayBufferPrototypeGetByteLength(input),
),
);
}
const _handle = Symbol("[[handle]]");
const _algorithm = Symbol("[[algorithm]]");
const _extractable = Symbol("[[extractable]]");
const _usages = Symbol("[[usages]]");
const _type = Symbol("[[type]]");
class CryptoKey {
/** @type {string} */
[_type];
/** @type {boolean} */
[_extractable];
/** @type {object} */
[_algorithm];
/** @type {string[]} */
[_usages];
/** @type {object} */
[_handle];
constructor() {
webidl.illegalConstructor();
}
/** @returns {string} */
get type() {
webidl.assertBranded(this, CryptoKeyPrototype);
return this[_type];
}
/** @returns {boolean} */
get extractable() {
webidl.assertBranded(this, CryptoKeyPrototype);
return this[_extractable];
}
/** @returns {string[]} */
get usages() {
webidl.assertBranded(this, CryptoKeyPrototype);
// TODO(lucacasonato): return a SameObject copy
return this[_usages];
}
/** @returns {object} */
get algorithm() {
webidl.assertBranded(this, CryptoKeyPrototype);
// TODO(lucacasonato): return a SameObject copy
return this[_algorithm];
}
[SymbolFor("Deno.privateCustomInspect")](inspect, inspectOptions) {
return inspect(
createFilteredInspectProxy({
object: this,
evaluate: ObjectPrototypeIsPrototypeOf(CryptoKeyPrototype, this),
keys: [
"type",
"extractable",
"algorithm",
"usages",
],
}),
inspectOptions,
);
}
}
webidl.configureInterface(CryptoKey);
const CryptoKeyPrototype = CryptoKey.prototype;
/**
* @param {string} type
* @param {boolean} extractable
* @param {string[]} usages
* @param {object} algorithm
* @param {object} handle
* @returns
*/
function constructKey(type, extractable, usages, algorithm, handle) {
const key = webidl.createBranded(CryptoKey);
key[_type] = type;
key[_extractable] = extractable;
key[_usages] = usages;
key[_algorithm] = algorithm;
key[_handle] = handle;
return key;
}
// https://w3c.github.io/webcrypto/#concept-usage-intersection
/**
* @param {string[]} a
* @param {string[]} b
* @returns
*/
function usageIntersection(a, b) {
return ArrayPrototypeFilter(
a,
(i) => ArrayPrototypeIncludes(b, i),
);
}
// TODO(lucacasonato): this should be moved to rust
/** @type {WeakMap<object, object>} */
const KEY_STORE = new SafeWeakMap();
function getKeyLength(algorithm) {
switch (algorithm.name) {
case "AES-CBC":
case "AES-CTR":
case "AES-GCM":
case "AES-KW": {
// 1.
if (!ArrayPrototypeIncludes([128, 192, 256], algorithm.length)) {
throw new DOMException(
`Length must be 128, 192, or 256: received ${algorithm.length}`,
"OperationError",
);
}
// 2.
return algorithm.length;
}
case "HMAC": {
// 1.
let length;
if (algorithm.length === undefined) {
switch (algorithm.hash.name) {
case "SHA-1":
length = 512;
break;
case "SHA-256":
length = 512;
break;
case "SHA-384":
length = 1024;
break;
case "SHA-512":
length = 1024;
break;
default:
throw new DOMException(
`Unrecognized hash algorithm: ${algorithm.hash.name}`,
"NotSupportedError",
);
}
} else if (algorithm.length !== 0) {
length = algorithm.length;
} else {
throw new TypeError(`Invalid length: ${algorithm.length}`);
}
// 2.
return length;
}
case "HKDF": {
// 1.
return null;
}
case "PBKDF2": {
// 1.
return null;
}
default:
throw new TypeError("Unreachable");
}
}
class SubtleCrypto {
constructor() {
webidl.illegalConstructor();
}
/**
* @param {string} algorithm
* @param {BufferSource} data
* @returns {Promise<ArrayBuffer>}
*/
async digest(algorithm, data) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'digest' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 2, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
data = webidl.converters.BufferSource(data, prefix, "Argument 2");
data = copyBuffer(data);
algorithm = normalizeAlgorithm(algorithm, "digest");
const result = await op_crypto_subtle_digest(
algorithm.name,
data,
);
return TypedArrayPrototypeGetBuffer(result);
}
/**
* @param {string} algorithm
* @param {CryptoKey} key
* @param {BufferSource} data
* @returns {Promise<any>}
*/
async encrypt(algorithm, key, data) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'encrypt' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 3, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
data = webidl.converters.BufferSource(data, prefix, "Argument 3");
// 2.
data = copyBuffer(data);
// 3.
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "encrypt");
// 8.
if (normalizedAlgorithm.name !== key[_algorithm].name) {
throw new DOMException(
`Encryption algorithm '${normalizedAlgorithm.name}' does not match key algorithm`,
"InvalidAccessError",
);
}
// 9.
if (!ArrayPrototypeIncludes(key[_usages], "encrypt")) {
throw new DOMException(
"Key does not support the 'encrypt' operation",
"InvalidAccessError",
);
}
return await encrypt(normalizedAlgorithm, key, data);
}
/**
* @param {string} algorithm
* @param {CryptoKey} key
* @param {BufferSource} data
* @returns {Promise<any>}
*/
async decrypt(algorithm, key, data) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'decrypt' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 3, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
data = webidl.converters.BufferSource(data, prefix, "Argument 3");
// 2.
data = copyBuffer(data);
// 3.
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "decrypt");
// 8.
if (normalizedAlgorithm.name !== key[_algorithm].name) {
throw new DOMException(
`Decryption algorithm "${normalizedAlgorithm.name}" does not match key algorithm`,
"OperationError",
);
}
// 9.
if (!ArrayPrototypeIncludes(key[_usages], "decrypt")) {
throw new DOMException(
"Key does not support the 'decrypt' operation",
"InvalidAccessError",
);
}
const handle = key[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
switch (normalizedAlgorithm.name) {
case "RSA-OAEP": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
if (normalizedAlgorithm.label) {
normalizedAlgorithm.label = copyBuffer(normalizedAlgorithm.label);
} else {
normalizedAlgorithm.label = new Uint8Array();
}
// 3-5.
const hashAlgorithm = key[_algorithm].hash.name;
const plainText = await op_crypto_decrypt({
key: keyData,
algorithm: "RSA-OAEP",
hash: hashAlgorithm,
label: normalizedAlgorithm.label,
}, data);
// 6.
return TypedArrayPrototypeGetBuffer(plainText);
}
case "AES-CBC": {
normalizedAlgorithm.iv = copyBuffer(normalizedAlgorithm.iv);
// 1.
if (TypedArrayPrototypeGetByteLength(normalizedAlgorithm.iv) !== 16) {
throw new DOMException(
"Counter must be 16 bytes",
"OperationError",
);
}
const plainText = await op_crypto_decrypt({
key: keyData,
algorithm: "AES-CBC",
iv: normalizedAlgorithm.iv,
length: key[_algorithm].length,
}, data);
// 6.
return TypedArrayPrototypeGetBuffer(plainText);
}
case "AES-CTR": {
normalizedAlgorithm.counter = copyBuffer(normalizedAlgorithm.counter);
// 1.
if (
TypedArrayPrototypeGetByteLength(normalizedAlgorithm.counter) !== 16
) {
throw new DOMException(
"Counter vector must be 16 bytes",
"OperationError",
);
}
// 2.
if (
normalizedAlgorithm.length === 0 || normalizedAlgorithm.length > 128
) {
throw new DOMException(
`Counter length must not be 0 or greater than 128: received ${normalizedAlgorithm.length}`,
"OperationError",
);
}
// 3.
const cipherText = await op_crypto_decrypt({
key: keyData,
algorithm: "AES-CTR",
keyLength: key[_algorithm].length,
counter: normalizedAlgorithm.counter,
ctrLength: normalizedAlgorithm.length,
}, data);
// 4.
return TypedArrayPrototypeGetBuffer(cipherText);
}
case "AES-GCM": {
normalizedAlgorithm.iv = copyBuffer(normalizedAlgorithm.iv);
// 1.
if (normalizedAlgorithm.tagLength === undefined) {
normalizedAlgorithm.tagLength = 128;
} else if (
!ArrayPrototypeIncludes(
[32, 64, 96, 104, 112, 120, 128],
normalizedAlgorithm.tagLength,
)
) {
throw new DOMException(
`Invalid tag length: ${normalizedAlgorithm.tagLength}`,
"OperationError",
);
}
// 2.
if (
TypedArrayPrototypeGetByteLength(data) <
normalizedAlgorithm.tagLength / 8
) {
throw new DOMException(
"Tag length overflows ciphertext",
"OperationError",
);
}
// 3. We only support 96-bit and 128-bit nonce.
if (
ArrayPrototypeIncludes(
[12, 16],
TypedArrayPrototypeGetByteLength(normalizedAlgorithm.iv),
) === undefined
) {
throw new DOMException(
"Initialization vector length not supported",
"NotSupportedError",
);
}
// 4.
if (normalizedAlgorithm.additionalData !== undefined) {
// NOTE: over the size of Number.MAX_SAFE_INTEGER is not available in V8
// if (normalizedAlgorithm.additionalData.byteLength > (2 ** 64) - 1) {
// throw new DOMException(
// "Additional data too large",
// "OperationError",
// );
// }
normalizedAlgorithm.additionalData = copyBuffer(
normalizedAlgorithm.additionalData,
);
}
// 5-8.
const plaintext = await op_crypto_decrypt({
key: keyData,
algorithm: "AES-GCM",
length: key[_algorithm].length,
iv: normalizedAlgorithm.iv,
additionalData: normalizedAlgorithm.additionalData ||
null,
tagLength: normalizedAlgorithm.tagLength,
}, data);
// 9.
return TypedArrayPrototypeGetBuffer(plaintext);
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
/**
* @param {string} algorithm
* @param {CryptoKey} key
* @param {BufferSource} data
* @returns {Promise<any>}
*/
async sign(algorithm, key, data) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'sign' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 3, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
data = webidl.converters.BufferSource(data, prefix, "Argument 3");
// 1.
data = copyBuffer(data);
// 2.
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "sign");
const handle = key[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
// 8.
if (normalizedAlgorithm.name !== key[_algorithm].name) {
throw new DOMException(
"Signing algorithm does not match key algorithm",
"InvalidAccessError",
);
}
// 9.
if (!ArrayPrototypeIncludes(key[_usages], "sign")) {
throw new DOMException(
"Key does not support the 'sign' operation",
"InvalidAccessError",
);
}
switch (normalizedAlgorithm.name) {
case "RSASSA-PKCS1-v1_5": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
const hashAlgorithm = key[_algorithm].hash.name;
const signature = await op_crypto_sign_key({
key: keyData,
algorithm: "RSASSA-PKCS1-v1_5",
hash: hashAlgorithm,
}, data);
return TypedArrayPrototypeGetBuffer(signature);
}
case "RSA-PSS": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
const hashAlgorithm = key[_algorithm].hash.name;
const signature = await op_crypto_sign_key({
key: keyData,
algorithm: "RSA-PSS",
hash: hashAlgorithm,
saltLength: normalizedAlgorithm.saltLength,
}, data);
return TypedArrayPrototypeGetBuffer(signature);
}
case "ECDSA": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
const hashAlgorithm = normalizedAlgorithm.hash.name;
const namedCurve = key[_algorithm].namedCurve;
if (!ArrayPrototypeIncludes(supportedNamedCurves, namedCurve)) {
throw new DOMException("Curve not supported", "NotSupportedError");
}
if (
(key[_algorithm].namedCurve === "P-256" &&
hashAlgorithm !== "SHA-256") ||
(key[_algorithm].namedCurve === "P-384" &&
hashAlgorithm !== "SHA-384")
) {
throw new DOMException(
"Not implemented",
"NotSupportedError",
);
}
const signature = await op_crypto_sign_key({
key: keyData,
algorithm: "ECDSA",
hash: hashAlgorithm,
namedCurve,
}, data);
return TypedArrayPrototypeGetBuffer(signature);
}
case "HMAC": {
const hashAlgorithm = key[_algorithm].hash.name;
const signature = await op_crypto_sign_key({
key: keyData,
algorithm: "HMAC",
hash: hashAlgorithm,
}, data);
return TypedArrayPrototypeGetBuffer(signature);
}
case "Ed25519": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// https://briansmith.org/rustdoc/src/ring/ec/curve25519/ed25519/signing.rs.html#260
const SIGNATURE_LEN = 32 * 2; // ELEM_LEN + SCALAR_LEN
const signature = new Uint8Array(SIGNATURE_LEN);
if (!op_crypto_sign_ed25519(keyData, data, signature)) {
throw new DOMException(
"Failed to sign",
"OperationError",
);
}
return TypedArrayPrototypeGetBuffer(signature);
}
}
throw new TypeError("Unreachable");
}
/**
* @param {string} format
* @param {BufferSource} keyData
* @param {string} algorithm
* @param {boolean} extractable
* @param {KeyUsages[]} keyUsages
* @returns {Promise<any>}
*/
async importKey(format, keyData, algorithm, extractable, keyUsages) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'importKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 4, prefix);
format = webidl.converters.KeyFormat(format, prefix, "Argument 1");
keyData = webidl.converters["BufferSource or JsonWebKey"](
keyData,
prefix,
"Argument 2",
);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 3",
);
extractable = webidl.converters.boolean(extractable, prefix, "Argument 4");
keyUsages = webidl.converters["sequence<KeyUsage>"](
keyUsages,
prefix,
"Argument 5",
);
// 2.
if (format !== "jwk") {
if (ArrayBufferIsView(keyData) || isArrayBuffer(keyData)) {
keyData = copyBuffer(keyData);
} else {
throw new TypeError("Cannot import key: 'keyData' is a JsonWebKey");
}
} else {
if (ArrayBufferIsView(keyData) || isArrayBuffer(keyData)) {
throw new TypeError("Cannot import key: 'keyData' is not a JsonWebKey");
}
}
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "importKey");
// 8.
const result = await importKeyInner(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
);
// 9.
if (
ArrayPrototypeIncludes(["private", "secret"], result[_type]) &&
keyUsages.length == 0
) {
throw new SyntaxError("Invalid key usage");
}
return result;
}
/**
* @param {string} format
* @param {CryptoKey} key
* @returns {Promise<any>}
*/
// deno-lint-ignore require-await
async exportKey(format, key) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'exportKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 2, prefix);
format = webidl.converters.KeyFormat(format, prefix, "Argument 1");
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
const handle = key[_handle];
// 2.
const innerKey = WeakMapPrototypeGet(KEY_STORE, handle);
const algorithmName = key[_algorithm].name;
let result;
switch (algorithmName) {
case "HMAC": {
result = exportKeyHMAC(format, key, innerKey);
break;
}
case "RSASSA-PKCS1-v1_5":
case "RSA-PSS":
case "RSA-OAEP": {
result = exportKeyRSA(format, key, innerKey);
break;
}
case "ECDH":
case "ECDSA": {
result = exportKeyEC(format, key, innerKey);
break;
}
case "Ed25519": {
result = exportKeyEd25519(format, key, innerKey);
break;
}
case "X448": {
result = exportKeyX448(format, key, innerKey);
break;
}
case "X25519": {
result = exportKeyX25519(format, key, innerKey);
break;
}
case "AES-CTR":
case "AES-CBC":
case "AES-GCM":
case "AES-KW": {
result = exportKeyAES(format, key, innerKey);
break;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
if (key.extractable === false) {
throw new DOMException(
"Key is not extractable",
"InvalidAccessError",
);
}
return result;
}
/**
* @param {AlgorithmIdentifier} algorithm
* @param {CryptoKey} baseKey
* @param {number | null} length
* @returns {Promise<ArrayBuffer>}
*/
async deriveBits(algorithm, baseKey, length = null) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'deriveBits' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 2, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
baseKey = webidl.converters.CryptoKey(baseKey, prefix, "Argument 2");
if (length !== null) {
length = webidl.converters["unsigned long"](length, prefix, "Argument 3");
}
// 2.
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "deriveBits");
// 4-6.
const result = await deriveBits(normalizedAlgorithm, baseKey, length);
// 7.
if (normalizedAlgorithm.name !== baseKey[_algorithm].name) {
throw new DOMException("Invalid algorithm name", "InvalidAccessError");
}
// 8.
if (!ArrayPrototypeIncludes(baseKey[_usages], "deriveBits")) {
throw new DOMException(
"'baseKey' usages does not contain 'deriveBits'",
"InvalidAccessError",
);
}
// 9-10.
return result;
}
/**
* @param {AlgorithmIdentifier} algorithm
* @param {CryptoKey} baseKey
* @param {number} length
* @returns {Promise<ArrayBuffer>}
*/
async deriveKey(
algorithm,
baseKey,
derivedKeyType,
extractable,
keyUsages,
) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'deriveKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 5, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
baseKey = webidl.converters.CryptoKey(baseKey, prefix, "Argument 2");
derivedKeyType = webidl.converters.AlgorithmIdentifier(
derivedKeyType,
prefix,
"Argument 3",
);
extractable = webidl.converters["boolean"](
extractable,
prefix,
"Argument 4",
);
keyUsages = webidl.converters["sequence<KeyUsage>"](
keyUsages,
prefix,
"Argument 5",
);
// 2-3.
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "deriveBits");
// 4-5.
const normalizedDerivedKeyAlgorithmImport = normalizeAlgorithm(
derivedKeyType,
"importKey",
);
// 6-7.
const normalizedDerivedKeyAlgorithmLength = normalizeAlgorithm(
derivedKeyType,
"get key length",
);
// 8-10.
// 11.
if (normalizedAlgorithm.name !== baseKey[_algorithm].name) {
throw new DOMException(
`Invalid algorithm name: ${normalizedAlgorithm.name}`,
"InvalidAccessError",
);
}
// 12.
if (!ArrayPrototypeIncludes(baseKey[_usages], "deriveKey")) {
throw new DOMException(
"'baseKey' usages does not contain 'deriveKey'",
"InvalidAccessError",
);
}
// 13.
const length = getKeyLength(normalizedDerivedKeyAlgorithmLength);
// 14.
const secret = await deriveBits(
normalizedAlgorithm,
baseKey,
length,
);
// 15.
const result = await this.importKey(
"raw",
secret,
normalizedDerivedKeyAlgorithmImport,
extractable,
keyUsages,
);
// 16.
if (
ArrayPrototypeIncludes(["private", "secret"], result[_type]) &&
keyUsages.length == 0
) {
throw new SyntaxError("Invalid key usage");
}
// 17.
return result;
}
/**
* @param {string} algorithm
* @param {CryptoKey} key
* @param {BufferSource} signature
* @param {BufferSource} data
* @returns {Promise<boolean>}
*/
async verify(algorithm, key, signature, data) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'verify' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 4, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
signature = webidl.converters.BufferSource(signature, prefix, "Argument 3");
data = webidl.converters.BufferSource(data, prefix, "Argument 4");
// 2.
signature = copyBuffer(signature);
// 3.
data = copyBuffer(data);
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "verify");
const handle = key[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
if (normalizedAlgorithm.name !== key[_algorithm].name) {
throw new DOMException(
"Verifying algorithm does not match key algorithm",
"InvalidAccessError",
);
}
if (!ArrayPrototypeIncludes(key[_usages], "verify")) {
throw new DOMException(
"Key does not support the 'verify' operation",
"InvalidAccessError",
);
}
switch (normalizedAlgorithm.name) {
case "RSASSA-PKCS1-v1_5": {
if (key[_type] !== "public") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
const hashAlgorithm = key[_algorithm].hash.name;
return await op_crypto_verify_key({
key: keyData,
algorithm: "RSASSA-PKCS1-v1_5",
hash: hashAlgorithm,
signature,
}, data);
}
case "RSA-PSS": {
if (key[_type] !== "public") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
const hashAlgorithm = key[_algorithm].hash.name;
return await op_crypto_verify_key({
key: keyData,
algorithm: "RSA-PSS",
hash: hashAlgorithm,
signature,
saltLength: normalizedAlgorithm.saltLength,
}, data);
}
case "HMAC": {
const hash = key[_algorithm].hash.name;
return await op_crypto_verify_key({
key: keyData,
algorithm: "HMAC",
hash,
signature,
}, data);
}
case "ECDSA": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
const hash = normalizedAlgorithm.hash.name;
if (
(key[_algorithm].namedCurve === "P-256" && hash !== "SHA-256") ||
(key[_algorithm].namedCurve === "P-384" && hash !== "SHA-384")
) {
throw new DOMException(
"Not implemented",
"NotSupportedError",
);
}
// 3-8.
return await op_crypto_verify_key({
key: keyData,
algorithm: "ECDSA",
hash,
signature,
namedCurve: key[_algorithm].namedCurve,
}, data);
}
case "Ed25519": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
return op_crypto_verify_ed25519(keyData, data, signature);
}
}
throw new TypeError("Unreachable");
}
/**
* @param {string} algorithm
* @param {boolean} extractable
* @param {KeyUsage[]} keyUsages
* @returns {Promise<any>}
*/
async wrapKey(format, key, wrappingKey, wrapAlgorithm) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'wrapKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 4, prefix);
format = webidl.converters.KeyFormat(format, prefix, "Argument 1");
key = webidl.converters.CryptoKey(key, prefix, "Argument 2");
wrappingKey = webidl.converters.CryptoKey(
wrappingKey,
prefix,
"Argument 3",
);
wrapAlgorithm = webidl.converters.AlgorithmIdentifier(
wrapAlgorithm,
prefix,
"Argument 4",
);
let normalizedAlgorithm;
try {
// 2.
normalizedAlgorithm = normalizeAlgorithm(wrapAlgorithm, "wrapKey");
} catch (_) {
// 3.
normalizedAlgorithm = normalizeAlgorithm(wrapAlgorithm, "encrypt");
}
// 8.
if (normalizedAlgorithm.name !== wrappingKey[_algorithm].name) {
throw new DOMException(
"Wrapping algorithm does not match key algorithm",
"InvalidAccessError",
);
}
// 9.
if (!ArrayPrototypeIncludes(wrappingKey[_usages], "wrapKey")) {
throw new DOMException(
"Key does not support the 'wrapKey' operation",
"InvalidAccessError",
);
}
// 10. NotSupportedError will be thrown in step 12.
// 11.
if (key[_extractable] === false) {
throw new DOMException(
"Key is not extractable",
"InvalidAccessError",
);
}
// 12.
const exportedKey = await this.exportKey(format, key);
let bytes;
// 13.
if (format !== "jwk") {
bytes = new Uint8Array(exportedKey);
} else {
const jwk = JSONStringify(exportedKey);
const ret = new Uint8Array(jwk.length);
for (let i = 0; i < jwk.length; i++) {
ret[i] = StringPrototypeCharCodeAt(jwk, i);
}
bytes = ret;
}
// 14-15.
if (
supportedAlgorithms["wrapKey"][normalizedAlgorithm.name] !== undefined
) {
const handle = wrappingKey[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
switch (normalizedAlgorithm.name) {
case "AES-KW": {
const cipherText = await op_crypto_wrap_key({
key: keyData,
algorithm: normalizedAlgorithm.name,
}, bytes);
// 4.
return TypedArrayPrototypeGetBuffer(cipherText);
}
default: {
throw new DOMException(
"Not implemented",
"NotSupportedError",
);
}
}
} else if (
supportedAlgorithms["encrypt"][normalizedAlgorithm.name] !== undefined
) {
// must construct a new key, since keyUsages is ["wrapKey"] and not ["encrypt"]
return await encrypt(
normalizedAlgorithm,
constructKey(
wrappingKey[_type],
wrappingKey[_extractable],
["encrypt"],
wrappingKey[_algorithm],
wrappingKey[_handle],
),
bytes,
);
} else {
throw new DOMException(
"Algorithm not supported",
"NotSupportedError",
);
}
}
/**
* @param {string} format
* @param {BufferSource} wrappedKey
* @param {CryptoKey} unwrappingKey
* @param {AlgorithmIdentifier} unwrapAlgorithm
* @param {AlgorithmIdentifier} unwrappedKeyAlgorithm
* @param {boolean} extractable
* @param {KeyUsage[]} keyUsages
* @returns {Promise<CryptoKey>}
*/
async unwrapKey(
format,
wrappedKey,
unwrappingKey,
unwrapAlgorithm,
unwrappedKeyAlgorithm,
extractable,
keyUsages,
) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'unwrapKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 7, prefix);
format = webidl.converters.KeyFormat(format, prefix, "Argument 1");
wrappedKey = webidl.converters.BufferSource(
wrappedKey,
prefix,
"Argument 2",
);
unwrappingKey = webidl.converters.CryptoKey(
unwrappingKey,
prefix,
"Argument 3",
);
unwrapAlgorithm = webidl.converters.AlgorithmIdentifier(
unwrapAlgorithm,
prefix,
"Argument 4",
);
unwrappedKeyAlgorithm = webidl.converters.AlgorithmIdentifier(
unwrappedKeyAlgorithm,
prefix,
"Argument 5",
);
extractable = webidl.converters.boolean(extractable, prefix, "Argument 6");
keyUsages = webidl.converters["sequence<KeyUsage>"](
keyUsages,
prefix,
"Argument 7",
);
// 2.
wrappedKey = copyBuffer(wrappedKey);
let normalizedAlgorithm;
try {
// 3.
normalizedAlgorithm = normalizeAlgorithm(unwrapAlgorithm, "unwrapKey");
} catch (_) {
// 4.
normalizedAlgorithm = normalizeAlgorithm(unwrapAlgorithm, "decrypt");
}
// 6.
const normalizedKeyAlgorithm = normalizeAlgorithm(
unwrappedKeyAlgorithm,
"importKey",
);
// 11.
if (normalizedAlgorithm.name !== unwrappingKey[_algorithm].name) {
throw new DOMException(
"Unwrapping algorithm does not match key algorithm",
"InvalidAccessError",
);
}
// 12.
if (!ArrayPrototypeIncludes(unwrappingKey[_usages], "unwrapKey")) {
throw new DOMException(
"Key does not support the 'unwrapKey' operation",
"InvalidAccessError",
);
}
// 13.
let key;
if (
supportedAlgorithms["unwrapKey"][normalizedAlgorithm.name] !== undefined
) {
const handle = unwrappingKey[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
switch (normalizedAlgorithm.name) {
case "AES-KW": {
const plainText = await op_crypto_unwrap_key({
key: keyData,
algorithm: normalizedAlgorithm.name,
}, wrappedKey);
// 4.
key = TypedArrayPrototypeGetBuffer(plainText);
break;
}
default: {
throw new DOMException(
"Not implemented",
"NotSupportedError",
);
}
}
} else if (
supportedAlgorithms["decrypt"][normalizedAlgorithm.name] !== undefined
) {
// must construct a new key, since keyUsages is ["unwrapKey"] and not ["decrypt"]
key = await this.decrypt(
normalizedAlgorithm,
constructKey(
unwrappingKey[_type],
unwrappingKey[_extractable],
["decrypt"],
unwrappingKey[_algorithm],
unwrappingKey[_handle],
),
wrappedKey,
);
} else {
throw new DOMException(
"Algorithm not supported",
"NotSupportedError",
);
}
let bytes;
// 14.
if (format !== "jwk") {
bytes = key;
} else {
const k = new Uint8Array(key);
let str = "";
for (let i = 0; i < k.length; i++) {
str += StringFromCharCode(k[i]);
}
bytes = JSONParse(str);
}
// 15.
const result = await this.importKey(
format,
bytes,
normalizedKeyAlgorithm,
extractable,
keyUsages,
);
// 16.
if (
(result[_type] == "secret" || result[_type] == "private") &&
keyUsages.length == 0
) {
throw new SyntaxError("Invalid key type");
}
// 17.
result[_extractable] = extractable;
// 18.
result[_usages] = usageIntersection(keyUsages, recognisedUsages);
// 19.
return result;
}
/**
* @param {string} algorithm
* @param {boolean} extractable
* @param {KeyUsage[]} keyUsages
* @returns {Promise<any>}
*/
async generateKey(algorithm, extractable, keyUsages) {
webidl.assertBranded(this, SubtleCryptoPrototype);
const prefix = "Failed to execute 'generateKey' on 'SubtleCrypto'";
webidl.requiredArguments(arguments.length, 3, prefix);
algorithm = webidl.converters.AlgorithmIdentifier(
algorithm,
prefix,
"Argument 1",
);
extractable = webidl.converters["boolean"](
extractable,
prefix,
"Argument 2",
);
keyUsages = webidl.converters["sequence<KeyUsage>"](
keyUsages,
prefix,
"Argument 3",
);
const usages = keyUsages;
const normalizedAlgorithm = normalizeAlgorithm(algorithm, "generateKey");
const result = await generateKey(
normalizedAlgorithm,
extractable,
usages,
);
if (ObjectPrototypeIsPrototypeOf(CryptoKeyPrototype, result)) {
const type = result[_type];
if ((type === "secret" || type === "private") && usages.length === 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
} else if (
ObjectPrototypeIsPrototypeOf(CryptoKeyPrototype, result.privateKey)
) {
if (result.privateKey[_usages].length === 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
}
return result;
}
[SymbolFor("Deno.privateCustomInspect")](inspect, inspectOptions) {
return `${this.constructor.name} ${inspect({}, inspectOptions)}`;
}
}
const SubtleCryptoPrototype = SubtleCrypto.prototype;
async function generateKey(normalizedAlgorithm, extractable, usages) {
const algorithmName = normalizedAlgorithm.name;
switch (algorithmName) {
case "RSASSA-PKCS1-v1_5":
case "RSA-PSS": {
// 1.
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["sign", "verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2.
const keyData = await op_crypto_generate_key(
{
algorithm: "RSA",
modulusLength: normalizedAlgorithm.modulusLength,
publicExponent: normalizedAlgorithm.publicExponent,
},
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "private",
data: keyData,
});
// 4-8.
const algorithm = {
name: algorithmName,
modulusLength: normalizedAlgorithm.modulusLength,
publicExponent: normalizedAlgorithm.publicExponent,
hash: normalizedAlgorithm.hash,
};
// 9-13.
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, ["verify"]),
algorithm,
handle,
);
// 14-18.
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["sign"]),
algorithm,
handle,
);
// 19-22.
return { publicKey, privateKey };
}
case "RSA-OAEP": {
if (
ArrayPrototypeFind(
usages,
(u) =>
!ArrayPrototypeIncludes([
"encrypt",
"decrypt",
"wrapKey",
"unwrapKey",
], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2.
const keyData = await op_crypto_generate_key(
{
algorithm: "RSA",
modulusLength: normalizedAlgorithm.modulusLength,
publicExponent: normalizedAlgorithm.publicExponent,
},
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "private",
data: keyData,
});
// 4-8.
const algorithm = {
name: algorithmName,
modulusLength: normalizedAlgorithm.modulusLength,
publicExponent: normalizedAlgorithm.publicExponent,
hash: normalizedAlgorithm.hash,
};
// 9-13.
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, ["encrypt", "wrapKey"]),
algorithm,
handle,
);
// 14-18.
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["decrypt", "unwrapKey"]),
algorithm,
handle,
);
// 19-22.
return { publicKey, privateKey };
}
case "ECDSA": {
const namedCurve = normalizedAlgorithm.namedCurve;
// 1.
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["sign", "verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2-3.
const handle = {};
if (
ArrayPrototypeIncludes(
supportedNamedCurves,
namedCurve,
)
) {
const keyData = await op_crypto_generate_key({
algorithm: "EC",
namedCurve,
});
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "private",
data: keyData,
});
} else {
throw new DOMException("Curve not supported", "NotSupportedError");
}
// 4-6.
const algorithm = {
name: algorithmName,
namedCurve,
};
// 7-11.
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, ["verify"]),
algorithm,
handle,
);
// 12-16.
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["sign"]),
algorithm,
handle,
);
// 17-20.
return { publicKey, privateKey };
}
case "ECDH": {
const namedCurve = normalizedAlgorithm.namedCurve;
// 1.
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2-3.
const handle = {};
if (
ArrayPrototypeIncludes(
supportedNamedCurves,
namedCurve,
)
) {
const keyData = await op_crypto_generate_key({
algorithm: "EC",
namedCurve,
});
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "private",
data: keyData,
});
} else {
throw new DOMException("Curve not supported", "NotSupportedError");
}
// 4-6.
const algorithm = {
name: algorithmName,
namedCurve,
};
// 7-11.
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, []),
algorithm,
handle,
);
// 12-16.
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["deriveKey", "deriveBits"]),
algorithm,
handle,
);
// 17-20.
return { publicKey, privateKey };
}
case "AES-CTR":
case "AES-CBC":
case "AES-GCM": {
// 1.
if (
ArrayPrototypeFind(
usages,
(u) =>
!ArrayPrototypeIncludes([
"encrypt",
"decrypt",
"wrapKey",
"unwrapKey",
], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
return generateKeyAES(normalizedAlgorithm, extractable, usages);
}
case "AES-KW": {
// 1.
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["wrapKey", "unwrapKey"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
return generateKeyAES(normalizedAlgorithm, extractable, usages);
}
case "X448": {
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const privateKeyData = new Uint8Array(56);
const publicKeyData = new Uint8Array(56);
op_crypto_generate_x448_keypair(privateKeyData, publicKeyData);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const publicHandle = {};
WeakMapPrototypeSet(KEY_STORE, publicHandle, publicKeyData);
const algorithm = {
name: algorithmName,
};
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, []),
algorithm,
publicHandle,
);
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["deriveKey", "deriveBits"]),
algorithm,
handle,
);
return { publicKey, privateKey };
}
case "X25519": {
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const privateKeyData = new Uint8Array(32);
const publicKeyData = new Uint8Array(32);
op_crypto_generate_x25519_keypair(privateKeyData, publicKeyData);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const publicHandle = {};
WeakMapPrototypeSet(KEY_STORE, publicHandle, publicKeyData);
const algorithm = {
name: algorithmName,
};
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, []),
algorithm,
publicHandle,
);
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["deriveKey", "deriveBits"]),
algorithm,
handle,
);
return { publicKey, privateKey };
}
case "Ed25519": {
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["sign", "verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const ED25519_SEED_LEN = 32;
const ED25519_PUBLIC_KEY_LEN = 32;
const privateKeyData = new Uint8Array(ED25519_SEED_LEN);
const publicKeyData = new Uint8Array(ED25519_PUBLIC_KEY_LEN);
if (
!op_crypto_generate_ed25519_keypair(privateKeyData, publicKeyData)
) {
throw new DOMException("Failed to generate key", "OperationError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const publicHandle = {};
WeakMapPrototypeSet(KEY_STORE, publicHandle, publicKeyData);
const algorithm = {
name: algorithmName,
};
const publicKey = constructKey(
"public",
true,
usageIntersection(usages, ["verify"]),
algorithm,
publicHandle,
);
const privateKey = constructKey(
"private",
extractable,
usageIntersection(usages, ["sign"]),
algorithm,
handle,
);
return { publicKey, privateKey };
}
case "HMAC": {
// 1.
if (
ArrayPrototypeFind(
usages,
(u) => !ArrayPrototypeIncludes(["sign", "verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2.
let length;
if (normalizedAlgorithm.length === undefined) {
length = null;
} else if (normalizedAlgorithm.length !== 0) {
length = normalizedAlgorithm.length;
} else {
throw new DOMException("Invalid length", "OperationError");
}
// 3-4.
const keyData = await op_crypto_generate_key({
algorithm: "HMAC",
hash: normalizedAlgorithm.hash.name,
length,
});
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data: keyData,
});
// 6-10.
const algorithm = {
name: algorithmName,
hash: {
name: normalizedAlgorithm.hash.name,
},
length: TypedArrayPrototypeGetByteLength(keyData) * 8,
};
// 5, 11-13.
const key = constructKey(
"secret",
extractable,
usages,
algorithm,
handle,
);
// 14.
return key;
}
}
}
function importKeyX448(
format,
keyData,
extractable,
keyUsages,
) {
switch (format) {
case "raw": {
// 1.
if (keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, keyData);
// 2-3.
const algorithm = {
name: "X448",
};
// 4-6.
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
case "spki": {
// 1.
if (keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const publicKeyData = new Uint8Array(56);
if (!op_crypto_import_spki_x448(keyData, publicKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "X448",
};
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
case "pkcs8": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const privateKeyData = new Uint8Array(32);
if (!op_crypto_import_pkcs8_x448(keyData, privateKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "X448",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
case "jwk": {
// 1.
const jwk = keyData;
// 2.
if (jwk.d !== undefined) {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
["deriveKey", "deriveBits"],
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
}
// 3.
if (jwk.d === undefined && keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 4.
if (jwk.kty !== "OKP") {
throw new DOMException("Invalid key type", "DataError");
}
// 5.
if (jwk.crv !== "X448") {
throw new DOMException("Invalid curve", "DataError");
}
// 6.
if (keyUsages.length > 0 && jwk.use !== undefined) {
if (jwk.use !== "enc") {
throw new DOMException("Invalid key use", "DataError");
}
}
// 7.
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
// 8.
if (jwk.ext !== undefined && jwk.ext === false && extractable) {
throw new DOMException("Invalid key extractability", "DataError");
}
// 9.
if (jwk.d !== undefined) {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
const privateKeyData = op_crypto_base64url_decode(jwk.d);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "X448",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, ["deriveKey", "deriveBits"]),
algorithm,
handle,
);
} else {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
const publicKeyData = op_crypto_base64url_decode(jwk.x);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "X448",
};
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function importKeyEd25519(
format,
keyData,
extractable,
keyUsages,
) {
switch (format) {
case "raw": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, keyData);
// 2-3.
const algorithm = {
name: "Ed25519",
};
// 4-6.
return constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
case "spki": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const publicKeyData = new Uint8Array(32);
if (!op_crypto_import_spki_ed25519(keyData, publicKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "Ed25519",
};
return constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
case "pkcs8": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["sign"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const privateKeyData = new Uint8Array(32);
if (!op_crypto_import_pkcs8_ed25519(keyData, privateKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "Ed25519",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
case "jwk": {
// 1.
const jwk = keyData;
// 2.
if (jwk.d !== undefined) {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
["sign"],
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
} else {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
["verify"],
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
}
// 3.
if (jwk.kty !== "OKP") {
throw new DOMException("Invalid key type", "DataError");
}
// 4.
if (jwk.crv !== "Ed25519") {
throw new DOMException("Invalid curve", "DataError");
}
// 5.
if (
keyUsages.length > 0 && jwk.use !== undefined && jwk.use !== "sig"
) {
throw new DOMException("Invalid key usage", "DataError");
}
// 6.
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
// 7.
if (jwk.ext !== undefined && jwk.ext === false && extractable) {
throw new DOMException("Invalid key extractability", "DataError");
}
// 8.
if (jwk.d !== undefined) {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
let privateKeyData;
try {
privateKeyData = op_crypto_base64url_decode(jwk.d);
} catch (_) {
throw new DOMException("Invalid private key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "Ed25519",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
} else {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
let publicKeyData;
try {
publicKeyData = op_crypto_base64url_decode(jwk.x);
} catch (_) {
throw new DOMException("Invalid public key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "Ed25519",
};
return constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function importKeyX25519(
format,
keyData,
extractable,
keyUsages,
) {
switch (format) {
case "raw": {
// 1.
if (keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, keyData);
// 2-3.
const algorithm = {
name: "X25519",
};
// 4-6.
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
case "spki": {
// 1.
if (keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const publicKeyData = new Uint8Array(32);
if (!op_crypto_import_spki_x25519(keyData, publicKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "X25519",
};
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
case "pkcs8": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const privateKeyData = new Uint8Array(32);
if (!op_crypto_import_pkcs8_x25519(keyData, privateKeyData)) {
throw new DOMException("Invalid key data", "DataError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "X25519",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
}
case "jwk": {
// 1.
const jwk = keyData;
// 2.
if (jwk.d !== undefined) {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
["deriveKey", "deriveBits"],
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
}
// 3.
if (jwk.d === undefined && keyUsages.length > 0) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 4.
if (jwk.kty !== "OKP") {
throw new DOMException("Invalid key type", "DataError");
}
// 5.
if (jwk.crv !== "X25519") {
throw new DOMException("Invalid curve", "DataError");
}
// 6.
if (keyUsages.length > 0 && jwk.use !== undefined) {
if (jwk.use !== "enc") {
throw new DOMException("Invalid key use", "DataError");
}
}
// 7.
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
// 8.
if (jwk.ext !== undefined && jwk.ext === false && extractable) {
throw new DOMException("Invalid key extractability", "DataError");
}
// 9.
if (jwk.d !== undefined) {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
const privateKeyData = op_crypto_base64url_decode(jwk.d);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, privateKeyData);
const algorithm = {
name: "X25519",
};
return constructKey(
"private",
extractable,
usageIntersection(keyUsages, ["deriveKey", "deriveBits"]),
algorithm,
handle,
);
} else {
// https://www.rfc-editor.org/rfc/rfc8037#section-2
const publicKeyData = op_crypto_base64url_decode(jwk.x);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, publicKeyData);
const algorithm = {
name: "X25519",
};
return constructKey(
"public",
extractable,
[],
algorithm,
handle,
);
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyAES(
format,
key,
innerKey,
) {
switch (format) {
// 2.
case "raw": {
// 1.
const data = innerKey.data;
// 2.
return TypedArrayPrototypeGetBuffer(data);
}
case "jwk": {
// 1-2.
const jwk = {
kty: "oct",
};
// 3.
const data = op_crypto_export_key({
format: "jwksecret",
algorithm: "AES",
}, innerKey);
ObjectAssign(jwk, data);
// 4.
const algorithm = key[_algorithm];
switch (algorithm.length) {
case 128:
jwk.alg = aesJwkAlg[algorithm.name][128];
break;
case 192:
jwk.alg = aesJwkAlg[algorithm.name][192];
break;
case 256:
jwk.alg = aesJwkAlg[algorithm.name][256];
break;
default:
throw new DOMException(
`Invalid key length: ${algorithm.length}`,
"NotSupportedError",
);
}
// 5.
jwk.key_ops = key.usages;
// 6.
jwk.ext = key[_extractable];
// 7.
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function importKeyAES(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
supportedKeyUsages,
) {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(supportedKeyUsages, u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
const algorithmName = normalizedAlgorithm.name;
// 2.
let data = keyData;
switch (format) {
case "raw": {
// 2.
if (
!ArrayPrototypeIncludes(
[128, 192, 256],
TypedArrayPrototypeGetByteLength(keyData) * 8,
)
) {
throw new DOMException("Invalid key length", "DataError");
}
break;
}
case "jwk": {
// 1.
const jwk = keyData;
// 2.
if (jwk.kty !== "oct") {
throw new DOMException(
"'kty' property of JsonWebKey must be 'oct'",
"DataError",
);
}
// Section 6.4.1 of RFC7518
if (jwk.k === undefined) {
throw new DOMException(
"'k' property of JsonWebKey must be present",
"DataError",
);
}
// 4.
const { rawData } = op_crypto_import_key(
{ algorithm: "AES" },
{ jwkSecret: jwk },
);
data = rawData.data;
// 5.
switch (TypedArrayPrototypeGetByteLength(data) * 8) {
case 128:
if (
jwk.alg !== undefined &&
jwk.alg !== aesJwkAlg[algorithmName][128]
) {
throw new DOMException(
`Invalid algorithm: ${jwk.alg}`,
"DataError",
);
}
break;
case 192:
if (
jwk.alg !== undefined &&
jwk.alg !== aesJwkAlg[algorithmName][192]
) {
throw new DOMException(
`Invalid algorithm: ${jwk.alg}`,
"DataError",
);
}
break;
case 256:
if (
jwk.alg !== undefined &&
jwk.alg !== aesJwkAlg[algorithmName][256]
) {
throw new DOMException(
`Invalid algorithm: ${jwk.alg}`,
"DataError",
);
}
break;
default:
throw new DOMException(
"Invalid key length",
"DataError",
);
}
// 6.
if (
keyUsages.length > 0 && jwk.use !== undefined && jwk.use !== "enc"
) {
throw new DOMException("Invalid key usage", "DataError");
}
// 7.
// Section 4.3 of RFC7517
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
// 8.
if (jwk.ext === false && extractable === true) {
throw new DOMException(
"'ext' property of JsonWebKey must not be false if extractable is true",
"DataError",
);
}
break;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data,
});
// 4-7.
const algorithm = {
name: algorithmName,
length: TypedArrayPrototypeGetByteLength(data) * 8,
};
const key = constructKey(
"secret",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
// 8.
return key;
}
function importKeyHMAC(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
) {
// 2.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["sign", "verify"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 3.
let hash;
let data;
// 4. https://w3c.github.io/webcrypto/#hmac-operations
switch (format) {
case "raw": {
data = keyData;
hash = normalizedAlgorithm.hash;
break;
}
case "jwk": {
const jwk = keyData;
// 2.
if (jwk.kty !== "oct") {
throw new DOMException(
"'kty' property of JsonWebKey must be 'oct'",
"DataError",
);
}
// Section 6.4.1 of RFC7518
if (jwk.k === undefined) {
throw new DOMException(
"'k' property of JsonWebKey must be present",
"DataError",
);
}
// 4.
const { rawData } = op_crypto_import_key(
{ algorithm: "HMAC" },
{ jwkSecret: jwk },
);
data = rawData.data;
// 5.
hash = normalizedAlgorithm.hash;
// 6.
switch (hash.name) {
case "SHA-1": {
if (jwk.alg !== undefined && jwk.alg !== "HS1") {
throw new DOMException(
"'alg' property of JsonWebKey must be 'HS1'",
"DataError",
);
}
break;
}
case "SHA-256": {
if (jwk.alg !== undefined && jwk.alg !== "HS256") {
throw new DOMException(
"'alg' property of JsonWebKey must be 'HS256'",
"DataError",
);
}
break;
}
case "SHA-384": {
if (jwk.alg !== undefined && jwk.alg !== "HS384") {
throw new DOMException(
"'alg' property of JsonWebKey must be 'HS384'",
"DataError",
);
}
break;
}
case "SHA-512": {
if (jwk.alg !== undefined && jwk.alg !== "HS512") {
throw new DOMException(
"'alg' property of JsonWebKey must be 'HS512'",
"DataError",
);
}
break;
}
default:
throw new TypeError("Unreachable");
}
// 7.
if (
keyUsages.length > 0 && jwk.use !== undefined && jwk.use !== "sig"
) {
throw new DOMException(
"'use' property of JsonWebKey must be 'sig'",
"DataError",
);
}
// 8.
// Section 4.3 of RFC7517
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
// 9.
if (jwk.ext === false && extractable === true) {
throw new DOMException(
"'ext' property of JsonWebKey must not be false if extractable is true",
"DataError",
);
}
break;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
// 5.
let length = TypedArrayPrototypeGetByteLength(data) * 8;
// 6.
if (length === 0) {
throw new DOMException("Key length is zero", "DataError");
}
// 7.
if (normalizedAlgorithm.length !== undefined) {
if (
normalizedAlgorithm.length > length ||
normalizedAlgorithm.length <= (length - 8)
) {
throw new DOMException(
"Key length is invalid",
"DataError",
);
}
length = normalizedAlgorithm.length;
}
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data,
});
const algorithm = {
name: "HMAC",
length,
hash,
};
const key = constructKey(
"secret",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
function importKeyEC(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
) {
const supportedUsages = SUPPORTED_KEY_USAGES[normalizedAlgorithm.name];
switch (format) {
case "raw": {
// 1.
if (
!ArrayPrototypeIncludes(
supportedNamedCurves,
normalizedAlgorithm.namedCurve,
)
) {
throw new DOMException(
"Invalid namedCurve",
"DataError",
);
}
// 2.
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].public,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 3.
const { rawData } = op_crypto_import_key({
algorithm: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
}, { raw: keyData });
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
// 4-5.
const algorithm = {
name: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
};
// 6-8.
const key = constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
case "pkcs8": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].private,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2-9.
const { rawData } = op_crypto_import_key({
algorithm: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
}, { pkcs8: keyData });
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
};
const key = constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
case "spki": {
// 1.
if (normalizedAlgorithm.name == "ECDSA") {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].public,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
} else if (keyUsages.length != 0) {
throw new DOMException("Key usage must be empty", "SyntaxError");
}
// 2-12
const { rawData } = op_crypto_import_key({
algorithm: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
}, { spki: keyData });
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
};
// 6-8.
const key = constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
case "jwk": {
const jwk = keyData;
const keyType = (jwk.d !== undefined) ? "private" : "public";
// 2.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(supportedUsages[keyType], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 3.
if (jwk.kty !== "EC") {
throw new DOMException(
"'kty' property of JsonWebKey must be 'EC'",
"DataError",
);
}
// 4.
if (
keyUsages.length > 0 && jwk.use !== undefined &&
jwk.use !== supportedUsages.jwkUse
) {
throw new DOMException(
`'use' property of JsonWebKey must be '${supportedUsages.jwkUse}'`,
"DataError",
);
}
// 5.
// Section 4.3 of RFC7517
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' member of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' member of JsonWebKey is invalid",
"DataError",
);
}
}
// 6.
if (jwk.ext === false && extractable === true) {
throw new DOMException(
"'ext' property of JsonWebKey must not be false if extractable is true",
"DataError",
);
}
// 9.
if (jwk.alg !== undefined && normalizedAlgorithm.name == "ECDSA") {
let algNamedCurve;
switch (jwk.alg) {
case "ES256": {
algNamedCurve = "P-256";
break;
}
case "ES384": {
algNamedCurve = "P-384";
break;
}
case "ES512": {
algNamedCurve = "P-521";
break;
}
default:
throw new DOMException(
"Curve algorithm not supported",
"DataError",
);
}
if (algNamedCurve) {
if (algNamedCurve !== normalizedAlgorithm.namedCurve) {
throw new DOMException(
"Mismatched curve algorithm",
"DataError",
);
}
}
}
// Validate that this is a valid public key.
if (jwk.x === undefined) {
throw new DOMException(
"'x' property of JsonWebKey is required for EC keys",
"DataError",
);
}
if (jwk.y === undefined) {
throw new DOMException(
"'y' property of JsonWebKey is required for EC keys",
"DataError",
);
}
if (jwk.d !== undefined) {
// it's also a Private key
const { rawData } = op_crypto_import_key({
algorithm: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
}, { jwkPrivateEc: jwk });
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
};
const key = constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
} else {
const { rawData } = op_crypto_import_key({
algorithm: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
}, { jwkPublicEc: jwk });
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
namedCurve: normalizedAlgorithm.namedCurve,
};
const key = constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
// deno-lint-ignore require-await
async function importKeyInner(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
) {
const algorithmName = normalizedAlgorithm.name;
switch (algorithmName) {
case "HMAC": {
return importKeyHMAC(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
);
}
case "ECDH":
case "ECDSA": {
return importKeyEC(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
);
}
case "RSASSA-PKCS1-v1_5":
case "RSA-PSS":
case "RSA-OAEP": {
return importKeyRSA(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
);
}
case "HKDF": {
return importKeyHKDF(format, keyData, extractable, keyUsages);
}
case "PBKDF2": {
return importKeyPBKDF2(format, keyData, extractable, keyUsages);
}
case "AES-CTR":
case "AES-CBC":
case "AES-GCM": {
return importKeyAES(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
["encrypt", "decrypt", "wrapKey", "unwrapKey"],
);
}
case "AES-KW": {
return importKeyAES(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
["wrapKey", "unwrapKey"],
);
}
case "X448": {
return importKeyX448(
format,
keyData,
extractable,
keyUsages,
);
}
case "X25519": {
return importKeyX25519(
format,
keyData,
extractable,
keyUsages,
);
}
case "Ed25519": {
return importKeyEd25519(
format,
keyData,
extractable,
keyUsages,
);
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
const SUPPORTED_KEY_USAGES = {
"RSASSA-PKCS1-v1_5": {
public: ["verify"],
private: ["sign"],
jwkUse: "sig",
},
"RSA-PSS": {
public: ["verify"],
private: ["sign"],
jwkUse: "sig",
},
"RSA-OAEP": {
public: ["encrypt", "wrapKey"],
private: ["decrypt", "unwrapKey"],
jwkUse: "enc",
},
"ECDSA": {
public: ["verify"],
private: ["sign"],
jwkUse: "sig",
},
"ECDH": {
public: [],
private: ["deriveKey", "deriveBits"],
jwkUse: "enc",
},
};
function importKeyRSA(
format,
normalizedAlgorithm,
keyData,
extractable,
keyUsages,
) {
switch (format) {
case "pkcs8": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].private,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2-9.
const { modulusLength, publicExponent, rawData } = op_crypto_import_key(
{
algorithm: normalizedAlgorithm.name,
// Needed to perform step 7 without normalization.
hash: normalizedAlgorithm.hash.name,
},
{ pkcs8: keyData },
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
modulusLength,
publicExponent,
hash: normalizedAlgorithm.hash,
};
const key = constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
case "spki": {
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].public,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2-9.
const { modulusLength, publicExponent, rawData } = op_crypto_import_key(
{
algorithm: normalizedAlgorithm.name,
// Needed to perform step 7 without normalization.
hash: normalizedAlgorithm.hash.name,
},
{ spki: keyData },
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
modulusLength,
publicExponent,
hash: normalizedAlgorithm.hash,
};
const key = constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
case "jwk": {
// 1.
const jwk = keyData;
// 2.
if (jwk.d !== undefined) {
if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].private,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
} else if (
ArrayPrototypeFind(
keyUsages,
(u) =>
!ArrayPrototypeIncludes(
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].public,
u,
),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 3.
if (StringPrototypeToUpperCase(jwk.kty) !== "RSA") {
throw new DOMException(
"'kty' property of JsonWebKey must be 'RSA'",
"DataError",
);
}
// 4.
if (
keyUsages.length > 0 && jwk.use !== undefined &&
StringPrototypeToLowerCase(jwk.use) !==
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].jwkUse
) {
throw new DOMException(
`'use' property of JsonWebKey must be '${
SUPPORTED_KEY_USAGES[normalizedAlgorithm.name].jwkUse
}'`,
"DataError",
);
}
// 5.
if (jwk.key_ops !== undefined) {
if (
ArrayPrototypeFind(
jwk.key_ops,
(u) => !ArrayPrototypeIncludes(recognisedUsages, u),
) !== undefined
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
if (
!ArrayPrototypeEvery(
jwk.key_ops,
(u) => ArrayPrototypeIncludes(keyUsages, u),
)
) {
throw new DOMException(
"'key_ops' property of JsonWebKey is invalid",
"DataError",
);
}
}
if (jwk.ext === false && extractable === true) {
throw new DOMException(
"'ext' property of JsonWebKey must not be false if extractable is true",
"DataError",
);
}
// 7.
let hash;
// 8.
if (normalizedAlgorithm.name === "RSASSA-PKCS1-v1_5") {
switch (jwk.alg) {
case undefined:
hash = undefined;
break;
case "RS1":
hash = "SHA-1";
break;
case "RS256":
hash = "SHA-256";
break;
case "RS384":
hash = "SHA-384";
break;
case "RS512":
hash = "SHA-512";
break;
default:
throw new DOMException(
`'alg' property of JsonWebKey must be one of 'RS1', 'RS256', 'RS384', 'RS512': received ${jwk.alg}`,
"DataError",
);
}
} else if (normalizedAlgorithm.name === "RSA-PSS") {
switch (jwk.alg) {
case undefined:
hash = undefined;
break;
case "PS1":
hash = "SHA-1";
break;
case "PS256":
hash = "SHA-256";
break;
case "PS384":
hash = "SHA-384";
break;
case "PS512":
hash = "SHA-512";
break;
default:
throw new DOMException(
`'alg' property of JsonWebKey must be one of 'PS1', 'PS256', 'PS384', 'PS512': received ${jwk.alg}`,
"DataError",
);
}
} else {
switch (jwk.alg) {
case undefined:
hash = undefined;
break;
case "RSA-OAEP":
hash = "SHA-1";
break;
case "RSA-OAEP-256":
hash = "SHA-256";
break;
case "RSA-OAEP-384":
hash = "SHA-384";
break;
case "RSA-OAEP-512":
hash = "SHA-512";
break;
default:
throw new DOMException(
`'alg' property of JsonWebKey must be one of 'RSA-OAEP', 'RSA-OAEP-256', 'RSA-OAEP-384', or 'RSA-OAEP-512': received ${jwk.alg}`,
"DataError",
);
}
}
// 9.
if (hash !== undefined) {
// 9.1.
const normalizedHash = normalizeAlgorithm(hash, "digest");
// 9.2.
if (normalizedHash.name !== normalizedAlgorithm.hash.name) {
throw new DOMException(
`'alg' property of JsonWebKey must be '${normalizedAlgorithm.name}': received ${jwk.alg}`,
"DataError",
);
}
}
// 10.
if (jwk.d !== undefined) {
// Private key
const optimizationsPresent = jwk.p !== undefined ||
jwk.q !== undefined || jwk.dp !== undefined ||
jwk.dq !== undefined || jwk.qi !== undefined;
if (optimizationsPresent) {
if (jwk.q === undefined) {
throw new DOMException(
"'q' property of JsonWebKey is required for private keys",
"DataError",
);
}
if (jwk.dp === undefined) {
throw new DOMException(
"'dp' property of JsonWebKey is required for private keys",
"DataError",
);
}
if (jwk.dq === undefined) {
throw new DOMException(
"'dq' property of JsonWebKey is required for private keys",
"DataError",
);
}
if (jwk.qi === undefined) {
throw new DOMException(
"'qi' property of JsonWebKey is required for private keys",
"DataError",
);
}
if (jwk.oth !== undefined) {
throw new DOMException(
"'oth' property of JsonWebKey is not supported",
"NotSupportedError",
);
}
} else {
throw new DOMException(
"Only optimized private keys are supported",
"NotSupportedError",
);
}
const { modulusLength, publicExponent, rawData } = op_crypto_import_key(
{
algorithm: normalizedAlgorithm.name,
hash: normalizedAlgorithm.hash.name,
},
{ jwkPrivateRsa: jwk },
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
modulusLength,
publicExponent,
hash: normalizedAlgorithm.hash,
};
const key = constructKey(
"private",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
} else {
// Validate that this is a valid public key.
if (jwk.n === undefined) {
throw new DOMException(
"'n' property of JsonWebKey is required for public keys",
"DataError",
);
}
if (jwk.e === undefined) {
throw new DOMException(
"'e' property of JsonWebKey is required for public keys",
"DataError",
);
}
const { modulusLength, publicExponent, rawData } = op_crypto_import_key(
{
algorithm: normalizedAlgorithm.name,
hash: normalizedAlgorithm.hash.name,
},
{ jwkPublicRsa: jwk },
);
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, rawData);
const algorithm = {
name: normalizedAlgorithm.name,
modulusLength,
publicExponent,
hash: normalizedAlgorithm.hash,
};
const key = constructKey(
"public",
extractable,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
return key;
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function importKeyHKDF(
format,
keyData,
extractable,
keyUsages,
) {
if (format !== "raw") {
throw new DOMException("Format not supported", "NotSupportedError");
}
// 1.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 2.
if (extractable !== false) {
throw new DOMException(
"Key must not be extractable",
"SyntaxError",
);
}
// 3.
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data: keyData,
});
// 4-8.
const algorithm = {
name: "HKDF",
};
const key = constructKey(
"secret",
false,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
// 9.
return key;
}
function importKeyPBKDF2(
format,
keyData,
extractable,
keyUsages,
) {
// 1.
if (format !== "raw") {
throw new DOMException("Format not supported", "NotSupportedError");
}
// 2.
if (
ArrayPrototypeFind(
keyUsages,
(u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u),
) !== undefined
) {
throw new DOMException("Invalid key usage", "SyntaxError");
}
// 3.
if (extractable !== false) {
throw new DOMException(
"Key must not be extractable",
"SyntaxError",
);
}
// 4.
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data: keyData,
});
// 5-9.
const algorithm = {
name: "PBKDF2",
};
const key = constructKey(
"secret",
false,
usageIntersection(keyUsages, recognisedUsages),
algorithm,
handle,
);
// 10.
return key;
}
function exportKeyHMAC(format, key, innerKey) {
// 1.
if (innerKey == null) {
throw new DOMException("Key is not available", "OperationError");
}
switch (format) {
// 3.
case "raw": {
const bits = innerKey.data;
// TODO(petamoriken): Uint8Array does not have push method
// for (let _i = 7 & (8 - bits.length % 8); _i > 0; _i--) {
// bits.push(0);
// }
// 4-5.
return TypedArrayPrototypeGetBuffer(bits);
}
case "jwk": {
// 1-2.
const jwk = {
kty: "oct",
};
// 3.
const data = op_crypto_export_key({
format: "jwksecret",
algorithm: key[_algorithm].name,
}, innerKey);
jwk.k = data.k;
// 4.
const algorithm = key[_algorithm];
// 5.
const hash = algorithm.hash;
// 6.
switch (hash.name) {
case "SHA-1":
jwk.alg = "HS1";
break;
case "SHA-256":
jwk.alg = "HS256";
break;
case "SHA-384":
jwk.alg = "HS384";
break;
case "SHA-512":
jwk.alg = "HS512";
break;
default:
throw new DOMException(
"Hash algorithm not supported",
"NotSupportedError",
);
}
// 7.
jwk.key_ops = key.usages;
// 8.
jwk.ext = key[_extractable];
// 9.
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyRSA(format, key, innerKey) {
switch (format) {
case "pkcs8": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key is not a private key",
"InvalidAccessError",
);
}
// 2.
const data = op_crypto_export_key({
algorithm: key[_algorithm].name,
format: "pkcs8",
}, innerKey);
// 3.
return TypedArrayPrototypeGetBuffer(data);
}
case "spki": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2.
const data = op_crypto_export_key({
algorithm: key[_algorithm].name,
format: "spki",
}, innerKey);
// 3.
return TypedArrayPrototypeGetBuffer(data);
}
case "jwk": {
// 1-2.
const jwk = {
kty: "RSA",
};
// 3.
const hash = key[_algorithm].hash.name;
// 4.
if (key[_algorithm].name === "RSASSA-PKCS1-v1_5") {
switch (hash) {
case "SHA-1":
jwk.alg = "RS1";
break;
case "SHA-256":
jwk.alg = "RS256";
break;
case "SHA-384":
jwk.alg = "RS384";
break;
case "SHA-512":
jwk.alg = "RS512";
break;
default:
throw new DOMException(
"Hash algorithm not supported",
"NotSupportedError",
);
}
} else if (key[_algorithm].name === "RSA-PSS") {
switch (hash) {
case "SHA-1":
jwk.alg = "PS1";
break;
case "SHA-256":
jwk.alg = "PS256";
break;
case "SHA-384":
jwk.alg = "PS384";
break;
case "SHA-512":
jwk.alg = "PS512";
break;
default:
throw new DOMException(
"Hash algorithm not supported",
"NotSupportedError",
);
}
} else {
switch (hash) {
case "SHA-1":
jwk.alg = "RSA-OAEP";
break;
case "SHA-256":
jwk.alg = "RSA-OAEP-256";
break;
case "SHA-384":
jwk.alg = "RSA-OAEP-384";
break;
case "SHA-512":
jwk.alg = "RSA-OAEP-512";
break;
default:
throw new DOMException(
"Hash algorithm not supported",
"NotSupportedError",
);
}
}
// 5-6.
const data = op_crypto_export_key({
format: key[_type] === "private" ? "jwkprivate" : "jwkpublic",
algorithm: key[_algorithm].name,
}, innerKey);
ObjectAssign(jwk, data);
// 7.
jwk.key_ops = key.usages;
// 8.
jwk.ext = key[_extractable];
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyEd25519(format, key, innerKey) {
switch (format) {
case "raw": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2-3.
return TypedArrayPrototypeGetBuffer(innerKey);
}
case "spki": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
const spkiDer = op_crypto_export_spki_ed25519(innerKey);
return TypedArrayPrototypeGetBuffer(spkiDer);
}
case "pkcs8": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
const pkcs8Der = op_crypto_export_pkcs8_ed25519(
new Uint8Array([0x04, 0x22, ...new SafeArrayIterator(innerKey)]),
);
pkcs8Der[15] = 0x20;
return TypedArrayPrototypeGetBuffer(pkcs8Der);
}
case "jwk": {
const x = key[_type] === "private"
? op_crypto_jwk_x_ed25519(innerKey)
: op_crypto_base64url_encode(innerKey);
const jwk = {
kty: "OKP",
crv: "Ed25519",
x,
"key_ops": key.usages,
ext: key[_extractable],
};
if (key[_type] === "private") {
jwk.d = op_crypto_base64url_encode(innerKey);
}
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyX448(format, key, innerKey) {
switch (format) {
case "raw": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2-3.
return TypedArrayPrototypeGetBuffer(innerKey);
}
case "spki": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
const spkiDer = op_crypto_export_spki_x448(innerKey);
return TypedArrayPrototypeGetBuffer(spkiDer);
}
case "pkcs8": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key is not a private key",
"InvalidAccessError",
);
}
const pkcs8Der = op_crypto_export_pkcs8_x448(
new Uint8Array([0x04, 0x22, ...new SafeArrayIterator(innerKey)]),
);
pkcs8Der[15] = 0x20;
return TypedArrayPrototypeGetBuffer(pkcs8Der);
}
case "jwk": {
if (key[_type] === "private") {
throw new DOMException("Not implemented", "NotSupportedError");
}
const x = op_crypto_base64url_encode(innerKey);
const jwk = {
kty: "OKP",
crv: "X448",
x,
"key_ops": key.usages,
ext: key[_extractable],
};
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyX25519(format, key, innerKey) {
switch (format) {
case "raw": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2-3.
return TypedArrayPrototypeGetBuffer(innerKey);
}
case "spki": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
const spkiDer = op_crypto_export_spki_x25519(innerKey);
return TypedArrayPrototypeGetBuffer(spkiDer);
}
case "pkcs8": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
const pkcs8Der = op_crypto_export_pkcs8_x25519(
new Uint8Array([0x04, 0x22, ...new SafeArrayIterator(innerKey)]),
);
pkcs8Der[15] = 0x20;
return TypedArrayPrototypeGetBuffer(pkcs8Der);
}
case "jwk": {
if (key[_type] === "private") {
throw new DOMException("Not implemented", "NotSupportedError");
}
const x = op_crypto_base64url_encode(innerKey);
const jwk = {
kty: "OKP",
crv: "X25519",
x,
"key_ops": key.usages,
ext: key[_extractable],
};
return jwk;
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
function exportKeyEC(format, key, innerKey) {
switch (format) {
case "raw": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2.
const data = op_crypto_export_key({
algorithm: key[_algorithm].name,
namedCurve: key[_algorithm].namedCurve,
format: "raw",
}, innerKey);
return TypedArrayPrototypeGetBuffer(data);
}
case "pkcs8": {
// 1.
if (key[_type] !== "private") {
throw new DOMException(
"Key is not a private key",
"InvalidAccessError",
);
}
// 2.
const data = op_crypto_export_key({
algorithm: key[_algorithm].name,
namedCurve: key[_algorithm].namedCurve,
format: "pkcs8",
}, innerKey);
return TypedArrayPrototypeGetBuffer(data);
}
case "spki": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key is not a public key",
"InvalidAccessError",
);
}
// 2.
const data = op_crypto_export_key({
algorithm: key[_algorithm].name,
namedCurve: key[_algorithm].namedCurve,
format: "spki",
}, innerKey);
return TypedArrayPrototypeGetBuffer(data);
}
case "jwk": {
if (key[_algorithm].name == "ECDSA") {
// 1-2.
const jwk = {
kty: "EC",
};
// 3.1
jwk.crv = key[_algorithm].namedCurve;
// Missing from spec
let algNamedCurve;
switch (key[_algorithm].namedCurve) {
case "P-256": {
algNamedCurve = "ES256";
break;
}
case "P-384": {
algNamedCurve = "ES384";
break;
}
case "P-521": {
algNamedCurve = "ES512";
break;
}
default:
throw new DOMException(
"Curve algorithm not supported",
"DataError",
);
}
jwk.alg = algNamedCurve;
// 3.2 - 3.4.
const data = op_crypto_export_key({
format: key[_type] === "private" ? "jwkprivate" : "jwkpublic",
algorithm: key[_algorithm].name,
namedCurve: key[_algorithm].namedCurve,
}, innerKey);
ObjectAssign(jwk, data);
// 4.
jwk.key_ops = key.usages;
// 5.
jwk.ext = key[_extractable];
return jwk;
} else { // ECDH
// 1-2.
const jwk = {
kty: "EC",
};
// missing step from spec
jwk.alg = "ECDH";
// 3.1
jwk.crv = key[_algorithm].namedCurve;
// 3.2 - 3.4
const data = op_crypto_export_key({
format: key[_type] === "private" ? "jwkprivate" : "jwkpublic",
algorithm: key[_algorithm].name,
namedCurve: key[_algorithm].namedCurve,
}, innerKey);
ObjectAssign(jwk, data);
// 4.
jwk.key_ops = key.usages;
// 5.
jwk.ext = key[_extractable];
return jwk;
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
async function generateKeyAES(normalizedAlgorithm, extractable, usages) {
const algorithmName = normalizedAlgorithm.name;
// 2.
if (!ArrayPrototypeIncludes([128, 192, 256], normalizedAlgorithm.length)) {
throw new DOMException(
`Invalid key length: ${normalizedAlgorithm.length}`,
"OperationError",
);
}
// 3.
const keyData = await op_crypto_generate_key({
algorithm: "AES",
length: normalizedAlgorithm.length,
});
const handle = {};
WeakMapPrototypeSet(KEY_STORE, handle, {
type: "secret",
data: keyData,
});
// 6-8.
const algorithm = {
name: algorithmName,
length: normalizedAlgorithm.length,
};
// 9-11.
const key = constructKey(
"secret",
extractable,
usages,
algorithm,
handle,
);
// 12.
return key;
}
async function deriveBits(normalizedAlgorithm, baseKey, length) {
switch (normalizedAlgorithm.name) {
case "PBKDF2": {
// 1.
if (length == null || length == 0 || length % 8 !== 0) {
throw new DOMException("Invalid length", "OperationError");
}
if (normalizedAlgorithm.iterations == 0) {
throw new DOMException(
"iterations must not be zero",
"OperationError",
);
}
const handle = baseKey[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
normalizedAlgorithm.salt = copyBuffer(normalizedAlgorithm.salt);
const buf = await op_crypto_derive_bits({
key: keyData,
algorithm: "PBKDF2",
hash: normalizedAlgorithm.hash.name,
iterations: normalizedAlgorithm.iterations,
length,
}, normalizedAlgorithm.salt);
return TypedArrayPrototypeGetBuffer(buf);
}
case "ECDH": {
// 1.
if (baseKey[_type] !== "private") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 2.
const publicKey = normalizedAlgorithm.public;
// 3.
if (publicKey[_type] !== "public") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 4.
if (publicKey[_algorithm].name !== baseKey[_algorithm].name) {
throw new DOMException(
"Algorithm mismatch",
"InvalidAccessError",
);
}
// 5.
if (
publicKey[_algorithm].namedCurve !== baseKey[_algorithm].namedCurve
) {
throw new DOMException(
"'namedCurve' mismatch",
"InvalidAccessError",
);
}
// 6.
if (
ArrayPrototypeIncludes(
supportedNamedCurves,
publicKey[_algorithm].namedCurve,
)
) {
const baseKeyhandle = baseKey[_handle];
const baseKeyData = WeakMapPrototypeGet(KEY_STORE, baseKeyhandle);
const publicKeyhandle = publicKey[_handle];
const publicKeyData = WeakMapPrototypeGet(KEY_STORE, publicKeyhandle);
const buf = await op_crypto_derive_bits({
key: baseKeyData,
publicKey: publicKeyData,
algorithm: "ECDH",
namedCurve: publicKey[_algorithm].namedCurve,
length: length ?? 0,
});
// 8.
if (length === null) {
return TypedArrayPrototypeGetBuffer(buf);
} else if (TypedArrayPrototypeGetByteLength(buf) * 8 < length) {
throw new DOMException("Invalid length", "OperationError");
} else {
return ArrayBufferPrototypeSlice(
TypedArrayPrototypeGetBuffer(buf),
0,
MathCeil(length / 8),
);
}
} else {
throw new DOMException("Not implemented", "NotSupportedError");
}
}
case "HKDF": {
// 1.
if (length === null || length === 0 || length % 8 !== 0) {
throw new DOMException("Invalid length", "OperationError");
}
const handle = baseKey[_handle];
const keyDerivationKey = WeakMapPrototypeGet(KEY_STORE, handle);
normalizedAlgorithm.salt = copyBuffer(normalizedAlgorithm.salt);
normalizedAlgorithm.info = copyBuffer(normalizedAlgorithm.info);
const buf = await op_crypto_derive_bits({
key: keyDerivationKey,
algorithm: "HKDF",
hash: normalizedAlgorithm.hash.name,
info: normalizedAlgorithm.info,
length,
}, normalizedAlgorithm.salt);
return TypedArrayPrototypeGetBuffer(buf);
}
case "X448": {
// 1.
if (baseKey[_type] !== "private") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 2.
const publicKey = normalizedAlgorithm.public;
// 3.
if (publicKey[_type] !== "public") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 4.
if (publicKey[_algorithm].name !== baseKey[_algorithm].name) {
throw new DOMException(
"Algorithm mismatch",
"InvalidAccessError",
);
}
// 5.
const kHandle = baseKey[_handle];
const k = WeakMapPrototypeGet(KEY_STORE, kHandle);
const uHandle = publicKey[_handle];
const u = WeakMapPrototypeGet(KEY_STORE, uHandle);
const secret = new Uint8Array(56);
const isIdentity = op_crypto_derive_bits_x448(k, u, secret);
// 6.
if (isIdentity) {
throw new DOMException("Invalid key", "OperationError");
}
// 7.
if (length === null) {
return TypedArrayPrototypeGetBuffer(secret);
} else if (
TypedArrayPrototypeGetByteLength(secret) * 8 < length
) {
throw new DOMException("Invalid length", "OperationError");
} else {
return ArrayBufferPrototypeSlice(
TypedArrayPrototypeGetBuffer(secret),
0,
MathCeil(length / 8),
);
}
}
case "X25519": {
// 1.
if (baseKey[_type] !== "private") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 2.
const publicKey = normalizedAlgorithm.public;
// 3.
if (publicKey[_type] !== "public") {
throw new DOMException("Invalid key type", "InvalidAccessError");
}
// 4.
if (publicKey[_algorithm].name !== baseKey[_algorithm].name) {
throw new DOMException(
"Algorithm mismatch",
"InvalidAccessError",
);
}
// 5.
const kHandle = baseKey[_handle];
const k = WeakMapPrototypeGet(KEY_STORE, kHandle);
const uHandle = publicKey[_handle];
const u = WeakMapPrototypeGet(KEY_STORE, uHandle);
const secret = new Uint8Array(32);
const isIdentity = op_crypto_derive_bits_x25519(k, u, secret);
// 6.
if (isIdentity) {
throw new DOMException("Invalid key", "OperationError");
}
// 7.
if (length === null) {
return TypedArrayPrototypeGetBuffer(secret);
} else if (
TypedArrayPrototypeGetByteLength(secret) * 8 < length
) {
throw new DOMException("Invalid length", "OperationError");
} else {
return ArrayBufferPrototypeSlice(
TypedArrayPrototypeGetBuffer(secret),
0,
MathCeil(length / 8),
);
}
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
async function encrypt(normalizedAlgorithm, key, data) {
const handle = key[_handle];
const keyData = WeakMapPrototypeGet(KEY_STORE, handle);
switch (normalizedAlgorithm.name) {
case "RSA-OAEP": {
// 1.
if (key[_type] !== "public") {
throw new DOMException(
"Key type not supported",
"InvalidAccessError",
);
}
// 2.
if (normalizedAlgorithm.label) {
normalizedAlgorithm.label = copyBuffer(normalizedAlgorithm.label);
} else {
normalizedAlgorithm.label = new Uint8Array();
}
// 3-5.
const hashAlgorithm = key[_algorithm].hash.name;
const cipherText = await op_crypto_encrypt({
key: keyData,
algorithm: "RSA-OAEP",
hash: hashAlgorithm,
label: normalizedAlgorithm.label,
}, data);
// 6.
return TypedArrayPrototypeGetBuffer(cipherText);
}
case "AES-CBC": {
normalizedAlgorithm.iv = copyBuffer(normalizedAlgorithm.iv);
// 1.
if (TypedArrayPrototypeGetByteLength(normalizedAlgorithm.iv) !== 16) {
throw new DOMException(
"Initialization vector must be 16 bytes",
"OperationError",
);
}
// 2.
const cipherText = await op_crypto_encrypt({
key: keyData,
algorithm: "AES-CBC",
length: key[_algorithm].length,
iv: normalizedAlgorithm.iv,
}, data);
// 4.
return TypedArrayPrototypeGetBuffer(cipherText);
}
case "AES-CTR": {
normalizedAlgorithm.counter = copyBuffer(normalizedAlgorithm.counter);
// 1.
if (
TypedArrayPrototypeGetByteLength(normalizedAlgorithm.counter) !== 16
) {
throw new DOMException(
"Counter vector must be 16 bytes",
"OperationError",
);
}
// 2.
if (
normalizedAlgorithm.length == 0 || normalizedAlgorithm.length > 128
) {
throw new DOMException(
"Counter length must not be 0 or greater than 128",
"OperationError",
);
}
// 3.
const cipherText = await op_crypto_encrypt({
key: keyData,
algorithm: "AES-CTR",
keyLength: key[_algorithm].length,
counter: normalizedAlgorithm.counter,
ctrLength: normalizedAlgorithm.length,
}, data);
// 4.
return TypedArrayPrototypeGetBuffer(cipherText);
}
case "AES-GCM": {
normalizedAlgorithm.iv = copyBuffer(normalizedAlgorithm.iv);
// 1.
if (TypedArrayPrototypeGetByteLength(data) > (2 ** 39) - 256) {
throw new DOMException(
"Plaintext too large",
"OperationError",
);
}
// 2.
// We only support 96-bit and 128-bit nonce.
if (
ArrayPrototypeIncludes(
[12, 16],
TypedArrayPrototypeGetByteLength(normalizedAlgorithm.iv),
) === undefined
) {
throw new DOMException(
"Initialization vector length not supported",
"NotSupportedError",
);
}
// 3.
// NOTE: over the size of Number.MAX_SAFE_INTEGER is not available in V8
// if (normalizedAlgorithm.additionalData !== undefined) {
// if (normalizedAlgorithm.additionalData.byteLength > (2 ** 64) - 1) {
// throw new DOMException(
// "Additional data too large",
// "OperationError",
// );
// }
// }
// 4.
if (normalizedAlgorithm.tagLength == undefined) {
normalizedAlgorithm.tagLength = 128;
} else if (
!ArrayPrototypeIncludes(
[32, 64, 96, 104, 112, 120, 128],
normalizedAlgorithm.tagLength,
)
) {
throw new DOMException(
`Invalid tag length: ${normalizedAlgorithm.tagLength}`,
"OperationError",
);
}
// 5.
if (normalizedAlgorithm.additionalData) {
normalizedAlgorithm.additionalData = copyBuffer(
normalizedAlgorithm.additionalData,
);
}
// 6-7.
const cipherText = await op_crypto_encrypt({
key: keyData,
algorithm: "AES-GCM",
length: key[_algorithm].length,
iv: normalizedAlgorithm.iv,
additionalData: normalizedAlgorithm.additionalData || null,
tagLength: normalizedAlgorithm.tagLength,
}, data);
// 8.
return TypedArrayPrototypeGetBuffer(cipherText);
}
default:
throw new DOMException("Not implemented", "NotSupportedError");
}
}
webidl.configureInterface(SubtleCrypto);
const subtle = webidl.createBranded(SubtleCrypto);
class Crypto {
constructor() {
webidl.illegalConstructor();
}
getRandomValues(typedArray) {
webidl.assertBranded(this, CryptoPrototype);
const prefix = "Failed to execute 'getRandomValues' on 'Crypto'";
webidl.requiredArguments(arguments.length, 1, prefix);
// Fast path for Uint8Array
const tag = TypedArrayPrototypeGetSymbolToStringTag(typedArray);
if (tag === "Uint8Array") {
op_crypto_get_random_values(typedArray);
return typedArray;
}
typedArray = webidl.converters.ArrayBufferView(
typedArray,
prefix,
"Argument 1",
);
switch (tag) {
case "Int8Array":
case "Uint8ClampedArray":
case "Int16Array":
case "Uint16Array":
case "Int32Array":
case "Uint32Array":
case "BigInt64Array":
case "BigUint64Array":
break;
default:
throw new DOMException(
"The provided ArrayBufferView is not an integer array type",
"TypeMismatchError",
);
}
const ui8 = new Uint8Array(
TypedArrayPrototypeGetBuffer(typedArray),
TypedArrayPrototypeGetByteOffset(typedArray),
TypedArrayPrototypeGetByteLength(typedArray),
);
op_crypto_get_random_values(ui8);
return typedArray;
}
randomUUID() {
webidl.assertBranded(this, CryptoPrototype);
return op_crypto_random_uuid();
}
get subtle() {
webidl.assertBranded(this, CryptoPrototype);
return subtle;
}
[SymbolFor("Deno.privateCustomInspect")](inspect, inspectOptions) {
return inspect(
createFilteredInspectProxy({
object: this,
evaluate: ObjectPrototypeIsPrototypeOf(CryptoPrototype, this),
keys: ["subtle"],
}),
inspectOptions,
);
}
}
webidl.configureInterface(Crypto);
const CryptoPrototype = Crypto.prototype;
const crypto = webidl.createBranded(Crypto);
webidl.converters.AlgorithmIdentifier = (V, prefix, context, opts) => {
// Union for (object or DOMString)
if (webidl.type(V) == "Object") {
return webidl.converters.object(V, prefix, context, opts);
}
return webidl.converters.DOMString(V, prefix, context, opts);
};
webidl.converters["BufferSource or JsonWebKey"] = (
V,
prefix,
context,
opts,
) => {
// Union for (BufferSource or JsonWebKey)
if (ArrayBufferIsView(V) || isArrayBuffer(V)) {
return webidl.converters.BufferSource(V, prefix, context, opts);
}
return webidl.converters.JsonWebKey(V, prefix, context, opts);
};
webidl.converters.KeyType = webidl.createEnumConverter("KeyType", [
"public",
"private",
"secret",
]);
webidl.converters.KeyFormat = webidl.createEnumConverter("KeyFormat", [
"raw",
"pkcs8",
"spki",
"jwk",
]);
webidl.converters.KeyUsage = webidl.createEnumConverter("KeyUsage", [
"encrypt",
"decrypt",
"sign",
"verify",
"deriveKey",
"deriveBits",
"wrapKey",
"unwrapKey",
]);
webidl.converters["sequence<KeyUsage>"] = webidl.createSequenceConverter(
webidl.converters.KeyUsage,
);
webidl.converters.HashAlgorithmIdentifier =
webidl.converters.AlgorithmIdentifier;
/** @type {webidl.Dictionary} */
const dictAlgorithm = [{
key: "name",
converter: webidl.converters.DOMString,
required: true,
}];
webidl.converters.Algorithm = webidl
.createDictionaryConverter("Algorithm", dictAlgorithm);
webidl.converters.BigInteger = webidl.converters.Uint8Array;
/** @type {webidl.Dictionary} */
const dictRsaKeyGenParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "modulusLength",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
{
key: "publicExponent",
converter: webidl.converters.BigInteger,
required: true,
},
];
webidl.converters.RsaKeyGenParams = webidl
.createDictionaryConverter("RsaKeyGenParams", dictRsaKeyGenParams);
const dictRsaHashedKeyGenParams = [
...new SafeArrayIterator(dictRsaKeyGenParams),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
];
webidl.converters.RsaHashedKeyGenParams = webidl.createDictionaryConverter(
"RsaHashedKeyGenParams",
dictRsaHashedKeyGenParams,
);
const dictRsaHashedImportParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
];
webidl.converters.RsaHashedImportParams = webidl.createDictionaryConverter(
"RsaHashedImportParams",
dictRsaHashedImportParams,
);
webidl.converters.NamedCurve = webidl.converters.DOMString;
const dictEcKeyImportParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "namedCurve",
converter: webidl.converters.NamedCurve,
required: true,
},
];
webidl.converters.EcKeyImportParams = webidl.createDictionaryConverter(
"EcKeyImportParams",
dictEcKeyImportParams,
);
const dictEcKeyGenParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "namedCurve",
converter: webidl.converters.NamedCurve,
required: true,
},
];
webidl.converters.EcKeyGenParams = webidl
.createDictionaryConverter("EcKeyGenParams", dictEcKeyGenParams);
const dictAesKeyGenParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "length",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned short"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
];
webidl.converters.AesKeyGenParams = webidl
.createDictionaryConverter("AesKeyGenParams", dictAesKeyGenParams);
const dictHmacKeyGenParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
{
key: "length",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
},
];
webidl.converters.HmacKeyGenParams = webidl
.createDictionaryConverter("HmacKeyGenParams", dictHmacKeyGenParams);
const dictRsaPssParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "saltLength",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
];
webidl.converters.RsaPssParams = webidl
.createDictionaryConverter("RsaPssParams", dictRsaPssParams);
const dictRsaOaepParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "label",
converter: webidl.converters["BufferSource"],
},
];
webidl.converters.RsaOaepParams = webidl
.createDictionaryConverter("RsaOaepParams", dictRsaOaepParams);
const dictEcdsaParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
];
webidl.converters["EcdsaParams"] = webidl
.createDictionaryConverter("EcdsaParams", dictEcdsaParams);
const dictHmacImportParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
{
key: "length",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
},
];
webidl.converters.HmacImportParams = webidl
.createDictionaryConverter("HmacImportParams", dictHmacImportParams);
const dictRsaOtherPrimesInfo = [
{
key: "r",
converter: webidl.converters["DOMString"],
},
{
key: "d",
converter: webidl.converters["DOMString"],
},
{
key: "t",
converter: webidl.converters["DOMString"],
},
];
webidl.converters.RsaOtherPrimesInfo = webidl.createDictionaryConverter(
"RsaOtherPrimesInfo",
dictRsaOtherPrimesInfo,
);
webidl.converters["sequence<RsaOtherPrimesInfo>"] = webidl
.createSequenceConverter(
webidl.converters.RsaOtherPrimesInfo,
);
const dictJsonWebKey = [
// Sections 4.2 and 4.3 of RFC7517.
// https://datatracker.ietf.org/doc/html/rfc7517#section-4
{
key: "kty",
converter: webidl.converters["DOMString"],
},
{
key: "use",
converter: webidl.converters["DOMString"],
},
{
key: "key_ops",
converter: webidl.converters["sequence<DOMString>"],
},
{
key: "alg",
converter: webidl.converters["DOMString"],
},
// JSON Web Key Parameters Registration
{
key: "ext",
converter: webidl.converters["boolean"],
},
// Section 6 of RFC7518 JSON Web Algorithms
// https://datatracker.ietf.org/doc/html/rfc7518#section-6
{
key: "crv",
converter: webidl.converters["DOMString"],
},
{
key: "x",
converter: webidl.converters["DOMString"],
},
{
key: "y",
converter: webidl.converters["DOMString"],
},
{
key: "d",
converter: webidl.converters["DOMString"],
},
{
key: "n",
converter: webidl.converters["DOMString"],
},
{
key: "e",
converter: webidl.converters["DOMString"],
},
{
key: "p",
converter: webidl.converters["DOMString"],
},
{
key: "q",
converter: webidl.converters["DOMString"],
},
{
key: "dp",
converter: webidl.converters["DOMString"],
},
{
key: "dq",
converter: webidl.converters["DOMString"],
},
{
key: "qi",
converter: webidl.converters["DOMString"],
},
{
key: "oth",
converter: webidl.converters["sequence<RsaOtherPrimesInfo>"],
},
{
key: "k",
converter: webidl.converters["DOMString"],
},
];
webidl.converters.JsonWebKey = webidl.createDictionaryConverter(
"JsonWebKey",
dictJsonWebKey,
);
const dictHkdfParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
{
key: "salt",
converter: webidl.converters["BufferSource"],
required: true,
},
{
key: "info",
converter: webidl.converters["BufferSource"],
required: true,
},
];
webidl.converters.HkdfParams = webidl
.createDictionaryConverter("HkdfParams", dictHkdfParams);
const dictPbkdf2Params = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "hash",
converter: webidl.converters.HashAlgorithmIdentifier,
required: true,
},
{
key: "iterations",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
{
key: "salt",
converter: webidl.converters["BufferSource"],
required: true,
},
];
webidl.converters.Pbkdf2Params = webidl
.createDictionaryConverter("Pbkdf2Params", dictPbkdf2Params);
const dictAesDerivedKeyParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "length",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
];
const dictAesCbcParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "iv",
converter: webidl.converters["BufferSource"],
required: true,
},
];
const dictAesGcmParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "iv",
converter: webidl.converters["BufferSource"],
required: true,
},
{
key: "tagLength",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned long"](V, prefix, context, {
...opts,
enforceRange: true,
}),
},
{
key: "additionalData",
converter: webidl.converters["BufferSource"],
},
];
const dictAesCtrParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "counter",
converter: webidl.converters["BufferSource"],
required: true,
},
{
key: "length",
converter: (V, prefix, context, opts) =>
webidl.converters["unsigned short"](V, prefix, context, {
...opts,
enforceRange: true,
}),
required: true,
},
];
webidl.converters.AesDerivedKeyParams = webidl
.createDictionaryConverter("AesDerivedKeyParams", dictAesDerivedKeyParams);
webidl.converters.AesCbcParams = webidl
.createDictionaryConverter("AesCbcParams", dictAesCbcParams);
webidl.converters.AesGcmParams = webidl
.createDictionaryConverter("AesGcmParams", dictAesGcmParams);
webidl.converters.AesCtrParams = webidl
.createDictionaryConverter("AesCtrParams", dictAesCtrParams);
webidl.converters.CryptoKey = webidl.createInterfaceConverter(
"CryptoKey",
CryptoKey.prototype,
);
const dictCryptoKeyPair = [
{
key: "publicKey",
converter: webidl.converters.CryptoKey,
},
{
key: "privateKey",
converter: webidl.converters.CryptoKey,
},
];
webidl.converters.CryptoKeyPair = webidl
.createDictionaryConverter("CryptoKeyPair", dictCryptoKeyPair);
const dictEcdhKeyDeriveParams = [
...new SafeArrayIterator(dictAlgorithm),
{
key: "public",
converter: webidl.converters.CryptoKey,
required: true,
},
];
webidl.converters.EcdhKeyDeriveParams = webidl
.createDictionaryConverter("EcdhKeyDeriveParams", dictEcdhKeyDeriveParams);
export { Crypto, crypto, CryptoKey, SubtleCrypto };