// Copyright 2018-2021 the Deno authors. All rights reserved. MIT license. // @ts-check /// /// /// /// "use strict"; ((window) => { const core = window.Deno.core; const webidl = window.__bootstrap.webidl; const { DOMException } = window.__bootstrap.domException; const { atob, btoa } = window.__bootstrap.base64; const { ArrayPrototypeFind, ArrayPrototypeEvery, ArrayPrototypeIncludes, ArrayBuffer, ArrayBufferIsView, BigInt64Array, StringPrototypeToUpperCase, StringPrototypeReplace, StringPrototypeCharCodeAt, StringFromCharCode, Symbol, SymbolFor, SymbolToStringTag, WeakMap, WeakMapPrototypeGet, WeakMapPrototypeSet, Int8Array, Uint8Array, TypedArrayPrototypeSlice, Int16Array, Uint16Array, Int32Array, Uint32Array, Uint8ClampedArray, TypeError, } = window.__bootstrap.primordials; // P-521 is not yet supported. const supportedNamedCurves = ["P-256", "P-384"]; const recognisedUsages = [ "encrypt", "decrypt", "sign", "verify", "deriveKey", "deriveBits", "wrapKey", "unwrapKey", ]; const simpleAlgorithmDictionaries = { 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" }, }; 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", }, "sign": { "RSASSA-PKCS1-v1_5": null, "RSA-PSS": "RsaPssParams", "ECDSA": "EcdsaParams", "HMAC": null, }, "verify": { "RSASSA-PKCS1-v1_5": null, "RSA-PSS": "RsaPssParams", "ECDSA": "EcdsaParams", "HMAC": null, }, "importKey": { "RSASSA-PKCS1-v1_5": "RsaHashedImportParams", "RSA-PSS": "RsaHashedImportParams", "RSA-OAEP": "RsaHashedImportParams", "HMAC": "HmacImportParams", "HKDF": null, "PBKDF2": null, }, "deriveBits": { "HKDF": "HkdfParams", "PBKDF2": "Pbkdf2Params", }, "encrypt": { "RSA-OAEP": "RsaOaepParams", }, "decrypt": { "RSA-OAEP": "RsaOaepParams", }, }; // Decodes the unpadded base64 to the octet sequence containing key value `k` defined in RFC7518 Section 6.4 function decodeSymmetricKey(key) { // Decode from base64url without `=` padding. const base64 = StringPrototypeReplace( StringPrototypeReplace(key, /\-/g, "+"), /\_/g, "/", ); const decodedKey = atob(base64); const keyLength = decodedKey.length; const keyBytes = new Uint8Array(keyLength); for (let i = 0; i < keyLength; i++) { keyBytes[i] = StringPrototypeCharCodeAt(decodedKey, i); } return keyBytes; } function unpaddedBase64(bytes) { let binaryString = ""; for (let i = 0; i < bytes.length; i++) { binaryString += StringFromCharCode(bytes[i]); } const base64String = btoa(binaryString); return StringPrototypeReplace(base64String, /=/g, ""); } // 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, { prefix: "Failed to normalize algorithm", context: "passed algorithm", }); // 4. let algName = initialAlg.name; // 5. let desiredType = undefined; for (const key in registeredAlgorithms) { 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, { prefix: "Failed to normalize algorithm", context: "passed algorithm", }); // 7. normalizedAlgorithm.name = algName; // 9. const dict = simpleAlgorithmDictionaries[desiredType]; // 10. for (const member in dict) { const idlType = dict[member]; const idlValue = normalizedAlgorithm[member]; // 3. if (idlType === "BufferSource" && idlValue) { normalizedAlgorithm[member] = TypedArrayPrototypeSlice( new Uint8Array( (ArrayBufferIsView(idlValue) ? idlValue.buffer : idlValue), idlValue.byteOffset ?? 0, idlValue.byteLength, ), ); } else if (idlType === "HashAlgorithmIdentifier") { normalizedAlgorithm[member] = normalizeAlgorithm(idlValue, "digest"); } else if (idlType === "AlgorithmIdentifier") { // TODO(lucacasonato): implement throw new TypeError("unimplemented"); } } return normalizedAlgorithm; } 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, CryptoKey); return this[_type]; } /** @returns {boolean} */ get extractable() { webidl.assertBranded(this, CryptoKey); return this[_extractable]; } /** @returns {string[]} */ get usages() { webidl.assertBranded(this, CryptoKey); // TODO(lucacasonato): return a SameObject copy return this[_usages]; } /** @returns {object} */ get algorithm() { webidl.assertBranded(this, CryptoKey); // TODO(lucacasonato): return a SameObject copy return this[_algorithm]; } get [SymbolToStringTag]() { return "CryptoKey"; } [SymbolFor("Deno.customInspect")](inspect) { return `${this.constructor.name} ${ inspect({ type: this.type, extractable: this.extractable, algorithm: this.algorithm, usages: this.usages, }) }`; } } webidl.configurePrototype(CryptoKey); /** * @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 a.filter((i) => b.includes(i)); } // TODO(lucacasonato): this should be moved to rust /** @type {WeakMap} */ const KEY_STORE = new WeakMap(); class SubtleCrypto { constructor() { webidl.illegalConstructor(); } /** * @param {string} algorithm * @param {BufferSource} data * @returns {Promise} */ async digest(algorithm, data) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'digest' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 2, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); data = webidl.converters.BufferSource(data, { prefix, context: "Argument 2", }); if (ArrayBufferIsView(data)) { data = new Uint8Array(data.buffer, data.byteOffset, data.byteLength); } else { data = new Uint8Array(data); } data = TypedArrayPrototypeSlice(data); algorithm = normalizeAlgorithm(algorithm, "digest"); const result = await core.opAsync( "op_crypto_subtle_digest", algorithm.name, data, ); return result.buffer; } /** * @param {string} algorithm * @param {CryptoKey} key * @param {BufferSource} data * @returns {Promise} */ async encrypt(algorithm, key, data) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'encrypt' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 3, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); key = webidl.converters.CryptoKey(key, { prefix, context: "Argument 2", }); data = webidl.converters.BufferSource(data, { prefix, context: "Argument 3", }); // 2. if (ArrayBufferIsView(data)) { data = new Uint8Array(data.buffer, data.byteOffset, data.byteLength); } else { data = new Uint8Array(data); } data = TypedArrayPrototypeSlice(data); // 3. const normalizedAlgorithm = normalizeAlgorithm(algorithm, "encrypt"); 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) { if (ArrayBufferIsView(normalizedAlgorithm.label)) { normalizedAlgorithm.label = new Uint8Array( normalizedAlgorithm.label.buffer, normalizedAlgorithm.label.byteOffset, normalizedAlgorithm.label.byteLength, ); } else { normalizedAlgorithm.label = new Uint8Array( normalizedAlgorithm.label, ); } normalizedAlgorithm.label = TypedArrayPrototypeSlice( normalizedAlgorithm.label, ); } else { normalizedAlgorithm.label = new Uint8Array(); } // 3-5. const hashAlgorithm = key[_algorithm].hash.name; const cipherText = await core.opAsync("op_crypto_encrypt_key", { key: keyData, algorithm: "RSA-OAEP", hash: hashAlgorithm, }, data); // 6. return cipherText.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } /** * @param {string} algorithm * @param {CryptoKey} key * @param {BufferSource} data * @returns {Promise} */ async decrypt(algorithm, key, data) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'decrypt' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 3, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); key = webidl.converters.CryptoKey(key, { prefix, context: "Argument 2", }); data = webidl.converters.BufferSource(data, { prefix, context: "Argument 3", }); // 2. if (ArrayBufferIsView(data)) { data = new Uint8Array(data.buffer, data.byteOffset, data.byteLength); } else { data = new Uint8Array(data); } data = TypedArrayPrototypeSlice(data); // 3. const normalizedAlgorithm = normalizeAlgorithm(algorithm, "decrypt"); 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) { if (ArrayBufferIsView(normalizedAlgorithm.label)) { normalizedAlgorithm.label = new Uint8Array( normalizedAlgorithm.label.buffer, normalizedAlgorithm.label.byteOffset, normalizedAlgorithm.label.byteLength, ); } else { normalizedAlgorithm.label = new Uint8Array( normalizedAlgorithm.label, ); } normalizedAlgorithm.label = TypedArrayPrototypeSlice( normalizedAlgorithm.label, ); } else { normalizedAlgorithm.label = new Uint8Array(); } // 3-5. const hashAlgorithm = key[_algorithm].hash.name; const plainText = await core.opAsync("op_crypto_decrypt_key", { key: keyData, algorithm: "RSA-OAEP", hash: hashAlgorithm, label: normalizedAlgorithm.label, }, data); // 6. return plainText.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } /** * @param {string} algorithm * @param {CryptoKey} key * @param {BufferSource} data * @returns {Promise} */ async sign(algorithm, key, data) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'sign' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 3, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); key = webidl.converters.CryptoKey(key, { prefix, context: "Argument 2", }); data = webidl.converters.BufferSource(data, { prefix, context: "Argument 3", }); // 1. if (ArrayBufferIsView(data)) { data = new Uint8Array(data.buffer, data.byteOffset, data.byteLength); } else { data = new Uint8Array(data); } data = TypedArrayPrototypeSlice(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 doesn't 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 core.opAsync("op_crypto_sign_key", { key: keyData, algorithm: "RSASSA-PKCS1-v1_5", hash: hashAlgorithm, }, data); return signature.buffer; } 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 core.opAsync("op_crypto_sign_key", { key: keyData, algorithm: "RSA-PSS", hash: hashAlgorithm, saltLength: normalizedAlgorithm.saltLength, }, data); return signature.buffer; } 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"); } const signature = await core.opAsync("op_crypto_sign_key", { key: keyData, algorithm: "ECDSA", hash: hashAlgorithm, namedCurve, }, data); return signature.buffer; } case "HMAC": { const hashAlgorithm = key[_algorithm].hash.name; const signature = await core.opAsync("op_crypto_sign_key", { key: keyData, algorithm: "HMAC", hash: hashAlgorithm, }, data); return signature.buffer; } } throw new TypeError("unreachable"); } /** * @param {string} format * @param {BufferSource} keyData * @param {string} algorithm * @param {boolean} extractable * @param {KeyUsages[]} keyUsages * @returns {Promise} */ async importKey(format, keyData, algorithm, extractable, keyUsages) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'importKey' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 4, { prefix }); format = webidl.converters.KeyFormat(format, { prefix, context: "Argument 1", }); keyData = webidl.converters["BufferSource or JsonWebKey"](keyData, { prefix, context: "Argument 2", }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 3", }); extractable = webidl.converters.boolean(extractable, { prefix, context: "Argument 4", }); keyUsages = webidl.converters["sequence"](keyUsages, { prefix, context: "Argument 5", }); // 2. if (format !== "jwk") { if (ArrayBufferIsView(keyData) || keyData instanceof ArrayBuffer) { if (ArrayBufferIsView(keyData)) { keyData = new Uint8Array( keyData.buffer, keyData.byteOffset, keyData.byteLength, ); } else { keyData = new Uint8Array(keyData); } keyData = TypedArrayPrototypeSlice(keyData); } else { throw new TypeError("keyData is a JsonWebKey"); } } else { if (ArrayBufferIsView(keyData) || keyData instanceof ArrayBuffer) { throw new TypeError("keyData is not a JsonWebKey"); } } const normalizedAlgorithm = normalizeAlgorithm(algorithm, "importKey"); switch (normalizedAlgorithm.name) { case "HMAC": { // 2. if ( ArrayPrototypeFind( keyUsages, (u) => !ArrayPrototypeIncludes(["sign", "verify"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "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": { // TODO(@littledivy): Why does the spec validate JWK twice? const jwk = keyData; // 2. if (jwk.kty !== "oct") { throw new DOMException( "`kty` member of JsonWebKey must be `oct`", "DataError", ); } // Section 6.4.1 of RFC7518 if (!jwk.k) { throw new DOMException( "`k` member of JsonWebKey must be present", "DataError", ); } // 4. data = decodeSymmetricKey(jwk.k); // 5. hash = normalizedAlgorithm.hash; // 6. switch (hash.name) { case "SHA-1": { if (jwk.alg !== undefined && jwk.alg !== "HS1") { throw new DOMException( "`alg` member of JsonWebKey must be `HS1`", "DataError", ); } break; } case "SHA-256": { if (jwk.alg !== undefined && jwk.alg !== "HS256") { throw new DOMException( "`alg` member of JsonWebKey must be `HS256`", "DataError", ); } break; } case "SHA-384": { if (jwk.alg !== undefined && jwk.alg !== "HS384") { throw new DOMException( "`alg` member of JsonWebKey must be `HS384`", "DataError", ); } break; } case "SHA-512": { if (jwk.alg !== undefined && jwk.alg !== "HS512") { throw new DOMException( "`alg` member of JsonWebKey must be `HS512`", "DataError", ); } break; } default: throw new TypeError("unreachable"); } // 7. if (keyUsages.length > 0 && jwk.use && jwk.use !== "sign") { throw new DOMException( "`use` member of JsonWebKey must be `sign`", "DataError", ); } // 8. // Section 4.3 of RFC7517 if (jwk.key_ops) { 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", ); } } // 9. if (jwk.ext === false && extractable == true) { throw new DOMException( "`ext` member of JsonWebKey is invalid", "DataError", ); } break; } default: throw new DOMException("Not implemented", "NotSupportedError"); } // 5. let length = data.byteLength * 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; } if (keyUsages.length == 0) { throw new DOMException("Key usage is empty", "SyntaxError"); } const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { type: "raw", data, }); const algorithm = { name: "HMAC", length, hash, }; const key = constructKey( "secret", extractable, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); return key; } case "RSASSA-PKCS1-v1_5": { switch (format) { case "pkcs8": { // 1. if ( ArrayPrototypeFind( keyUsages, (u) => !ArrayPrototypeIncludes(["sign"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } if (keyUsages.length == 0) { throw new DOMException("Key usage is empty", "SyntaxError"); } // 2-9. const { modulusLength, publicExponent, data } = await core .opAsync( "op_crypto_import_key", { algorithm: "RSASSA-PKCS1-v1_5", format: "pkcs8", // Needed to perform step 7 without normalization. hash: normalizedAlgorithm.hash.name, }, keyData, ); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { // PKCS#1 for RSA type: "raw", data, }); const algorithm = { name: "RSASSA-PKCS1-v1_5", modulusLength, publicExponent, hash: normalizedAlgorithm.hash, }; const key = constructKey( "private", extractable, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); return key; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } case "RSA-PSS": { switch (format) { case "pkcs8": { // 1. if ( ArrayPrototypeFind( keyUsages, (u) => !ArrayPrototypeIncludes(["sign"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } if (keyUsages.length == 0) { throw new DOMException("Key usage is empty", "SyntaxError"); } // 2-9. const { modulusLength, publicExponent, data } = await core .opAsync( "op_crypto_import_key", { algorithm: "RSA-PSS", format: "pkcs8", // Needed to perform step 7 without normalization. hash: normalizedAlgorithm.hash.name, }, keyData, ); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { // PKCS#1 for RSA type: "raw", data, }); const algorithm = { name: "RSA-PSS", modulusLength, publicExponent, hash: normalizedAlgorithm.hash, }; const key = constructKey( "private", extractable, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); return key; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } case "RSA-OAEP": { switch (format) { case "pkcs8": { // 1. if ( ArrayPrototypeFind( keyUsages, (u) => !ArrayPrototypeIncludes(["decrypt", "unwrapKey"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } if (keyUsages.length == 0) { throw new DOMException("Key usage is empty", "SyntaxError"); } // 2-9. const { modulusLength, publicExponent, data } = await core .opAsync( "op_crypto_import_key", { algorithm: "RSA-OAEP", format: "pkcs8", // Needed to perform step 7 without normalization. hash: normalizedAlgorithm.hash.name, }, keyData, ); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { // PKCS#1 for RSA type: "raw", data, }); const algorithm = { name: "RSA-OAEP", modulusLength, publicExponent, hash: normalizedAlgorithm.hash, }; const key = constructKey( "private", extractable, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); return key; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } // TODO(@littledivy): ECDSA case "HKDF": { 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 usages", "SyntaxError"); } // 2. if (extractable !== false) { throw new DOMException( "Key must not be extractable", "SyntaxError", ); } // 3. const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { type: "raw", data: keyData, }); // 4-8. const algorithm = { name: "HKDF", }; const key = constructKey( "secret", false, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); // 9. return key; } case "PBKDF2": { // 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 usages", "SyntaxError"); } // 3. if (extractable !== false) { throw new DOMException( "Key must not be extractable", "SyntaxError", ); } // 4. const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { type: "raw", data: keyData, }); // 5-9. const algorithm = { name: "PBKDF2", }; const key = constructKey( "secret", false, usageIntersection(keyUsages, recognisedUsages), algorithm, handle, ); // 10. return key; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } /** * @param {string} format * @param {CryptoKey} key * @returns {Promise} */ async exportKey(format, key) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'exportKey' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 2, { prefix }); format = webidl.converters.KeyFormat(format, { prefix, context: "Argument 1", }); key = webidl.converters.CryptoKey(key, { prefix, context: "Argument 2", }); const handle = key[_handle]; // 2. const innerKey = WeakMapPrototypeGet(KEY_STORE, handle); switch (key[_algorithm].name) { case "HMAC": { if (innerKey == null) { throw new DOMException("Key is not available", "OperationError"); } switch (format) { // 3. case "raw": { const bits = innerKey.data; for (let _i = 7 & (8 - bits.length % 8); _i > 0; _i--) { bits.push(0); } // 4-5. return bits.buffer; } case "jwk": { // 1-3. const jwk = { kty: "oct", k: unpaddedBase64(innerKey.data), }; // 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"); } // TODO(@littledivy): Redundant break but deno_lint complains without it break; } case "RSASSA-PKCS1-v1_5": { switch (format) { case "pkcs8": { // 1. if (key[_type] !== "private") { throw new DOMException( "Key is not a private key", "InvalidAccessError", ); } // 2. const data = await core.opAsync( "op_crypto_export_key", { key: innerKey, format: "pkcs8", algorithm: "RSASSA-PKCS1-v1_5", }, ); // 3. return data.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } case "RSA-PSS": { switch (format) { case "pkcs8": { // 1. if (key[_type] !== "private") { throw new DOMException( "Key is not a private key", "InvalidAccessError", ); } // 2. const data = await core.opAsync( "op_crypto_export_key", { key: innerKey, format: "pkcs8", algorithm: "RSA-PSS", hash: key[_algorithm].hash.name, }, ); // 3. return data.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } case "RSA-OAEP": { switch (format) { case "pkcs8": { // 1. if (key[_type] !== "private") { throw new DOMException( "Key is not a private key", "InvalidAccessError", ); } // 2. const data = await core.opAsync( "op_crypto_export_key", { key: innerKey, format: "pkcs8", algorithm: "RSA-PSS", hash: key[_algorithm].hash.name, }, ); // 3. return data.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } // TODO(@littledivy): ECDSA default: throw new DOMException("Not implemented", "NotSupportedError"); } } /** * @param {AlgorithmIdentifier} algorithm * @param {CryptoKey} baseKey * @param {number} length * @returns {Promise} */ async deriveBits(algorithm, baseKey, length) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'deriveBits' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 3, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); baseKey = webidl.converters.CryptoKey(baseKey, { prefix, context: "Argument 2", }); length = webidl.converters["unsigned long"](length, { prefix, context: "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("InvalidAccessError", "Invalid algorithm name"); } // 8. if (!ArrayPrototypeIncludes(baseKey[_usages], "deriveBits")) { throw new DOMException( "InvalidAccessError", "baseKey usages does not contain `deriveBits`", ); } // 9-10. return result; } /** * @param {string} algorithm * @param {CryptoKey} key * @param {BufferSource} signature * @param {BufferSource} data * @returns {Promise} */ async verify(algorithm, key, signature, data) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'verify' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 4, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); key = webidl.converters.CryptoKey(key, { prefix, context: "Argument 2", }); signature = webidl.converters.BufferSource(signature, { prefix, context: "Argument 3", }); data = webidl.converters.BufferSource(data, { prefix, context: "Argument 4", }); // 2. if (ArrayBufferIsView(signature)) { signature = new Uint8Array( signature.buffer, signature.byteOffset, signature.byteLength, ); } else { signature = new Uint8Array(signature); } signature = TypedArrayPrototypeSlice(signature); // 3. if (ArrayBufferIsView(data)) { data = new Uint8Array(data.buffer, data.byteOffset, data.byteLength); } else { data = new Uint8Array(data); } data = TypedArrayPrototypeSlice(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 doesn't 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 core.opAsync("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; const saltLength = normalizedAlgorithm.saltLength; return await core.opAsync("op_crypto_verify_key", { key: keyData, algorithm: "RSA-PSS", hash: hashAlgorithm, saltLength, signature, }, data); } case "HMAC": { const hash = key[_algorithm].hash.name; return await core.opAsync("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; // 3-8. return await core.opAsync("op_crypto_verify_key", { key: keyData, algorithm: "ECDSA", hash, signature, namedCurve: key[_algorithm].namedCurve, }, data); } } throw new TypeError("unreachable"); } /** * @param {string} algorithm * @param {boolean} extractable * @param {KeyUsage[]} keyUsages * @returns {Promise} */ async generateKey(algorithm, extractable, keyUsages) { webidl.assertBranded(this, SubtleCrypto); const prefix = "Failed to execute 'generateKey' on 'SubtleCrypto'"; webidl.requiredArguments(arguments.length, 3, { prefix }); algorithm = webidl.converters.AlgorithmIdentifier(algorithm, { prefix, context: "Argument 1", }); extractable = webidl.converters["boolean"](extractable, { prefix, context: "Argument 2", }); keyUsages = webidl.converters["sequence"](keyUsages, { prefix, context: "Argument 3", }); const usages = keyUsages; const normalizedAlgorithm = normalizeAlgorithm(algorithm, "generateKey"); const result = await generateKey( normalizedAlgorithm, extractable, usages, ); if (result instanceof CryptoKey) { const type = result[_type]; if ((type === "secret" || type === "private") && usages.length === 0) { throw new DOMException("Invalid key usages", "SyntaxError"); } } else if (result.privateKey instanceof CryptoKey) { if (result.privateKey[_usages].length === 0) { throw new DOMException("Invalid key usages", "SyntaxError"); } } return result; } get [SymbolToStringTag]() { return "SubtleCrypto"; } } async function generateKey(normalizedAlgorithm, extractable, usages) { switch (normalizedAlgorithm.name) { case "RSASSA-PKCS1-v1_5": case "RSA-PSS": { // 1. if ( ArrayPrototypeFind( usages, (u) => !ArrayPrototypeIncludes(["sign", "verify"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } // 2. const keyData = await core.opAsync( "op_crypto_generate_key", { name: normalizedAlgorithm.name, modulusLength: normalizedAlgorithm.modulusLength, publicExponent: normalizedAlgorithm.publicExponent, }, ); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { // PKCS#1 for RSA type: "raw", data: keyData, }); // 4-8. const algorithm = { name: normalizedAlgorithm.name, 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 usages", "SyntaxError"); } // 2. const keyData = await core.opAsync( "op_crypto_generate_key", { name: normalizedAlgorithm.name, modulusLength: normalizedAlgorithm.modulusLength, publicExponent: normalizedAlgorithm.publicExponent, }, ); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { // PKCS#1 for RSA type: "raw", data: keyData, }); // 4-8. const algorithm = { name: normalizedAlgorithm.name, 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": { // 1. if ( ArrayPrototypeFind( usages, (u) => !ArrayPrototypeIncludes(["sign", "verify"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } // 2-3. const handle = {}; if ( ArrayPrototypeIncludes( supportedNamedCurves, normalizedAlgorithm.namedCurve, ) ) { const keyData = await core.opAsync("op_crypto_generate_key", { name: "ECDSA", namedCurve: normalizedAlgorithm.namedCurve, }); WeakMapPrototypeSet(KEY_STORE, handle, { type: "pkcs8", data: keyData, }); } else { throw new DOMException("Curve not supported", "NotSupportedError"); } // 4-6. const algorithm = { name: "ECDSA", namedCurve: normalizedAlgorithm.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": { // 1. if ( ArrayPrototypeFind( usages, (u) => !ArrayPrototypeIncludes(["deriveKey", "deriveBits"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } // 2-3. const handle = {}; if ( ArrayPrototypeIncludes( supportedNamedCurves, normalizedAlgorithm.namedCurve, ) ) { const keyData = await core.opAsync("op_crypto_generate_key", { name: "ECDH", namedCurve: normalizedAlgorithm.namedCurve, }); WeakMapPrototypeSet(KEY_STORE, handle, { type: "pkcs8", data: keyData, }); } else { throw new DOMException("Curve not supported", "NotSupportedError"); } // 4-6. const algorithm = { name: "ECDH", namedCurve: normalizedAlgorithm.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 usages", "SyntaxError"); } return generateKeyAES(normalizedAlgorithm, extractable, usages); } case "AES-KW": { // 1. if ( ArrayPrototypeFind( usages, (u) => !ArrayPrototypeIncludes(["wrapKey", "unwrapKey"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "SyntaxError"); } return generateKeyAES(normalizedAlgorithm, extractable, usages); } case "HMAC": { // 1. if ( ArrayPrototypeFind( usages, (u) => !ArrayPrototypeIncludes(["sign", "verify"], u), ) !== undefined ) { throw new DOMException("Invalid key usages", "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 core.opAsync("op_crypto_generate_key", { name: "HMAC", hash: normalizedAlgorithm.hash.name, length, }); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { type: "raw", data: keyData }); // 6-10. const algorithm = { name: "HMAC", hash: { name: normalizedAlgorithm.hash.name, }, length: keyData.byteLength * 8, }; // 5, 11-13. const key = constructKey( "secret", extractable, usages, algorithm, handle, ); // 14. return key; } } } async function generateKeyAES(normalizedAlgorithm, extractable, usages) { // 2. if (!ArrayPrototypeIncludes([128, 192, 256], normalizedAlgorithm.length)) { throw new DOMException("Invalid key length", "OperationError"); } // 3. const keyData = await core.opAsync("op_crypto_generate_key", { name: normalizedAlgorithm.name, length: normalizedAlgorithm.length, }); const handle = {}; WeakMapPrototypeSet(KEY_STORE, handle, { type: "raw", data: keyData, }); // 6-8. const algorithm = { name: normalizedAlgorithm.name, 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); if (ArrayBufferIsView(normalizedAlgorithm.salt)) { normalizedAlgorithm.salt = new Uint8Array( normalizedAlgorithm.salt.buffer, normalizedAlgorithm.salt.byteOffset, normalizedAlgorithm.salt.byteLength, ); } else { normalizedAlgorithm.salt = new Uint8Array(normalizedAlgorithm.salt); } normalizedAlgorithm.salt = TypedArrayPrototypeSlice( normalizedAlgorithm.salt, ); const buf = await core.opAsync("op_crypto_derive_bits", { key: keyData, algorithm: "PBKDF2", hash: normalizedAlgorithm.hash.name, iterations: normalizedAlgorithm.iterations, length, }, normalizedAlgorithm.salt); return buf.buffer; } 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); if (ArrayBufferIsView(normalizedAlgorithm.salt)) { normalizedAlgorithm.salt = new Uint8Array( normalizedAlgorithm.salt.buffer, normalizedAlgorithm.salt.byteOffset, normalizedAlgorithm.salt.byteLength, ); } else { normalizedAlgorithm.salt = new Uint8Array(normalizedAlgorithm.salt); } normalizedAlgorithm.salt = TypedArrayPrototypeSlice( normalizedAlgorithm.salt, ); if (ArrayBufferIsView(normalizedAlgorithm.info)) { normalizedAlgorithm.info = new Uint8Array( normalizedAlgorithm.info.buffer, normalizedAlgorithm.info.byteOffset, normalizedAlgorithm.info.byteLength, ); } else { normalizedAlgorithm.info = new Uint8Array(normalizedAlgorithm.info); } normalizedAlgorithm.info = TypedArrayPrototypeSlice( normalizedAlgorithm.info, ); const buf = await core.opAsync("op_crypto_derive_bits", { key: keyDerivationKey, algorithm: "HKDF", hash: normalizedAlgorithm.hash.name, info: normalizedAlgorithm.info, length, }, normalizedAlgorithm.salt); return buf.buffer; } default: throw new DOMException("Not implemented", "NotSupportedError"); } } const subtle = webidl.createBranded(SubtleCrypto); class Crypto { constructor() { webidl.illegalConstructor(); } getRandomValues(arrayBufferView) { webidl.assertBranded(this, Crypto); const prefix = "Failed to execute 'getRandomValues' on 'Crypto'"; webidl.requiredArguments(arguments.length, 1, { prefix }); arrayBufferView = webidl.converters.ArrayBufferView(arrayBufferView, { prefix, context: "Argument 1", }); if ( !( arrayBufferView instanceof Int8Array || arrayBufferView instanceof Uint8Array || arrayBufferView instanceof Uint8ClampedArray || arrayBufferView instanceof Int16Array || arrayBufferView instanceof Uint16Array || arrayBufferView instanceof Int32Array || arrayBufferView instanceof Uint32Array || arrayBufferView instanceof BigInt64Array || arrayBufferView instanceof BigUint64Array ) ) { throw new DOMException( "The provided ArrayBufferView is not an integer array type", "TypeMismatchError", ); } const ui8 = new Uint8Array( arrayBufferView.buffer, arrayBufferView.byteOffset, arrayBufferView.byteLength, ); core.opSync("op_crypto_get_random_values", ui8); return arrayBufferView; } randomUUID() { webidl.assertBranded(this, Crypto); return core.opSync("op_crypto_random_uuid"); } get subtle() { webidl.assertBranded(this, Crypto); return subtle; } get [SymbolToStringTag]() { return "Crypto"; } [SymbolFor("Deno.customInspect")](inspect) { return `${this.constructor.name} ${inspect({})}`; } } webidl.configurePrototype(Crypto); window.__bootstrap.crypto = { SubtleCrypto, crypto: webidl.createBranded(Crypto), Crypto, CryptoKey, }; })(this);