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Diffstat (limited to 'third_party/js/PKI.js/src/CryptoEngine')
4 files changed, 2429 insertions, 0 deletions
diff --git a/third_party/js/PKI.js/src/CryptoEngine/AbstractCryptoEngine.ts b/third_party/js/PKI.js/src/CryptoEngine/AbstractCryptoEngine.ts new file mode 100644 index 0000000000..7a91ca84b1 --- /dev/null +++ b/third_party/js/PKI.js/src/CryptoEngine/AbstractCryptoEngine.ts @@ -0,0 +1,111 @@ +import { BitString, OctetString } from "asn1js"; +import * as pvutils from "pvutils"; +import { AlgorithmIdentifier } from "../AlgorithmIdentifier"; +import { EMPTY_STRING } from "../constants"; +import { EncryptedContentInfo } from "../EncryptedContentInfo"; +import { PublicKeyInfo } from "../PublicKeyInfo"; +import * as type from "./CryptoEngineInterface"; + +export abstract class AbstractCryptoEngine implements type.ICryptoEngine { + public name: string; + public crypto: Crypto; + public subtle: SubtleCrypto; + + /** + * Constructor for CryptoEngine class + * @param parameters + */ + constructor(parameters: type.CryptoEngineParameters) { + this.crypto = parameters.crypto; + this.subtle = "webkitSubtle" in parameters.crypto + ? (parameters.crypto as any).webkitSubtle + : parameters.crypto.subtle; + this.name = pvutils.getParametersValue(parameters, "name", EMPTY_STRING); + } + + public abstract getOIDByAlgorithm(algorithm: Algorithm, safety?: boolean, target?: string): string; + public abstract getAlgorithmParameters(algorithmName: string, operation: type.CryptoEngineAlgorithmOperation): type.CryptoEngineAlgorithmParams; + public abstract getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety?: boolean, target?: string): object | T; + public abstract getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety: true, target?: string): T; + public abstract getAlgorithmByOID(oid: any, safety?: any, target?: any): object; + public abstract getHashAlgorithm(signatureAlgorithm: AlgorithmIdentifier): string; + public abstract getSignatureParameters(privateKey: CryptoKey, hashAlgorithm?: string): Promise<type.CryptoEngineSignatureParams>; + public abstract signWithPrivateKey(data: BufferSource, privateKey: CryptoKey, parameters: type.CryptoEngineSignWithPrivateKeyParams): Promise<ArrayBuffer>; + public abstract verifyWithPublicKey(data: BufferSource, signature: BitString | OctetString, publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, shaAlgorithm?: string): Promise<boolean>; + public abstract getPublicKey(publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, parameters?: type.CryptoEnginePublicKeyParams): Promise<CryptoKey>; + public abstract encryptEncryptedContentInfo(parameters: type.CryptoEngineEncryptParams): Promise<EncryptedContentInfo>; + public abstract decryptEncryptedContentInfo(parameters: type.CryptoEngineDecryptParams): Promise<ArrayBuffer>; + public abstract stampDataWithPassword(parameters: type.CryptoEngineStampDataWithPasswordParams): Promise<ArrayBuffer>; + public abstract verifyDataStampedWithPassword(parameters: type.CryptoEngineVerifyDataStampedWithPasswordParams): Promise<boolean>; + public async encrypt(algorithm: globalThis.AlgorithmIdentifier | RsaOaepParams | AesCtrParams | AesCbcParams | AesGcmParams, key: CryptoKey, data: BufferSource): Promise<ArrayBuffer>; + public async encrypt(...args: any[]): Promise<ArrayBuffer> { + return (this.subtle.encrypt as any)(...args); + } + + public decrypt(algorithm: globalThis.AlgorithmIdentifier | RsaOaepParams | AesCtrParams | AesCbcParams | AesGcmParams, key: CryptoKey, data: BufferSource): Promise<ArrayBuffer>; + public async decrypt(...args: any[]): Promise<ArrayBuffer> { + return (this.subtle.decrypt as any)(...args); + } + + public sign(algorithm: globalThis.AlgorithmIdentifier | RsaPssParams | EcdsaParams, key: CryptoKey, data: BufferSource): Promise<ArrayBuffer>; + public sign(...args: any[]): Promise<ArrayBuffer> { + return (this.subtle.sign as any)(...args); + } + + public verify(algorithm: globalThis.AlgorithmIdentifier | RsaPssParams | EcdsaParams, key: CryptoKey, signature: BufferSource, data: BufferSource): Promise<boolean>; + public async verify(...args: any[]): Promise<boolean> { + return (this.subtle.verify as any)(...args); + } + + public digest(algorithm: globalThis.AlgorithmIdentifier, data: BufferSource): Promise<ArrayBuffer>; + public async digest(...args: any[]) { + return (this.subtle.digest as any)(...args); + } + + public generateKey(algorithm: RsaHashedKeyGenParams | EcKeyGenParams, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKeyPair>; + public generateKey(algorithm: AesKeyGenParams | HmacKeyGenParams | Pbkdf2Params, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + public generateKey(algorithm: globalThis.AlgorithmIdentifier, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKeyPair | CryptoKey>; + public async generateKey(...args: any[]): Promise<CryptoKey | CryptoKeyPair> { + return (this.subtle.generateKey as any)(...args); + } + + public deriveKey(algorithm: globalThis.AlgorithmIdentifier | EcdhKeyDeriveParams | HkdfParams | Pbkdf2Params, baseKey: CryptoKey, derivedKeyType: globalThis.AlgorithmIdentifier | HkdfParams | Pbkdf2Params | AesDerivedKeyParams | HmacImportParams, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + public deriveKey(algorithm: globalThis.AlgorithmIdentifier | EcdhKeyDeriveParams | HkdfParams | Pbkdf2Params, baseKey: CryptoKey, derivedKeyType: globalThis.AlgorithmIdentifier | HkdfParams | Pbkdf2Params | AesDerivedKeyParams | HmacImportParams, extractable: boolean, keyUsages: Iterable<KeyUsage>): Promise<CryptoKey>; + public async deriveKey(...args: any[]): Promise<CryptoKey> { + return (this.subtle.deriveKey as any)(...args); + } + + public deriveBits(algorithm: globalThis.AlgorithmIdentifier | EcdhKeyDeriveParams | HkdfParams | Pbkdf2Params, baseKey: CryptoKey, length: number): Promise<ArrayBuffer>; + public async deriveBits(...args: any[]): Promise<ArrayBuffer> { + return (this.subtle.deriveBits as any)(...args); + } + + public wrapKey(format: KeyFormat, key: CryptoKey, wrappingKey: CryptoKey, wrapAlgorithm: globalThis.AlgorithmIdentifier | RsaOaepParams | AesCtrParams | AesCbcParams | AesGcmParams): Promise<ArrayBuffer>; + public async wrapKey(...args: any[]): Promise<ArrayBuffer> { + return (this.subtle.wrapKey as any)(...args); + } + + public unwrapKey(format: KeyFormat, wrappedKey: BufferSource, unwrappingKey: CryptoKey, unwrapAlgorithm: globalThis.AlgorithmIdentifier | RsaOaepParams | AesCtrParams | AesCbcParams | AesGcmParams, unwrappedKeyAlgorithm: globalThis.AlgorithmIdentifier | HmacImportParams | RsaHashedImportParams | EcKeyImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + public unwrapKey(format: KeyFormat, wrappedKey: BufferSource, unwrappingKey: CryptoKey, unwrapAlgorithm: globalThis.AlgorithmIdentifier | RsaOaepParams | AesCtrParams | AesCbcParams | AesGcmParams, unwrappedKeyAlgorithm: globalThis.AlgorithmIdentifier | HmacImportParams | RsaHashedImportParams | EcKeyImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: Iterable<KeyUsage>): Promise<CryptoKey>; + public async unwrapKey(...args: any[]): Promise<CryptoKey> { + return (this.subtle.unwrapKey as any)(...args); + } + + exportKey(format: "jwk", key: CryptoKey): Promise<JsonWebKey>; + exportKey(format: "pkcs8" | "raw" | "spki", key: CryptoKey): Promise<ArrayBuffer>; + exportKey(...args: any[]): Promise<ArrayBuffer> | Promise<JsonWebKey> { + return (this.subtle.exportKey as any)(...args); + } + importKey(format: "jwk", keyData: JsonWebKey, algorithm: globalThis.AlgorithmIdentifier | RsaHashedImportParams | EcKeyImportParams | HmacImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + importKey(format: "pkcs8" | "raw" | "spki", keyData: BufferSource, algorithm: globalThis.AlgorithmIdentifier | RsaHashedImportParams | EcKeyImportParams | HmacImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + importKey(format: "jwk", keyData: JsonWebKey, algorithm: globalThis.AlgorithmIdentifier | RsaHashedImportParams | EcKeyImportParams | HmacImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey>; + importKey(format: "pkcs8" | "raw" | "spki", keyData: BufferSource, algorithm: globalThis.AlgorithmIdentifier | RsaHashedImportParams | EcKeyImportParams | HmacImportParams | AesKeyAlgorithm, extractable: boolean, keyUsages: Iterable<KeyUsage>): Promise<CryptoKey>; + importKey(...args: any[]): Promise<CryptoKey> { + return (this.subtle.importKey as any)(...args); + } + + public getRandomValues<T extends ArrayBufferView | null>(array: T): T { + return this.crypto.getRandomValues(array); + } + +} diff --git a/third_party/js/PKI.js/src/CryptoEngine/CryptoEngine.ts b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngine.ts new file mode 100644 index 0000000000..45f63f48f5 --- /dev/null +++ b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngine.ts @@ -0,0 +1,2112 @@ +import * as asn1js from "asn1js"; +import * as pvutils from "pvutils"; +import * as pvtsutils from "pvtsutils"; +import * as common from "../common"; +import { PublicKeyInfo } from "../PublicKeyInfo"; +import { PrivateKeyInfo } from "../PrivateKeyInfo"; +import { AlgorithmIdentifier } from "../AlgorithmIdentifier"; +import { EncryptedContentInfo } from "../EncryptedContentInfo"; +import { IRSASSAPSSParams, RSASSAPSSParams } from "../RSASSAPSSParams"; +import { PBKDF2Params } from "../PBKDF2Params"; +import { PBES2Params } from "../PBES2Params"; +import { ArgumentError, AsnError, ParameterError } from "../errors"; +import * as type from "./CryptoEngineInterface"; +import { AbstractCryptoEngine } from "./AbstractCryptoEngine"; +import { EMPTY_STRING } from "../constants"; +import { ECNamedCurves } from "../ECNamedCurves"; + +/** + * Making MAC key using algorithm described in B.2 of PKCS#12 standard. + */ +async function makePKCS12B2Key(cryptoEngine: CryptoEngine, hashAlgorithm: string, keyLength: number, password: ArrayBuffer, salt: ArrayBuffer, iterationCount: number) { + //#region Initial variables + let u: number; + let v: number; + + const result: number[] = []; + //#endregion + + //#region Get "u" and "v" values + switch (hashAlgorithm.toUpperCase()) { + case "SHA-1": + u = 20; // 160 + v = 64; // 512 + break; + case "SHA-256": + u = 32; // 256 + v = 64; // 512 + break; + case "SHA-384": + u = 48; // 384 + v = 128; // 1024 + break; + case "SHA-512": + u = 64; // 512 + v = 128; // 1024 + break; + default: + throw new Error("Unsupported hashing algorithm"); + } + //#endregion + + //#region Main algorithm making key + //#region Transform password to UTF-8 like string + const passwordViewInitial = new Uint8Array(password); + + const passwordTransformed = new ArrayBuffer((password.byteLength * 2) + 2); + const passwordTransformedView = new Uint8Array(passwordTransformed); + + for (let i = 0; i < passwordViewInitial.length; i++) { + passwordTransformedView[i * 2] = 0x00; + passwordTransformedView[i * 2 + 1] = passwordViewInitial[i]; + } + + passwordTransformedView[passwordTransformedView.length - 2] = 0x00; + passwordTransformedView[passwordTransformedView.length - 1] = 0x00; + + password = passwordTransformed.slice(0); + //#endregion + + //#region Construct a string D (the "diversifier") by concatenating v/8 copies of ID + const D = new ArrayBuffer(v); + const dView = new Uint8Array(D); + + for (let i = 0; i < D.byteLength; i++) + dView[i] = 3; // The ID value equal to "3" for MACing (see B.3 of standard) + //#endregion + + //#region Concatenate copies of the salt together to create a string S of length v * ceil(s / v) bytes (the final copy of the salt may be trunacted to create S) + const saltLength = salt.byteLength; + + const sLen = v * Math.ceil(saltLength / v); + const S = new ArrayBuffer(sLen); + const sView = new Uint8Array(S); + + const saltView = new Uint8Array(salt); + + for (let i = 0; i < sLen; i++) + sView[i] = saltView[i % saltLength]; + //#endregion + + //#region Concatenate copies of the password together to create a string P of length v * ceil(p / v) bytes (the final copy of the password may be truncated to create P) + const passwordLength = password.byteLength; + + const pLen = v * Math.ceil(passwordLength / v); + const P = new ArrayBuffer(pLen); + const pView = new Uint8Array(P); + + const passwordView = new Uint8Array(password); + + for (let i = 0; i < pLen; i++) + pView[i] = passwordView[i % passwordLength]; + //#endregion + + //#region Set I=S||P to be the concatenation of S and P + const sPlusPLength = S.byteLength + P.byteLength; + + let I = new ArrayBuffer(sPlusPLength); + let iView = new Uint8Array(I); + + iView.set(sView); + iView.set(pView, sView.length); + //#endregion + + //#region Set c=ceil(n / u) + const c = Math.ceil((keyLength >> 3) / u); + //#endregion + + //#region Initial variables + let internalSequence = Promise.resolve(I); + //#endregion + + //#region For i=1, 2, ..., c, do the following: + for (let i = 0; i <= c; i++) { + internalSequence = internalSequence.then(_I => { + //#region Create contecanetion of D and I + const dAndI = new ArrayBuffer(D.byteLength + _I.byteLength); + const dAndIView = new Uint8Array(dAndI); + + dAndIView.set(dView); + dAndIView.set(iView, dView.length); + //#endregion + + return dAndI; + }); + + //#region Make "iterationCount" rounds of hashing + for (let j = 0; j < iterationCount; j++) + internalSequence = internalSequence.then(roundBuffer => cryptoEngine.digest({ name: hashAlgorithm }, new Uint8Array(roundBuffer))); + //#endregion + + internalSequence = internalSequence.then(roundBuffer => { + //#region Concatenate copies of Ai to create a string B of length v bits (the final copy of Ai may be truncated to create B) + const B = new ArrayBuffer(v); + const bView = new Uint8Array(B); + + for (let j = 0; j < B.byteLength; j++) + bView[j] = (roundBuffer as any)[j % roundBuffer.byteLength]; // TODO roundBuffer is ArrayBuffer. It doesn't have indexed values + //#endregion + + //#region Make new I value + const k = Math.ceil(saltLength / v) + Math.ceil(passwordLength / v); + const iRound = []; + + let sliceStart = 0; + let sliceLength = v; + + for (let j = 0; j < k; j++) { + const chunk = Array.from(new Uint8Array(I.slice(sliceStart, sliceStart + sliceLength))); + sliceStart += v; + if ((sliceStart + v) > I.byteLength) + sliceLength = I.byteLength - sliceStart; + + let x = 0x1ff; + + for (let l = (B.byteLength - 1); l >= 0; l--) { + x >>= 8; + x += bView[l] + chunk[l]; + chunk[l] = (x & 0xff); + } + + iRound.push(...chunk); + } + + I = new ArrayBuffer(iRound.length); + iView = new Uint8Array(I); + + iView.set(iRound); + //#endregion + + result.push(...(new Uint8Array(roundBuffer))); + + return I; + }); + } + //#endregion + + //#region Initialize final key + internalSequence = internalSequence.then(() => { + const resultBuffer = new ArrayBuffer(keyLength >> 3); + const resultView = new Uint8Array(resultBuffer); + + resultView.set((new Uint8Array(result)).slice(0, keyLength >> 3)); + + return resultBuffer; + }); + //#endregion + //#endregion + + return internalSequence; +} + +function prepareAlgorithm(data: globalThis.AlgorithmIdentifier | EcdsaParams): Algorithm & { hash?: Algorithm; } { + const res = typeof data === "string" + ? { name: data } + : data; + + // TODO fix type casting `as EcdsaParams` + if ("hash" in (res as EcdsaParams)) { + return { + ...res, + hash: prepareAlgorithm((res as EcdsaParams).hash) + }; + } + + return res; +} + +/** + * Default cryptographic engine for Web Cryptography API + */ +export class CryptoEngine extends AbstractCryptoEngine { + + public override async importKey(format: KeyFormat, keyData: BufferSource | JsonWebKey, algorithm: globalThis.AlgorithmIdentifier, extractable: boolean, keyUsages: KeyUsage[]): Promise<CryptoKey> { + //#region Initial variables + let jwk: JsonWebKey = {}; + //#endregion + + const alg = prepareAlgorithm(algorithm); + + switch (format.toLowerCase()) { + case "raw": + return this.subtle.importKey("raw", keyData as BufferSource, algorithm, extractable, keyUsages); + case "spki": + { + const asn1 = asn1js.fromBER(pvtsutils.BufferSourceConverter.toArrayBuffer(keyData as BufferSource)); + AsnError.assert(asn1, "keyData"); + + const publicKeyInfo = new PublicKeyInfo(); + try { + publicKeyInfo.fromSchema(asn1.result); + } catch { + throw new ArgumentError("Incorrect keyData"); + } + + switch (alg.name.toUpperCase()) { + case "RSA-PSS": + { + //#region Get information about used hash function + if (!alg.hash) { + throw new ParameterError("hash", "algorithm.hash", "Incorrect hash algorithm: Hash algorithm is missed"); + } + switch (alg.hash.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash.name.toUpperCase()}`); + } + //#endregion + } + // break omitted + // eslint-disable-next-line no-fallthrough + case "RSASSA-PKCS1-V1_5": + { + keyUsages = ["verify"]; // Override existing keyUsages value since the key is a public key + + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + + if (publicKeyInfo.algorithm.algorithmId !== "1.2.840.113549.1.1.1") + throw new Error(`Incorrect public key algorithm: ${publicKeyInfo.algorithm.algorithmId}`); + + //#region Get information about used hash function + if (!jwk.alg) { + if (!alg.hash) { + throw new ParameterError("hash", "algorithm.hash", "Incorrect hash algorithm: Hash algorithm is missed"); + } + switch (alg.hash.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash.name.toUpperCase()}`); + } + } + //#endregion + + //#region Create RSA Public Key elements + const publicKeyJSON = publicKeyInfo.toJSON(); + Object.assign(jwk, publicKeyJSON); + //#endregion + } + break; + case "ECDSA": + keyUsages = ["verify"]; // Override existing keyUsages value since the key is a public key + // break omitted + // eslint-disable-next-line no-fallthrough + case "ECDH": + { + //#region Initial variables + jwk = { + kty: "EC", + ext: extractable, + key_ops: keyUsages + }; + //#endregion + + //#region Get information about algorithm + if (publicKeyInfo.algorithm.algorithmId !== "1.2.840.10045.2.1") { + throw new Error(`Incorrect public key algorithm: ${publicKeyInfo.algorithm.algorithmId}`); + } + //#endregion + + //#region Create ECDSA Public Key elements + const publicKeyJSON = publicKeyInfo.toJSON(); + Object.assign(jwk, publicKeyJSON); + //#endregion + } + break; + case "RSA-OAEP": + { + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + + if (this.name.toLowerCase() === "safari") + jwk.alg = "RSA-OAEP"; + else { + if (!alg.hash) { + throw new ParameterError("hash", "algorithm.hash", "Incorrect hash algorithm: Hash algorithm is missed"); + } + switch (alg.hash.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash.name.toUpperCase()}`); + } + } + + //#region Create ECDSA Public Key elements + const publicKeyJSON = publicKeyInfo.toJSON(); + Object.assign(jwk, publicKeyJSON); + //#endregion + } + break; + case "RSAES-PKCS1-V1_5": + { + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + jwk.alg = "PS1"; + + const publicKeyJSON = publicKeyInfo.toJSON(); + Object.assign(jwk, publicKeyJSON); + } + break; + default: + throw new Error(`Incorrect algorithm name: ${alg.name.toUpperCase()}`); + } + } + break; + case "pkcs8": + { + const privateKeyInfo = new PrivateKeyInfo(); + + //#region Parse "PrivateKeyInfo" object + const asn1 = asn1js.fromBER(pvtsutils.BufferSourceConverter.toArrayBuffer(keyData as BufferSource)); + AsnError.assert(asn1, "keyData"); + + try { + privateKeyInfo.fromSchema(asn1.result); + } + catch (ex) { + throw new Error("Incorrect keyData"); + } + + if (!privateKeyInfo.parsedKey) + throw new Error("Incorrect keyData"); + //#endregion + + switch (alg.name.toUpperCase()) { + case "RSA-PSS": + { + //#region Get information about used hash function + switch (alg.hash?.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash?.name.toUpperCase()}`); + } + //#endregion + } + // break omitted + // eslint-disable-next-line no-fallthrough + case "RSASSA-PKCS1-V1_5": + { + keyUsages = ["sign"]; // Override existing keyUsages value since the key is a private key + + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + + //#region Get information about used hash function + if (privateKeyInfo.privateKeyAlgorithm.algorithmId !== "1.2.840.113549.1.1.1") + throw new Error(`Incorrect private key algorithm: ${privateKeyInfo.privateKeyAlgorithm.algorithmId}`); + //#endregion + + //#region Get information about used hash function + if (("alg" in jwk) === false) { + switch (alg.hash?.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash?.name.toUpperCase()}`); + } + } + //#endregion + + //#region Create RSA Private Key elements + const privateKeyJSON = privateKeyInfo.toJSON(); + Object.assign(jwk, privateKeyJSON); + //#endregion + } + break; + case "ECDSA": + keyUsages = ["sign"]; // Override existing keyUsages value since the key is a private key + // break omitted + // eslint-disable-next-line no-fallthrough + case "ECDH": + { + //#region Initial variables + jwk = { + kty: "EC", + ext: extractable, + key_ops: keyUsages + }; + //#endregion + + //#region Get information about used hash function + if (privateKeyInfo.privateKeyAlgorithm.algorithmId !== "1.2.840.10045.2.1") + throw new Error(`Incorrect algorithm: ${privateKeyInfo.privateKeyAlgorithm.algorithmId}`); + //#endregion + + //#region Create ECDSA Private Key elements + const privateKeyJSON = privateKeyInfo.toJSON(); + Object.assign(jwk, privateKeyJSON); + //#endregion + } + break; + case "RSA-OAEP": + { + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + + //#region Get information about used hash function + if (this.name.toLowerCase() === "safari") + jwk.alg = "RSA-OAEP"; + else { + switch (alg.hash?.name.toUpperCase()) { + 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 Error(`Incorrect hash algorithm: ${alg.hash?.name.toUpperCase()}`); + } + } + //#endregion + + //#region Create RSA Private Key elements + const privateKeyJSON = privateKeyInfo.toJSON(); + Object.assign(jwk, privateKeyJSON); + //#endregion + } + break; + case "RSAES-PKCS1-V1_5": + { + keyUsages = ["decrypt"]; // Override existing keyUsages value since the key is a private key + + jwk.kty = "RSA"; + jwk.ext = extractable; + jwk.key_ops = keyUsages; + jwk.alg = "PS1"; + + //#region Create RSA Private Key elements + const privateKeyJSON = privateKeyInfo.toJSON(); + Object.assign(jwk, privateKeyJSON); + //#endregion + } + break; + default: + throw new Error(`Incorrect algorithm name: ${alg.name.toUpperCase()}`); + } + } + break; + case "jwk": + jwk = keyData as JsonWebKey; + break; + default: + throw new Error(`Incorrect format: ${format}`); + } + + //#region Special case for Safari browser (since its acting not as WebCrypto standard describes) + if (this.name.toLowerCase() === "safari") { + // Try to use both ways - import using ArrayBuffer and pure JWK (for Safari Technology Preview) + try { + return this.subtle.importKey("jwk", pvutils.stringToArrayBuffer(JSON.stringify(jwk)) as any, algorithm, extractable, keyUsages); + } catch { + return this.subtle.importKey("jwk", jwk, algorithm, extractable, keyUsages); + } + } + //#endregion + + return this.subtle.importKey("jwk", jwk, algorithm, extractable, keyUsages); + } + + /** + * Export WebCrypto keys to different formats + * @param format + * @param key + */ + public override exportKey(format: "jwk", key: CryptoKey): Promise<JsonWebKey>; + public override exportKey(format: Exclude<KeyFormat, "jwk">, key: CryptoKey): Promise<ArrayBuffer>; + public override exportKey(format: string, key: CryptoKey): Promise<ArrayBuffer | JsonWebKey>; + public override async exportKey(format: KeyFormat, key: CryptoKey): Promise<ArrayBuffer | JsonWebKey> { + let jwk = await this.subtle.exportKey("jwk", key); + + //#region Currently Safari returns ArrayBuffer as JWK thus we need an additional transformation + if (this.name.toLowerCase() === "safari") { + // Some additional checks for Safari Technology Preview + if (jwk instanceof ArrayBuffer) { + jwk = JSON.parse(pvutils.arrayBufferToString(jwk)); + } + } + //#endregion + + switch (format.toLowerCase()) { + case "raw": + return this.subtle.exportKey("raw", key); + case "spki": { + const publicKeyInfo = new PublicKeyInfo(); + + try { + publicKeyInfo.fromJSON(jwk); + } + catch (ex) { + throw new Error("Incorrect key data"); + } + + return publicKeyInfo.toSchema().toBER(false); + } + case "pkcs8": { + const privateKeyInfo = new PrivateKeyInfo(); + + try { + privateKeyInfo.fromJSON(jwk); + } + catch (ex) { + throw new Error("Incorrect key data"); + } + + return privateKeyInfo.toSchema().toBER(false); + } + case "jwk": + return jwk; + default: + throw new Error(`Incorrect format: ${format}`); + } + } + + /** + * Convert WebCrypto keys between different export formats + * @param inputFormat + * @param outputFormat + * @param keyData + * @param algorithm + * @param extractable + * @param keyUsages + */ + public async convert(inputFormat: KeyFormat, outputFormat: KeyFormat, keyData: ArrayBuffer | JsonWebKey, algorithm: Algorithm, extractable: boolean, keyUsages: KeyUsage[]) { + if (inputFormat.toLowerCase() === outputFormat.toLowerCase()) { + return keyData; + } + + const key = await this.importKey(inputFormat, keyData, algorithm, extractable, keyUsages); + return this.exportKey(outputFormat, key); + } + + /** + * Gets WebCrypto algorithm by wel-known OID + * @param oid algorithm identifier + * @param safety if `true` throws exception on unknown algorithm identifier + * @param target name of the target + * @returns Returns WebCrypto algorithm or an empty object + */ + public getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety?: boolean, target?: string): T | object; + /** + * Gets WebCrypto algorithm by wel-known OID + * @param oid algorithm identifier + * @param safety if `true` throws exception on unknown algorithm identifier + * @param target name of the target + * @returns Returns WebCrypto algorithm + * @throws Throws {@link Error} exception if unknown algorithm identifier + */ + public getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety: true, target?: string): T; + public getAlgorithmByOID(oid: string, safety = false, target?: string): any { + switch (oid) { + case "1.2.840.113549.1.1.1": + return { + name: "RSAES-PKCS1-v1_5" + }; + case "1.2.840.113549.1.1.5": + return { + name: "RSASSA-PKCS1-v1_5", + hash: { + name: "SHA-1" + } + }; + case "1.2.840.113549.1.1.11": + return { + name: "RSASSA-PKCS1-v1_5", + hash: { + name: "SHA-256" + } + }; + case "1.2.840.113549.1.1.12": + return { + name: "RSASSA-PKCS1-v1_5", + hash: { + name: "SHA-384" + } + }; + case "1.2.840.113549.1.1.13": + return { + name: "RSASSA-PKCS1-v1_5", + hash: { + name: "SHA-512" + } + }; + case "1.2.840.113549.1.1.10": + return { + name: "RSA-PSS" + }; + case "1.2.840.113549.1.1.7": + return { + name: "RSA-OAEP" + }; + case "1.2.840.10045.2.1": + case "1.2.840.10045.4.1": + return { + name: "ECDSA", + hash: { + name: "SHA-1" + } + }; + case "1.2.840.10045.4.3.2": + return { + name: "ECDSA", + hash: { + name: "SHA-256" + } + }; + case "1.2.840.10045.4.3.3": + return { + name: "ECDSA", + hash: { + name: "SHA-384" + } + }; + case "1.2.840.10045.4.3.4": + return { + name: "ECDSA", + hash: { + name: "SHA-512" + } + }; + case "1.3.133.16.840.63.0.2": + return { + name: "ECDH", + kdf: "SHA-1" + }; + case "1.3.132.1.11.1": + return { + name: "ECDH", + kdf: "SHA-256" + }; + case "1.3.132.1.11.2": + return { + name: "ECDH", + kdf: "SHA-384" + }; + case "1.3.132.1.11.3": + return { + name: "ECDH", + kdf: "SHA-512" + }; + case "2.16.840.1.101.3.4.1.2": + return { + name: "AES-CBC", + length: 128 + }; + case "2.16.840.1.101.3.4.1.22": + return { + name: "AES-CBC", + length: 192 + }; + case "2.16.840.1.101.3.4.1.42": + return { + name: "AES-CBC", + length: 256 + }; + case "2.16.840.1.101.3.4.1.6": + return { + name: "AES-GCM", + length: 128 + }; + case "2.16.840.1.101.3.4.1.26": + return { + name: "AES-GCM", + length: 192 + }; + case "2.16.840.1.101.3.4.1.46": + return { + name: "AES-GCM", + length: 256 + }; + case "2.16.840.1.101.3.4.1.4": + return { + name: "AES-CFB", + length: 128 + }; + case "2.16.840.1.101.3.4.1.24": + return { + name: "AES-CFB", + length: 192 + }; + case "2.16.840.1.101.3.4.1.44": + return { + name: "AES-CFB", + length: 256 + }; + case "2.16.840.1.101.3.4.1.5": + return { + name: "AES-KW", + length: 128 + }; + case "2.16.840.1.101.3.4.1.25": + return { + name: "AES-KW", + length: 192 + }; + case "2.16.840.1.101.3.4.1.45": + return { + name: "AES-KW", + length: 256 + }; + case "1.2.840.113549.2.7": + return { + name: "HMAC", + hash: { + name: "SHA-1" + } + }; + case "1.2.840.113549.2.9": + return { + name: "HMAC", + hash: { + name: "SHA-256" + } + }; + case "1.2.840.113549.2.10": + return { + name: "HMAC", + hash: { + name: "SHA-384" + } + }; + case "1.2.840.113549.2.11": + return { + name: "HMAC", + hash: { + name: "SHA-512" + } + }; + case "1.2.840.113549.1.9.16.3.5": + return { + name: "DH" + }; + case "1.3.14.3.2.26": + return { + name: "SHA-1" + }; + case "2.16.840.1.101.3.4.2.1": + return { + name: "SHA-256" + }; + case "2.16.840.1.101.3.4.2.2": + return { + name: "SHA-384" + }; + case "2.16.840.1.101.3.4.2.3": + return { + name: "SHA-512" + }; + case "1.2.840.113549.1.5.12": + return { + name: "PBKDF2" + }; + //#region Special case - OIDs for ECC curves + case "1.2.840.10045.3.1.7": + return { + name: "P-256" + }; + case "1.3.132.0.34": + return { + name: "P-384" + }; + case "1.3.132.0.35": + return { + name: "P-521" + }; + //#endregion + default: + } + + if (safety) { + throw new Error(`Unsupported algorithm identifier ${target ? `for ${target} ` : EMPTY_STRING}: ${oid}`); + } + + return {}; + } + + public getOIDByAlgorithm(algorithm: Algorithm, safety = false, target?: string): string { + let result = EMPTY_STRING; + + switch (algorithm.name.toUpperCase()) { + case "RSAES-PKCS1-V1_5": + result = "1.2.840.113549.1.1.1"; + break; + case "RSASSA-PKCS1-V1_5": + switch ((algorithm as any).hash.name.toUpperCase()) { + case "SHA-1": + result = "1.2.840.113549.1.1.5"; + break; + case "SHA-256": + result = "1.2.840.113549.1.1.11"; + break; + case "SHA-384": + result = "1.2.840.113549.1.1.12"; + break; + case "SHA-512": + result = "1.2.840.113549.1.1.13"; + break; + default: + } + break; + case "RSA-PSS": + result = "1.2.840.113549.1.1.10"; + break; + case "RSA-OAEP": + result = "1.2.840.113549.1.1.7"; + break; + case "ECDSA": + switch ((algorithm as any).hash.name.toUpperCase()) { + case "SHA-1": + result = "1.2.840.10045.4.1"; + break; + case "SHA-256": + result = "1.2.840.10045.4.3.2"; + break; + case "SHA-384": + result = "1.2.840.10045.4.3.3"; + break; + case "SHA-512": + result = "1.2.840.10045.4.3.4"; + break; + default: + } + break; + case "ECDH": + switch ((algorithm as any).kdf.toUpperCase()) // Non-standard addition - hash algorithm of KDF function + { + case "SHA-1": + result = "1.3.133.16.840.63.0.2"; // dhSinglePass-stdDH-sha1kdf-scheme + break; + case "SHA-256": + result = "1.3.132.1.11.1"; // dhSinglePass-stdDH-sha256kdf-scheme + break; + case "SHA-384": + result = "1.3.132.1.11.2"; // dhSinglePass-stdDH-sha384kdf-scheme + break; + case "SHA-512": + result = "1.3.132.1.11.3"; // dhSinglePass-stdDH-sha512kdf-scheme + break; + default: + } + break; + case "AES-CTR": + break; + case "AES-CBC": + switch ((algorithm as any).length) { + case 128: + result = "2.16.840.1.101.3.4.1.2"; + break; + case 192: + result = "2.16.840.1.101.3.4.1.22"; + break; + case 256: + result = "2.16.840.1.101.3.4.1.42"; + break; + default: + } + break; + case "AES-CMAC": + break; + case "AES-GCM": + switch ((algorithm as any).length) { + case 128: + result = "2.16.840.1.101.3.4.1.6"; + break; + case 192: + result = "2.16.840.1.101.3.4.1.26"; + break; + case 256: + result = "2.16.840.1.101.3.4.1.46"; + break; + default: + } + break; + case "AES-CFB": + switch ((algorithm as any).length) { + case 128: + result = "2.16.840.1.101.3.4.1.4"; + break; + case 192: + result = "2.16.840.1.101.3.4.1.24"; + break; + case 256: + result = "2.16.840.1.101.3.4.1.44"; + break; + default: + } + break; + case "AES-KW": + switch ((algorithm as any).length) { + case 128: + result = "2.16.840.1.101.3.4.1.5"; + break; + case 192: + result = "2.16.840.1.101.3.4.1.25"; + break; + case 256: + result = "2.16.840.1.101.3.4.1.45"; + break; + default: + } + break; + case "HMAC": + switch ((algorithm as any).hash.name.toUpperCase()) { + case "SHA-1": + result = "1.2.840.113549.2.7"; + break; + case "SHA-256": + result = "1.2.840.113549.2.9"; + break; + case "SHA-384": + result = "1.2.840.113549.2.10"; + break; + case "SHA-512": + result = "1.2.840.113549.2.11"; + break; + default: + } + break; + case "DH": + result = "1.2.840.113549.1.9.16.3.5"; + break; + case "SHA-1": + result = "1.3.14.3.2.26"; + break; + case "SHA-256": + result = "2.16.840.1.101.3.4.2.1"; + break; + case "SHA-384": + result = "2.16.840.1.101.3.4.2.2"; + break; + case "SHA-512": + result = "2.16.840.1.101.3.4.2.3"; + break; + case "CONCAT": + break; + case "HKDF": + break; + case "PBKDF2": + result = "1.2.840.113549.1.5.12"; + break; + //#region Special case - OIDs for ECC curves + case "P-256": + result = "1.2.840.10045.3.1.7"; + break; + case "P-384": + result = "1.3.132.0.34"; + break; + case "P-521": + result = "1.3.132.0.35"; + break; + //#endregion + default: + } + + if (!result && safety) { + throw new Error(`Unsupported algorithm ${target ? `for ${target} ` : EMPTY_STRING}: ${algorithm.name}`); + } + + return result; + } + + public getAlgorithmParameters(algorithmName: string, operation: type.CryptoEngineAlgorithmOperation): type.CryptoEngineAlgorithmParams { + let result: type.CryptoEngineAlgorithmParams = { + algorithm: {}, + usages: [] + }; + + switch (algorithmName.toUpperCase()) { + case "RSAES-PKCS1-V1_5": + case "RSASSA-PKCS1-V1_5": + switch (operation.toLowerCase()) { + case "generatekey": + result = { + algorithm: { + name: "RSASSA-PKCS1-v1_5", + modulusLength: 2048, + publicExponent: new Uint8Array([0x01, 0x00, 0x01]), + hash: { + name: "SHA-256" + } + }, + usages: ["sign", "verify"] + }; + break; + case "verify": + case "sign": + case "importkey": + result = { + algorithm: { + name: "RSASSA-PKCS1-v1_5", + hash: { + name: "SHA-256" + } + }, + usages: ["verify"] // For importKey("pkcs8") usage must be "sign" only + }; + break; + case "exportkey": + default: + return { + algorithm: { + name: "RSASSA-PKCS1-v1_5" + }, + usages: [] + }; + } + break; + case "RSA-PSS": + switch (operation.toLowerCase()) { + case "sign": + case "verify": + result = { + algorithm: { + name: "RSA-PSS", + hash: { + name: "SHA-1" + }, + saltLength: 20 + }, + usages: ["sign", "verify"] + }; + break; + case "generatekey": + result = { + algorithm: { + name: "RSA-PSS", + modulusLength: 2048, + publicExponent: new Uint8Array([0x01, 0x00, 0x01]), + hash: { + name: "SHA-1" + } + }, + usages: ["sign", "verify"] + }; + break; + case "importkey": + result = { + algorithm: { + name: "RSA-PSS", + hash: { + name: "SHA-1" + } + }, + usages: ["verify"] // For importKey("pkcs8") usage must be "sign" only + }; + break; + case "exportkey": + default: + return { + algorithm: { + name: "RSA-PSS" + }, + usages: [] + }; + } + break; + case "RSA-OAEP": + switch (operation.toLowerCase()) { + case "encrypt": + case "decrypt": + result = { + algorithm: { + name: "RSA-OAEP" + }, + usages: ["encrypt", "decrypt"] + }; + break; + case "generatekey": + result = { + algorithm: { + name: "RSA-OAEP", + modulusLength: 2048, + publicExponent: new Uint8Array([0x01, 0x00, 0x01]), + hash: { + name: "SHA-256" + } + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + case "importkey": + result = { + algorithm: { + name: "RSA-OAEP", + hash: { + name: "SHA-256" + } + }, + usages: ["encrypt"] // encrypt for "spki" and decrypt for "pkcs8" + }; + break; + case "exportkey": + default: + return { + algorithm: { + name: "RSA-OAEP" + }, + usages: [] + }; + } + break; + case "ECDSA": + switch (operation.toLowerCase()) { + case "generatekey": + result = { + algorithm: { + name: "ECDSA", + namedCurve: "P-256" + }, + usages: ["sign", "verify"] + }; + break; + case "importkey": + result = { + algorithm: { + name: "ECDSA", + namedCurve: "P-256" + }, + usages: ["verify"] // "sign" for "pkcs8" + }; + break; + case "verify": + case "sign": + result = { + algorithm: { + name: "ECDSA", + hash: { + name: "SHA-256" + } + }, + usages: ["sign"] + }; + break; + default: + return { + algorithm: { + name: "ECDSA" + }, + usages: [] + }; + } + break; + case "ECDH": + switch (operation.toLowerCase()) { + case "exportkey": + case "importkey": + case "generatekey": + result = { + algorithm: { + name: "ECDH", + namedCurve: "P-256" + }, + usages: ["deriveKey", "deriveBits"] + }; + break; + case "derivekey": + case "derivebits": + result = { + algorithm: { + name: "ECDH", + namedCurve: "P-256", + public: [] // Must be a "publicKey" + }, + usages: ["encrypt", "decrypt"] + }; + break; + default: + return { + algorithm: { + name: "ECDH" + }, + usages: [] + }; + } + break; + case "AES-CTR": + switch (operation.toLowerCase()) { + case "importkey": + case "exportkey": + case "generatekey": + result = { + algorithm: { + name: "AES-CTR", + length: 256 + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + case "decrypt": + case "encrypt": + result = { + algorithm: { + name: "AES-CTR", + counter: new Uint8Array(16), + length: 10 + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + default: + return { + algorithm: { + name: "AES-CTR" + }, + usages: [] + }; + } + break; + case "AES-CBC": + switch (operation.toLowerCase()) { + case "importkey": + case "exportkey": + case "generatekey": + result = { + algorithm: { + name: "AES-CBC", + length: 256 + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + case "decrypt": + case "encrypt": + result = { + algorithm: { + name: "AES-CBC", + iv: this.getRandomValues(new Uint8Array(16)) // For "decrypt" the value should be replaced with value got on "encrypt" step + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + default: + return { + algorithm: { + name: "AES-CBC" + }, + usages: [] + }; + } + break; + case "AES-GCM": + switch (operation.toLowerCase()) { + case "importkey": + case "exportkey": + case "generatekey": + result = { + algorithm: { + name: "AES-GCM", + length: 256 + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + case "decrypt": + case "encrypt": + result = { + algorithm: { + name: "AES-GCM", + iv: this.getRandomValues(new Uint8Array(16)) // For "decrypt" the value should be replaced with value got on "encrypt" step + }, + usages: ["encrypt", "decrypt", "wrapKey", "unwrapKey"] + }; + break; + default: + return { + algorithm: { + name: "AES-GCM" + }, + usages: [] + }; + } + break; + case "AES-KW": + switch (operation.toLowerCase()) { + case "importkey": + case "exportkey": + case "generatekey": + case "wrapkey": + case "unwrapkey": + result = { + algorithm: { + name: "AES-KW", + length: 256 + }, + usages: ["wrapKey", "unwrapKey"] + }; + break; + default: + return { + algorithm: { + name: "AES-KW" + }, + usages: [] + }; + } + break; + case "HMAC": + switch (operation.toLowerCase()) { + case "sign": + case "verify": + result = { + algorithm: { + name: "HMAC" + }, + usages: ["sign", "verify"] + }; + break; + case "importkey": + case "exportkey": + case "generatekey": + result = { + algorithm: { + name: "HMAC", + length: 32, + hash: { + name: "SHA-256" + } + }, + usages: ["sign", "verify"] + }; + break; + default: + return { + algorithm: { + name: "HMAC" + }, + usages: [] + }; + } + break; + case "HKDF": + switch (operation.toLowerCase()) { + case "derivekey": + result = { + algorithm: { + name: "HKDF", + hash: "SHA-256", + salt: new Uint8Array([]), + info: new Uint8Array([]) + }, + usages: ["encrypt", "decrypt"] + }; + break; + default: + return { + algorithm: { + name: "HKDF" + }, + usages: [] + }; + } + break; + case "PBKDF2": + switch (operation.toLowerCase()) { + case "derivekey": + result = { + algorithm: { + name: "PBKDF2", + hash: { name: "SHA-256" }, + salt: new Uint8Array([]), + iterations: 10000 + }, + usages: ["encrypt", "decrypt"] + }; + break; + default: + return { + algorithm: { + name: "PBKDF2" + }, + usages: [] + }; + } + break; + default: + } + + return result; + } + + /** + * Getting hash algorithm by signature algorithm + * @param signatureAlgorithm Signature algorithm + */ + // TODO use safety + getHashAlgorithm(signatureAlgorithm: AlgorithmIdentifier): string { + let result = EMPTY_STRING; + + switch (signatureAlgorithm.algorithmId) { + case "1.2.840.10045.4.1": // ecdsa-with-SHA1 + case "1.2.840.113549.1.1.5": // rsa-encryption-with-SHA1 + result = "SHA-1"; + break; + case "1.2.840.10045.4.3.2": // ecdsa-with-SHA256 + case "1.2.840.113549.1.1.11": // rsa-encryption-with-SHA256 + result = "SHA-256"; + break; + case "1.2.840.10045.4.3.3": // ecdsa-with-SHA384 + case "1.2.840.113549.1.1.12": // rsa-encryption-with-SHA384 + result = "SHA-384"; + break; + case "1.2.840.10045.4.3.4": // ecdsa-with-SHA512 + case "1.2.840.113549.1.1.13": // rsa-encryption-with-SHA512 + result = "SHA-512"; + break; + case "1.2.840.113549.1.1.10": // RSA-PSS + { + try { + const params = new RSASSAPSSParams({ schema: signatureAlgorithm.algorithmParams }); + if (params.hashAlgorithm) { + const algorithm = this.getAlgorithmByOID(params.hashAlgorithm.algorithmId); + if ("name" in algorithm) { + result = algorithm.name; + } + else { + return EMPTY_STRING; + } + } + else + result = "SHA-1"; + } + catch { + // nothing + } + } + break; + default: + } + + return result; + } + + public async encryptEncryptedContentInfo(parameters: type.CryptoEngineEncryptParams): Promise<EncryptedContentInfo> { + //#region Check for input parameters + ParameterError.assert(parameters, + "password", "contentEncryptionAlgorithm", "hmacHashAlgorithm", + "iterationCount", "contentToEncrypt", "contentToEncrypt", "contentType"); + + const contentEncryptionOID = this.getOIDByAlgorithm(parameters.contentEncryptionAlgorithm, true, "contentEncryptionAlgorithm"); + + const pbkdf2OID = this.getOIDByAlgorithm({ + name: "PBKDF2" + }, true, "PBKDF2"); + const hmacOID = this.getOIDByAlgorithm({ + name: "HMAC", + hash: { + name: parameters.hmacHashAlgorithm + } + } as Algorithm, true, "hmacHashAlgorithm"); + //#endregion + + //#region Initial variables + + // TODO Should we reuse iv from parameters.contentEncryptionAlgorithm or use it's length for ivBuffer? + const ivBuffer = new ArrayBuffer(16); // For AES we need IV 16 bytes long + const ivView = new Uint8Array(ivBuffer); + this.getRandomValues(ivView); + + const saltBuffer = new ArrayBuffer(64); + const saltView = new Uint8Array(saltBuffer); + this.getRandomValues(saltView); + + const contentView = new Uint8Array(parameters.contentToEncrypt); + + const pbkdf2Params = new PBKDF2Params({ + salt: new asn1js.OctetString({ valueHex: saltBuffer }), + iterationCount: parameters.iterationCount, + prf: new AlgorithmIdentifier({ + algorithmId: hmacOID, + algorithmParams: new asn1js.Null() + }) + }); + //#endregion + + //#region Derive PBKDF2 key from "password" buffer + const passwordView = new Uint8Array(parameters.password); + + const pbkdfKey = await this.importKey("raw", + passwordView, + "PBKDF2", + false, + ["deriveKey"]); + + //#endregion + + //#region Derive key for "contentEncryptionAlgorithm" + const derivedKey = await this.deriveKey({ + name: "PBKDF2", + hash: { + name: parameters.hmacHashAlgorithm + }, + salt: saltView, + iterations: parameters.iterationCount + }, + pbkdfKey, + parameters.contentEncryptionAlgorithm, + false, + ["encrypt"]); + //#endregion + + //#region Encrypt content + // TODO encrypt doesn't use all parameters from parameters.contentEncryptionAlgorithm (eg additionalData and tagLength for AES-GCM) + const encryptedData = await this.encrypt( + { + name: parameters.contentEncryptionAlgorithm.name, + iv: ivView + }, + derivedKey, + contentView); + //#endregion + + //#region Store all parameters in EncryptedData object + const pbes2Parameters = new PBES2Params({ + keyDerivationFunc: new AlgorithmIdentifier({ + algorithmId: pbkdf2OID, + algorithmParams: pbkdf2Params.toSchema() + }), + encryptionScheme: new AlgorithmIdentifier({ + algorithmId: contentEncryptionOID, + algorithmParams: new asn1js.OctetString({ valueHex: ivBuffer }) + }) + }); + + return new EncryptedContentInfo({ + contentType: parameters.contentType, + contentEncryptionAlgorithm: new AlgorithmIdentifier({ + algorithmId: "1.2.840.113549.1.5.13", // pkcs5PBES2 + algorithmParams: pbes2Parameters.toSchema() + }), + encryptedContent: new asn1js.OctetString({ valueHex: encryptedData }) + }); + //#endregion + } + + /** + * Decrypt data stored in "EncryptedContentInfo" object using parameters + * @param parameters + */ + public async decryptEncryptedContentInfo(parameters: type.CryptoEngineDecryptParams): Promise<ArrayBuffer> { + //#region Check for input parameters + ParameterError.assert(parameters, "password", "encryptedContentInfo"); + + if (parameters.encryptedContentInfo.contentEncryptionAlgorithm.algorithmId !== "1.2.840.113549.1.5.13") // pkcs5PBES2 + throw new Error(`Unknown "contentEncryptionAlgorithm": ${parameters.encryptedContentInfo.contentEncryptionAlgorithm.algorithmId}`); + //#endregion + + //#region Initial variables + let pbes2Parameters: PBES2Params; + + try { + pbes2Parameters = new PBES2Params({ schema: parameters.encryptedContentInfo.contentEncryptionAlgorithm.algorithmParams }); + } + catch (ex) { + throw new Error("Incorrectly encoded \"pbes2Parameters\""); + } + + let pbkdf2Params; + + try { + pbkdf2Params = new PBKDF2Params({ schema: pbes2Parameters.keyDerivationFunc.algorithmParams }); + } + catch (ex) { + throw new Error("Incorrectly encoded \"pbkdf2Params\""); + } + + const contentEncryptionAlgorithm = this.getAlgorithmByOID(pbes2Parameters.encryptionScheme.algorithmId, true); + + const ivBuffer = pbes2Parameters.encryptionScheme.algorithmParams.valueBlock.valueHex; + const ivView = new Uint8Array(ivBuffer); + + const saltBuffer = pbkdf2Params.salt.valueBlock.valueHex; + const saltView = new Uint8Array(saltBuffer); + + const iterationCount = pbkdf2Params.iterationCount; + + let hmacHashAlgorithm = "SHA-1"; + + if (pbkdf2Params.prf) { + const algorithm = this.getAlgorithmByOID<any>(pbkdf2Params.prf.algorithmId, true); + hmacHashAlgorithm = algorithm.hash.name; + } + //#endregion + + //#region Derive PBKDF2 key from "password" buffer + const pbkdfKey = await this.importKey("raw", + parameters.password, + "PBKDF2", + false, + ["deriveKey"]); + //#endregion + + //#region Derive key for "contentEncryptionAlgorithm" + const result = await this.deriveKey( + { + name: "PBKDF2", + hash: { + name: hmacHashAlgorithm + }, + salt: saltView, + iterations: iterationCount + }, + pbkdfKey, + contentEncryptionAlgorithm as any, + false, + ["decrypt"]); + //#endregion + + //#region Decrypt internal content using derived key + //#region Create correct data block for decryption + const dataBuffer = parameters.encryptedContentInfo.getEncryptedContent(); + //#endregion + + return this.decrypt({ + name: contentEncryptionAlgorithm.name, + iv: ivView + }, + result, + dataBuffer); + //#endregion + } + + public async stampDataWithPassword(parameters: type.CryptoEngineStampDataWithPasswordParams): Promise<ArrayBuffer> { + //#region Check for input parameters + if ((parameters instanceof Object) === false) + throw new Error("Parameters must have type \"Object\""); + + ParameterError.assert(parameters, "password", "hashAlgorithm", "iterationCount", "salt", "contentToStamp"); + //#endregion + + //#region Choose correct length for HMAC key + let length: number; + + switch (parameters.hashAlgorithm.toLowerCase()) { + case "sha-1": + length = 160; + break; + case "sha-256": + length = 256; + break; + case "sha-384": + length = 384; + break; + case "sha-512": + length = 512; + break; + default: + throw new Error(`Incorrect "parameters.hashAlgorithm" parameter: ${parameters.hashAlgorithm}`); + } + //#endregion + + //#region Initial variables + const hmacAlgorithm = { + name: "HMAC", + length, + hash: { + name: parameters.hashAlgorithm + } + }; + //#endregion + + //#region Create PKCS#12 key for integrity checking + const pkcsKey = await makePKCS12B2Key(this, parameters.hashAlgorithm, length, parameters.password, parameters.salt, parameters.iterationCount); + //#endregion + + //#region Import HMAC key + + const hmacKey = await this.importKey("raw", + new Uint8Array(pkcsKey), + hmacAlgorithm, + false, + ["sign"]); + //#endregion + + //#region Make signed HMAC value + return this.sign(hmacAlgorithm, hmacKey, new Uint8Array(parameters.contentToStamp)); + //#endregion + } + + public async verifyDataStampedWithPassword(parameters: type.CryptoEngineVerifyDataStampedWithPasswordParams): Promise<boolean> { + //#region Check for input parameters + ParameterError.assert(parameters, + "password", "hashAlgorithm", "salt", + "iterationCount", "contentToVerify", "signatureToVerify"); + //#endregion + + //#region Choose correct length for HMAC key + let length = 0; + + switch (parameters.hashAlgorithm.toLowerCase()) { + case "sha-1": + length = 160; + break; + case "sha-256": + length = 256; + break; + case "sha-384": + length = 384; + break; + case "sha-512": + length = 512; + break; + default: + throw new Error(`Incorrect "parameters.hashAlgorithm" parameter: ${parameters.hashAlgorithm}`); + } + //#endregion + + //#region Initial variables + const hmacAlgorithm = { + name: "HMAC", + length, + hash: { + name: parameters.hashAlgorithm + } + }; + //#endregion + + //#region Create PKCS#12 key for integrity checking + const pkcsKey = await makePKCS12B2Key(this, parameters.hashAlgorithm, length, parameters.password, parameters.salt, parameters.iterationCount); + //#endregion + + //#region Import HMAC key + const hmacKey = await this.importKey("raw", + new Uint8Array(pkcsKey), + hmacAlgorithm, + false, + ["verify"]); + //#endregion + + //#region Make signed HMAC value + return this.verify(hmacAlgorithm, hmacKey, new Uint8Array(parameters.signatureToVerify), new Uint8Array(parameters.contentToVerify)); + //#endregion + } + + public async getSignatureParameters(privateKey: CryptoKey, hashAlgorithm = "SHA-1"): Promise<type.CryptoEngineSignatureParams> { + // Check hashing algorithm + this.getOIDByAlgorithm({ name: hashAlgorithm }, true, "hashAlgorithm"); + + // Initial variables + const signatureAlgorithm = new AlgorithmIdentifier(); + + //#region Get a "default parameters" for current algorithm + const parameters = this.getAlgorithmParameters(privateKey.algorithm.name, "sign"); + if (!Object.keys(parameters.algorithm).length) { + throw new Error("Parameter 'algorithm' is empty"); + } + const algorithm = parameters.algorithm as any; // TODO remove `as any` + algorithm.hash.name = hashAlgorithm; + //#endregion + + //#region Fill internal structures base on "privateKey" and "hashAlgorithm" + switch (privateKey.algorithm.name.toUpperCase()) { + case "RSASSA-PKCS1-V1_5": + case "ECDSA": + signatureAlgorithm.algorithmId = this.getOIDByAlgorithm(algorithm, true); + break; + case "RSA-PSS": + { + //#region Set "saltLength" as a length (in octets) of hash function result + switch (hashAlgorithm.toUpperCase()) { + case "SHA-256": + algorithm.saltLength = 32; + break; + case "SHA-384": + algorithm.saltLength = 48; + break; + case "SHA-512": + algorithm.saltLength = 64; + break; + default: + } + //#endregion + + //#region Fill "RSASSA_PSS_params" object + const paramsObject: Partial<IRSASSAPSSParams> = {}; + + if (hashAlgorithm.toUpperCase() !== "SHA-1") { + const hashAlgorithmOID = this.getOIDByAlgorithm({ name: hashAlgorithm }, true, "hashAlgorithm"); + + paramsObject.hashAlgorithm = new AlgorithmIdentifier({ + algorithmId: hashAlgorithmOID, + algorithmParams: new asn1js.Null() + }); + + paramsObject.maskGenAlgorithm = new AlgorithmIdentifier({ + algorithmId: "1.2.840.113549.1.1.8", // MGF1 + algorithmParams: paramsObject.hashAlgorithm.toSchema() + }); + } + + if (algorithm.saltLength !== 20) + paramsObject.saltLength = algorithm.saltLength; + + const pssParameters = new RSASSAPSSParams(paramsObject); + //#endregion + + //#region Automatically set signature algorithm + signatureAlgorithm.algorithmId = "1.2.840.113549.1.1.10"; + signatureAlgorithm.algorithmParams = pssParameters.toSchema(); + //#endregion + } + break; + default: + throw new Error(`Unsupported signature algorithm: ${privateKey.algorithm.name}`); + } + //#endregion + + return { + signatureAlgorithm, + parameters + }; + } + + public async signWithPrivateKey(data: BufferSource, privateKey: CryptoKey, parameters: type.CryptoEngineSignWithPrivateKeyParams): Promise<ArrayBuffer> { + const signature = await this.sign(parameters.algorithm, + privateKey, + data); + + //#region Special case for ECDSA algorithm + if (parameters.algorithm.name === "ECDSA") { + return common.createCMSECDSASignature(signature); + } + //#endregion + + return signature; + } + + public fillPublicKeyParameters(publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier): type.CryptoEnginePublicKeyParams { + const parameters = {} as any; + + //#region Find signer's hashing algorithm + const shaAlgorithm = this.getHashAlgorithm(signatureAlgorithm); + if (shaAlgorithm === EMPTY_STRING) + throw new Error(`Unsupported signature algorithm: ${signatureAlgorithm.algorithmId}`); + //#endregion + + //#region Get information about public key algorithm and default parameters for import + let algorithmId: string; + if (signatureAlgorithm.algorithmId === "1.2.840.113549.1.1.10") + algorithmId = signatureAlgorithm.algorithmId; + else + algorithmId = publicKeyInfo.algorithm.algorithmId; + + const algorithmObject = this.getAlgorithmByOID(algorithmId, true); + + parameters.algorithm = this.getAlgorithmParameters(algorithmObject.name, "importKey"); + if ("hash" in parameters.algorithm.algorithm) + parameters.algorithm.algorithm.hash.name = shaAlgorithm; + + //#region Special case for ECDSA + if (algorithmObject.name === "ECDSA") { + //#region Get information about named curve + const publicKeyAlgorithm = publicKeyInfo.algorithm; + if (!publicKeyAlgorithm.algorithmParams) { + throw new Error("Algorithm parameters for ECDSA public key are missed"); + } + const publicKeyAlgorithmParams = publicKeyAlgorithm.algorithmParams; + if ("idBlock" in publicKeyAlgorithm.algorithmParams) { + if (!((publicKeyAlgorithmParams.idBlock.tagClass === 1) && (publicKeyAlgorithmParams.idBlock.tagNumber === 6))) { + throw new Error("Incorrect type for ECDSA public key parameters"); + } + } + + const curveObject = this.getAlgorithmByOID(publicKeyAlgorithmParams.valueBlock.toString(), true); + //#endregion + + parameters.algorithm.algorithm.namedCurve = curveObject.name; + } + //#endregion + //#endregion + + return parameters; + } + + public async getPublicKey(publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, parameters?: type.CryptoEnginePublicKeyParams): Promise<CryptoKey> { + if (!parameters) { + parameters = this.fillPublicKeyParameters(publicKeyInfo, signatureAlgorithm); + } + + const publicKeyInfoBuffer = publicKeyInfo.toSchema().toBER(false); + + return this.importKey("spki", + publicKeyInfoBuffer, + parameters.algorithm.algorithm as Algorithm, + true, + parameters.algorithm.usages + ); + } + + public async verifyWithPublicKey(data: BufferSource, signature: asn1js.BitString | asn1js.OctetString, publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, shaAlgorithm?: string): Promise<boolean> { + //#region Find signer's hashing algorithm + let publicKey: CryptoKey; + if (!shaAlgorithm) { + shaAlgorithm = this.getHashAlgorithm(signatureAlgorithm); + if (!shaAlgorithm) + throw new Error(`Unsupported signature algorithm: ${signatureAlgorithm.algorithmId}`); + + //#region Import public key + publicKey = await this.getPublicKey(publicKeyInfo, signatureAlgorithm); + //#endregion + } else { + const parameters = {} as type.CryptoEnginePublicKeyParams; + + //#region Get information about public key algorithm and default parameters for import + let algorithmId; + if (signatureAlgorithm.algorithmId === "1.2.840.113549.1.1.10") + algorithmId = signatureAlgorithm.algorithmId; + else + algorithmId = publicKeyInfo.algorithm.algorithmId; + + const algorithmObject = this.getAlgorithmByOID(algorithmId, true); + + parameters.algorithm = this.getAlgorithmParameters(algorithmObject.name, "importKey"); + if ("hash" in parameters.algorithm.algorithm) + (parameters.algorithm.algorithm as any).hash.name = shaAlgorithm; + + //#region Special case for ECDSA + if (algorithmObject.name === "ECDSA") { + //#region Get information about named curve + let algorithmParamsChecked = false; + + if (("algorithmParams" in publicKeyInfo.algorithm) === true) { + if ("idBlock" in publicKeyInfo.algorithm.algorithmParams) { + if ((publicKeyInfo.algorithm.algorithmParams.idBlock.tagClass === 1) && (publicKeyInfo.algorithm.algorithmParams.idBlock.tagNumber === 6)) + algorithmParamsChecked = true; + } + } + + if (algorithmParamsChecked === false) { + throw new Error("Incorrect type for ECDSA public key parameters"); + } + + const curveObject = this.getAlgorithmByOID(publicKeyInfo.algorithm.algorithmParams.valueBlock.toString(), true); + //#endregion + + (parameters.algorithm.algorithm as any).namedCurve = curveObject.name; + } + //#endregion + //#endregion + + //#region Import public key + + publicKey = await this.getPublicKey(publicKeyInfo, null as any, parameters); // TODO null!!! + //#endregion + } + //#endregion + + //#region Verify signature + //#region Get default algorithm parameters for verification + const algorithm = this.getAlgorithmParameters(publicKey.algorithm.name, "verify"); + if ("hash" in algorithm.algorithm) + (algorithm.algorithm as any).hash.name = shaAlgorithm; + //#endregion + + //#region Special case for ECDSA signatures + let signatureValue: BufferSource = signature.valueBlock.valueHexView; + + if (publicKey.algorithm.name === "ECDSA") { + const namedCurve = ECNamedCurves.find((publicKey.algorithm as EcKeyAlgorithm).namedCurve); + if (!namedCurve) { + throw new Error("Unsupported named curve in use"); + } + const asn1 = asn1js.fromBER(signatureValue); + AsnError.assert(asn1, "Signature value"); + signatureValue = common.createECDSASignatureFromCMS(asn1.result, namedCurve.size); + } + //#endregion + + //#region Special case for RSA-PSS + if (publicKey.algorithm.name === "RSA-PSS") { + const pssParameters = new RSASSAPSSParams({ schema: signatureAlgorithm.algorithmParams }); + + if ("saltLength" in pssParameters) + (algorithm.algorithm as any).saltLength = pssParameters.saltLength; + else + (algorithm.algorithm as any).saltLength = 20; + + let hashAlgo = "SHA-1"; + + if ("hashAlgorithm" in pssParameters) { + const hashAlgorithm = this.getAlgorithmByOID(pssParameters.hashAlgorithm.algorithmId, true); + + hashAlgo = hashAlgorithm.name; + } + + (algorithm.algorithm as any).hash.name = hashAlgo; + } + //#endregion + + return this.verify((algorithm.algorithm as any), + publicKey, + signatureValue, + data, + ); + //#endregion + } + +} + diff --git a/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInit.ts b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInit.ts new file mode 100644 index 0000000000..93422f8add --- /dev/null +++ b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInit.ts @@ -0,0 +1,23 @@ +import * as common from "../common"; +import { CryptoEngine } from "./CryptoEngine"; + +export function initCryptoEngine() { + if (typeof self !== "undefined") { + if ("crypto" in self) { + let engineName = "webcrypto"; + + // Apple Safari support + if ("webkitSubtle" in self.crypto) { + engineName = "safari"; + } + + common.setEngine(engineName, new CryptoEngine({ name: engineName, crypto: crypto })); + } + } else if (typeof crypto !== "undefined" && "webcrypto" in crypto) { + // NodeJS ^15 + const name = "NodeJS ^15"; + const nodeCrypto = (crypto as any).webcrypto as Crypto; + common.setEngine(name, new CryptoEngine({ name, crypto: nodeCrypto })); + } + +} diff --git a/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInterface.ts b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInterface.ts new file mode 100644 index 0000000000..8aab69c604 --- /dev/null +++ b/third_party/js/PKI.js/src/CryptoEngine/CryptoEngineInterface.ts @@ -0,0 +1,183 @@ +import type * as asn1js from "asn1js"; +import type { AlgorithmIdentifier } from "../AlgorithmIdentifier"; +import type { EncryptedContentInfo } from "../EncryptedContentInfo"; +import type { PublicKeyInfo } from "../PublicKeyInfo"; + +export type CryptoEngineAlgorithmOperation = "sign" | "encrypt" | "generateKey" | "importKey" | "exportKey" | "verify"; + +/** + * Algorithm parameters + */ +export interface CryptoEngineAlgorithmParams { + /** + * Algorithm + */ + algorithm: Algorithm | object; + /** + * Key usages + */ + usages: KeyUsage[]; +} + +export interface CryptoEngineSignatureParams { + signatureAlgorithm: AlgorithmIdentifier; + parameters: CryptoEngineAlgorithmParams; +} + +export interface CryptoEngineSignWithPrivateKeyParams { + algorithm: Algorithm; +} + +/** + * Public key parameters + */ +export interface CryptoEnginePublicKeyParams { + /** + * Algorithm + */ + algorithm: CryptoEngineAlgorithmParams; +} + + +export type ContentEncryptionAesCbcParams = AesCbcParams & AesDerivedKeyParams; +export type ContentEncryptionAesGcmParams = AesGcmParams & AesDerivedKeyParams; +export type ContentEncryptionAlgorithm = ContentEncryptionAesCbcParams | ContentEncryptionAesGcmParams; + +export interface CryptoEngineEncryptParams { + password: ArrayBuffer; + contentEncryptionAlgorithm: ContentEncryptionAlgorithm; + hmacHashAlgorithm: string; + iterationCount: number; + contentToEncrypt: ArrayBuffer; + contentType: string; +} + +export interface CryptoEngineDecryptParams { + password: ArrayBuffer; + encryptedContentInfo: EncryptedContentInfo; +} + +export interface CryptoEngineStampDataWithPasswordParams { + password: ArrayBuffer; + hashAlgorithm: string; + salt: ArrayBuffer; + iterationCount: number; + contentToStamp: ArrayBuffer; +} + +export interface CryptoEngineVerifyDataStampedWithPasswordParams { + password: ArrayBuffer; + hashAlgorithm: string; + salt: ArrayBuffer; + iterationCount: number; + contentToVerify: ArrayBuffer; + signatureToVerify: ArrayBuffer; +} + +export interface ICryptoEngine extends SubtleCrypto { + name: string; + crypto: Crypto; + subtle: SubtleCrypto; + + getRandomValues<T extends ArrayBufferView | null>(array: T): T; + + /** + * Get OID for each specific algorithm + * @param algorithm WebCrypto Algorithm + * @param safety If `true` throws exception on unknown algorithm. Default is `false` + * @param target Name of the target + * @throws Throws {@link Error} exception if unknown WebCrypto algorithm + */ + getOIDByAlgorithm(algorithm: Algorithm, safety?: boolean, target?: string): string; + /** + * Get default algorithm parameters for each kind of operation + * @param algorithmName Algorithm name to get common parameters for + * @param operation Kind of operation: "sign", "encrypt", "generateKey", "importKey", "exportKey", "verify" + */ + // TODO Use safety + getAlgorithmParameters(algorithmName: string, operation: CryptoEngineAlgorithmOperation): CryptoEngineAlgorithmParams; + + /** + * Gets WebCrypto algorithm by wel-known OID + * @param oid algorithm identifier + * @param safety if `true` throws exception on unknown algorithm identifier + * @param target name of the target + * @returns Returns WebCrypto algorithm or an empty object + */ + getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety?: boolean, target?: string): T | object; + /** + * Gets WebCrypto algorithm by wel-known OID + * @param oid algorithm identifier + * @param safety if `true` throws exception on unknown algorithm identifier + * @param target name of the target + * @returns Returns WebCrypto algorithm + * @throws Throws {@link Error} exception if unknown algorithm identifier + */ + getAlgorithmByOID<T extends Algorithm = Algorithm>(oid: string, safety: true, target?: string): T; + + /** + * Getting hash algorithm by signature algorithm + * @param signatureAlgorithm Signature algorithm + */ + // TODO use safety + getHashAlgorithm(signatureAlgorithm: AlgorithmIdentifier): string; + + /** + * Get signature parameters by analyzing private key algorithm + * @param privateKey The private key user would like to use + * @param hashAlgorithm Hash algorithm user would like to use. Default is SHA-1 + */ + getSignatureParameters(privateKey: CryptoKey, hashAlgorithm?: string): Promise<CryptoEngineSignatureParams>; + + /** + * Sign data with pre-defined private key + * @param data Data to be signed + * @param privateKey Private key to use + * @param parameters Parameters for used algorithm + */ + signWithPrivateKey(data: BufferSource, privateKey: CryptoKey, parameters: CryptoEngineSignWithPrivateKeyParams): Promise<ArrayBuffer>; + + /** + * Verify data with the public key + * @param data Data to be verified + * @param signature Signature value + * @param publicKeyInfo Public key information + * @param signatureAlgorithm Signature algorithm + * @param shaAlgorithm Hash algorithm + */ + verifyWithPublicKey(data: BufferSource, signature: asn1js.BitString | asn1js.OctetString, publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, shaAlgorithm?: string): Promise<boolean>; + + getPublicKey(publicKeyInfo: PublicKeyInfo, signatureAlgorithm: AlgorithmIdentifier, parameters?: CryptoEnginePublicKeyParams): Promise<CryptoKey>; + + /** + * Specialized function encrypting "EncryptedContentInfo" object using parameters + * @param parameters + */ + encryptEncryptedContentInfo(parameters: CryptoEngineEncryptParams): Promise<EncryptedContentInfo>; + + /** + * Decrypt data stored in "EncryptedContentInfo" object using parameters + * @param parameters + */ + decryptEncryptedContentInfo(parameters: CryptoEngineDecryptParams): Promise<ArrayBuffer>; + + /** + * Stamping (signing) data using algorithm similar to HMAC + * @param parameters + */ + stampDataWithPassword(parameters: CryptoEngineStampDataWithPasswordParams): Promise<ArrayBuffer>; + verifyDataStampedWithPassword(parameters: CryptoEngineVerifyDataStampedWithPasswordParams): Promise<boolean>; +} + +export interface CryptoEngineParameters { + name?: string; + crypto: Crypto; + /** + * @deprecated + */ + subtle?: SubtleCrypto; +} + +export interface CryptoEngineConstructor { + new(params: CryptoEngineParameters): ICryptoEngine; +} |