// Copyright 2018-2023 the Deno authors. All rights reserved. MIT license. import { Buffer } from "ext:deno_node/buffer.ts"; import { createHash } from "ext:deno_node/internal/crypto/hash.ts"; import { HASH_DATA } from "ext:deno_node/internal/crypto/types.ts"; export const MAX_ALLOC = Math.pow(2, 30) - 1; export type NormalizedAlgorithms = | "md5" | "ripemd160" | "sha1" | "sha224" | "sha256" | "sha384" | "sha512"; export type Algorithms = | "md5" | "ripemd160" | "rmd160" | "sha1" | "sha224" | "sha256" | "sha384" | "sha512"; const createHasher = (algorithm: string) => (value: Uint8Array) => Buffer.from(createHash(algorithm).update(value).digest() as Buffer); function getZeroes(zeros: number) { return Buffer.alloc(zeros); } const sizes = { md5: 16, sha1: 20, sha224: 28, sha256: 32, sha384: 48, sha512: 64, rmd160: 20, ripemd160: 20, }; function toBuffer(bufferable: HASH_DATA) { if (bufferable instanceof Uint8Array || typeof bufferable === "string") { return Buffer.from(bufferable as Uint8Array); } else { return Buffer.from(bufferable.buffer); } } export class Hmac { hash: (value: Uint8Array) => Buffer; ipad1: Buffer; opad: Buffer; alg: string; blocksize: number; size: number; ipad2: Buffer; constructor(alg: Algorithms, key: Buffer, saltLen: number) { this.hash = createHasher(alg); const blocksize = alg === "sha512" || alg === "sha384" ? 128 : 64; if (key.length > blocksize) { key = this.hash(key); } else if (key.length < blocksize) { key = Buffer.concat([key, getZeroes(blocksize - key.length)], blocksize); } const ipad = Buffer.allocUnsafe(blocksize + sizes[alg]); const opad = Buffer.allocUnsafe(blocksize + sizes[alg]); for (let i = 0; i < blocksize; i++) { ipad[i] = key[i] ^ 0x36; opad[i] = key[i] ^ 0x5c; } const ipad1 = Buffer.allocUnsafe(blocksize + saltLen + 4); ipad.copy(ipad1, 0, 0, blocksize); this.ipad1 = ipad1; this.ipad2 = ipad; this.opad = opad; this.alg = alg; this.blocksize = blocksize; this.size = sizes[alg]; } run(data: Buffer, ipad: Buffer) { data.copy(ipad, this.blocksize); const h = this.hash(ipad); h.copy(this.opad, this.blocksize); return this.hash(this.opad); } } /** * @param iterations Needs to be higher or equal than zero * @param keylen Needs to be higher or equal than zero but less than max allocation size (2^30) * @param digest Algorithm to be used for encryption */ export function pbkdf2Sync( password: HASH_DATA, salt: HASH_DATA, iterations: number, keylen: number, digest: Algorithms = "sha1", ): Buffer { if (typeof iterations !== "number" || iterations < 0) { throw new TypeError("Bad iterations"); } if (typeof keylen !== "number" || keylen < 0 || keylen > MAX_ALLOC) { throw new TypeError("Bad key length"); } const bufferedPassword = toBuffer(password); const bufferedSalt = toBuffer(salt); const hmac = new Hmac(digest, bufferedPassword, bufferedSalt.length); const DK = Buffer.allocUnsafe(keylen); const block1 = Buffer.allocUnsafe(bufferedSalt.length + 4); bufferedSalt.copy(block1, 0, 0, bufferedSalt.length); let destPos = 0; const hLen = sizes[digest]; const l = Math.ceil(keylen / hLen); for (let i = 1; i <= l; i++) { block1.writeUInt32BE(i, bufferedSalt.length); const T = hmac.run(block1, hmac.ipad1); let U = T; for (let j = 1; j < iterations; j++) { U = hmac.run(U, hmac.ipad2); for (let k = 0; k < hLen; k++) T[k] ^= U[k]; } T.copy(DK, destPos); destPos += hLen; } return DK; } /** * @param iterations Needs to be higher or equal than zero * @param keylen Needs to be higher or equal than zero but less than max allocation size (2^30) * @param digest Algorithm to be used for encryption */ export function pbkdf2( password: HASH_DATA, salt: HASH_DATA, iterations: number, keylen: number, digest: Algorithms = "sha1", callback: (err: Error | null, derivedKey?: Buffer) => void, ) { setTimeout(() => { let err = null, res; try { res = pbkdf2Sync(password, salt, iterations, keylen, digest); } catch (e) { err = e; } if (err) { callback(err instanceof Error ? err : new Error("[non-error thrown]")); } else { callback(null, res); } }, 0); } export default { Hmac, MAX_ALLOC, pbkdf2, pbkdf2Sync, };