@shogun-sdk/accounts
Version:
Shogun with Turnkey: configs, encryption, authentication with Telegram/Turnkey OIDC, etc.
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text/typescript
import crypto from 'crypto';
/**
* Generate a secure salt from a user ID and a private key.
* @param userId The unique, immutable identifier of the user.
* @returns The generated salt.
*
* IMPORTANT: We use the userId instead of editable fields like username for salt generation.
* This is crucial for maintaining consistent encryption/decryption capabilities:
*
* 1. Immutability: The userId doesn't change, unlike usernames which can be edited.
* If we used the username, changing it would result in a different salt,
* making it impossible to decrypt previously encrypted data.
*
* 2. Consistency: Using the userId ensures that the salt (and thus the derived encryption key)
* remains the same throughout the user's lifetime in the system.
*
* 3. Security: The userId is typically not known to the user, adding an extra layer of security.
*
* Example scenario:
* - User signs up with username "ABC69" and is assigned userId "12345"
* - We generate a salt and encrypt their private key using this salt
* - Later, the user changes their username to "XYZ107"
* - If we had used the username for salt generation, we'd no longer be able to decrypt
* their private key because the new salt would be different
* - By using the unchanging userId, we maintain the ability to decrypt regardless of username changes
*
* This approach ensures that we can always decrypt the user's encrypted data,
* even if they change their editable profile information.
*/
export function createSecureSalt(inputString: string, privateKey: string): string {
if (!privateKey) {
throw new Error('privateKey is not set in the environment variables');
}
// Combine the input string with the private key
const combinedString = inputString + privateKey;
// Create a SHA-256 hash of the combined string
const hash = crypto.createHash('sha256').update(combinedString).digest('hex');
return hash;
}
/**
* Encrypt data using AES with the derived key from the salt.
* @param data The data to encrypt.
* @param salt The salt to use for key derivation.
* @returns The encrypted data in base64 format with IV prepended.
*/
export function aesEncrypt(data: string, pwd: string, salt: string): string {
// Derive a key from the salt using PBKDF2
const key = crypto.pbkdf2Sync(pwd, salt, 100000, 32, 'sha256');
// Generate a random initialization vector (IV)
const iv = crypto.randomBytes(16);
// Create AES cipher using the key and IV
const cipher = crypto.createCipheriv('aes-256-cbc', key, iv);
// Encrypt the data
const encryptedBuffer = Buffer.concat([cipher.update(Buffer.from(data, 'utf8')), cipher.final()]);
// Combine IV and encrypted data, then convert to base64
return Buffer.concat([iv, encryptedBuffer]).toString('base64');
}
// Helper function to check if a string is base64 encoded
export function isBase64(str: string): boolean {
try {
return Buffer.from(str, 'base64').toString('base64') === str;
} catch {
return false;
}
}
export function aesDecrypt(encryptedData: string, pwdHash: string, salt: string): string {
// Derive the key from the salt using PBKDF2
const key = crypto.pbkdf2Sync(pwdHash, salt, 100000, 32, 'sha256');
let iv: Buffer;
let encrypted: string;
// Check if the data is in the old base64 format or the new hex format
if (isBase64(encryptedData)) {
// Old format: base64 encoded
const buffer = Buffer.from(encryptedData, 'base64');
iv = buffer.slice(0, 16);
encrypted = buffer.slice(16).toString('hex');
} else {
// New format: hex encoded
iv = Buffer.from(encryptedData.slice(0, 32), 'hex');
encrypted = encryptedData.slice(32);
}
// Create AES decipher using the key and IV
const decipher = crypto.createDecipheriv('aes-256-cbc', key, iv);
// Decrypt the data
let decrypted = decipher.update(encrypted, 'hex', 'utf8');
decrypted += decipher.final('utf8');
return decrypted;
}
export function getSecret(
id: string,
encryptKey: string,
publicOrganizationId: string,
dataEncryptionKey: string,
): string | null {
try {
const pwdHash = createSecureSalt(id, publicOrganizationId);
const salt = createSecureSalt(id, dataEncryptionKey);
return aesDecrypt(encryptKey, pwdHash, salt);
} catch (error) {
console.error('Error in getSecret:', error);
return null;
}
}
export const createEncryptedValue = (
privateKey: string,
id: string,
publicOrganizationId: string,
dataEncryptionKey: string,
) => {
const pwdHash = createSecureSalt(id, publicOrganizationId);
const salt = createSecureSalt(id, dataEncryptionKey);
return aesEncrypt(privateKey, pwdHash, salt);
};