refactor crypto service to use crypto functions

This commit is contained in:
Kyle Spearrin 2018-04-21 23:14:04 -04:00
parent cda2814192
commit fc1114a6bd
15 changed files with 211 additions and 329 deletions

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@ -22,14 +22,13 @@ export abstract class CryptoService {
clearOrgKeys: (memoryOnly?: boolean) => Promise<any>;
clearKeys: () => Promise<any>;
toggleKey: () => Promise<any>;
makeKey: (password: string, salt: string) => SymmetricCryptoKey;
makeKey: (password: string, salt: string) => Promise<SymmetricCryptoKey>;
hashPassword: (password: string, key: SymmetricCryptoKey) => Promise<string>;
makeEncKey: (key: SymmetricCryptoKey) => Promise<CipherString>;
encrypt: (plainValue: string | Uint8Array, key?: SymmetricCryptoKey,
plainValueEncoding?: string) => Promise<CipherString>;
encrypt: (plainValue: string | ArrayBuffer, key?: SymmetricCryptoKey) => Promise<CipherString>;
encryptToBytes: (plainValue: ArrayBuffer, key?: SymmetricCryptoKey) => Promise<ArrayBuffer>;
decrypt: (cipherString: CipherString, key?: SymmetricCryptoKey, outputEncoding?: string) => Promise<string>;
decrypt: (cipherString: CipherString, key?: SymmetricCryptoKey) => Promise<ArrayBuffer>;
decryptToUtf8: (cipherString: CipherString, key?: SymmetricCryptoKey) => Promise<string>;
decryptFromBytes: (encBuf: ArrayBuffer, key: SymmetricCryptoKey) => Promise<ArrayBuffer>;
rsaDecrypt: (encValue: string) => Promise<string>;
sha1: (password: string) => Promise<string>;
}

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@ -3,5 +3,10 @@ export abstract class CryptoFunctionService {
iterations: number) => Promise<ArrayBuffer>;
hash: (value: string | ArrayBuffer, algorithm: 'sha1' | 'sha256' | 'sha512') => Promise<ArrayBuffer>;
hmac: (value: ArrayBuffer, key: ArrayBuffer, algorithm: 'sha1' | 'sha256' | 'sha512') => Promise<ArrayBuffer>;
aesEncrypt: (data: ArrayBuffer, iv: ArrayBuffer, key: ArrayBuffer) => Promise<ArrayBuffer>;
aesDecryptSmall: (data: ArrayBuffer, iv: ArrayBuffer, key: ArrayBuffer) => Promise<ArrayBuffer>;
aesDecryptLarge: (data: ArrayBuffer, iv: ArrayBuffer, key: ArrayBuffer) => Promise<ArrayBuffer>;
rsaEncrypt: (data: ArrayBuffer, publicKey: ArrayBuffer, algorithm: 'sha1' | 'sha256') => Promise<ArrayBuffer>;
rsaDecrypt: (data: ArrayBuffer, key: ArrayBuffer, algorithm: 'sha1' | 'sha256') => Promise<ArrayBuffer>;
randomBytes: (length: number) => Promise<ArrayBuffer>;
}

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@ -40,7 +40,7 @@ export class ExportComponent {
}
const email = await this.userService.getEmail();
const key = this.cryptoService.makeKey(this.masterPassword, email);
const key = await this.cryptoService.makeKey(this.masterPassword, email);
const keyHash = await this.cryptoService.hashPassword(this.masterPassword, key);
const storedKeyHash = await this.cryptoService.getKeyHash();
@ -67,7 +67,7 @@ export class ExportComponent {
private async checkPassword() {
const email = await this.userService.getEmail();
const key = this.cryptoService.makeKey(this.masterPassword, email);
const key = await this.cryptoService.makeKey(this.masterPassword, email);
const keyHash = await this.cryptoService.hashPassword(this.masterPassword, key);
const storedKeyHash = await this.cryptoService.getKeyHash();
if (storedKeyHash == null || keyHash == null || storedKeyHash !== keyHash) {

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@ -28,7 +28,7 @@ export class LockComponent {
}
const email = await this.userService.getEmail();
const key = this.cryptoService.makeKey(this.masterPassword, email);
const key = await this.cryptoService.makeKey(this.masterPassword, email);
const keyHash = await this.cryptoService.hashPassword(this.masterPassword, key);
const storedKeyHash = await this.cryptoService.getKeyHash();

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@ -69,7 +69,7 @@ export class RegisterComponent {
private async register() {
this.email = this.email.toLowerCase();
const key = this.cryptoService.makeKey(this.masterPassword, this.email);
const key = await this.cryptoService.makeKey(this.masterPassword, this.email);
const encKey = await this.cryptoService.makeEncKey(key);
const hashedPassword = await this.cryptoService.hashPassword(this.masterPassword, key);
const request = new RegisterRequest(this.email, hashedPassword, this.hint, encKey.encryptedString);

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@ -87,7 +87,7 @@ export class CipherString {
}
}
decrypt(orgId: string): Promise<string> {
async decrypt(orgId: string): Promise<string> {
if (this.decryptedValue) {
return Promise.resolve(this.decryptedValue);
}
@ -100,14 +100,12 @@ export class CipherString {
throw new Error('window.bitwardenContainerService not initialized.');
}
return cryptoService.getOrgKey(orgId).then((orgKey: any) => {
return cryptoService.decrypt(this, orgKey);
}).then((decValue: any) => {
this.decryptedValue = decValue;
return this.decryptedValue;
}).catch(() => {
try {
const orgKey = await cryptoService.getOrgKey(orgId);
this.decryptedValue = await cryptoService.decryptToUtf8(this, orgKey);
} catch (e) {
this.decryptedValue = '[error: cannot decrypt]';
return this.decryptedValue;
});
}
return this.decryptedValue;
}
}

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@ -1,8 +1,8 @@
import { SymmetricCryptoKey } from './symmetricCryptoKey';
export class EncryptedObject {
iv: Uint8Array;
ct: Uint8Array;
mac: Uint8Array;
iv: ArrayBuffer;
ct: ArrayBuffer;
mac: ArrayBuffer;
key: SymmetricCryptoKey;
}

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@ -14,4 +14,3 @@ export { LoginUri } from './loginUri';
export { PasswordHistory } from './passwordHistory';
export { SecureNote } from './secureNote';
export { SymmetricCryptoKey } from './symmetricCryptoKey';
export { SymmetricCryptoKeyBuffers } from './symmetricCryptoKeyBuffers';

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@ -1,80 +1,45 @@
import * as forge from 'node-forge';
import { EncryptionType } from '../../enums/encryptionType';
import { SymmetricCryptoKeyBuffers } from './symmetricCryptoKeyBuffers';
import { UtilsService } from '../../services/utils.service';
import { Utils } from '../../misc/utils';
export class SymmetricCryptoKey {
key: string;
keyB64: string;
encKey: string;
macKey: string;
key: ArrayBuffer;
encKey?: ArrayBuffer;
macKey?: ArrayBuffer;
encType: EncryptionType;
keyBuf: SymmetricCryptoKeyBuffers;
constructor(keyBytes: string, b64KeyBytes?: boolean, encType?: EncryptionType) {
if (b64KeyBytes) {
keyBytes = forge.util.decode64(keyBytes);
keyB64: string;
constructor(key: ArrayBuffer, encType?: EncryptionType) {
if (key == null) {
throw new Error('Must provide key');
}
if (!keyBytes) {
throw new Error('Must provide keyBytes');
}
const buffer = (forge as any).util.createBuffer(keyBytes);
if (!buffer || buffer.length() === 0) {
throw new Error('Couldn\'t make buffer');
}
const bufferLength: number = buffer.length();
if (encType == null) {
if (bufferLength === 32) {
if (key.byteLength === 32) {
encType = EncryptionType.AesCbc256_B64;
} else if (bufferLength === 64) {
} else if (key.byteLength === 64) {
encType = EncryptionType.AesCbc256_HmacSha256_B64;
} else {
throw new Error('Unable to determine encType.');
}
}
this.key = keyBytes;
this.keyB64 = forge.util.encode64(keyBytes);
this.key = key;
this.keyB64 = Utils.fromBufferToB64(key);
this.encType = encType;
if (encType === EncryptionType.AesCbc256_B64 && bufferLength === 32) {
this.encKey = keyBytes;
if (encType === EncryptionType.AesCbc256_B64 && key.byteLength === 32) {
this.encKey = key;
this.macKey = null;
} else if (encType === EncryptionType.AesCbc128_HmacSha256_B64 && bufferLength === 32) {
this.encKey = buffer.getBytes(16); // first half
this.macKey = buffer.getBytes(16); // second half
} else if (encType === EncryptionType.AesCbc256_HmacSha256_B64 && bufferLength === 64) {
this.encKey = buffer.getBytes(32); // first half
this.macKey = buffer.getBytes(32); // second half
} else if (encType === EncryptionType.AesCbc128_HmacSha256_B64 && key.byteLength === 32) {
this.encKey = key.slice(0, 16);
this.macKey = key.slice(16, 32);
} else if (encType === EncryptionType.AesCbc256_HmacSha256_B64 && key.byteLength === 64) {
this.encKey = key.slice(0, 32);
this.macKey = key.slice(32, 64);
} else {
throw new Error('Unsupported encType/key length.');
}
}
getBuffers(): SymmetricCryptoKeyBuffers {
if (this.keyBuf) {
return this.keyBuf;
}
const key = UtilsService.fromB64ToArray(this.keyB64);
const keys = new SymmetricCryptoKeyBuffers(key.buffer);
if (this.macKey) {
keys.encKey = key.slice(0, key.length / 2).buffer;
keys.macKey = key.slice(key.length / 2).buffer;
} else {
keys.encKey = key.buffer;
keys.macKey = null;
}
this.keyBuf = keys;
return this.keyBuf;
}
}

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@ -1,9 +0,0 @@
export class SymmetricCryptoKeyBuffers {
key: ArrayBuffer;
encKey?: ArrayBuffer;
macKey?: ArrayBuffer;
constructor(key: ArrayBuffer) {
this.key = key;
}
}

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@ -95,7 +95,7 @@ export class AuthService {
async logIn(email: string, masterPassword: string): Promise<AuthResult> {
this.selectedTwoFactorProviderType = null;
email = email.toLowerCase();
const key = this.cryptoService.makeKey(masterPassword, email);
const key = await this.cryptoService.makeKey(masterPassword, email);
const hashedPassword = await this.cryptoService.hashPassword(masterPassword, key);
return await this.logInHelper(email, hashedPassword, key);
}

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@ -8,10 +8,12 @@ import { SymmetricCryptoKey } from '../models/domain/symmetricCryptoKey';
import { ProfileOrganizationResponse } from '../models/response/profileOrganizationResponse';
import { CryptoService as CryptoServiceAbstraction } from '../abstractions/crypto.service';
import { StorageService as StorageServiceInterface } from '../abstractions/storage.service';
import { CryptoFunctionService } from '../abstractions/cryptoFunction.service';
import { StorageService } from '../abstractions/storage.service';
import { ConstantsService } from './constants.service';
import { UtilsService } from './utils.service';
import { Utils } from '../misc/utils';
const Keys = {
key: 'key',
@ -21,18 +23,6 @@ const Keys = {
keyHash: 'keyHash',
};
const SigningAlgorithm = {
name: 'HMAC',
hash: { name: 'SHA-256' },
};
const AesAlgorithm = {
name: 'AES-CBC',
};
const Crypto = window.crypto;
const Subtle = Crypto.subtle;
export class CryptoService implements CryptoServiceAbstraction {
private key: SymmetricCryptoKey;
private encKey: SymmetricCryptoKey;
@ -41,9 +31,8 @@ export class CryptoService implements CryptoServiceAbstraction {
private privateKey: ArrayBuffer;
private orgKeys: Map<string, SymmetricCryptoKey>;
constructor(private storageService: StorageServiceInterface,
private secureStorageService: StorageServiceInterface) {
}
constructor(private storageService: StorageService, private secureStorageService: StorageService,
private cryptoFunctionService: CryptoFunctionService) { }
async setKey(key: SymmetricCryptoKey): Promise<any> {
this.key = key;
@ -66,6 +55,7 @@ export class CryptoService implements CryptoServiceAbstraction {
if (encKey == null) {
return;
}
await this.storageService.save(Keys.encKey, encKey);
this.encKey = null;
}
@ -99,8 +89,8 @@ export class CryptoService implements CryptoServiceAbstraction {
}
const key = await this.secureStorageService.get<string>(Keys.key);
if (key) {
this.key = new SymmetricCryptoKey(key, true);
if (key != null) {
this.key = new SymmetricCryptoKey(Utils.fromB64ToArray(key).buffer);
}
return key == null ? null : this.key;
@ -129,7 +119,7 @@ export class CryptoService implements CryptoServiceAbstraction {
return null;
}
const decEncKey = await this.decrypt(new CipherString(encKey), key, 'raw');
const decEncKey = await this.decrypt(new CipherString(encKey), key);
if (decEncKey == null) {
return null;
}
@ -148,8 +138,7 @@ export class CryptoService implements CryptoServiceAbstraction {
return null;
}
const privateKeyB64 = await this.decrypt(new CipherString(encPrivateKey), null, 'b64');
this.privateKey = UtilsService.fromB64ToArray(privateKeyB64).buffer;
this.privateKey = await this.decrypt(new CipherString(encPrivateKey), null);
return this.privateKey;
}
@ -159,7 +148,7 @@ export class CryptoService implements CryptoServiceAbstraction {
}
const encOrgKeys = await this.storageService.get<any>(Keys.encOrgKeys);
if (!encOrgKeys) {
if (encOrgKeys == null) {
return null;
}
@ -171,8 +160,8 @@ export class CryptoService implements CryptoServiceAbstraction {
continue;
}
const decValueB64 = await this.rsaDecrypt(encOrgKeys[orgId]);
orgKeys.set(orgId, new SymmetricCryptoKey(decValueB64, true));
const decValue = await this.rsaDecrypt(encOrgKeys[orgId]);
orgKeys.set(orgId, new SymmetricCryptoKey(decValue));
setKey = true;
}
@ -253,91 +242,83 @@ export class CryptoService implements CryptoServiceAbstraction {
await this.setKey(key);
}
makeKey(password: string, salt: string): SymmetricCryptoKey {
const keyBytes: string = (forge as any).pbkdf2(forge.util.encodeUtf8(password), forge.util.encodeUtf8(salt),
5000, 256 / 8, 'sha256');
return new SymmetricCryptoKey(keyBytes);
async makeKey(password: string, salt: string): Promise<SymmetricCryptoKey> {
const key = await this.cryptoFunctionService.pbkdf2(password, salt, 'sha256', 5000);
return new SymmetricCryptoKey(key);
}
async hashPassword(password: string, key: SymmetricCryptoKey): Promise<string> {
const storedKey = await this.getKey();
key = key || storedKey;
if (!password || !key) {
if (password == null || key == null) {
throw new Error('Invalid parameters.');
}
const hashBits = (forge as any).pbkdf2(key.key, forge.util.encodeUtf8(password), 1, 256 / 8, 'sha256');
return forge.util.encode64(hashBits);
const hash = await this.cryptoFunctionService.pbkdf2(key.key, password, 'sha256', 1);
return Utils.fromBufferToB64(hash);
}
makeEncKey(key: SymmetricCryptoKey): Promise<CipherString> {
const bytes = new Uint8Array(512 / 8);
Crypto.getRandomValues(bytes);
return this.encrypt(bytes, key, 'raw');
async makeEncKey(key: SymmetricCryptoKey): Promise<CipherString> {
const bytes = await this.cryptoFunctionService.randomBytes(64);
return this.encrypt(bytes, key);
}
async encrypt(plainValue: string | Uint8Array, key?: SymmetricCryptoKey,
plainValueEncoding: string = 'utf8'): Promise<CipherString> {
if (!plainValue) {
async encrypt(plainValue: string | ArrayBuffer, key?: SymmetricCryptoKey): Promise<CipherString> {
if (plainValue == null) {
return Promise.resolve(null);
}
let plainValueArr: Uint8Array;
if (plainValueEncoding === 'utf8') {
plainValueArr = UtilsService.fromUtf8ToArray(plainValue as string);
let plainBuf: ArrayBuffer;
if (typeof (plainValue) === 'string') {
plainBuf = Utils.fromUtf8ToArray(plainValue).buffer;
} else {
plainValueArr = plainValue as Uint8Array;
plainBuf = plainValue;
}
const encValue = await this.aesEncrypt(plainValueArr.buffer, key);
const iv = UtilsService.fromBufferToB64(encValue.iv.buffer);
const ct = UtilsService.fromBufferToB64(encValue.ct.buffer);
const mac = encValue.mac ? UtilsService.fromBufferToB64(encValue.mac.buffer) : null;
return new CipherString(encValue.key.encType, iv, ct, mac);
const encObj = await this.aesEncrypt(plainBuf, key);
const iv = Utils.fromBufferToB64(encObj.iv);
const ct = Utils.fromBufferToB64(encObj.ct);
const mac = encObj.mac != null ? Utils.fromBufferToB64(encObj.mac) : null;
return new CipherString(encObj.key.encType, iv, ct, mac);
}
async encryptToBytes(plainValue: ArrayBuffer, key?: SymmetricCryptoKey): Promise<ArrayBuffer> {
const encValue = await this.aesEncrypt(plainValue, key);
let macLen = 0;
if (encValue.mac) {
macLen = encValue.mac.length;
if (encValue.mac != null) {
macLen = encValue.mac.byteLength;
}
const encBytes = new Uint8Array(1 + encValue.iv.length + macLen + encValue.ct.length);
const encBytes = new Uint8Array(1 + encValue.iv.byteLength + macLen + encValue.ct.byteLength);
encBytes.set([encValue.key.encType]);
encBytes.set(encValue.iv, 1);
if (encValue.mac) {
encBytes.set(encValue.mac, 1 + encValue.iv.length);
encBytes.set(new Uint8Array(encValue.iv), 1);
if (encValue.mac != null) {
encBytes.set(new Uint8Array(encValue.mac), 1 + encValue.iv.byteLength);
}
encBytes.set(encValue.ct, 1 + encValue.iv.length + macLen);
encBytes.set(new Uint8Array(encValue.ct), 1 + encValue.iv.byteLength + macLen);
return encBytes.buffer;
}
async decrypt(cipherString: CipherString, key?: SymmetricCryptoKey,
outputEncoding: string = 'utf8'): Promise<string> {
const ivBytes: string = forge.util.decode64(cipherString.initializationVector);
const ctBytes: string = forge.util.decode64(cipherString.cipherText);
const macBytes: string = cipherString.mac ? forge.util.decode64(cipherString.mac) : null;
const decipher = await this.aesDecrypt(cipherString.encryptionType, ctBytes, ivBytes, macBytes, key);
if (!decipher) {
async decrypt(cipherString: CipherString, key?: SymmetricCryptoKey): Promise<ArrayBuffer> {
const iv = Utils.fromB64ToArray(cipherString.initializationVector).buffer;
const ct = Utils.fromB64ToArray(cipherString.cipherText).buffer;
const mac = cipherString.mac ? Utils.fromB64ToArray(cipherString.mac).buffer : null;
const decipher = await this.aesDecrypt(cipherString.encryptionType, ct, iv, mac, key);
if (decipher == null) {
return null;
}
if (outputEncoding === 'utf8') {
return decipher.output.toString('utf8');
}
return decipher;
}
const decipherBytes = decipher.output.getBytes();
if (outputEncoding === 'b64') {
return forge.util.encode64(decipherBytes);
} else {
return decipherBytes;
}
async decryptToUtf8(cipherString: CipherString, key?: SymmetricCryptoKey): Promise<string> {
const decipher = await this.decrypt(cipherString, key);
return Utils.fromBufferToUtf8(decipher);
}
async decryptFromBytes(encBuf: ArrayBuffer, key: SymmetricCryptoKey): Promise<ArrayBuffer> {
if (!encBuf) {
if (encBuf == null) {
throw new Error('no encBuf.');
}
@ -370,10 +351,93 @@ export class CryptoService implements CryptoServiceAbstraction {
return null;
}
return await this.aesDecryptWC(encType, ctBytes.buffer, ivBytes.buffer, macBytes ? macBytes.buffer : null, key);
return await this.aesDecryptLarge(encType, ctBytes.buffer, ivBytes.buffer,
macBytes != null ? macBytes.buffer : null, key);
}
async rsaDecrypt(encValue: string): Promise<string> {
async sha1(password: string): Promise<string> {
const hash = await this.cryptoFunctionService.hash(password, 'sha1');
return Utils.fromBufferToHex(hash);
}
// Helpers
private async aesEncrypt(plainValue: ArrayBuffer, key: SymmetricCryptoKey): Promise<EncryptedObject> {
const obj = new EncryptedObject();
obj.key = await this.getKeyForEncryption(key);
obj.iv = await this.cryptoFunctionService.randomBytes(16);
obj.ct = await this.cryptoFunctionService.aesEncrypt(plainValue, obj.iv, obj.key.encKey);
if (obj.key.macKey != null) {
const macData = new Uint8Array(obj.iv.byteLength + obj.ct.byteLength);
macData.set(new Uint8Array(obj.iv), 0);
macData.set(new Uint8Array(obj.ct), obj.iv.byteLength);
obj.mac = await this.cryptoFunctionService.hmac(macData.buffer, obj.key.macKey, 'sha256');
}
return obj;
}
private async aesDecrypt(encType: EncryptionType, ct: ArrayBuffer, iv: ArrayBuffer, mac: ArrayBuffer,
key: SymmetricCryptoKey): Promise<ArrayBuffer> {
const keyForEnc = await this.getKeyForEncryption(key);
const theKey = this.resolveLegacyKey(encType, keyForEnc);
if (theKey.macKey != null && mac == null) {
// tslint:disable-next-line
console.error('mac required.');
return null;
}
if (encType !== theKey.encType) {
// tslint:disable-next-line
console.error('encType unavailable.');
return null;
}
if (theKey.macKey != null && mac != null) {
const macData = new Uint8Array(iv.byteLength + ct.byteLength);
macData.set(new Uint8Array(iv), 0);
macData.set(new Uint8Array(ct), iv.byteLength);
const computedMac = await this.cryptoFunctionService.hmac(new Uint8Array(iv).buffer,
theKey.macKey, 'sha256');
if (!this.macsEqual(computedMac, mac)) {
// tslint:disable-next-line
console.error('mac failed.');
return null;
}
}
return this.cryptoFunctionService.aesDecryptSmall(ct, iv, theKey.encKey);
}
private async aesDecryptLarge(encType: EncryptionType, ct: ArrayBuffer, iv: ArrayBuffer,
mac: ArrayBuffer, key: SymmetricCryptoKey): Promise<ArrayBuffer> {
const theKey = await this.getKeyForEncryption(key);
if (theKey.macKey == null || mac == null) {
return null;
}
const macData = new Uint8Array(iv.byteLength + ct.byteLength);
macData.set(new Uint8Array(iv), 0);
macData.set(new Uint8Array(ct), iv.byteLength);
const computedMac = await this.cryptoFunctionService.hmac(new Uint8Array(iv).buffer,
theKey.macKey, 'sha256');
if (computedMac === null) {
return null;
}
const macsMatch = await this.macsEqual(mac, computedMac);
if (macsMatch === false) {
// tslint:disable-next-line
console.error('mac failed.');
return null;
}
return await this.cryptoFunctionService.aesDecryptLarge(ct, iv, theKey.encKey);
}
private async rsaDecrypt(encValue: string): Promise<ArrayBuffer> {
const headerPieces = encValue.split('.');
let encType: EncryptionType = null;
let encPieces: string[];
@ -409,186 +473,51 @@ export class CryptoService implements CryptoServiceAbstraction {
throw new Error('encPieces unavailable.');
}
const ct = Utils.fromB64ToArray(encPieces[0]).buffer;
const key = await this.getEncKey();
if (key != null && key.macKey != null && encPieces.length > 1) {
const ctBytes: string = forge.util.decode64(encPieces[0]);
const macBytes: string = forge.util.decode64(encPieces[1]);
const computedMacBytes = await this.computeMac(ctBytes, key.macKey, false);
const macsEqual = await this.macsEqual(macBytes, computedMacBytes);
const mac = Utils.fromB64ToArray(encPieces[1]).buffer;
const computedMac = await this.cryptoFunctionService.hmac(ct, key.macKey, 'sha256');
const macsEqual = await this.macsEqual(mac, computedMac);
if (!macsEqual) {
throw new Error('MAC failed.');
}
}
const privateKeyBytes = await this.getPrivateKey();
if (!privateKeyBytes) {
const privateKey = await this.getPrivateKey();
if (privateKey == null) {
throw new Error('No private key.');
}
let rsaAlgorithm: any = null;
let alg: 'sha1' | 'sha256' = 'sha1';
switch (encType) {
case EncryptionType.Rsa2048_OaepSha256_B64:
case EncryptionType.Rsa2048_OaepSha256_HmacSha256_B64:
rsaAlgorithm = {
name: 'RSA-OAEP',
hash: { name: 'SHA-256' },
};
alg = 'sha256';
break;
case EncryptionType.Rsa2048_OaepSha1_B64:
case EncryptionType.Rsa2048_OaepSha1_HmacSha256_B64:
rsaAlgorithm = {
name: 'RSA-OAEP',
hash: { name: 'SHA-1' },
};
break;
default:
throw new Error('encType unavailable.');
}
const privateKey = await Subtle.importKey('pkcs8', privateKeyBytes, rsaAlgorithm, false, ['decrypt']);
const ctArr = UtilsService.fromB64ToArray(encPieces[0]);
const decBytes = await Subtle.decrypt(rsaAlgorithm, privateKey, ctArr.buffer);
const b64DecValue = UtilsService.fromBufferToB64(decBytes);
return b64DecValue;
}
async sha1(password: string): Promise<string> {
const passwordArr = UtilsService.fromUtf8ToArray(password);
const hash = await Subtle.digest({ name: 'SHA-1' }, passwordArr);
return UtilsService.fromBufferToHex(hash);
}
// Helpers
private async aesEncrypt(plainValue: ArrayBuffer, key: SymmetricCryptoKey): Promise<EncryptedObject> {
const obj = new EncryptedObject();
obj.key = await this.getKeyForEncryption(key);
const keyBuf = obj.key.getBuffers();
obj.iv = new Uint8Array(16);
Crypto.getRandomValues(obj.iv);
const encKey = await Subtle.importKey('raw', keyBuf.encKey, AesAlgorithm, false, ['encrypt']);
const encValue = await Subtle.encrypt({ name: 'AES-CBC', iv: obj.iv }, encKey, plainValue);
obj.ct = new Uint8Array(encValue);
if (keyBuf.macKey) {
const data = new Uint8Array(obj.iv.length + obj.ct.length);
data.set(obj.iv, 0);
data.set(obj.ct, obj.iv.length);
const mac = await this.computeMacWC(data.buffer, keyBuf.macKey);
obj.mac = new Uint8Array(mac);
}
return obj;
}
private async aesDecrypt(encType: EncryptionType, ctBytes: string, ivBytes: string, macBytes: string,
key: SymmetricCryptoKey): Promise<any> {
const keyForEnc = await this.getKeyForEncryption(key);
const theKey = this.resolveLegacyKey(encType, keyForEnc);
if (theKey.macKey != null && macBytes == null) {
// tslint:disable-next-line
console.error('macBytes required.');
return null;
}
if (encType !== theKey.encType) {
// tslint:disable-next-line
console.error('encType unavailable.');
return null;
}
if (theKey.macKey != null && macBytes != null) {
const computedMacBytes = this.computeMac(ivBytes + ctBytes, theKey.macKey, false);
if (!this.macsEqual(computedMacBytes, macBytes)) {
// tslint:disable-next-line
console.error('MAC failed.');
return null;
}
}
const ctBuffer = (forge as any).util.createBuffer(ctBytes);
const decipher = (forge as any).cipher.createDecipher('AES-CBC', theKey.encKey);
decipher.start({ iv: ivBytes });
decipher.update(ctBuffer);
decipher.finish();
return decipher;
}
private async aesDecryptWC(encType: EncryptionType, ctBuf: ArrayBuffer, ivBuf: ArrayBuffer,
macBuf: ArrayBuffer, key: SymmetricCryptoKey): Promise<ArrayBuffer> {
const theKey = await this.getKeyForEncryption(key);
const keyBuf = theKey.getBuffers();
const encKey = await Subtle.importKey('raw', keyBuf.encKey, AesAlgorithm, false, ['decrypt']);
if (!keyBuf.macKey || !macBuf) {
return null;
}
const data = new Uint8Array(ivBuf.byteLength + ctBuf.byteLength);
data.set(new Uint8Array(ivBuf), 0);
data.set(new Uint8Array(ctBuf), ivBuf.byteLength);
const computedMacBuf = await this.computeMacWC(data.buffer, keyBuf.macKey);
if (computedMacBuf === null) {
return null;
}
const macsMatch = await this.macsEqualWC(macBuf, computedMacBuf);
if (macsMatch === false) {
// tslint:disable-next-line
console.error('MAC failed.');
return null;
}
return await Subtle.decrypt({ name: 'AES-CBC', iv: ivBuf }, encKey, ctBuf);
}
private computeMac(dataBytes: string, macKey: string, b64Output: boolean): string {
const hmac = (forge as any).hmac.create();
hmac.start('sha256', macKey);
hmac.update(dataBytes);
const mac = hmac.digest();
return b64Output ? forge.util.encode64(mac.getBytes()) : mac.getBytes();
}
private async computeMacWC(dataBuf: ArrayBuffer, macKeyBuf: ArrayBuffer): Promise<ArrayBuffer> {
const key = await Subtle.importKey('raw', macKeyBuf, SigningAlgorithm, false, ['sign']);
return await Subtle.sign(SigningAlgorithm, key, dataBuf);
return this.cryptoFunctionService.rsaDecrypt(ct, privateKey, alg);
}
// Safely compare two MACs in a way that protects against timing attacks (Double HMAC Verification).
// ref: https://www.nccgroup.trust/us/about-us/newsroom-and-events/blog/2011/february/double-hmac-verification/
// ref: https://paragonie.com/blog/2015/11/preventing-timing-attacks-on-string-comparison-with-double-hmac-strategy
private macsEqual(mac1: string, mac2: string): boolean {
const hmac = (forge as any).hmac.create();
hmac.start('sha256', this.getRandomBytes(32));
hmac.update(mac1);
const mac1Bytes = hmac.digest().getBytes();
hmac.start(null, null);
hmac.update(mac2);
const mac2Bytes = hmac.digest().getBytes();
return mac1Bytes === mac2Bytes;
}
private async macsEqualWC(mac1Buf: ArrayBuffer, mac2Buf: ArrayBuffer): Promise<boolean> {
const compareKey = new Uint8Array(32);
Crypto.getRandomValues(compareKey);
const macKey = await Subtle.importKey('raw', compareKey.buffer, SigningAlgorithm, false, ['sign']);
const mac1 = await Subtle.sign(SigningAlgorithm, macKey, mac1Buf);
const mac2 = await Subtle.sign(SigningAlgorithm, macKey, mac2Buf);
if (mac1.byteLength !== mac2.byteLength) {
private async macsEqual(mac1: ArrayBuffer, mac2: ArrayBuffer): Promise<boolean> {
const key = await this.cryptoFunctionService.randomBytes(32);
const newMac1 = await this.cryptoFunctionService.hmac(mac1, key, 'sha256');
const newMac2 = await this.cryptoFunctionService.hmac(mac2, key, 'sha256');
if (newMac1.byteLength !== newMac2.byteLength) {
return false;
}
const arr1 = new Uint8Array(mac1);
const arr2 = new Uint8Array(mac2);
const arr1 = new Uint8Array(newMac1);
const arr2 = new Uint8Array(newMac2);
for (let i = 0; i < arr2.length; i++) {
if (arr1[i] !== arr2[i]) {
return false;
@ -599,33 +528,28 @@ export class CryptoService implements CryptoServiceAbstraction {
}
private async getKeyForEncryption(key?: SymmetricCryptoKey): Promise<SymmetricCryptoKey> {
if (key) {
if (key != null) {
return key;
}
const encKey = await this.getEncKey();
return encKey || (await this.getKey());
if (encKey != null) {
return encKey;
}
return await this.getKey();
}
private resolveLegacyKey(encType: EncryptionType, key: SymmetricCryptoKey): SymmetricCryptoKey {
if (encType === EncryptionType.AesCbc128_HmacSha256_B64 &&
key.encType === EncryptionType.AesCbc256_B64) {
// Old encrypt-then-mac scheme, make a new key
this.legacyEtmKey = this.legacyEtmKey ||
new SymmetricCryptoKey(key.key, false, EncryptionType.AesCbc128_HmacSha256_B64);
if (this.legacyEtmKey == null) {
this.legacyEtmKey = new SymmetricCryptoKey(key.key, EncryptionType.AesCbc128_HmacSha256_B64);
}
return this.legacyEtmKey;
}
return key;
}
private getRandomBytes(byteLength: number): string {
const bytes = new Uint32Array(byteLength / 4);
Crypto.getRandomValues(bytes);
const buffer = forge.util.createBuffer();
for (let i = 0; i < bytes.length; i++) {
buffer.putInt32(bytes[i]);
}
return buffer.getBytes();
}
}

View File

@ -32,7 +32,7 @@ export class NodeCryptoFunctionService implements CryptoFunctionService {
hmac(value: ArrayBuffer, key: ArrayBuffer, algorithm: 'sha1' | 'sha256' | 'sha512'): Promise<ArrayBuffer> {
const nodeValue = this.toNodeBuffer(value);
const nodeKey = this.toNodeBuffer(value);
const nodeKey = this.toNodeBuffer(key);
const hmac = crypto.createHmac(algorithm, nodeKey);
hmac.update(nodeValue);
return Promise.resolve(this.toArrayBuffer(hmac.digest()));

View File

@ -238,7 +238,7 @@ export class PasswordGenerationService implements PasswordGenerationServiceAbstr
}
const promises = history.map(async (item) => {
const decrypted = await this.cryptoService.decrypt(new CipherString(item.password));
const decrypted = await this.cryptoService.decryptToUtf8(new CipherString(item.password));
return new PasswordHistory(decrypted, item.date);
});

View File

@ -1,5 +1,6 @@
{
"compilerOptions": {
"pretty": true,
"moduleResolution": "node",
"target": "ES6",
"module": "commonjs",