signal-desktop/js/modules/crypto.js

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/* eslint-env browser */
/* global dcodeIO, libsignal */
/* eslint-disable camelcase, no-bitwise */
module.exports = {
arrayBufferToBase64,
typedArrayToArrayBuffer,
base64ToArrayBuffer,
bytesFromHexString,
bytesFromString,
concatenateBytes,
constantTimeEqual,
decryptAesCtr,
decryptDeviceName,
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decryptAttachment,
decryptFile,
decryptSymmetric,
deriveAccessKey,
deriveStickerPackKey,
encryptAesCtr,
encryptDeviceName,
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encryptAttachment,
encryptFile,
encryptSymmetric,
fromEncodedBinaryToArrayBuffer,
getAccessKeyVerifier,
getFirstBytes,
getRandomBytes,
getRandomValue,
getViewOfArrayBuffer,
getZeroes,
hexFromBytes,
highBitsToInt,
hmacSha256,
intsToByteHighAndLow,
splitBytes,
stringFromBytes,
trimBytes,
verifyAccessKey,
};
function typedArrayToArrayBuffer(typedArray) {
const { buffer, byteOffset, byteLength } = typedArray;
return buffer.slice(byteOffset, byteLength + byteOffset);
}
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function arrayBufferToBase64(arrayBuffer) {
return dcodeIO.ByteBuffer.wrap(arrayBuffer).toString('base64');
}
function base64ToArrayBuffer(base64string) {
return dcodeIO.ByteBuffer.wrap(base64string, 'base64').toArrayBuffer();
}
function fromEncodedBinaryToArrayBuffer(key) {
return dcodeIO.ByteBuffer.wrap(key, 'binary').toArrayBuffer();
}
function bytesFromString(string) {
return dcodeIO.ByteBuffer.wrap(string, 'utf8').toArrayBuffer();
}
function stringFromBytes(buffer) {
return dcodeIO.ByteBuffer.wrap(buffer).toString('utf8');
}
function hexFromBytes(buffer) {
return dcodeIO.ByteBuffer.wrap(buffer).toString('hex');
}
function bytesFromHexString(string) {
return dcodeIO.ByteBuffer.wrap(string, 'hex').toArrayBuffer();
}
async function deriveStickerPackKey(packKey) {
const salt = getZeroes(32);
const info = bytesFromString('Sticker Pack');
const [part1, part2] = await libsignal.HKDF.deriveSecrets(
packKey,
salt,
info
);
return concatenateBytes(part1, part2);
}
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// High-level Operations
async function encryptDeviceName(deviceName, identityPublic) {
const plaintext = bytesFromString(deviceName);
const ephemeralKeyPair = await libsignal.KeyHelper.generateIdentityKeyPair();
const masterSecret = await libsignal.Curve.async.calculateAgreement(
identityPublic,
ephemeralKeyPair.privKey
);
const key1 = await hmacSha256(masterSecret, bytesFromString('auth'));
const syntheticIv = getFirstBytes(await hmacSha256(key1, plaintext), 16);
const key2 = await hmacSha256(masterSecret, bytesFromString('cipher'));
const cipherKey = await hmacSha256(key2, syntheticIv);
const counter = getZeroes(16);
const ciphertext = await encryptAesCtr(cipherKey, plaintext, counter);
return {
ephemeralPublic: ephemeralKeyPair.pubKey,
syntheticIv,
ciphertext,
};
}
async function decryptDeviceName(
{ ephemeralPublic, syntheticIv, ciphertext } = {},
identityPrivate
) {
const masterSecret = await libsignal.Curve.async.calculateAgreement(
ephemeralPublic,
identityPrivate
);
const key2 = await hmacSha256(masterSecret, bytesFromString('cipher'));
const cipherKey = await hmacSha256(key2, syntheticIv);
const counter = getZeroes(16);
const plaintext = await decryptAesCtr(cipherKey, ciphertext, counter);
const key1 = await hmacSha256(masterSecret, bytesFromString('auth'));
const ourSyntheticIv = getFirstBytes(await hmacSha256(key1, plaintext), 16);
if (!constantTimeEqual(ourSyntheticIv, syntheticIv)) {
throw new Error('decryptDeviceName: synthetic IV did not match');
}
return stringFromBytes(plaintext);
}
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// Path structure: 'fa/facdf99c22945b1c9393345599a276f4b36ad7ccdc8c2467f5441b742c2d11fa'
function getAttachmentLabel(path) {
const filename = path.slice(3);
return base64ToArrayBuffer(filename);
}
const PUB_KEY_LENGTH = 32;
async function encryptAttachment(staticPublicKey, path, plaintext) {
const uniqueId = getAttachmentLabel(path);
return encryptFile(staticPublicKey, uniqueId, plaintext);
}
async function decryptAttachment(staticPrivateKey, path, data) {
const uniqueId = getAttachmentLabel(path);
return decryptFile(staticPrivateKey, uniqueId, data);
}
async function encryptFile(staticPublicKey, uniqueId, plaintext) {
const ephemeralKeyPair = await libsignal.KeyHelper.generateIdentityKeyPair();
const agreement = await libsignal.Curve.async.calculateAgreement(
staticPublicKey,
ephemeralKeyPair.privKey
);
const key = await hmacSha256(agreement, uniqueId);
const prefix = ephemeralKeyPair.pubKey.slice(1);
return concatenateBytes(prefix, await encryptSymmetric(key, plaintext));
}
async function decryptFile(staticPrivateKey, uniqueId, data) {
const ephemeralPublicKey = getFirstBytes(data, PUB_KEY_LENGTH);
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const ciphertext = _getBytes(data, PUB_KEY_LENGTH, data.byteLength);
const agreement = await libsignal.Curve.async.calculateAgreement(
ephemeralPublicKey,
staticPrivateKey
);
const key = await hmacSha256(agreement, uniqueId);
return decryptSymmetric(key, ciphertext);
}
async function deriveAccessKey(profileKey) {
const iv = getZeroes(12);
const plaintext = getZeroes(16);
const accessKey = await _encrypt_aes_gcm(profileKey, iv, plaintext);
return getFirstBytes(accessKey, 16);
}
async function getAccessKeyVerifier(accessKey) {
const plaintext = getZeroes(32);
const hmac = await hmacSha256(accessKey, plaintext);
return hmac;
}
async function verifyAccessKey(accessKey, theirVerifier) {
const ourVerifier = await getAccessKeyVerifier(accessKey);
if (constantTimeEqual(ourVerifier, theirVerifier)) {
return true;
}
return false;
}
const IV_LENGTH = 16;
const MAC_LENGTH = 16;
const NONCE_LENGTH = 16;
async function encryptSymmetric(key, plaintext) {
const iv = getZeroes(IV_LENGTH);
const nonce = getRandomBytes(NONCE_LENGTH);
const cipherKey = await hmacSha256(key, nonce);
const macKey = await hmacSha256(key, cipherKey);
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const cipherText = await _encrypt_aes256_CBC_PKCSPadding(
cipherKey,
iv,
plaintext
);
const mac = getFirstBytes(await hmacSha256(macKey, cipherText), MAC_LENGTH);
return concatenateBytes(nonce, cipherText, mac);
}
async function decryptSymmetric(key, data) {
const iv = getZeroes(IV_LENGTH);
const nonce = getFirstBytes(data, NONCE_LENGTH);
const cipherText = _getBytes(
data,
NONCE_LENGTH,
data.byteLength - NONCE_LENGTH - MAC_LENGTH
);
const theirMac = _getBytes(data, data.byteLength - MAC_LENGTH, MAC_LENGTH);
const cipherKey = await hmacSha256(key, nonce);
const macKey = await hmacSha256(key, cipherKey);
const ourMac = getFirstBytes(
await hmacSha256(macKey, cipherText),
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MAC_LENGTH
);
if (!constantTimeEqual(theirMac, ourMac)) {
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throw new Error(
'decryptSymmetric: Failed to decrypt; MAC verification failed'
);
}
return _decrypt_aes256_CBC_PKCSPadding(cipherKey, iv, cipherText);
}
function constantTimeEqual(left, right) {
if (left.byteLength !== right.byteLength) {
return false;
}
let result = 0;
const ta1 = new Uint8Array(left);
const ta2 = new Uint8Array(right);
for (let i = 0, max = left.byteLength; i < max; i += 1) {
// eslint-disable-next-line no-bitwise
result |= ta1[i] ^ ta2[i];
}
return result === 0;
}
// Encryption
async function hmacSha256(key, plaintext) {
const algorithm = {
name: 'HMAC',
hash: 'SHA-256',
};
const extractable = false;
const cryptoKey = await window.crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['sign']
);
return window.crypto.subtle.sign(algorithm, cryptoKey, plaintext);
}
async function _encrypt_aes256_CBC_PKCSPadding(key, iv, plaintext) {
const algorithm = {
name: 'AES-CBC',
iv,
};
const extractable = false;
const cryptoKey = await window.crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['encrypt']
);
return window.crypto.subtle.encrypt(algorithm, cryptoKey, plaintext);
}
async function _decrypt_aes256_CBC_PKCSPadding(key, iv, plaintext) {
const algorithm = {
name: 'AES-CBC',
iv,
};
const extractable = false;
const cryptoKey = await window.crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['decrypt']
);
return window.crypto.subtle.decrypt(algorithm, cryptoKey, plaintext);
}
async function encryptAesCtr(key, plaintext, counter) {
const extractable = false;
const algorithm = {
name: 'AES-CTR',
counter: new Uint8Array(counter),
length: 128,
};
const cryptoKey = await crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['encrypt']
);
const ciphertext = await crypto.subtle.encrypt(
algorithm,
cryptoKey,
plaintext
);
return ciphertext;
}
async function decryptAesCtr(key, ciphertext, counter) {
const extractable = false;
const algorithm = {
name: 'AES-CTR',
counter: new Uint8Array(counter),
length: 128,
};
const cryptoKey = await crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['decrypt']
);
const plaintext = await crypto.subtle.decrypt(
algorithm,
cryptoKey,
ciphertext
);
return plaintext;
}
async function _encrypt_aes_gcm(key, iv, plaintext) {
const algorithm = {
name: 'AES-GCM',
iv,
};
const extractable = false;
const cryptoKey = await crypto.subtle.importKey(
'raw',
key,
algorithm,
extractable,
['encrypt']
);
return crypto.subtle.encrypt(algorithm, cryptoKey, plaintext);
}
// Utility
function getRandomBytes(n) {
const bytes = new Uint8Array(n);
window.crypto.getRandomValues(bytes);
return bytes;
}
function getRandomValue(low, high) {
const diff = high - low;
const bytes = new Uint32Array(1);
window.crypto.getRandomValues(bytes);
// Because high and low are inclusive
const mod = diff + 1;
return bytes[0] % mod + low;
}
function getZeroes(n) {
const result = new Uint8Array(n);
const value = 0;
const startIndex = 0;
const endExclusive = n;
result.fill(value, startIndex, endExclusive);
return result;
}
function highBitsToInt(byte) {
return (byte & 0xff) >> 4;
}
function intsToByteHighAndLow(highValue, lowValue) {
return ((highValue << 4) | lowValue) & 0xff;
}
function trimBytes(buffer, length) {
return getFirstBytes(buffer, length);
}
function getViewOfArrayBuffer(buffer, start, finish) {
const source = new Uint8Array(buffer);
const result = source.slice(start, finish);
return result.buffer;
}
function concatenateBytes(...elements) {
const length = elements.reduce(
(total, element) => total + element.byteLength,
0
);
const result = new Uint8Array(length);
let position = 0;
for (let i = 0, max = elements.length; i < max; i += 1) {
const element = new Uint8Array(elements[i]);
result.set(element, position);
position += element.byteLength;
}
if (position !== result.length) {
throw new Error('problem concatenating!');
}
return result.buffer;
}
function splitBytes(buffer, ...lengths) {
const total = lengths.reduce((acc, length) => acc + length, 0);
if (total !== buffer.byteLength) {
throw new Error(
`Requested lengths total ${total} does not match source total ${
buffer.byteLength
}`
);
}
const source = new Uint8Array(buffer);
const results = [];
let position = 0;
for (let i = 0, max = lengths.length; i < max; i += 1) {
const length = lengths[i];
const result = new Uint8Array(length);
const section = source.slice(position, position + length);
result.set(section);
position += result.byteLength;
results.push(result);
}
return results;
}
function getFirstBytes(data, n) {
const source = new Uint8Array(data);
return source.subarray(0, n);
}
// Internal-only
function _getBytes(data, start, n) {
const source = new Uint8Array(data);
return source.subarray(start, start + n);
}