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<!doctype html>
< html >
< head >
< meta charset = "utf-8" >
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< title > StatiCrypt: Password protect static HTML< / title >
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< meta name = "description" content = "" >
< meta name = "viewport" content = "width=device-width, initial-scale=1" >
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< link rel = "stylesheet"
type="text/css"
href="https://maxcdn.bootstrapcdn.com/bootstrap/3.3.7/css/bootstrap.min.css"
integrity="sha384-BVYiiSIFeK1dGmJRAkycuHAHRg32OmUcww7on3RYdg4Va+PmSTsz/K68vbdEjh4u"
crossorigin="anonymous">
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< style >
a.no-style {
color: inherit;
text-decoration: inherit;
}
body {
font-size: 16px;
}
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label.no-style {
font-weight: normal;
}
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< / style >
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< / head >
< body >
< div class = "container" >
< div class = "row" >
< div class = "col-xs-12" >
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< h1 >
StatiCrypt
< div class = "pull-right" >
< iframe src = "https://ghbtns.com/github-btn.html?user=robinmoisson&repo=staticrypt&type=star&size=large"
frameborder="0" scrolling="0" width="80px" height="30px">< / iframe >
< iframe src = "https://ghbtns.com/github-btn.html?user=robinmoisson&repo=staticrypt&type=fork&size=large"
frameborder="0" scrolling="0" width="80px" height="30px">< / iframe >
< / div >
< br >
< small > Password protect a static HTML page< / small >
< / h1 >
< p >
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StatiCrypt uses AES-256 with WebCrypto to encrypt your html string with your long password, in your browser (client side).
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< / p >
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< p >
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Download your encrypted string in a HTML page with a password prompt you can upload anywhere (see < a
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target="_blank" href="example/encrypted/example.html">example< / a > ).
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< / p >
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< p >
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The tool is also available as < a href = "https://npmjs.com/package/staticrypt" > a CLI on NPM< / a > and is < a
href="https://github.com/robinmoisson/staticrypt">open source on GitHub< / a > .
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< / p >
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< br >
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< h4 >
< a class = "no-style" id = "toggle-concept" href = "#" >
< span id = "toggle-concept-sign" > ►< / span > HOW IT WORKS
< / a >
< / h4 >
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< div id = "concept" class = "hidden" >
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< p >
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< b class = "text-danger" > Disclaimer< / b > if you are an at-risk activist, or have extra sensitive
banking data, you should probably use something else!
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< / p >
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< p >
StatiCrypt generates a static, password protected page that can be decrypted in-browser:
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just send or upload the generated page to a place serving static content (github pages, for example)
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and you're done: the javascript will prompt users for password, decrypt the page and load your HTML.
< / p >
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< p >
The page is encrypted with AES-256 in CBC mode (see why this mode is appropriate for StatiCrypt in
< a href = "https://github.com/robinmoisson/staticrypt/issues/19" > #19< / a > ). The password is hashed with
PBKDF2 (599k iterations with SHA-256, plus 1k with SHA-1 for legacy reasons (see
< a href = "https://github.com/robinmoisson/staticrypt/issues/159" > #159< / a > ), for the added
< a href = "https://cheatsheetseries.owasp.org/cheatsheets/Password_Storage_Cheat_Sheet.html#pbkdf2" > recommended
total< / a > of 600k) and used to encrypt the page.
< / p >
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< p >
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It basically encrypts your page and puts everything with a user-friendly way to use a password
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in the new file. AES-256 is state of the art but < b > brute-force/dictionary attacks would be easy to
do at a really fast pace: use a long, unusual password!< / b >
< br / > => To be safe, we recommend 16+ alphanum characters, and using a password manager like the
open-source < a href = "http://bitwarden.com" > Bitwarden< / a > .
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< / p >
< p >
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Feel free to contribute or report any thought to the
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< a href = "https://github.com/robinmoisson/staticrypt" > GitHub project< / a > .
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< / p >
< / div >
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< br >
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< / div >
< / div >
< div class = "row" >
< div class = "col-xs-12" >
< form id = "encrypt_form" >
< div class = "form-group" >
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< label for = "passphrase" > Password< / label >
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< input type = "password" class = "form-control" id = "passphrase"
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placeholder="Password (choose a long one!)">
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< / div >
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< div class = "form-group" >
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< label for = "unencrypted_html" > HTML/string to encrypt< / label >
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< textarea class = "form-control"
id="unencrypted_html"
placeholder="< html > < head > ..."
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rows="5">< / textarea >
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< / div >
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< div class = "form-group" >
< label class = "no-style" >
< input type = "checkbox" id = "remember" checked >
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Add "Remember me" checkbox (append < code > #staticrypt_logout< / code > to your URL to logout)
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< small >
< abbr class = "text-muted"
title="The password will be stored in clear text in the browser's localStorage upon entry by the user. See " More options" to set the expiration (default: none)">
(?)
< / abbr >
< / small >
< / label >
< / div >
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< p >
< a href = "#" id = "toggle-extra-option" > + More options< / a >
< / p >
< div id = "extra-options" class = "hidden" >
< div class = "form-group" >
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< label for = "template_title" > Page title< / label >
< input type = "text" class = "form-control" id = "template_title" placeholder = "Default: 'Protected Page'" >
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< / div >
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< div class = "form-group" >
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< label for = "template_instructions" > Instructions to display the user< / label >
< textarea class = "form-control" id = "template_instructions" placeholder = "Default: nothing." > < / textarea >
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< / div >
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< div class = "form-group" >
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< label for = "template_placeholder" > Passphrase input placeholder< / label >
< input type = "text" class = "form-control" id = "template_placeholder"
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placeholder="Default: 'Passphrase'">
< / div >
< div class = "form-group" >
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< label for = "template_remember" > "Remember me" checkbox label< / label >
< input type = "text" class = "form-control" id = "template_remember" placeholder = "Default: 'Remember me'" >
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< / div >
< div class = "form-group" >
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< label for = "remember_in_days" > "Remember me" expiration in days< / label >
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< input type = "number"
class="form-control"
id="remember_in_days"
step="any"
placeholder="Default: 0 (no expiration)">
< small class = "form-text text-muted" >
After this many days, the user will have to enter the passphrase again. Leave empty or set
to 0 for no expiration.
< / small >
< / div >
< div class = "form-group" >
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< label for = "template_button" > Decrypt button label< / label >
< input type = "text" class = "form-control" id = "template_button" placeholder = "Default: 'DECRYPT'" >
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< / div >
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< / div >
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< button class = "btn btn-primary pull-right" type = "submit" > Generate passphrase protected HTML< / button >
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< / form >
< / div >
< / div >
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< div class = "row mb-5" >
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< div class = "col-xs-12" >
< h2 > Encrypted HTML< / h2 >
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< p > < a class = "btn btn-success download"
download="encrypted.html"
id="download-link"
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disabled="disabled">Download html file with password prompt< / a > < / p >
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< pre id = "encrypted_html_display" >
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Your encrypted string< / pre >
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< / div >
< / div >
< / div >
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< script src = "https://cdn.ckeditor.com/4.7.0/standard/ckeditor.js" > < / script >
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< script id = "cryptoEngine" >
window.cryptoEngine = ((function(){
const exports = {};
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const { subtle } = crypto;
const IV_BITS = 16 * 8;
const HEX_BITS = 4;
const ENCRYPTION_ALGO = "AES-CBC";
/**
* Translates between utf8 encoded hexadecimal strings
* and Uint8Array bytes.
*/
const HexEncoder = {
/**
* hex string -> bytes
* @param {string} hexString
* @returns {Uint8Array}
*/
parse: function (hexString) {
if (hexString.length % 2 !== 0) throw "Invalid hexString";
const arrayBuffer = new Uint8Array(hexString.length / 2);
for (let i = 0; i < hexString.length ; i + = 2 ) {
const byteValue = parseInt(hexString.substring(i, i + 2), 16);
if (isNaN(byteValue)) {
throw "Invalid hexString";
}
arrayBuffer[i / 2] = byteValue;
}
return arrayBuffer;
},
/**
* bytes -> hex string
* @param {Uint8Array} bytes
* @returns {string}
*/
stringify: function (bytes) {
const hexBytes = [];
for (let i = 0; i < bytes.length ; + + i ) {
let byteString = bytes[i].toString(16);
if (byteString.length < 2 ) {
byteString = "0" + byteString;
}
hexBytes.push(byteString);
}
return hexBytes.join("");
},
};
/**
* Translates between utf8 strings and Uint8Array bytes.
*/
const UTF8Encoder = {
parse: function (str) {
return new TextEncoder().encode(str);
},
stringify: function (bytes) {
return new TextDecoder().decode(bytes);
},
};
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/**
* Salt and encrypt a msg with a password.
*/
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async function encrypt(msg, hashedPassphrase) {
// Must be 16 bytes, unpredictable, and preferably cryptographically random. However, it need not be secret.
// https://developer.mozilla.org/en-US/docs/Web/API/SubtleCrypto/encrypt#parameters
const iv = crypto.getRandomValues(new Uint8Array(IV_BITS / 8));
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
ENCRYPTION_ALGO,
false,
["encrypt"]
);
const encrypted = await subtle.encrypt(
{
name: ENCRYPTION_ALGO,
iv: iv,
},
key,
UTF8Encoder.parse(msg)
);
// iv will be 32 hex characters, we prepend it to the ciphertext for use in decryption
return HexEncoder.stringify(iv) + HexEncoder.stringify(new Uint8Array(encrypted));
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}
exports.encrypt = encrypt;
/**
* Decrypt a salted msg using a password.
*
* @param {string} encryptedMsg
* @param {string} hashedPassphrase
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* @returns {Promise< string > }
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*/
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async function decrypt(encryptedMsg, hashedPassphrase) {
const ivLength = IV_BITS / HEX_BITS;
const iv = HexEncoder.parse(encryptedMsg.substring(0, ivLength));
const encrypted = encryptedMsg.substring(ivLength);
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
ENCRYPTION_ALGO,
false,
["decrypt"]
);
const outBuffer = await subtle.decrypt(
{
name: ENCRYPTION_ALGO,
iv: iv,
},
key,
HexEncoder.parse(encrypted)
);
return UTF8Encoder.stringify(new Uint8Array(outBuffer));
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}
exports.decrypt = decrypt;
/**
* Salt and hash the passphrase so it can be stored in localStorage without opening a password reuse vulnerability.
*
* @param {string} passphrase
* @param {string} salt
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* @returns {Promise< string > }
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*/
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async function hashPassphrase(passphrase, salt) {
// we hash the passphrase in multiple steps, each adding more iterations. This is because we used to allow less
// iterations, so for backward compatibility reasons, we need to support going from that to more iterations.
let hashedPassphrase = await hashLegacyRound(passphrase, salt);
hashedPassphrase = await hashSecondRound(hashedPassphrase, salt);
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return hashThirdRound(hashedPassphrase, salt);
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}
exports.hashPassphrase = hashPassphrase;
/**
* This hashes the passphrase with 1k iterations. This is a low number, we need this function to support backwards
* compatibility.
*
* @param {string} passphrase
* @param {string} salt
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* @returns {Promise< string > }
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*/
function hashLegacyRound(passphrase, salt) {
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return pbkdf2(passphrase, salt, 1000, "SHA-1");
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}
exports.hashLegacyRound = hashLegacyRound;
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/**
* Add a second round of iterations. This is because we used to use 1k, so for backwards compatibility with
* remember-me/autodecrypt links, we need to support going from that to more iterations.
*
* @param hashedPassphrase
* @param salt
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* @returns {Promise< string > }
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*/
function hashSecondRound(hashedPassphrase, salt) {
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return pbkdf2(hashedPassphrase, salt, 14000, "SHA-256");
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}
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exports.hashSecondRound = hashSecondRound;
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/**
* Add a third round of iterations to bring total number to 600k. This is because we used to use 1k, then 15k, so for
* backwards compatibility with remember-me/autodecrypt links, we need to support going from that to more iterations.
*
* @param hashedPassphrase
* @param salt
* @returns {Promise< string > }
*/
function hashThirdRound(hashedPassphrase, salt) {
return pbkdf2(hashedPassphrase, salt, 585000, "SHA-256");
}
exports.hashThirdRound = hashThirdRound;
/**
* Salt and hash the passphrase so it can be stored in localStorage without opening a password reuse vulnerability.
*
* @param {string} passphrase
* @param {string} salt
* @param {int} iterations
* @param {string} hashAlgorithm
* @returns {Promise< string > }
*/
async function pbkdf2(passphrase, salt, iterations, hashAlgorithm) {
const key = await subtle.importKey(
"raw",
UTF8Encoder.parse(passphrase),
"PBKDF2",
false,
["deriveBits"]
);
const keyBytes = await subtle.deriveBits(
{
name: "PBKDF2",
hash: hashAlgorithm,
iterations,
salt: UTF8Encoder.parse(salt),
},
key,
256
);
return HexEncoder.stringify(new Uint8Array(keyBytes));
}
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function generateRandomSalt() {
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const bytes = crypto.getRandomValues(new Uint8Array(128 / 8));
return HexEncoder.stringify(new Uint8Array(bytes));
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}
exports.generateRandomSalt = generateRandomSalt;
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async function signMessage(hashedPassphrase, message) {
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
{
name: "HMAC",
hash: "SHA-256",
},
false,
["sign"]
);
const signature = await subtle.sign("HMAC", key, UTF8Encoder.parse(message));
return HexEncoder.stringify(new Uint8Array(signature));
}
exports.signMessage = signMessage;
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function getRandomAlphanum() {
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const possibleCharacters = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789";
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let byteArray;
let parsedInt;
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// Keep generating new random bytes until we get a value that falls
// within a range that can be evenly divided by possibleCharacters.length
do {
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byteArray = crypto.getRandomValues(new Uint8Array(1));
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// extract the lowest byte to get an int from 0 to 255 (probably unnecessary, since we're only generating 1 byte)
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parsedInt = byteArray[0] & 0xff;
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} while (parsedInt >= 256 - (256 % possibleCharacters.length));
// Take the modulo of the parsed integer to get a random number between 0 and totalLength - 1
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const randomIndex = parsedInt % possibleCharacters.length;
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return possibleCharacters[randomIndex];
}
/**
* Generate a random string of a given length.
*
* @param {int} length
* @returns {string}
*/
function generateRandomString(length) {
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let randomString = '';
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for (let i = 0; i < length ; i + + ) {
randomString += getRandomAlphanum();
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}
return randomString;
}
exports.generateRandomString = generateRandomString;
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return exports;
})())
< / script >
< script id = "codec" >
window.codec = ((function(){
const exports = {};
/**
* Initialize the codec with the provided cryptoEngine - this return functions to encode and decode messages.
*
* @param cryptoEngine - the engine to use for encryption / decryption
*/
function init(cryptoEngine) {
const exports = {};
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/**
* Top-level function for encoding a message.
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* Includes password hashing, encryption, and signing.
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*
* @param {string} msg
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* @param {string} password
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* @param {string} salt
*
* @returns {string} The encoded text
*/
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async function encode(msg, password, salt) {
const hashedPassphrase = await cryptoEngine.hashPassphrase(password, salt);
const encrypted = await cryptoEngine.encrypt(msg, hashedPassphrase);
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// we use the hashed password in the HMAC because this is effectively what will be used a password (so we can store
// it in localStorage safely, we don't use the clear text password)
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const hmac = await cryptoEngine.signMessage(hashedPassphrase, encrypted);
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return hmac + encrypted;
}
exports.encode = encode;
/**
* Top-level function for decoding a message.
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* Includes signature check and decryption.
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*
* @param {string} signedMsg
* @param {string} hashedPassphrase
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* @param {string} salt
* @param {int} backwardCompatibleAttempt
* @param {string} originalPassphrase
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*
* @returns {Object} {success: true, decoded: string} | {success: false, message: string}
*/
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async function decode(
signedMsg,
hashedPassphrase,
salt,
backwardCompatibleAttempt = 0,
originalPassphrase = ''
) {
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const encryptedHMAC = signedMsg.substring(0, 64);
const encryptedMsg = signedMsg.substring(64);
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const decryptedHMAC = await cryptoEngine.signMessage(hashedPassphrase, encryptedMsg);
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if (decryptedHMAC !== encryptedHMAC) {
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// we have been raising the number of iterations in the hashing algorithm multiple times, so to support the old
// remember-me/autodecrypt links we need to try bringing the old hashes up to speed.
originalPassphrase = originalPassphrase || hashedPassphrase;
if (backwardCompatibleAttempt === 0) {
const updatedHashedPassphrase = await cryptoEngine.hashThirdRound(originalPassphrase, salt);
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return decode(signedMsg, updatedHashedPassphrase, salt, backwardCompatibleAttempt + 1, originalPassphrase);
}
if (backwardCompatibleAttempt === 1) {
let updatedHashedPassphrase = await cryptoEngine.hashSecondRound(originalPassphrase, salt);
updatedHashedPassphrase = await cryptoEngine.hashThirdRound(updatedHashedPassphrase, salt);
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return decode(signedMsg, updatedHashedPassphrase, salt, backwardCompatibleAttempt + 1, originalPassphrase);
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}
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return { success: false, message: "Signature mismatch" };
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}
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return {
success: true,
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decoded: await cryptoEngine.decrypt(encryptedMsg, hashedPassphrase),
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};
}
exports.decode = decode;
return exports;
}
exports.init = init;
return exports;
})())
< / script >
< script id = "formater" >
window.formater = ((function(){
const exports = {};
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/**
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* Replace the placeholder tags (between '/*[|tag|]* /0') in the template string with provided data.
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*
* @param {string} templateString
* @param {Object} data
*
* @returns string
*/
function renderTemplate(templateString, data) {
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return templateString.replace(/\/\*\[\|\s*(\w+)\s*\|]\*\/0/g, function (_, key) {
if (!data || data[key] === undefined) {
return key;
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}
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if (typeof data[key] === 'object') {
return JSON.stringify(data[key]);
}
return data[key];
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});
}
exports.renderTemplate = renderTemplate;
return exports;
})())
< / script >
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< script id = "staticrypt" >
window.staticrypt = ((function(){
const exports = {};
const cryptoEngine = ((function(){
const exports = {};
const { subtle } = crypto;
const IV_BITS = 16 * 8;
const HEX_BITS = 4;
const ENCRYPTION_ALGO = "AES-CBC";
/**
* Translates between utf8 encoded hexadecimal strings
* and Uint8Array bytes.
*/
const HexEncoder = {
/**
* hex string -> bytes
* @param {string} hexString
* @returns {Uint8Array}
*/
parse: function (hexString) {
if (hexString.length % 2 !== 0) throw "Invalid hexString";
const arrayBuffer = new Uint8Array(hexString.length / 2);
for (let i = 0; i < hexString.length ; i + = 2 ) {
const byteValue = parseInt(hexString.substring(i, i + 2), 16);
if (isNaN(byteValue)) {
throw "Invalid hexString";
}
arrayBuffer[i / 2] = byteValue;
}
return arrayBuffer;
},
/**
* bytes -> hex string
* @param {Uint8Array} bytes
* @returns {string}
*/
stringify: function (bytes) {
const hexBytes = [];
for (let i = 0; i < bytes.length ; + + i ) {
let byteString = bytes[i].toString(16);
if (byteString.length < 2 ) {
byteString = "0" + byteString;
}
hexBytes.push(byteString);
}
return hexBytes.join("");
},
};
/**
* Translates between utf8 strings and Uint8Array bytes.
*/
const UTF8Encoder = {
parse: function (str) {
return new TextEncoder().encode(str);
},
stringify: function (bytes) {
return new TextDecoder().decode(bytes);
},
};
/**
* Salt and encrypt a msg with a password.
*/
async function encrypt(msg, hashedPassphrase) {
// Must be 16 bytes, unpredictable, and preferably cryptographically random. However, it need not be secret.
// https://developer.mozilla.org/en-US/docs/Web/API/SubtleCrypto/encrypt#parameters
const iv = crypto.getRandomValues(new Uint8Array(IV_BITS / 8));
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
ENCRYPTION_ALGO,
false,
["encrypt"]
);
const encrypted = await subtle.encrypt(
{
name: ENCRYPTION_ALGO,
iv: iv,
},
key,
UTF8Encoder.parse(msg)
);
// iv will be 32 hex characters, we prepend it to the ciphertext for use in decryption
return HexEncoder.stringify(iv) + HexEncoder.stringify(new Uint8Array(encrypted));
}
exports.encrypt = encrypt;
/**
* Decrypt a salted msg using a password.
*
* @param {string} encryptedMsg
* @param {string} hashedPassphrase
* @returns {Promise< string > }
*/
async function decrypt(encryptedMsg, hashedPassphrase) {
const ivLength = IV_BITS / HEX_BITS;
const iv = HexEncoder.parse(encryptedMsg.substring(0, ivLength));
const encrypted = encryptedMsg.substring(ivLength);
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
ENCRYPTION_ALGO,
false,
["decrypt"]
);
const outBuffer = await subtle.decrypt(
{
name: ENCRYPTION_ALGO,
iv: iv,
},
key,
HexEncoder.parse(encrypted)
);
return UTF8Encoder.stringify(new Uint8Array(outBuffer));
}
exports.decrypt = decrypt;
/**
* Salt and hash the passphrase so it can be stored in localStorage without opening a password reuse vulnerability.
*
* @param {string} passphrase
* @param {string} salt
* @returns {Promise< string > }
*/
async function hashPassphrase(passphrase, salt) {
// we hash the passphrase in multiple steps, each adding more iterations. This is because we used to allow less
// iterations, so for backward compatibility reasons, we need to support going from that to more iterations.
let hashedPassphrase = await hashLegacyRound(passphrase, salt);
hashedPassphrase = await hashSecondRound(hashedPassphrase, salt);
return hashThirdRound(hashedPassphrase, salt);
}
exports.hashPassphrase = hashPassphrase;
/**
* This hashes the passphrase with 1k iterations. This is a low number, we need this function to support backwards
* compatibility.
*
* @param {string} passphrase
* @param {string} salt
* @returns {Promise< string > }
*/
function hashLegacyRound(passphrase, salt) {
return pbkdf2(passphrase, salt, 1000, "SHA-1");
}
exports.hashLegacyRound = hashLegacyRound;
/**
* Add a second round of iterations. This is because we used to use 1k, so for backwards compatibility with
* remember-me/autodecrypt links, we need to support going from that to more iterations.
*
* @param hashedPassphrase
* @param salt
* @returns {Promise< string > }
*/
function hashSecondRound(hashedPassphrase, salt) {
return pbkdf2(hashedPassphrase, salt, 14000, "SHA-256");
}
exports.hashSecondRound = hashSecondRound;
/**
* Add a third round of iterations to bring total number to 600k. This is because we used to use 1k, then 15k, so for
* backwards compatibility with remember-me/autodecrypt links, we need to support going from that to more iterations.
*
* @param hashedPassphrase
* @param salt
* @returns {Promise< string > }
*/
function hashThirdRound(hashedPassphrase, salt) {
return pbkdf2(hashedPassphrase, salt, 585000, "SHA-256");
}
exports.hashThirdRound = hashThirdRound;
/**
* Salt and hash the passphrase so it can be stored in localStorage without opening a password reuse vulnerability.
*
* @param {string} passphrase
* @param {string} salt
* @param {int} iterations
* @param {string} hashAlgorithm
* @returns {Promise< string > }
*/
async function pbkdf2(passphrase, salt, iterations, hashAlgorithm) {
const key = await subtle.importKey(
"raw",
UTF8Encoder.parse(passphrase),
"PBKDF2",
false,
["deriveBits"]
);
const keyBytes = await subtle.deriveBits(
{
name: "PBKDF2",
hash: hashAlgorithm,
iterations,
salt: UTF8Encoder.parse(salt),
},
key,
256
);
return HexEncoder.stringify(new Uint8Array(keyBytes));
}
function generateRandomSalt() {
const bytes = crypto.getRandomValues(new Uint8Array(128 / 8));
return HexEncoder.stringify(new Uint8Array(bytes));
}
exports.generateRandomSalt = generateRandomSalt;
async function signMessage(hashedPassphrase, message) {
const key = await subtle.importKey(
"raw",
HexEncoder.parse(hashedPassphrase),
{
name: "HMAC",
hash: "SHA-256",
},
false,
["sign"]
);
const signature = await subtle.sign("HMAC", key, UTF8Encoder.parse(message));
return HexEncoder.stringify(new Uint8Array(signature));
}
exports.signMessage = signMessage;
function getRandomAlphanum() {
const possibleCharacters = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789";
let byteArray;
let parsedInt;
// Keep generating new random bytes until we get a value that falls
// within a range that can be evenly divided by possibleCharacters.length
do {
byteArray = crypto.getRandomValues(new Uint8Array(1));
// extract the lowest byte to get an int from 0 to 255 (probably unnecessary, since we're only generating 1 byte)
parsedInt = byteArray[0] & 0xff;
} while (parsedInt >= 256 - (256 % possibleCharacters.length));
// Take the modulo of the parsed integer to get a random number between 0 and totalLength - 1
const randomIndex = parsedInt % possibleCharacters.length;
return possibleCharacters[randomIndex];
}
/**
* Generate a random string of a given length.
*
* @param {int} length
* @returns {string}
*/
function generateRandomString(length) {
let randomString = '';
for (let i = 0; i < length ; i + + ) {
randomString += getRandomAlphanum();
}
return randomString;
}
exports.generateRandomString = generateRandomString;
return exports;
})())
const codec = ((function(){
const exports = {};
/**
* Initialize the codec with the provided cryptoEngine - this return functions to encode and decode messages.
*
* @param cryptoEngine - the engine to use for encryption / decryption
*/
function init(cryptoEngine) {
const exports = {};
/**
* Top-level function for encoding a message.
* Includes password hashing, encryption, and signing.
*
* @param {string} msg
* @param {string} password
* @param {string} salt
*
* @returns {string} The encoded text
*/
async function encode(msg, password, salt) {
const hashedPassphrase = await cryptoEngine.hashPassphrase(password, salt);
const encrypted = await cryptoEngine.encrypt(msg, hashedPassphrase);
// we use the hashed password in the HMAC because this is effectively what will be used a password (so we can store
// it in localStorage safely, we don't use the clear text password)
const hmac = await cryptoEngine.signMessage(hashedPassphrase, encrypted);
return hmac + encrypted;
}
exports.encode = encode;
/**
* Top-level function for decoding a message.
* Includes signature check and decryption.
*
* @param {string} signedMsg
* @param {string} hashedPassphrase
* @param {string} salt
* @param {int} backwardCompatibleAttempt
* @param {string} originalPassphrase
*
* @returns {Object} {success: true, decoded: string} | {success: false, message: string}
*/
async function decode(
signedMsg,
hashedPassphrase,
salt,
backwardCompatibleAttempt = 0,
originalPassphrase = ''
) {
const encryptedHMAC = signedMsg.substring(0, 64);
const encryptedMsg = signedMsg.substring(64);
const decryptedHMAC = await cryptoEngine.signMessage(hashedPassphrase, encryptedMsg);
if (decryptedHMAC !== encryptedHMAC) {
// we have been raising the number of iterations in the hashing algorithm multiple times, so to support the old
// remember-me/autodecrypt links we need to try bringing the old hashes up to speed.
originalPassphrase = originalPassphrase || hashedPassphrase;
if (backwardCompatibleAttempt === 0) {
const updatedHashedPassphrase = await cryptoEngine.hashThirdRound(originalPassphrase, salt);
return decode(signedMsg, updatedHashedPassphrase, salt, backwardCompatibleAttempt + 1, originalPassphrase);
}
if (backwardCompatibleAttempt === 1) {
let updatedHashedPassphrase = await cryptoEngine.hashSecondRound(originalPassphrase, salt);
updatedHashedPassphrase = await cryptoEngine.hashThirdRound(updatedHashedPassphrase, salt);
return decode(signedMsg, updatedHashedPassphrase, salt, backwardCompatibleAttempt + 1, originalPassphrase);
}
return { success: false, message: "Signature mismatch" };
}
return {
success: true,
decoded: await cryptoEngine.decrypt(encryptedMsg, hashedPassphrase),
};
}
exports.decode = decode;
return exports;
}
exports.init = init;
return exports;
})())
const decode = codec.init(cryptoEngine).decode;
/**
* Initialize the staticrypt module, that exposes functions callbable by the password_template.
*
* @param {{
* encryptedMsg: string,
* isRememberEnabled: boolean,
* rememberDurationInDays: number,
* salt: string,
* }} staticryptConfig - object of data that is stored on the password_template at encryption time.
*
* @param {{
* rememberExpirationKey: string,
* rememberPassphraseKey: string,
* replaceHtmlCallback: function,
* clearLocalStorageCallback: function,
* }} templateConfig - object of data that can be configured by a custom password_template.
*/
function init(staticryptConfig, templateConfig) {
const exports = {};
/**
* Decrypt our encrypted page, replace the whole HTML.
*
* @param {string} hashedPassphrase
* @returns {Promise< boolean > }
*/
async function decryptAndReplaceHtml(hashedPassphrase) {
const { encryptedMsg, salt } = staticryptConfig;
const { replaceHtmlCallback } = templateConfig;
const result = await decode(encryptedMsg, hashedPassphrase, salt);
if (!result.success) {
return false;
}
const plainHTML = result.decoded;
// if the user configured a callback call it, otherwise just replace the whole HTML
if (typeof replaceHtmlCallback === 'function') {
replaceHtmlCallback(plainHTML);
} else {
document.write(plainHTML);
document.close();
}
return true;
}
/**
* Attempt to decrypt the page and replace the whole HTML.
*
* @param {string} password
* @param {boolean} isRememberChecked
*
* @returns {Promise< {isSuccessful: boolean, hashedPassword?: string}>} - we return an object, so that if we want to
* expose more information in the future we can do it without breaking the password_template
*/
async function handleDecryptionOfPage(password, isRememberChecked) {
const { isRememberEnabled, rememberDurationInDays, salt } = staticryptConfig;
const { rememberExpirationKey, rememberPassphraseKey } = templateConfig;
// decrypt and replace the whole page
const hashedPassword = await cryptoEngine.hashPassphrase(password, salt);
const isDecryptionSuccessful = await decryptAndReplaceHtml(hashedPassword);
if (!isDecryptionSuccessful) {
return {
isSuccessful: false,
hashedPassword,
};
}
// remember the hashedPassword and set its expiration if necessary
if (isRememberEnabled & & isRememberChecked) {
window.localStorage.setItem(rememberPassphraseKey, hashedPassword);
// set the expiration if the duration isn't 0 (meaning no expiration)
if (rememberDurationInDays > 0) {
window.localStorage.setItem(
rememberExpirationKey,
(new Date().getTime() + rememberDurationInDays * 24 * 60 * 60 * 1000).toString()
);
}
}
return {
isSuccessful: true,
hashedPassword,
};
}
exports.handleDecryptionOfPage = handleDecryptionOfPage;
/**
* Clear localstorage from staticrypt related values
*/
function clearLocalStorage() {
const { clearLocalStorageCallback, rememberExpirationKey, rememberPassphraseKey } = templateConfig;
if (typeof clearLocalStorageCallback === 'function') {
clearLocalStorageCallback();
} else {
localStorage.removeItem(rememberPassphraseKey);
localStorage.removeItem(rememberExpirationKey);
}
}
async function handleDecryptOnLoad() {
let isSuccessful = await decryptOnLoadFromUrl();
if (!isSuccessful) {
isSuccessful = await decryptOnLoadFromRememberMe();
}
return { isSuccessful };
}
exports.handleDecryptOnLoad = handleDecryptOnLoad;
/**
* Clear storage if we are logging out
*
* @returns {boolean} - whether we logged out
*/
function logoutIfNeeded() {
const logoutKey = "staticrypt_logout";
// handle logout through query param
const queryParams = new URLSearchParams(window.location.search);
if (queryParams.has(logoutKey)) {
clearLocalStorage();
return true;
}
// handle logout through URL fragment
const hash = window.location.hash.substring(1);
if (hash.includes(logoutKey)) {
clearLocalStorage();
return true;
}
return false;
}
/**
* To be called on load: check if we want to try to decrypt and replace the HTML with the decrypted content, and
* try to do it if needed.
*
* @returns {Promise< boolean > } true if we derypted and replaced the whole page, false otherwise
*/
async function decryptOnLoadFromRememberMe() {
const { rememberDurationInDays } = staticryptConfig;
const { rememberExpirationKey, rememberPassphraseKey } = templateConfig;
// if we are login out, terminate
if (logoutIfNeeded()) {
return false;
}
// if there is expiration configured, check if we're not beyond the expiration
if (rememberDurationInDays & & rememberDurationInDays > 0) {
const expiration = localStorage.getItem(rememberExpirationKey),
isExpired = expiration & & new Date().getTime() > parseInt(expiration);
if (isExpired) {
clearLocalStorage();
return false;
}
}
const hashedPassphrase = localStorage.getItem(rememberPassphraseKey);
if (hashedPassphrase) {
// try to decrypt
const isDecryptionSuccessful = await decryptAndReplaceHtml(hashedPassphrase);
// if the decryption is unsuccessful the password might be wrong - silently clear the saved data and let
// the user fill the password form again
if (!isDecryptionSuccessful) {
clearLocalStorage();
return false;
}
return true;
}
return false;
}
function decryptOnLoadFromUrl() {
const passwordKey = "staticrypt_pwd";
// get the password from the query param
const queryParams = new URLSearchParams(window.location.search);
const hashedPassphraseQuery = queryParams.get(passwordKey);
// get the password from the url fragment
const hashRegexMatch = window.location.hash.substring(1).match(new RegExp(passwordKey + "=(.*)"));
const hashedPassphraseFragment = hashRegexMatch ? hashRegexMatch[1] : null;
const hashedPassphrase = hashedPassphraseFragment || hashedPassphraseQuery;
if (hashedPassphrase) {
return decryptAndReplaceHtml(hashedPassphrase);
}
return false;
}
return exports;
}
exports.init = init;
return exports;
})())
< / script >
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< script >
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const encode = codec.init(cryptoEngine).encode;
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// enable CKEDIRTOR
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CKEDITOR.replace('template_instructions');
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let htmlToDownload;
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/**
* Extract js code from < script > t a g a n d r e t u r n i t a s a s t r i n g
*
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* @param {string} id
* @returns {string}
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*/
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function getScriptAsString(id) {
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return document.getElementById(id)
.innerText.replace(/window\.\w+ = /, '');
}
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/**
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* Register something happened - this uses a simple Supabase function to implement a counter, and allows to drop
* google analytics. We don't store any personal data or IP.
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*
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* @param {string} action
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*/
function trackEvent(action) {
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const xhr = new XMLHttpRequest();
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xhr.open('POST', 'https://zlgpaemmniviswibzuwt.supabase.co/rest/v1/rpc/increment_analytics', true);
xhr.setRequestHeader('Content-type', 'application/json; charset=UTF-8')
xhr.setRequestHeader('apikey', 'eyJhbGciOiJIUzI1NiIsInR5cCI6IkpXVCJ9.eyJpc3MiOiJzdXBhYmFzZSIsInJlZiI6InpsZ3BhZW1tbml2aXN3aWJ6dXd0Iiwicm9sZSI6ImFub24iLCJpYXQiOjE2NjkxMjM0OTcsImV4cCI6MTk4NDY5OTQ5N30.wNoVDHG7F6INx-IPotMs3fL1nudfaF2qvQDgG-1PhNI')
xhr.setRequestHeader('Authorization', 'Bearer eyJhbGciOiJIUzI1NiIsInR5cCI6IkpXVCJ9.eyJpc3MiOiJzdXBhYmFzZSIsInJlZiI6InpsZ3BhZW1tbml2aXN3aWJ6dXd0Iiwicm9sZSI6ImFub24iLCJpYXQiOjE2NjkxMjM0OTcsImV4cCI6MTk4NDY5OTQ5N30.wNoVDHG7F6INx-IPotMs3fL1nudfaF2qvQDgG-1PhNI')
xhr.send(
JSON.stringify({
action_input: action
}
));
}
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/**
* Fill the password prompt template with data provided.
* @param data
*/
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function setFileToDownload (data) {
const request = new XMLHttpRequest();
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request.open('GET', 'lib/password_template.html', true);
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request.onload = function () {
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const renderedTmpl = formater.renderTemplate(request.responseText, data);
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const downloadLink = document.querySelector('a.download');
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downloadLink.href = 'data:text/html,' + encodeURIComponent(renderedTmpl);
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downloadLink.removeAttribute('disabled');
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htmlToDownload = renderedTmpl;
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};
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request.send();
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}
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// register page load
window.onload = function () {
trackEvent('show_index');
};
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/**
* Handle form submission.
*/
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document.getElementById('encrypt_form').addEventListener('submit', async function (e) {
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e.preventDefault();
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trackEvent('generate_encrypted');
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// update instruction textarea value with CKEDITOR content
// (see https://stackoverflow.com/questions/3147670/ckeditor-update-textarea)
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CKEDITOR.instances['template_instructions'].updateElement();
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const unencrypted = document.getElementById('unencrypted_html').value,
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passphrase = document.getElementById('passphrase').value;
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const salt = cryptoEngine.generateRandomSalt();
const encryptedMsg = await encode(unencrypted, passphrase, salt);
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const templateButton = document.getElementById('template_button').value,
templateInstructions = document.getElementById('template_instructions').value,
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isRememberEnabled = document.getElementById('remember').checked,
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templateTitle = document.getElementById('template_title').value.trim(),
templatePlaceholder = document.getElementById('template_placeholder').value.trim(),
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rememberDurationInDays = document.getElementById('remember_in_days').value || 0,
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templateRemember = document.getElementById('template_remember').value;
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const data = {
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staticrypt_config: {
encryptedMsg,
isRememberEnabled,
rememberDurationInDays,
salt,
},
is_remember_enabled: JSON.stringify(isRememberEnabled),
js_staticrypt: getScriptAsString('staticrypt'),
template_button: templateButton ? templateButton : 'DECRYPT',
template_instructions: templateInstructions || '',
template_placeholder: templatePlaceholder || 'Passphrase',
template_remember: templateRemember || 'Remember me',
template_title: templateTitle || 'Protected Page',
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};
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document.getElementById('encrypted_html_display').textContent = encryptedMsg;
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setFileToDownload(data);
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});
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document.getElementById('toggle-extra-option')
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.addEventListener('click', function (e) {
e.preventDefault();
document.getElementById('extra-options').classList.toggle('hidden');
});
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let isConceptShown = false;
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document.getElementById('toggle-concept')
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.addEventListener('click', function (e) {
e.preventDefault();
isConceptShown = !isConceptShown;
document.getElementById('toggle-concept-sign').innerText = isConceptShown ? '▼' : '►';
document.getElementById('concept').classList.toggle('hidden');
});
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/**
* Browser specific download code.
*/
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document.getElementById('download-link')
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.addEventListener('click', function (e) {
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// only register the click event if there is actually a generated file
if (htmlToDownload) {
trackEvent('download_encrypted');
}
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const isIE = (navigator.userAgent.indexOf("MSIE") !== -1) || (!!document.documentMode === true); // >= 10
const isEdge = navigator.userAgent.indexOf("Edge") !== -1;
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// download with MS specific feature
if (htmlToDownload & & (isIE || isEdge)) {
e.preventDefault();
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const blobObject = new Blob([htmlToDownload]);
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window.navigator.msSaveOrOpenBlob(blobObject, 'encrypted.html');
}
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return true;
})
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< / script >
< / body >
< / html >