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701db7da42
localbitcoinplusplus/supernode/index.html
Abhishek Sinha 701db7da42 fixed db functions for primary and backup db
2019-05-14 21:12:01 +05:30

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<!DOCTYPE html>
<html lang="en">
<head>
<meta charset="UTF-8">
<meta name="viewport" content="width=device-width, initial-scale=1.0">
<meta http-equiv="X-UA-Compatible" content="ie=edge">
<title>P2P CRYPTO TRADING SOFTWARE</title>
<link href="https://fonts.googleapis.com/css?family=Montserrat" rel="stylesheet">
<style>
html, body {
height: 100%;
width: 100%;
margin: 0;
color: #ffffff;
font-family: 'Montserrat', sans-serif;
}
input[type=text] {
border: 1px solid #F4F4F4;
border-radius: 3px;
display: block;
width: 100%;
margin-top: 10px;
margin-bottom: 10px;
padding: 15px;
}
h1 { font-size: 5.9vw; }
h2 { font-size: 4.0vh; }
h3 { font-size: 3.0vh; }
h4 { font-size: 5.0vh; }
h5 { font-size: 1.0vh; }
p { font-size: 4vmin; }
p, span, h1, h2, h3, h4, h5 {
white-space: pre-line;
word-wrap: break-word;
overflow-wrap: break-word;
}
ul, li { list-style: none; }
a, u { text-decoration: none; }
a:hover{
text-decoration:none;
cursor:pointer;
}
/* ::-webkit-scrollbar {
height: 4px; /* height of horizontal scrollbar ← You're missing this */
/* width: 4px; /* width of vertical scrollbar */
/* border: 1px solid #d5d5d5;
} */
/*change the thinkness of the scrollbar here*/
::-webkit-scrollbar {
width: 10px;
height: 10px;
-webkit-box-shadow: inset 0 0 6px rgba(0,0,0,0);
-webkit-border-radius: 10px;
border-radius: 10px;
}
/*add a shadow to the scrollbar here*/
::-webkit-scrollbar-track {
-webkit-box-shadow: inset 0 0 0px rgba(0,0,0,0);
-webkit-border-radius: 10px;
border-radius: 10px;
}
/*this is the little scrolly dealio in the bar*/
::-webkit-scrollbar-thumb {
border-radius: 10px;
background: #d5d5d5;
height: 3px;
}
/*nobody needs this little scrollbar corner, I mean really, get rid of it haha*/
::-webkit-scrollbar-corner { display: none; height: 0px; width: 0px; }
.flex {
display: flex;
flex: 1;
flex-wrap: wrap;
}
.box {
min-height: 100%;
min-width: 100%;
display: flex;
flex: 1;
align-items: center;
justify-content: center;
flex-wrap: wrap;
}
.center-div {
display: block;
align-items: center;
justify-content: center;
text-align: center;
}
.custom-select {
width: 100%;
height: auto;
display: flex;
flex-wrap: wrap;
flex: 1;
}
select {
display: flex;
flex: 1;
margin: 20px 20px;
width: auto;
padding: 10px 10px 10px 10px;
font-size: 16px;
height: 47px;
-webkit-appearance: none;
-moz-appearance: none;
appearance: none;
background-color: rgba(0, 0, 0, 0.1); /*#1f8ffc*/
color: #ffffff;
font-family: 'Montserrat';
border-radius: 2px;
border: none;
}
/* CAUTION: IE hackery ahead */
select::-ms-expand {
display: none; /* remove default arrow in IE 10 and 11 */
}
option {
color: #6b8e23;
padding: 8px 16px;
border: 1px solid transparent;
cursor: pointer;
user-select: none;
white-space: pre;
background-color: transparent;
}
/* target Internet Explorer 9 to undo the custom arrow */
@media screen and (min-width:0\0) {
select {
background:none\9;
padding: 5px\9;
}
}
.button {
width: 220px;
border: none;
color: white;
padding: 15px 32px;
justify-content: center;
text-decoration: none;
display: inline-block;
font-size: 16px;
border-radius: 2px;
-webkit-transition-duration: 0.4s; /* Safari */
transition-duration: 0.4s;
text-align: center;
flex-grow: inherit;
}
.button:hover {
background-color: #4CAF50; /* Green */
color: white;
}
.bg-green {background-color: #4CAF50;} /* Green */
.bg-blue {background-color: #008CBA;} /* Blue */
.bg-lightblue {background-color: #7acfd6}
.bg-lightblue2 {background-color: #93b7ec}
.bg-red {background-color: #f44336;} /* Red */
.bg-grey {background-color: #e7e7e7; color: black;} /* Gray */
.bg-black {background-color: #101010;}
.bg-white {background-color: #ffffff;}
.bg-purple {background-color: #9f93ec}
.bg-olive {background-color: olivedrab}
.bg-pink {background-color: #e0474c}
.bg-lightpink {background-color: #ec93d3}
.bg-gold {background-color: #DCAE1D}
.bg-darkred {background-color: #b11a21}
.bg-transparent {background-color: rgba(0, 0, 0, 0.1)}
.bg-yellow {background-color: #e2ec93}
.fs-10 {font-size: 10px;}
.fs-12 {font-size: 12px;}
.fs-16 {font-size: 16px;}
.fs-20 {font-size: 20px;}
.fs-24 {font-size: 24px;}
.pd1 {padding: 10px 24px;}
.pd2 {padding: 12px 28px;}
.pd3 {padding: 14px 40px;}
.pd4 {padding: 32px 16px;}
.pd5 {padding: 16px;}
.mg-top-5 {margin-top: 5rem;}
.mg-5 {margin: 5px 5px}
.center {
text-align:center;
margin: 2rem 3rem;
}
.ptext {
color: #ffffff;
font-weight: 700;
font-size: 5.4vw;;
}
.h1text {
color: #ffffff; /*008CBA*/
font-weight: bolder;
font-size: 3rem;
}
.circles {
display: flex;
flex-wrap: wrap;
justify-content: center;
}
.circle-with-text {
justify-content: center;
align-items: center;
border-radius: 100%;
text-align: center;
margin: 5px 20px;
font-size: 16px;
font-weight: 900;
padding: 15px;
display: flex;
height: 125px;
width: 125px;
color: #9f93ec;
}
.multi-line-text {
font-size: 20px;
}
.center {
text-align: center;
}
#talkbubble {
width: 75%;
height: 75%;
background: #ec9393;
position: relative;
-moz-border-radius: 10px;
-webkit-border-radius: 10px;
border-radius: 10px;
}
#talkbubble:before {
content: "";
position: absolute;
right: 100%;
top: 26px;
width: 0;
height: 0;
border-top: 13px solid transparent;
border-right: 26px solid #ec9393;
border-bottom: 13px solid transparent;
}
.push-left {
float: left;
}
.push-right {
float: right;
}
#talkbubble {
width: 80%;
height: 75%;
position: relative;
-moz-border-radius: 10px;
-webkit-border-radius: 10px;
border-radius: 10px;
}
#talkbubble:before {
content: "";
position: absolute;
right: 100%;
top: 26px;
width: 0;
height: 0;
border-top: 13px solid transparent;
border-right: 26px solid #ec9293;
border-bottom: 13px solid transparent;
}
.action-keys-right, .action-keys-left {
display: flex;
flex: 1;
flex-direction: column;
flex-wrap: wrap;
height: 100%;
margin: 10px 10px;
}
.flo_gen_keys_div, .messages_div {
word-break: break-word;
min-height: 400px;
width: auto;
background-color: rgb(199, 219, 226);
color: #555555;
padding: 20px 20px;
border-radius: 5px;
}
.action-keys-left {
flex-basis: 350px;
}
.action-keys-right {
flex-basis: 500px;
}
.send_crypto_form {
text-align: center;
display: flex;
flex-wrap: wrap;
flex: 1;
margin: 20px 20px;
justify-content: center;
max-width: 500px;
}
@media only screen and (max-width: 600px) {
.center-div { width: 100%; }
.flo_gen_keys_div, .messages_div { margin: 0 0; }
.button { width: 100%; }
}
.hidden {
display: none;
}
/* The Modal (background) */
.modal {
display: none; /* Hidden by default */
position: fixed; /* Stay in place */
z-index: 1; /* Sit on top */
left: 0;
top: 0;
width: 100%; /* Full width */
height: 100%; /* Full height */
overflow: auto; /* Enable scroll if needed */
background-color: rgb(0,0,0); /* Fallback color */
background-color: rgba(0,0,0,0.4); /* Black w/ opacity */
}
/* Modal Content/Box */
.modal-content {
background-color: #fefefe;
margin: 15% auto; /* 15% from the top and centered */
padding: 20px;
border: 1px solid #888;
width: 80%; /* Could be more or less, depending on screen size */
}
#modal_msg {
color: #888;
}
/* The Close Button */
.close {
color: #aaa;
float: right;
font-size: 28px;
font-weight: bold;
}
.close:hover, .close:focus {
color: black;
text-decoration: none;
cursor: pointer;
}
/* Server logs */
pre {
max-height: 20em;
font-family: monospace;
font-size: 1em;
padding: 2px 5px;
color: #0f0;
background-color: #111;
border: 1px solid #030;
overflow: auto;
margin : 0;
white-space: pre-line;
}
.w3-sidebar {
height: 100%;
width: auto;
transition: width 2s ease 0s;
-webkit-transition: width 2s;
position: fixed!important;
z-index: 1;
}
.w3-bar-block .w3-bar-item {
display: block;
padding: 8px 16px;
text-align: left;
border: none;
white-space: normal;
float: none;
outline: 0;
color: #fff;
}
.w3-large {
font-size: 18px!important;
}
.w3-teal, .w3-hover-teal:hover {
color: #fff!important;
}
.w3-xlarge {
font-size: 24px!important;
}
.sidenav {
position: fixed;
z-index: 1;
top: 20px;
left: 10px;
background: #eee;
overflow-x: hidden;
}
.sidebar_div {
z-index: 1;
top: 20px;
left: 10px;
background: #eee;
overflow-x: hidden;
}
</style>
</head>
<body>
<div class="sidenav">
<div class="w3-sidebar w3-bar-block" style="display:none" id="mySidebar">
<div onclick="closeMessage()" class="w3-bar-item w3-button w3-large bg-black">Close</div>
<pre id="log">Event information log
=====================
</pre>
</div>
<div class="w3-button w3-teal w3-xlarge" onclick="displayMessages()">☰</div>
</div>
<div class="box bg-purple">
<div class="center-div">
<em>
<h1 class="h1text">Local Bitcoin Plus Plus P2P EXCHANGE </h1>
</em>
<div class="circles">
<a href="#deposit_withdraw_div">
<div class="circle-with-text bg-white">DEPOSIT WITHDRAW SECTION</div>
</a>
<a href="#buy_sell_div">
<div class="circle-with-text bg-white">TRADE ASSETS SECTION</div>
</a>
<a href="#manage_keys_div">
<div class="circle-with-text bg-white">MANAGE ACTIONS SECTION</div>
</a>
</div>
<h3 class="mg-top-5">FLO ID: <span id="localbitcoinuserdiv"></span></h3>
<strong class="center" id="balances_div"></strong>
</div>
<div class="center-div">
<span> Lorem ipsum dolor sit amet, consectetur adipisicing elit.
Aliquam, ipsum recusandae voluptatibus mollitia quidem.
</span>
</div>
</div>
<div class="box bg-olive" id="deposit_withdraw_div">
<div class="center-div">
<div class="center">
<span class="ptext">DEPOSIT WITHDRAW ASSET</span>
</div>
<div class="custom-select" id="asset_box"></div>
<div class="center" id="asset_button_box"></div>
</div>
</div>
<div class="box bg-pink" id="buy_sell_div">
<div class="center-div" id="tradebox">
<div style="text-align:center; margin-bottom: 3rem">
<span class="ptext">BUY SELL ASSET</span>
</div>
</div>
</div>
<div class="box bg-grey">
<div class="center-div" id="my_trades_div"></div>
<div class="center-div" id="withdraw_deposit_table"></div>
</div>
<div class="box bg-lightblue">
<div class="center-div">
<div style="text-align:center; margin-bottom: 3rem">
<span class="ptext">SEND CRYPTO</span>
</div>
<div class="custom-select" id="send_crypto_select_div"></div>
<div class="send_crypto_form" id="send_crypto_form_ui"></div>
</div>
</div>
<div class="box bg-lightblue2" id="manage_keys_div">
<div class="push-right action-keys-right">
<div class="flex messages_div">
<ul id="new_flo_keys_ul"></ul>
</div>
<div class="flex" id="flo_keys_div">
<input type='button' class="button bg-purple mg-5" id="new_flo_keys" value="Generate FLO Keys">
</div>
</div>
<div class="push-left action-keys-left">
<div class="flex flo_gen_keys_div" id="output_div"></div>
<div id="d3div" class="flex"></div>
</div>
</div>
<div id="myModal" class="modal">
<!-- Modal content -->
<div class="modal-content">
<span class="close">&times;</span>
<div id="modal_msg"></div>
</div>
</div>
<script type="text/javascript">
//crypto-sha256-hmac.js
/*
* Crypto-JS v2.5.4
* http://code.google.com/p/crypto-js/
* (c) 2009-2012 by Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
function ascii_to_hexa(str) {
var arr1 = [];
for (var n = 0, l = str.length; n < l; n++) {
var hex = Number(str.charCodeAt(n)).toString(16);
arr1.push(hex);
}
return arr1.join('');
}
//ripemd160.js
/*
CryptoJS v3.1.2
code.google.com/p/crypto-js
(c) 2009-2013 by Jeff Mott. All rights reserved.
code.google.com/p/crypto-js/wiki/License
*/
/** @preserve
(c) 2012 by C<>dric Mesnil. All rights reserved.
Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met:
- Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer.
- Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
// Constants table
var zl = [
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
7, 4, 13, 1, 10, 6, 15, 3, 12, 0, 9, 5, 2, 14, 11, 8,
3, 10, 14, 4, 9, 15, 8, 1, 2, 7, 0, 6, 13, 11, 5, 12,
1, 9, 11, 10, 0, 8, 12, 4, 13, 3, 7, 15, 14, 5, 6, 2,
4, 0, 5, 9, 7, 12, 2, 10, 14, 1, 3, 8, 11, 6, 15, 13
];
var zr = [
5, 14, 7, 0, 9, 2, 11, 4, 13, 6, 15, 8, 1, 10, 3, 12,
6, 11, 3, 7, 0, 13, 5, 10, 14, 15, 8, 12, 4, 9, 1, 2,
15, 5, 1, 3, 7, 14, 6, 9, 11, 8, 12, 2, 10, 0, 4, 13,
8, 6, 4, 1, 3, 11, 15, 0, 5, 12, 2, 13, 9, 7, 10, 14,
12, 15, 10, 4, 1, 5, 8, 7, 6, 2, 13, 14, 0, 3, 9, 11
];
var sl = [
11, 14, 15, 12, 5, 8, 7, 9, 11, 13, 14, 15, 6, 7, 9, 8,
7, 6, 8, 13, 11, 9, 7, 15, 7, 12, 15, 9, 11, 7, 13, 12,
11, 13, 6, 7, 14, 9, 13, 15, 14, 8, 13, 6, 5, 12, 7, 5,
11, 12, 14, 15, 14, 15, 9, 8, 9, 14, 5, 6, 8, 6, 5, 12,
9, 15, 5, 11, 6, 8, 13, 12, 5, 12, 13, 14, 11, 8, 5, 6
];
var sr = [
8, 9, 9, 11, 13, 15, 15, 5, 7, 7, 8, 11, 14, 14, 12, 6,
9, 13, 15, 7, 12, 8, 9, 11, 7, 7, 12, 7, 6, 15, 13, 11,
9, 7, 15, 11, 8, 6, 6, 14, 12, 13, 5, 14, 13, 13, 7, 5,
15, 5, 8, 11, 14, 14, 6, 14, 6, 9, 12, 9, 12, 5, 15, 8,
8, 5, 12, 9, 12, 5, 14, 6, 8, 13, 6, 5, 15, 13, 11, 11
];
var hl = [0x00000000, 0x5A827999, 0x6ED9EBA1, 0x8F1BBCDC, 0xA953FD4E];
var hr = [0x50A28BE6, 0x5C4DD124, 0x6D703EF3, 0x7A6D76E9, 0x00000000];
var bytesToWords = function (bytes) {
var words = [];
for (var i = 0, b = 0; i < bytes.length; i++, b += 8) {
words[b >>> 5] |= bytes[i] << (24 - b % 32);
}
return words;
};
var wordsToBytes = function (words) {
var bytes = [];
for (var b = 0; b < words.length * 32; b += 8) {
bytes.push((words[b >>> 5] >>> (24 - b % 32)) & 0xFF);
}
return bytes;
};
var processBlock = function (H, M, offset) {
// Swap endian
for (var i = 0; i < 16; i++) {
var offset_i = offset + i;
var M_offset_i = M[offset_i];
// Swap
M[offset_i] = (
(((M_offset_i << 8) | (M_offset_i >>> 24)) & 0x00ff00ff) |
(((M_offset_i << 24) | (M_offset_i >>> 8)) & 0xff00ff00)
);
}
// Working variables
var al, bl, cl, dl, el;
var ar, br, cr, dr, er;
ar = al = H[0];
br = bl = H[1];
cr = cl = H[2];
dr = dl = H[3];
er = el = H[4];
// Computation
var t;
for (var i = 0; i < 80; i += 1) {
t = (al + M[offset + zl[i]]) | 0;
if (i < 16) {
t += f1(bl, cl, dl) + hl[0];
} else if (i < 32) {
t += f2(bl, cl, dl) + hl[1];
} else if (i < 48) {
t += f3(bl, cl, dl) + hl[2];
} else if (i < 64) {
t += f4(bl, cl, dl) + hl[3];
} else { // if (i<80) {
t += f5(bl, cl, dl) + hl[4];
}
t = t | 0;
t = rotl(t, sl[i]);
t = (t + el) | 0;
al = el;
el = dl;
dl = rotl(cl, 10);
cl = bl;
bl = t;
t = (ar + M[offset + zr[i]]) | 0;
if (i < 16) {
t += f5(br, cr, dr) + hr[0];
} else if (i < 32) {
t += f4(br, cr, dr) + hr[1];
} else if (i < 48) {
t += f3(br, cr, dr) + hr[2];
} else if (i < 64) {
t += f2(br, cr, dr) + hr[3];
} else { // if (i<80) {
t += f1(br, cr, dr) + hr[4];
}
t = t | 0;
t = rotl(t, sr[i]);
t = (t + er) | 0;
ar = er;
er = dr;
dr = rotl(cr, 10);
cr = br;
br = t;
}
// Intermediate hash value
t = (H[1] + cl + dr) | 0;
H[1] = (H[2] + dl + er) | 0;
H[2] = (H[3] + el + ar) | 0;
H[3] = (H[4] + al + br) | 0;
H[4] = (H[0] + bl + cr) | 0;
H[0] = t;
};
function f1(x, y, z) {
return ((x) ^ (y) ^ (z));
}
function f2(x, y, z) {
return (((x) & (y)) | ((~x) & (z)));
}
function f3(x, y, z) {
return (((x) | (~(y))) ^ (z));
}
function f4(x, y, z) {
return (((x) & (z)) | ((y) & (~(z))));
}
function f5(x, y, z) {
return ((x) ^ ((y) | (~(z))));
}
function rotl(x, n) {
return (x << n) | (x >>> (32 - n));
}
function ripemd160(message) {
var H = [0x67452301, 0xEFCDAB89, 0x98BADCFE, 0x10325476, 0xC3D2E1F0];
var m = bytesToWords(message);
var nBitsLeft = message.length * 8;
var nBitsTotal = message.length * 8;
// Add padding
m[nBitsLeft >>> 5] |= 0x80 << (24 - nBitsLeft % 32);
m[(((nBitsLeft + 64) >>> 9) << 4) + 14] = (
(((nBitsTotal << 8) | (nBitsTotal >>> 24)) & 0x00ff00ff) |
(((nBitsTotal << 24) | (nBitsTotal >>> 8)) & 0xff00ff00)
);
for (var i = 0; i < m.length; i += 16) {
processBlock(H, m, i);
}
// Swap endian
for (var i = 0; i < 5; i++) {
// Shortcut
var H_i = H[i];
// Swap
H[i] = (((H_i << 8) | (H_i >>> 24)) & 0x00ff00ff) |
(((H_i << 24) | (H_i >>> 8)) & 0xff00ff00);
}
var digestbytes = wordsToBytes(H);
return digestbytes;
}
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.5.4 Crypto.js
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009-2013, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
if (typeof Crypto == "undefined" || !Crypto.util) {
(function () {
var base64map = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
// Global Crypto object
var Crypto = window.Crypto = {};
// Crypto utilities
var util = Crypto.util = {
// Bit-wise rotate left
rotl: function (n, b) {
return (n << b) | (n >>> (32 - b));
},
// Bit-wise rotate right
rotr: function (n, b) {
return (n << (32 - b)) | (n >>> b);
},
// Swap big-endian to little-endian and vice versa
endian: function (n) {
// If number given, swap endian
if (n.constructor == Number) {
return util.rotl(n, 8) & 0x00FF00FF |
util.rotl(n, 24) & 0xFF00FF00;
}
// Else, assume array and swap all items
for (var i = 0; i < n.length; i++)
n[i] = util.endian(n[i]);
return n;
},
// Generate an array of any length of random bytes
randomBytes: function (n) {
for (var bytes = []; n > 0; n--)
bytes.push(Math.floor(Math.random() * 256));
return bytes;
},
// Convert a byte array to big-endian 32-bit words
bytesToWords: function (bytes) {
for (var words = [], i = 0, b = 0; i < bytes.length; i++, b += 8)
words[b >>> 5] |= (bytes[i] & 0xFF) << (24 - b % 32);
return words;
},
// Convert big-endian 32-bit words to a byte array
wordsToBytes: function (words) {
for (var bytes = [], b = 0; b < words.length * 32; b += 8)
bytes.push((words[b >>> 5] >>> (24 - b % 32)) & 0xFF);
return bytes;
},
// Convert a byte array to a hex string
bytesToHex: function (bytes) {
for (var hex = [], i = 0; i < bytes.length; i++) {
hex.push((bytes[i] >>> 4).toString(16));
hex.push((bytes[i] & 0xF).toString(16));
}
return hex.join("");
},
// Convert a hex string to a byte array
hexToBytes: function (hex) {
for (var bytes = [], c = 0; c < hex.length; c += 2)
bytes.push(parseInt(hex.substr(c, 2), 16));
return bytes;
},
// Convert a byte array to a base-64 string
bytesToBase64: function (bytes) {
for (var base64 = [], i = 0; i < bytes.length; i += 3) {
var triplet = (bytes[i] << 16) | (bytes[i + 1] << 8) | bytes[i + 2];
for (var j = 0; j < 4; j++) {
if (i * 8 + j * 6 <= bytes.length * 8)
base64.push(base64map.charAt((triplet >>> 6 * (3 - j)) & 0x3F));
else base64.push("=");
}
}
return base64.join("");
},
// Convert a base-64 string to a byte array
base64ToBytes: function (base64) {
// Remove non-base-64 characters
base64 = base64.replace(/[^A-Z0-9+\/]/ig, "");
for (var bytes = [], i = 0, imod4 = 0; i < base64.length; imod4 = ++i % 4) {
if (imod4 == 0) continue;
bytes.push(((base64map.indexOf(base64.charAt(i - 1)) & (Math.pow(2, -2 * imod4 +
8) -
1)) << (imod4 * 2)) |
(base64map.indexOf(base64.charAt(i)) >>> (6 - imod4 * 2)));
}
return bytes;
}
};
// Crypto character encodings
var charenc = Crypto.charenc = {};
// UTF-8 encoding
var UTF8 = charenc.UTF8 = {
// Convert a string to a byte array
stringToBytes: function (str) {
return Binary.stringToBytes(unescape(encodeURIComponent(str)));
},
// Convert a byte array to a string
bytesToString: function (bytes) {
return decodeURIComponent(escape(Binary.bytesToString(bytes)));
}
};
// Binary encoding
var Binary = charenc.Binary = {
// Convert a string to a byte array
stringToBytes: function (str) {
for (var bytes = [], i = 0; i < str.length; i++)
bytes.push(str.charCodeAt(i) & 0xFF);
return bytes;
},
// Convert a byte array to a string
bytesToString: function (bytes) {
for (var str = [], i = 0; i < bytes.length; i++)
str.push(String.fromCharCode(bytes[i]));
return str.join("");
}
};
})();
}
</script>
<!-- SHA1 -->
<script type="text/javascript">
//Adding SHA1 to fix basic PKBDF2
/*
* Crypto-JS v2.5.4
* http://code.google.com/p/crypto-js/
* (c) 2009-2012 by Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
// Public API
var SHA1 = C.SHA1 = function (message, options) {
var digestbytes = util.wordsToBytes(SHA1._sha1(message));
return options && options.asBytes ? digestbytes :
options && options.asString ? Binary.bytesToString(digestbytes) :
util.bytesToHex(digestbytes);
};
// The core
SHA1._sha1 = function (message) {
// Convert to byte array
if (message.constructor == String) message = UTF8.stringToBytes(message);
/* else, assume byte array already */
var m = util.bytesToWords(message),
l = message.length * 8,
w = [],
H0 = 1732584193,
H1 = -271733879,
H2 = -1732584194,
H3 = 271733878,
H4 = -1009589776;
// Padding
m[l >> 5] |= 0x80 << (24 - l % 32);
m[((l + 64 >>> 9) << 4) + 15] = l;
for (var i = 0; i < m.length; i += 16) {
var a = H0,
b = H1,
c = H2,
d = H3,
e = H4;
for (var j = 0; j < 80; j++) {
if (j < 16) w[j] = m[i + j];
else {
var n = w[j - 3] ^ w[j - 8] ^ w[j - 14] ^ w[j - 16];
w[j] = (n << 1) | (n >>> 31);
}
var t = ((H0 << 5) | (H0 >>> 27)) + H4 + (w[j] >>> 0) + (
j < 20 ? (H1 & H2 | ~H1 & H3) + 1518500249 :
j < 40 ? (H1 ^ H2 ^ H3) + 1859775393 :
j < 60 ? (H1 & H2 | H1 & H3 | H2 & H3) - 1894007588 :
(H1 ^ H2 ^ H3) - 899497514);
H4 = H3;
H3 = H2;
H2 = (H1 << 30) | (H1 >>> 2);
H1 = H0;
H0 = t;
}
H0 += a;
H1 += b;
H2 += c;
H3 += d;
H4 += e;
}
return [H0, H1, H2, H3, H4];
};
// Package private blocksize
SHA1._blocksize = 16;
SHA1._digestsize = 20;
})();
</script>
<!-- HMAC -->
<script type="text/javascript">
//Added to make PKBDF2 work
/*
* Crypto-JS v2.5.4
* http://code.google.com/p/crypto-js/
* (c) 2009-2012 by Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
C.HMAC = function (hasher, message, key, options) {
// Convert to byte arrays
if (message.constructor == String) message = UTF8.stringToBytes(message);
if (key.constructor == String) key = UTF8.stringToBytes(key);
/* else, assume byte arrays already */
// Allow arbitrary length keys
if (key.length > hasher._blocksize * 4)
key = hasher(key, {
asBytes: true
});
// XOR keys with pad constants
var okey = key.slice(0),
ikey = key.slice(0);
for (var i = 0; i < hasher._blocksize * 4; i++) {
okey[i] ^= 0x5C;
ikey[i] ^= 0x36;
}
var hmacbytes = hasher(okey.concat(hasher(ikey.concat(message), {
asBytes: true
})), {
asBytes: true
});
return options && options.asBytes ? hmacbytes :
options && options.asString ? Binary.bytesToString(hmacbytes) :
util.bytesToHex(hmacbytes);
};
})();
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.5.4 SHA256.js
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009-2013, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
// Constants
var K = [0x428A2F98, 0x71374491, 0xB5C0FBCF, 0xE9B5DBA5,
0x3956C25B, 0x59F111F1, 0x923F82A4, 0xAB1C5ED5,
0xD807AA98, 0x12835B01, 0x243185BE, 0x550C7DC3,
0x72BE5D74, 0x80DEB1FE, 0x9BDC06A7, 0xC19BF174,
0xE49B69C1, 0xEFBE4786, 0x0FC19DC6, 0x240CA1CC,
0x2DE92C6F, 0x4A7484AA, 0x5CB0A9DC, 0x76F988DA,
0x983E5152, 0xA831C66D, 0xB00327C8, 0xBF597FC7,
0xC6E00BF3, 0xD5A79147, 0x06CA6351, 0x14292967,
0x27B70A85, 0x2E1B2138, 0x4D2C6DFC, 0x53380D13,
0x650A7354, 0x766A0ABB, 0x81C2C92E, 0x92722C85,
0xA2BFE8A1, 0xA81A664B, 0xC24B8B70, 0xC76C51A3,
0xD192E819, 0xD6990624, 0xF40E3585, 0x106AA070,
0x19A4C116, 0x1E376C08, 0x2748774C, 0x34B0BCB5,
0x391C0CB3, 0x4ED8AA4A, 0x5B9CCA4F, 0x682E6FF3,
0x748F82EE, 0x78A5636F, 0x84C87814, 0x8CC70208,
0x90BEFFFA, 0xA4506CEB, 0xBEF9A3F7, 0xC67178F2
];
// Public API
var SHA256 = C.SHA256 = function (message, options) {
var digestbytes = util.wordsToBytes(SHA256._sha256(message));
return options && options.asBytes ? digestbytes :
options && options.asString ? Binary.bytesToString(digestbytes) :
util.bytesToHex(digestbytes);
};
// The core
SHA256._sha256 = function (message) {
// Convert to byte array
if (message.constructor == String) message = UTF8.stringToBytes(message);
/* else, assume byte array already */
var m = util.bytesToWords(message),
l = message.length * 8,
H = [0x6A09E667, 0xBB67AE85, 0x3C6EF372, 0xA54FF53A,
0x510E527F, 0x9B05688C, 0x1F83D9AB, 0x5BE0CD19
],
w = [],
a, b, c, d, e, f, g, h, i, j,
t1, t2;
// Padding
m[l >> 5] |= 0x80 << (24 - l % 32);
m[((l + 64 >> 9) << 4) + 15] = l;
for (var i = 0; i < m.length; i += 16) {
a = H[0];
b = H[1];
c = H[2];
d = H[3];
e = H[4];
f = H[5];
g = H[6];
h = H[7];
for (var j = 0; j < 64; j++) {
if (j < 16) w[j] = m[j + i];
else {
var gamma0x = w[j - 15],
gamma1x = w[j - 2],
gamma0 = ((gamma0x << 25) | (gamma0x >>> 7)) ^
((gamma0x << 14) | (gamma0x >>> 18)) ^
(gamma0x >>> 3),
gamma1 = ((gamma1x << 15) | (gamma1x >>> 17)) ^
((gamma1x << 13) | (gamma1x >>> 19)) ^
(gamma1x >>> 10);
w[j] = gamma0 + (w[j - 7] >>> 0) +
gamma1 + (w[j - 16] >>> 0);
}
var ch = e & f ^ ~e & g,
maj = a & b ^ a & c ^ b & c,
sigma0 = ((a << 30) | (a >>> 2)) ^
((a << 19) | (a >>> 13)) ^
((a << 10) | (a >>> 22)),
sigma1 = ((e << 26) | (e >>> 6)) ^
((e << 21) | (e >>> 11)) ^
((e << 7) | (e >>> 25));
t1 = (h >>> 0) + sigma1 + ch + (K[j]) + (w[j] >>> 0);
t2 = sigma0 + maj;
h = g;
g = f;
f = e;
e = (d + t1) >>> 0;
d = c;
c = b;
b = a;
a = (t1 + t2) >>> 0;
}
H[0] += a;
H[1] += b;
H[2] += c;
H[3] += d;
H[4] += e;
H[5] += f;
H[6] += g;
H[7] += h;
}
return H;
};
// Package private blocksize
SHA256._blocksize = 16;
SHA256._digestsize = 32;
})();
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.5.4 PBKDF2.js
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009-2013, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
C.PBKDF2 = function (password, salt, keylen, options) {
// Convert to byte arrays
if (password.constructor == String) password = UTF8.stringToBytes(password);
if (salt.constructor == String) salt = UTF8.stringToBytes(salt);
/* else, assume byte arrays already */
// Defaults
var hasher = options && options.hasher || C.SHA1,
iterations = options && options.iterations || 1;
// Pseudo-random function
function PRF(password, salt) {
return C.HMAC(hasher, salt, password, {
asBytes: true
});
}
// Generate key
var derivedKeyBytes = [],
blockindex = 1;
while (derivedKeyBytes.length < keylen) {
var block = PRF(password, salt.concat(util.wordsToBytes([blockindex])));
for (var u = block, i = 1; i < iterations; i++) {
u = PRF(password, u);
for (var j = 0; j < block.length; j++) block[j] ^= u[j];
}
derivedKeyBytes = derivedKeyBytes.concat(block);
blockindex++;
}
// Truncate excess bytes
derivedKeyBytes.length = keylen;
return options && options.asBytes ? derivedKeyBytes :
options && options.asString ? Binary.bytesToString(derivedKeyBytes) :
util.bytesToHex(derivedKeyBytes);
};
})();
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.5.4 HMAC.js
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009-2013, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
C.HMAC = function (hasher, message, key, options) {
// Convert to byte arrays
if (message.constructor == String) message = UTF8.stringToBytes(message);
if (key.constructor == String) key = UTF8.stringToBytes(key);
/* else, assume byte arrays already */
// Allow arbitrary length keys
if (key.length > hasher._blocksize * 4)
key = hasher(key, {
asBytes: true
});
// XOR keys with pad constants
var okey = key.slice(0),
ikey = key.slice(0);
for (var i = 0; i < hasher._blocksize * 4; i++) {
okey[i] ^= 0x5C;
ikey[i] ^= 0x36;
}
var hmacbytes = hasher(okey.concat(hasher(ikey.concat(message), {
asBytes: true
})), {
asBytes: true
});
return options && options.asBytes ? hmacbytes :
options && options.asString ? Binary.bytesToString(hmacbytes) :
util.bytesToHex(hmacbytes);
};
})();
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.5.4 AES.js
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009-2013, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8;
// Precomputed SBOX
var SBOX = [0x63, 0x7c, 0x77, 0x7b, 0xf2, 0x6b, 0x6f, 0xc5,
0x30, 0x01, 0x67, 0x2b, 0xfe, 0xd7, 0xab, 0x76,
0xca, 0x82, 0xc9, 0x7d, 0xfa, 0x59, 0x47, 0xf0,
0xad, 0xd4, 0xa2, 0xaf, 0x9c, 0xa4, 0x72, 0xc0,
0xb7, 0xfd, 0x93, 0x26, 0x36, 0x3f, 0xf7, 0xcc,
0x34, 0xa5, 0xe5, 0xf1, 0x71, 0xd8, 0x31, 0x15,
0x04, 0xc7, 0x23, 0xc3, 0x18, 0x96, 0x05, 0x9a,
0x07, 0x12, 0x80, 0xe2, 0xeb, 0x27, 0xb2, 0x75,
0x09, 0x83, 0x2c, 0x1a, 0x1b, 0x6e, 0x5a, 0xa0,
0x52, 0x3b, 0xd6, 0xb3, 0x29, 0xe3, 0x2f, 0x84,
0x53, 0xd1, 0x00, 0xed, 0x20, 0xfc, 0xb1, 0x5b,
0x6a, 0xcb, 0xbe, 0x39, 0x4a, 0x4c, 0x58, 0xcf,
0xd0, 0xef, 0xaa, 0xfb, 0x43, 0x4d, 0x33, 0x85,
0x45, 0xf9, 0x02, 0x7f, 0x50, 0x3c, 0x9f, 0xa8,
0x51, 0xa3, 0x40, 0x8f, 0x92, 0x9d, 0x38, 0xf5,
0xbc, 0xb6, 0xda, 0x21, 0x10, 0xff, 0xf3, 0xd2,
0xcd, 0x0c, 0x13, 0xec, 0x5f, 0x97, 0x44, 0x17,
0xc4, 0xa7, 0x7e, 0x3d, 0x64, 0x5d, 0x19, 0x73,
0x60, 0x81, 0x4f, 0xdc, 0x22, 0x2a, 0x90, 0x88,
0x46, 0xee, 0xb8, 0x14, 0xde, 0x5e, 0x0b, 0xdb,
0xe0, 0x32, 0x3a, 0x0a, 0x49, 0x06, 0x24, 0x5c,
0xc2, 0xd3, 0xac, 0x62, 0x91, 0x95, 0xe4, 0x79,
0xe7, 0xc8, 0x37, 0x6d, 0x8d, 0xd5, 0x4e, 0xa9,
0x6c, 0x56, 0xf4, 0xea, 0x65, 0x7a, 0xae, 0x08,
0xba, 0x78, 0x25, 0x2e, 0x1c, 0xa6, 0xb4, 0xc6,
0xe8, 0xdd, 0x74, 0x1f, 0x4b, 0xbd, 0x8b, 0x8a,
0x70, 0x3e, 0xb5, 0x66, 0x48, 0x03, 0xf6, 0x0e,
0x61, 0x35, 0x57, 0xb9, 0x86, 0xc1, 0x1d, 0x9e,
0xe1, 0xf8, 0x98, 0x11, 0x69, 0xd9, 0x8e, 0x94,
0x9b, 0x1e, 0x87, 0xe9, 0xce, 0x55, 0x28, 0xdf,
0x8c, 0xa1, 0x89, 0x0d, 0xbf, 0xe6, 0x42, 0x68,
0x41, 0x99, 0x2d, 0x0f, 0xb0, 0x54, 0xbb, 0x16
];
// Compute inverse SBOX lookup table
for (var INVSBOX = [], i = 0; i < 256; i++) INVSBOX[SBOX[i]] = i;
// Compute multiplication in GF(2^8) lookup tables
var MULT2 = [],
MULT3 = [],
MULT9 = [],
MULTB = [],
MULTD = [],
MULTE = [];
function xtime(a, b) {
for (var result = 0, i = 0; i < 8; i++) {
if (b & 1) result ^= a;
var hiBitSet = a & 0x80;
a = (a << 1) & 0xFF;
if (hiBitSet) a ^= 0x1b;
b >>>= 1;
}
return result;
}
for (var i = 0; i < 256; i++) {
MULT2[i] = xtime(i, 2);
MULT3[i] = xtime(i, 3);
MULT9[i] = xtime(i, 9);
MULTB[i] = xtime(i, 0xB);
MULTD[i] = xtime(i, 0xD);
MULTE[i] = xtime(i, 0xE);
}
// Precomputed RCon lookup
var RCON = [0x00, 0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80, 0x1b, 0x36];
// Inner state
var state = [
[],
[],
[],
[]
],
keylength,
nrounds,
keyschedule;
var AES = C.AES = {
/**
* Public API
*/
encrypt: function (message, password, options) {
options = options || {};
// Determine mode
var mode = options.mode || new C.mode.OFB;
// Allow mode to override options
if (mode.fixOptions) mode.fixOptions(options);
var
// Convert to bytes if message is a string
m = (
message.constructor == String ?
UTF8.stringToBytes(message) :
message
),
// Generate random IV
iv = options.iv || util.randomBytes(AES._blocksize * 4),
// Generate key
k = (
password.constructor == String ?
// Derive key from pass-phrase
C.PBKDF2(password, iv, 32, {
asBytes: true
}) :
// else, assume byte array representing cryptographic key
password
);
// Encrypt
AES._init(k);
mode.encrypt(AES, m, iv);
// Return ciphertext
m = options.iv ? m : iv.concat(m);
return (options && options.asBytes) ? m : util.bytesToBase64(m);
},
decrypt: function (ciphertext, password, options) {
options = options || {};
// Determine mode
var mode = options.mode || new C.mode.OFB;
// Allow mode to override options
if (mode.fixOptions) mode.fixOptions(options);
var
// Convert to bytes if ciphertext is a string
c = (
ciphertext.constructor == String ?
util.base64ToBytes(ciphertext) :
ciphertext
),
// Separate IV and message
iv = options.iv || c.splice(0, AES._blocksize * 4),
// Generate key
k = (
password.constructor == String ?
// Derive key from pass-phrase
C.PBKDF2(password, iv, 32, {
asBytes: true
}) :
// else, assume byte array representing cryptographic key
password
);
// Decrypt
AES._init(k);
mode.decrypt(AES, c, iv);
// Return plaintext
return (options && options.asBytes) ? c : UTF8.bytesToString(c);
},
/**
* Package private methods and properties
*/
_blocksize: 4,
_encryptblock: function (m, offset) {
// Set input
for (var row = 0; row < AES._blocksize; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = m[offset + col * 4 + row];
}
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[col][row];
}
for (var round = 1; round < nrounds; round++) {
// Sub bytes
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = SBOX[state[row][col]];
}
// Shift rows
state[1].push(state[1].shift());
state[2].push(state[2].shift());
state[2].push(state[2].shift());
state[3].unshift(state[3].pop());
// Mix columns
for (var col = 0; col < 4; col++) {
var s0 = state[0][col],
s1 = state[1][col],
s2 = state[2][col],
s3 = state[3][col];
state[0][col] = MULT2[s0] ^ MULT3[s1] ^ s2 ^ s3;
state[1][col] = s0 ^ MULT2[s1] ^ MULT3[s2] ^ s3;
state[2][col] = s0 ^ s1 ^ MULT2[s2] ^ MULT3[s3];
state[3][col] = MULT3[s0] ^ s1 ^ s2 ^ MULT2[s3];
}
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[round * 4 + col][row];
}
}
// Sub bytes
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = SBOX[state[row][col]];
}
// Shift rows
state[1].push(state[1].shift());
state[2].push(state[2].shift());
state[2].push(state[2].shift());
state[3].unshift(state[3].pop());
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[nrounds * 4 + col][row];
}
// Set output
for (var row = 0; row < AES._blocksize; row++) {
for (var col = 0; col < 4; col++)
m[offset + col * 4 + row] = state[row][col];
}
},
_decryptblock: function (c, offset) {
// Set input
for (var row = 0; row < AES._blocksize; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = c[offset + col * 4 + row];
}
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[nrounds * 4 + col][row];
}
for (var round = 1; round < nrounds; round++) {
// Inv shift rows
state[1].unshift(state[1].pop());
state[2].push(state[2].shift());
state[2].push(state[2].shift());
state[3].push(state[3].shift());
// Inv sub bytes
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = INVSBOX[state[row][col]];
}
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[(nrounds - round) * 4 + col][row];
}
// Inv mix columns
for (var col = 0; col < 4; col++) {
var s0 = state[0][col],
s1 = state[1][col],
s2 = state[2][col],
s3 = state[3][col];
state[0][col] = MULTE[s0] ^ MULTB[s1] ^ MULTD[s2] ^ MULT9[s3];
state[1][col] = MULT9[s0] ^ MULTE[s1] ^ MULTB[s2] ^ MULTD[s3];
state[2][col] = MULTD[s0] ^ MULT9[s1] ^ MULTE[s2] ^ MULTB[s3];
state[3][col] = MULTB[s0] ^ MULTD[s1] ^ MULT9[s2] ^ MULTE[s3];
}
}
// Inv shift rows
state[1].unshift(state[1].pop());
state[2].push(state[2].shift());
state[2].push(state[2].shift());
state[3].push(state[3].shift());
// Inv sub bytes
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] = INVSBOX[state[row][col]];
}
// Add round key
for (var row = 0; row < 4; row++) {
for (var col = 0; col < 4; col++)
state[row][col] ^= keyschedule[col][row];
}
// Set output
for (var row = 0; row < AES._blocksize; row++) {
for (var col = 0; col < 4; col++)
c[offset + col * 4 + row] = state[row][col];
}
},
/**
* Private methods
*/
_init: function (k) {
keylength = k.length / 4;
nrounds = keylength + 6;
AES._keyexpansion(k);
},
// Generate a key schedule
_keyexpansion: function (k) {
keyschedule = [];
for (var row = 0; row < keylength; row++) {
keyschedule[row] = [
k[row * 4],
k[row * 4 + 1],
k[row * 4 + 2],
k[row * 4 + 3]
];
}
for (var row = keylength; row < AES._blocksize * (nrounds + 1); row++) {
var temp = [
keyschedule[row - 1][0],
keyschedule[row - 1][1],
keyschedule[row - 1][2],
keyschedule[row - 1][3]
];
if (row % keylength == 0) {
// Rot word
temp.push(temp.shift());
// Sub word
temp[0] = SBOX[temp[0]];
temp[1] = SBOX[temp[1]];
temp[2] = SBOX[temp[2]];
temp[3] = SBOX[temp[3]];
temp[0] ^= RCON[row / keylength];
} else if (keylength > 6 && row % keylength == 4) {
// Sub word
temp[0] = SBOX[temp[0]];
temp[1] = SBOX[temp[1]];
temp[2] = SBOX[temp[2]];
temp[3] = SBOX[temp[3]];
}
keyschedule[row] = [
keyschedule[row - keylength][0] ^ temp[0],
keyschedule[row - keylength][1] ^ temp[1],
keyschedule[row - keylength][2] ^ temp[2],
keyschedule[row - keylength][3] ^ temp[3]
];
}
}
};
})();
</script>
<script type="text/javascript">
/*!
* Crypto-JS 2.5.4 BlockModes.js
* contribution from Simon Greatrix
*/
(function (C) {
// Create pad namespace
var C_pad = C.pad = {};
// Calculate the number of padding bytes required.
function _requiredPadding(cipher, message) {
var blockSizeInBytes = cipher._blocksize * 4;
var reqd = blockSizeInBytes - message.length % blockSizeInBytes;
return reqd;
}
// Remove padding when the final byte gives the number of padding bytes.
var _unpadLength = function (cipher, message, alg, padding) {
var pad = message.pop();
if (pad == 0) {
throw new Error("Invalid zero-length padding specified for " + alg +
". Wrong cipher specification or key used?");
}
var maxPad = cipher._blocksize * 4;
if (pad > maxPad) {
throw new Error("Invalid padding length of " + pad +
" specified for " + alg +
". Wrong cipher specification or key used?");
}
for (var i = 1; i < pad; i++) {
var b = message.pop();
if (padding != undefined && padding != b) {
throw new Error("Invalid padding byte of 0x" + b.toString(16) +
" specified for " + alg +
". Wrong cipher specification or key used?");
}
}
};
// No-operation padding, used for stream ciphers
C_pad.NoPadding = {
pad: function (cipher, message) {},
unpad: function (cipher, message) {}
};
// Zero Padding.
//
// If the message is not an exact number of blocks, the final block is
// completed with 0x00 bytes. There is no unpadding.
C_pad.ZeroPadding = {
pad: function (cipher, message) {
var blockSizeInBytes = cipher._blocksize * 4;
var reqd = message.length % blockSizeInBytes;
if (reqd != 0) {
for (reqd = blockSizeInBytes - reqd; reqd > 0; reqd--) {
message.push(0x00);
}
}
},
unpad: function (cipher, message) {
while (message[message.length - 1] == 0) {
message.pop();
}
}
};
// ISO/IEC 7816-4 padding.
//
// Pads the plain text with an 0x80 byte followed by as many 0x00
// bytes are required to complete the block.
C_pad.iso7816 = {
pad: function (cipher, message) {
var reqd = _requiredPadding(cipher, message);
message.push(0x80);
for (; reqd > 1; reqd--) {
message.push(0x00);
}
},
unpad: function (cipher, message) {
var padLength;
for (padLength = cipher._blocksize * 4; padLength > 0; padLength--) {
var b = message.pop();
if (b == 0x80) return;
if (b != 0x00) {
throw new Error("ISO-7816 padding byte must be 0, not 0x" + b.toString(16) +
". Wrong cipher specification or key used?");
}
}
throw new Error(
"ISO-7816 padded beyond cipher block size. Wrong cipher specification or key used?"
);
}
};
// ANSI X.923 padding
//
// The final block is padded with zeros except for the last byte of the
// last block which contains the number of padding bytes.
C_pad.ansix923 = {
pad: function (cipher, message) {
var reqd = _requiredPadding(cipher, message);
for (var i = 1; i < reqd; i++) {
message.push(0x00);
}
message.push(reqd);
},
unpad: function (cipher, message) {
_unpadLength(cipher, message, "ANSI X.923", 0);
}
};
// ISO 10126
//
// The final block is padded with random bytes except for the last
// byte of the last block which contains the number of padding bytes.
C_pad.iso10126 = {
pad: function (cipher, message) {
var reqd = _requiredPadding(cipher, message);
for (var i = 1; i < reqd; i++) {
message.push(Math.floor(Math.random() * 256));
}
message.push(reqd);
},
unpad: function (cipher, message) {
_unpadLength(cipher, message, "ISO 10126", undefined);
}
};
// PKCS7 padding
//
// PKCS7 is described in RFC 5652. Padding is in whole bytes. The
// value of each added byte is the number of bytes that are added,
// i.e. N bytes, each of value N are added.
C_pad.pkcs7 = {
pad: function (cipher, message) {
var reqd = _requiredPadding(cipher, message);
for (var i = 0; i < reqd; i++) {
message.push(reqd);
}
},
unpad: function (cipher, message) {
_unpadLength(cipher, message, "PKCS 7", message[message.length - 1]);
}
};
// Create mode namespace
var C_mode = C.mode = {};
/**
* Mode base "class".
*/
var Mode = C_mode.Mode = function (padding) {
if (padding) {
this._padding = padding;
}
};
Mode.prototype = {
encrypt: function (cipher, m, iv) {
this._padding.pad(cipher, m);
this._doEncrypt(cipher, m, iv);
},
decrypt: function (cipher, m, iv) {
this._doDecrypt(cipher, m, iv);
this._padding.unpad(cipher, m);
},
// Default padding
_padding: C_pad.iso7816
};
/**
* Electronic Code Book mode.
*
* ECB applies the cipher directly against each block of the input.
*
* ECB does not require an initialization vector.
*/
var ECB = C_mode.ECB = function () {
// Call parent constructor
Mode.apply(this, arguments);
};
// Inherit from Mode
var ECB_prototype = ECB.prototype = new Mode;
// Concrete steps for Mode template
ECB_prototype._doEncrypt = function (cipher, m, iv) {
var blockSizeInBytes = cipher._blocksize * 4;
// Encrypt each block
for (var offset = 0; offset < m.length; offset += blockSizeInBytes) {
cipher._encryptblock(m, offset);
}
};
ECB_prototype._doDecrypt = function (cipher, c, iv) {
var blockSizeInBytes = cipher._blocksize * 4;
// Decrypt each block
for (var offset = 0; offset < c.length; offset += blockSizeInBytes) {
cipher._decryptblock(c, offset);
}
};
// ECB never uses an IV
ECB_prototype.fixOptions = function (options) {
options.iv = [];
};
/**
* Cipher block chaining
*
* The first block is XORed with the IV. Subsequent blocks are XOR with the
* previous cipher output.
*/
var CBC = C_mode.CBC = function () {
// Call parent constructor
Mode.apply(this, arguments);
};
// Inherit from Mode
var CBC_prototype = CBC.prototype = new Mode;
// Concrete steps for Mode template
CBC_prototype._doEncrypt = function (cipher, m, iv) {
var blockSizeInBytes = cipher._blocksize * 4;
// Encrypt each block
for (var offset = 0; offset < m.length; offset += blockSizeInBytes) {
if (offset == 0) {
// XOR first block using IV
for (var i = 0; i < blockSizeInBytes; i++)
m[i] ^= iv[i];
} else {
// XOR this block using previous crypted block
for (var i = 0; i < blockSizeInBytes; i++)
m[offset + i] ^= m[offset + i - blockSizeInBytes];
}
// Encrypt block
cipher._encryptblock(m, offset);
}
};
CBC_prototype._doDecrypt = function (cipher, c, iv) {
var blockSizeInBytes = cipher._blocksize * 4;
// At the start, the previously crypted block is the IV
var prevCryptedBlock = iv;
// Decrypt each block
for (var offset = 0; offset < c.length; offset += blockSizeInBytes) {
// Save this crypted block
var thisCryptedBlock = c.slice(offset, offset + blockSizeInBytes);
// Decrypt block
cipher._decryptblock(c, offset);
// XOR decrypted block using previous crypted block
for (var i = 0; i < blockSizeInBytes; i++) {
c[offset + i] ^= prevCryptedBlock[i];
}
prevCryptedBlock = thisCryptedBlock;
}
};
/**
* Cipher feed back
*
* The cipher output is XORed with the plain text to produce the cipher output,
* which is then fed back into the cipher to produce a bit pattern to XOR the
* next block with.
*
* This is a stream cipher mode and does not require padding.
*/
var CFB = C_mode.CFB = function () {
// Call parent constructor
Mode.apply(this, arguments);
};
// Inherit from Mode
var CFB_prototype = CFB.prototype = new Mode;
// Override padding
CFB_prototype._padding = C_pad.NoPadding;
// Concrete steps for Mode template
CFB_prototype._doEncrypt = function (cipher, m, iv) {
var blockSizeInBytes = cipher._blocksize * 4,
keystream = iv.slice(0);
// Encrypt each byte
for (var i = 0; i < m.length; i++) {
var j = i % blockSizeInBytes;
if (j == 0) cipher._encryptblock(keystream, 0);
m[i] ^= keystream[j];
keystream[j] = m[i];
}
};
CFB_prototype._doDecrypt = function (cipher, c, iv) {
var blockSizeInBytes = cipher._blocksize * 4,
keystream = iv.slice(0);
// Encrypt each byte
for (var i = 0; i < c.length; i++) {
var j = i % blockSizeInBytes;
if (j == 0) cipher._encryptblock(keystream, 0);
var b = c[i];
c[i] ^= keystream[j];
keystream[j] = b;
}
};
/**
* Output feed back
*
* The cipher repeatedly encrypts its own output. The output is XORed with the
* plain text to produce the cipher text.
*
* This is a stream cipher mode and does not require padding.
*/
var OFB = C_mode.OFB = function () {
// Call parent constructor
Mode.apply(this, arguments);
};
// Inherit from Mode
var OFB_prototype = OFB.prototype = new Mode;
// Override padding
OFB_prototype._padding = C_pad.NoPadding;
// Concrete steps for Mode template
OFB_prototype._doEncrypt = function (cipher, m, iv) {
var blockSizeInBytes = cipher._blocksize * 4,
keystream = iv.slice(0);
// Encrypt each byte
for (var i = 0; i < m.length; i++) {
// Generate keystream
if (i % blockSizeInBytes == 0)
cipher._encryptblock(keystream, 0);
// Encrypt byte
m[i] ^= keystream[i % blockSizeInBytes];
}
};
OFB_prototype._doDecrypt = OFB_prototype._doEncrypt;
/**
* Counter
* @author Gergely Risko
*
* After every block the last 4 bytes of the IV is increased by one
* with carry and that IV is used for the next block.
*
* This is a stream cipher mode and does not require padding.
*/
var CTR = C_mode.CTR = function () {
// Call parent constructor
Mode.apply(this, arguments);
};
// Inherit from Mode
var CTR_prototype = CTR.prototype = new Mode;
// Override padding
CTR_prototype._padding = C_pad.NoPadding;
CTR_prototype._doEncrypt = function (cipher, m, iv) {
var blockSizeInBytes = cipher._blocksize * 4;
var counter = iv.slice(0);
for (var i = 0; i < m.length;) {
// do not lose iv
var keystream = counter.slice(0);
// Generate keystream for next block
cipher._encryptblock(keystream, 0);
// XOR keystream with block
for (var j = 0; i < m.length && j < blockSizeInBytes; j++, i++) {
m[i] ^= keystream[j];
}
// Increase counter
if (++(counter[blockSizeInBytes - 1]) == 256) {
counter[blockSizeInBytes - 1] = 0;
if (++(counter[blockSizeInBytes - 2]) == 256) {
counter[blockSizeInBytes - 2] = 0;
if (++(counter[blockSizeInBytes - 3]) == 256) {
counter[blockSizeInBytes - 3] = 0;
++(counter[blockSizeInBytes - 4]);
}
}
}
}
};
CTR_prototype._doDecrypt = CTR_prototype._doEncrypt;
})(Crypto);
</script>
<script type="text/javascript">
/*!
* Crypto-JS v2.0.0 RIPEMD-160
* http://code.google.com/p/crypto-js/
* Copyright (c) 2009, Jeff Mott. All rights reserved.
* http://code.google.com/p/crypto-js/wiki/License
*
* A JavaScript implementation of the RIPEMD-160 Algorithm
* Version 2.2 Copyright Jeremy Lin, Paul Johnston 2000 - 2009.
* Other contributors: Greg Holt, Andrew Kepert, Ydnar, Lostinet
* Distributed under the BSD License
* See http://pajhome.org.uk/crypt/md5 for details.
* Also http://www.ocf.berkeley.edu/~jjlin/jsotp/
* Ported to Crypto-JS by Stefan Thomas.
*/
(function () {
// Shortcuts
var C = Crypto,
util = C.util,
charenc = C.charenc,
UTF8 = charenc.UTF8,
Binary = charenc.Binary;
// Convert a byte array to little-endian 32-bit words
util.bytesToLWords = function (bytes) {
var output = Array(bytes.length >> 2);
for (var i = 0; i < output.length; i++)
output[i] = 0;
for (var i = 0; i < bytes.length * 8; i += 8)
output[i >> 5] |= (bytes[i / 8] & 0xFF) << (i % 32);
return output;
};
// Convert little-endian 32-bit words to a byte array
util.lWordsToBytes = function (words) {
var output = [];
for (var i = 0; i < words.length * 32; i += 8)
output.push((words[i >> 5] >>> (i % 32)) & 0xff);
return output;
};
// Public API
var RIPEMD160 = C.RIPEMD160 = function (message, options) {
var digestbytes = util.lWordsToBytes(RIPEMD160._rmd160(message));
return options && options.asBytes ? digestbytes :
options && options.asString ? Binary.bytesToString(digestbytes) :
util.bytesToHex(digestbytes);
};
// The core
RIPEMD160._rmd160 = function (message) {
// Convert to byte array
if (message.constructor == String) message = UTF8.stringToBytes(message);
var x = util.bytesToLWords(message),
len = message.length * 8;
/* append padding */
x[len >> 5] |= 0x80 << (len % 32);
x[(((len + 64) >>> 9) << 4) + 14] = len;
var h0 = 0x67452301;
var h1 = 0xefcdab89;
var h2 = 0x98badcfe;
var h3 = 0x10325476;
var h4 = 0xc3d2e1f0;
for (var i = 0; i < x.length; i += 16) {
var T;
var A1 = h0,
B1 = h1,
C1 = h2,
D1 = h3,
E1 = h4;
var A2 = h0,
B2 = h1,
C2 = h2,
D2 = h3,
E2 = h4;
for (var j = 0; j <= 79; ++j) {
T = safe_add(A1, rmd160_f(j, B1, C1, D1));
T = safe_add(T, x[i + rmd160_r1[j]]);
T = safe_add(T, rmd160_K1(j));
T = safe_add(bit_rol(T, rmd160_s1[j]), E1);
A1 = E1;
E1 = D1;
D1 = bit_rol(C1, 10);
C1 = B1;
B1 = T;
T = safe_add(A2, rmd160_f(79 - j, B2, C2, D2));
T = safe_add(T, x[i + rmd160_r2[j]]);
T = safe_add(T, rmd160_K2(j));
T = safe_add(bit_rol(T, rmd160_s2[j]), E2);
A2 = E2;
E2 = D2;
D2 = bit_rol(C2, 10);
C2 = B2;
B2 = T;
}
T = safe_add(h1, safe_add(C1, D2));
h1 = safe_add(h2, safe_add(D1, E2));
h2 = safe_add(h3, safe_add(E1, A2));
h3 = safe_add(h4, safe_add(A1, B2));
h4 = safe_add(h0, safe_add(B1, C2));
h0 = T;
}
return [h0, h1, h2, h3, h4];
}
function rmd160_f(j, x, y, z) {
return (0 <= j && j <= 15) ? (x ^ y ^ z) :
(16 <= j && j <= 31) ? (x & y) | (~x & z) :
(32 <= j && j <= 47) ? (x | ~y) ^ z :
(48 <= j && j <= 63) ? (x & z) | (y & ~z) :
(64 <= j && j <= 79) ? x ^ (y | ~z) :
"rmd160_f: j out of range";
}
function rmd160_K1(j) {
return (0 <= j && j <= 15) ? 0x00000000 :
(16 <= j && j <= 31) ? 0x5a827999 :
(32 <= j && j <= 47) ? 0x6ed9eba1 :
(48 <= j && j <= 63) ? 0x8f1bbcdc :
(64 <= j && j <= 79) ? 0xa953fd4e :
"rmd160_K1: j out of range";
}
function rmd160_K2(j) {
return (0 <= j && j <= 15) ? 0x50a28be6 :
(16 <= j && j <= 31) ? 0x5c4dd124 :
(32 <= j && j <= 47) ? 0x6d703ef3 :
(48 <= j && j <= 63) ? 0x7a6d76e9 :
(64 <= j && j <= 79) ? 0x00000000 :
"rmd160_K2: j out of range";
}
var rmd160_r1 = [
0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15,
7, 4, 13, 1, 10, 6, 15, 3, 12, 0, 9, 5, 2, 14, 11, 8,
3, 10, 14, 4, 9, 15, 8, 1, 2, 7, 0, 6, 13, 11, 5, 12,
1, 9, 11, 10, 0, 8, 12, 4, 13, 3, 7, 15, 14, 5, 6, 2,
4, 0, 5, 9, 7, 12, 2, 10, 14, 1, 3, 8, 11, 6, 15, 13
];
var rmd160_r2 = [
5, 14, 7, 0, 9, 2, 11, 4, 13, 6, 15, 8, 1, 10, 3, 12,
6, 11, 3, 7, 0, 13, 5, 10, 14, 15, 8, 12, 4, 9, 1, 2,
15, 5, 1, 3, 7, 14, 6, 9, 11, 8, 12, 2, 10, 0, 4, 13,
8, 6, 4, 1, 3, 11, 15, 0, 5, 12, 2, 13, 9, 7, 10, 14,
12, 15, 10, 4, 1, 5, 8, 7, 6, 2, 13, 14, 0, 3, 9, 11
];
var rmd160_s1 = [
11, 14, 15, 12, 5, 8, 7, 9, 11, 13, 14, 15, 6, 7, 9, 8,
7, 6, 8, 13, 11, 9, 7, 15, 7, 12, 15, 9, 11, 7, 13, 12,
11, 13, 6, 7, 14, 9, 13, 15, 14, 8, 13, 6, 5, 12, 7, 5,
11, 12, 14, 15, 14, 15, 9, 8, 9, 14, 5, 6, 8, 6, 5, 12,
9, 15, 5, 11, 6, 8, 13, 12, 5, 12, 13, 14, 11, 8, 5, 6
];
var rmd160_s2 = [
8, 9, 9, 11, 13, 15, 15, 5, 7, 7, 8, 11, 14, 14, 12, 6,
9, 13, 15, 7, 12, 8, 9, 11, 7, 7, 12, 7, 6, 15, 13, 11,
9, 7, 15, 11, 8, 6, 6, 14, 12, 13, 5, 14, 13, 13, 7, 5,
15, 5, 8, 11, 14, 14, 6, 14, 6, 9, 12, 9, 12, 5, 15, 8,
8, 5, 12, 9, 12, 5, 14, 6, 8, 13, 6, 5, 15, 13, 11, 11
];
/*
* Add integers, wrapping at 2^32. This uses 16-bit operations internally
* to work around bugs in some JS interpreters.
*/
function safe_add(x, y) {
var lsw = (x & 0xFFFF) + (y & 0xFFFF);
var msw = (x >> 16) + (y >> 16) + (lsw >> 16);
return (msw << 16) | (lsw & 0xFFFF);
}
/*
* Bitwise rotate a 32-bit number to the left.
*/
function bit_rol(num, cnt) {
return (num << cnt) | (num >>> (32 - cnt));
}
})();
</script>
<script type="text/javascript">
/*!
* Random number generator with ArcFour PRNG
*
* NOTE: For best results, put code like
* <body onclick='SecureRandom.seedTime();' onkeypress='SecureRandom.seedTime();'>
* in your main HTML document.
*
* Copyright Tom Wu, bitaddress.org BSD License.
* http://www-cs-students.stanford.edu/~tjw/jsbn/LICENSE
*/
(function () {
// Constructor function of Global SecureRandom object
var sr = window.SecureRandom = function () {};
// Properties
sr.state;
sr.pool;
sr.pptr;
sr.poolCopyOnInit;
// Pool size must be a multiple of 4 and greater than 32.
// An array of bytes the size of the pool will be passed to init()
sr.poolSize = 256;
// --- object methods ---
// public method
// ba: byte array
sr.prototype.nextBytes = function (ba) {
var i;
if (window.crypto && window.crypto.getRandomValues && window.Uint8Array) {
try {
var rvBytes = new Uint8Array(ba.length);
window.crypto.getRandomValues(rvBytes);
for (i = 0; i < ba.length; ++i)
ba[i] = sr.getByte() ^ rvBytes[i];
return;
} catch (e) {
alert(e);
}
}
for (i = 0; i < ba.length; ++i) ba[i] = sr.getByte();
};
// --- static methods ---
// Mix in the current time (w/milliseconds) into the pool
// NOTE: this method should be called from body click/keypress event handlers to increase entropy
sr.seedTime = function () {
sr.seedInt(new Date().getTime());
}
sr.getByte = function () {
if (sr.state == null) {
sr.seedTime();
sr.state = sr.ArcFour(); // Plug in your RNG constructor here
sr.state.init(sr.pool);
sr.poolCopyOnInit = [];
for (sr.pptr = 0; sr.pptr < sr.pool.length; ++sr.pptr)
sr.poolCopyOnInit[sr.pptr] = sr.pool[sr.pptr];
sr.pptr = 0;
}
// TODO: allow reseeding after first request
return sr.state.next();
}
// Mix in a 32-bit integer into the pool
sr.seedInt = function (x) {
sr.seedInt8(x);
sr.seedInt8((x >> 8));
sr.seedInt8((x >> 16));
sr.seedInt8((x >> 24));
}
// Mix in a 16-bit integer into the pool
sr.seedInt16 = function (x) {
sr.seedInt8(x);
sr.seedInt8((x >> 8));
}
// Mix in a 8-bit integer into the pool
sr.seedInt8 = function (x) {
sr.pool[sr.pptr++] ^= x & 255;
if (sr.pptr >= sr.poolSize) sr.pptr -= sr.poolSize;
}
// Arcfour is a PRNG
sr.ArcFour = function () {
function Arcfour() {
this.i = 0;
this.j = 0;
this.S = new Array();
}
// Initialize arcfour context from key, an array of ints, each from [0..255]
function ARC4init(key) {
var i, j, t;
for (i = 0; i < 256; ++i)
this.S[i] = i;
j = 0;
for (i = 0; i < 256; ++i) {
j = (j + this.S[i] + key[i % key.length]) & 255;
t = this.S[i];
this.S[i] = this.S[j];
this.S[j] = t;
}
this.i = 0;
this.j = 0;
}
function ARC4next() {
var t;
this.i = (this.i + 1) & 255;
this.j = (this.j + this.S[this.i]) & 255;
t = this.S[this.i];
this.S[this.i] = this.S[this.j];
this.S[this.j] = t;
return this.S[(t + this.S[this.i]) & 255];
}
Arcfour.prototype.init = ARC4init;
Arcfour.prototype.next = ARC4next;
return new Arcfour();
};
// Initialize the pool with junk if needed.
if (sr.pool == null) {
sr.pool = new Array();
sr.pptr = 0;
var t;
if (window.crypto && window.crypto.getRandomValues && window.Uint8Array) {
try {
// Use webcrypto if available
var ua = new Uint8Array(sr.poolSize);
window.crypto.getRandomValues(ua);
for (t = 0; t < sr.poolSize; ++t)
sr.pool[sr.pptr++] = ua[t];
} catch (e) {
alert(e);
}
}
while (sr.pptr < sr.poolSize) { // extract some randomness from Math.random()
t = Math.floor(65536 * Math.random());
sr.pool[sr.pptr++] = t >>> 8;
sr.pool[sr.pptr++] = t & 255;
}
sr.pptr = Math.floor(sr.poolSize * Math.random());
sr.seedTime();
// entropy
var entropyStr = "";
// screen size and color depth: ~4.8 to ~5.4 bits
entropyStr += (window.screen.height * window.screen.width * window.screen.colorDepth);
entropyStr += (window.screen.availHeight * window.screen.availWidth * window.screen.pixelDepth);
// time zone offset: ~4 bits
var dateObj = new Date();
var timeZoneOffset = dateObj.getTimezoneOffset();
entropyStr += timeZoneOffset;
// user agent: ~8.3 to ~11.6 bits
entropyStr += navigator.userAgent;
// browser plugin details: ~16.2 to ~21.8 bits
var pluginsStr = "";
for (var i = 0; i < navigator.plugins.length; i++) {
pluginsStr += navigator.plugins[i].name + " " + navigator.plugins[i].filename + " " + navigator
.plugins[
i].description + " " + navigator.plugins[i].version + ", ";
}
var mimeTypesStr = "";
for (var i = 0; i < navigator.mimeTypes.length; i++) {
mimeTypesStr += navigator.mimeTypes[i].description + " " + navigator.mimeTypes[i].type + " " +
navigator.mimeTypes[i].suffixes + ", ";
}
entropyStr += pluginsStr + mimeTypesStr;
// cookies and storage: 1 bit
entropyStr += navigator.cookieEnabled + typeof (sessionStorage) + typeof (localStorage);
// language: ~7 bit
entropyStr += navigator.language;
// history: ~2 bit
entropyStr += window.history.length;
// location
entropyStr += window.location;
var entropyBytes = Crypto.SHA256(entropyStr, {
asBytes: true
});
for (var i = 0; i < entropyBytes.length; i++) {
sr.seedInt8(entropyBytes[i]);
}
}
})();
</script>
<script type="text/javascript">
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/faa10f0f6a1fff0b9a99fffb9bc30cee33b17212/src/ecdsa.js
/*!
* Basic Javascript Elliptic Curve implementation
* Ported loosely from BouncyCastle's Java EC code
* Only Fp curves implemented for now
*
* Copyright Tom Wu, bitaddress.org BSD License.
* http://www-cs-students.stanford.edu/~tjw/jsbn/LICENSE
*/
(function () {
// Constructor function of Global EllipticCurve object
var ec = window.EllipticCurve = function () {};
// ----------------
// ECFieldElementFp constructor
// q instanceof BigInteger
// x instanceof BigInteger
ec.FieldElementFp = function (q, x) {
this.x = x;
// TODO if(x.compareTo(q) >= 0) error
this.q = q;
};
ec.FieldElementFp.prototype.equals = function (other) {
if (other == this) return true;
return (this.q.equals(other.q) && this.x.equals(other.x));
};
ec.FieldElementFp.prototype.toBigInteger = function () {
return this.x;
};
ec.FieldElementFp.prototype.negate = function () {
return new ec.FieldElementFp(this.q, this.x.negate().mod(this.q));
};
ec.FieldElementFp.prototype.add = function (b) {
return new ec.FieldElementFp(this.q, this.x.add(b.toBigInteger()).mod(this.q));
};
ec.FieldElementFp.prototype.subtract = function (b) {
return new ec.FieldElementFp(this.q, this.x.subtract(b.toBigInteger()).mod(this.q));
};
ec.FieldElementFp.prototype.multiply = function (b) {
return new ec.FieldElementFp(this.q, this.x.multiply(b.toBigInteger()).mod(this.q));
};
ec.FieldElementFp.prototype.square = function () {
return new ec.FieldElementFp(this.q, this.x.square().mod(this.q));
};
ec.FieldElementFp.prototype.divide = function (b) {
return new ec.FieldElementFp(this.q, this.x.multiply(b.toBigInteger().modInverse(this.q)).mod(
this.q));
};
ec.FieldElementFp.prototype.getByteLength = function () {
return Math.floor((this.toBigInteger().bitLength() + 7) / 8);
};
// D.1.4 91
/**
* return a sqrt root - the routine verifies that the calculation
* returns the right value - if none exists it returns null.
*
* Copyright (c) 2000 - 2011 The Legion Of The Bouncy Castle (http://www.bouncycastle.org)
* Ported to JavaScript by bitaddress.org
*/
ec.FieldElementFp.prototype.sqrt = function () {
if (!this.q.testBit(0)) throw new Error("even value of q");
// p mod 4 == 3
if (this.q.testBit(1)) {
// z = g^(u+1) + p, p = 4u + 3
var z = new ec.FieldElementFp(this.q, this.x.modPow(this.q.shiftRight(2).add(BigInteger.ONE),
this.q));
return z.square().equals(this) ? z : null;
}
// p mod 4 == 1
var qMinusOne = this.q.subtract(BigInteger.ONE);
var legendreExponent = qMinusOne.shiftRight(1);
if (!(this.x.modPow(legendreExponent, this.q).equals(BigInteger.ONE))) return null;
var u = qMinusOne.shiftRight(2);
var k = u.shiftLeft(1).add(BigInteger.ONE);
var Q = this.x;
var fourQ = Q.shiftLeft(2).mod(this.q);
var U, V;
do {
var rand = new SecureRandom();
var P;
do {
P = new BigInteger(this.q.bitLength(), rand);
}
while (P.compareTo(this.q) >= 0 || !(P.multiply(P).subtract(fourQ).modPow(legendreExponent,
this.q).equals(qMinusOne)));
var result = ec.FieldElementFp.fastLucasSequence(this.q, P, Q, k);
U = result[0];
V = result[1];
if (V.multiply(V).mod(this.q).equals(fourQ)) {
// Integer division by 2, mod q
if (V.testBit(0)) {
V = V.add(this.q);
}
V = V.shiftRight(1);
return new ec.FieldElementFp(this.q, V);
}
}
while (U.equals(BigInteger.ONE) || U.equals(qMinusOne));
return null;
};
/*
* Copyright (c) 2000 - 2011 The Legion Of The Bouncy Castle (http://www.bouncycastle.org)
* Ported to JavaScript by bitaddress.org
*/
ec.FieldElementFp.fastLucasSequence = function (p, P, Q, k) {
// TODO Research and apply "common-multiplicand multiplication here"
var n = k.bitLength();
var s = k.getLowestSetBit();
var Uh = BigInteger.ONE;
var Vl = BigInteger.TWO;
var Vh = P;
var Ql = BigInteger.ONE;
var Qh = BigInteger.ONE;
for (var j = n - 1; j >= s + 1; --j) {
Ql = Ql.multiply(Qh).mod(p);
if (k.testBit(j)) {
Qh = Ql.multiply(Q).mod(p);
Uh = Uh.multiply(Vh).mod(p);
Vl = Vh.multiply(Vl).subtract(P.multiply(Ql)).mod(p);
Vh = Vh.multiply(Vh).subtract(Qh.shiftLeft(1)).mod(p);
} else {
Qh = Ql;
Uh = Uh.multiply(Vl).subtract(Ql).mod(p);
Vh = Vh.multiply(Vl).subtract(P.multiply(Ql)).mod(p);
Vl = Vl.multiply(Vl).subtract(Ql.shiftLeft(1)).mod(p);
}
}
Ql = Ql.multiply(Qh).mod(p);
Qh = Ql.multiply(Q).mod(p);
Uh = Uh.multiply(Vl).subtract(Ql).mod(p);
Vl = Vh.multiply(Vl).subtract(P.multiply(Ql)).mod(p);
Ql = Ql.multiply(Qh).mod(p);
for (var j = 1; j <= s; ++j) {
Uh = Uh.multiply(Vl).mod(p);
Vl = Vl.multiply(Vl).subtract(Ql.shiftLeft(1)).mod(p);
Ql = Ql.multiply(Ql).mod(p);
}
return [Uh, Vl];
};
// ----------------
// ECPointFp constructor
ec.PointFp = function (curve, x, y, z, compressed) {
this.curve = curve;
this.x = x;
this.y = y;
// Projective coordinates: either zinv == null or z * zinv == 1
// z and zinv are just BigIntegers, not fieldElements
if (z == null) {
this.z = BigInteger.ONE;
} else {
this.z = z;
}
this.zinv = null;
// compression flag
this.compressed = !!compressed;
};
ec.PointFp.prototype.getX = function () {
if (this.zinv == null) {
this.zinv = this.z.modInverse(this.curve.q);
}
var r = this.x.toBigInteger().multiply(this.zinv);
this.curve.reduce(r);
return this.curve.fromBigInteger(r);
};
ec.PointFp.prototype.getY = function () {
if (this.zinv == null) {
this.zinv = this.z.modInverse(this.curve.q);
}
var r = this.y.toBigInteger().multiply(this.zinv);
this.curve.reduce(r);
return this.curve.fromBigInteger(r);
};
ec.PointFp.prototype.equals = function (other) {
if (other == this) return true;
if (this.isInfinity()) return other.isInfinity();
if (other.isInfinity()) return this.isInfinity();
var u, v;
// u = Y2 * Z1 - Y1 * Z2
u = other.y.toBigInteger().multiply(this.z).subtract(this.y.toBigInteger().multiply(other.z)).mod(
this.curve.q);
if (!u.equals(BigInteger.ZERO)) return false;
// v = X2 * Z1 - X1 * Z2
v = other.x.toBigInteger().multiply(this.z).subtract(this.x.toBigInteger().multiply(other.z)).mod(
this.curve.q);
return v.equals(BigInteger.ZERO);
};
ec.PointFp.prototype.isInfinity = function () {
if ((this.x == null) && (this.y == null)) return true;
return this.z.equals(BigInteger.ZERO) && !this.y.toBigInteger().equals(BigInteger.ZERO);
};
ec.PointFp.prototype.negate = function () {
return new ec.PointFp(this.curve, this.x, this.y.negate(), this.z);
};
ec.PointFp.prototype.add = function (b) {
if (this.isInfinity()) return b;
if (b.isInfinity()) return this;
// u = Y2 * Z1 - Y1 * Z2
var u = b.y.toBigInteger().multiply(this.z).subtract(this.y.toBigInteger().multiply(b.z)).mod(
this.curve
.q);
// v = X2 * Z1 - X1 * Z2
var v = b.x.toBigInteger().multiply(this.z).subtract(this.x.toBigInteger().multiply(b.z)).mod(
this.curve
.q);
if (BigInteger.ZERO.equals(v)) {
if (BigInteger.ZERO.equals(u)) {
return this.twice(); // this == b, so double
}
return this.curve.getInfinity(); // this = -b, so infinity
}
var THREE = new BigInteger("3");
var x1 = this.x.toBigInteger();
var y1 = this.y.toBigInteger();
var x2 = b.x.toBigInteger();
var y2 = b.y.toBigInteger();
var v2 = v.square();
var v3 = v2.multiply(v);
var x1v2 = x1.multiply(v2);
var zu2 = u.square().multiply(this.z);
// x3 = v * (z2 * (z1 * u^2 - 2 * x1 * v^2) - v^3)
var x3 = zu2.subtract(x1v2.shiftLeft(1)).multiply(b.z).subtract(v3).multiply(v).mod(this.curve.q);
// y3 = z2 * (3 * x1 * u * v^2 - y1 * v^3 - z1 * u^3) + u * v^3
var y3 = x1v2.multiply(THREE).multiply(u).subtract(y1.multiply(v3)).subtract(zu2.multiply(u)).multiply(
b.z).add(u.multiply(v3)).mod(this.curve.q);
// z3 = v^3 * z1 * z2
var z3 = v3.multiply(this.z).multiply(b.z).mod(this.curve.q);
return new ec.PointFp(this.curve, this.curve.fromBigInteger(x3), this.curve.fromBigInteger(y3),
z3);
};
ec.PointFp.prototype.twice = function () {
if (this.isInfinity()) return this;
if (this.y.toBigInteger().signum() == 0) return this.curve.getInfinity();
// TODO: optimized handling of constants
var THREE = new BigInteger("3");
var x1 = this.x.toBigInteger();
var y1 = this.y.toBigInteger();
var y1z1 = y1.multiply(this.z);
var y1sqz1 = y1z1.multiply(y1).mod(this.curve.q);
var a = this.curve.a.toBigInteger();
// w = 3 * x1^2 + a * z1^2
var w = x1.square().multiply(THREE);
if (!BigInteger.ZERO.equals(a)) {
w = w.add(this.z.square().multiply(a));
}
w = w.mod(this.curve.q);
//this.curve.reduce(w);
// x3 = 2 * y1 * z1 * (w^2 - 8 * x1 * y1^2 * z1)
var x3 = w.square().subtract(x1.shiftLeft(3).multiply(y1sqz1)).shiftLeft(1).multiply(y1z1).mod(
this
.curve.q);
// y3 = 4 * y1^2 * z1 * (3 * w * x1 - 2 * y1^2 * z1) - w^3
var y3 = w.multiply(THREE).multiply(x1).subtract(y1sqz1.shiftLeft(1)).shiftLeft(2).multiply(
y1sqz1)
.subtract(w.square().multiply(w)).mod(this.curve.q);
// z3 = 8 * (y1 * z1)^3
var z3 = y1z1.square().multiply(y1z1).shiftLeft(3).mod(this.curve.q);
return new ec.PointFp(this.curve, this.curve.fromBigInteger(x3), this.curve.fromBigInteger(y3),
z3);
};
// Simple NAF (Non-Adjacent Form) multiplication algorithm
// TODO: modularize the multiplication algorithm
ec.PointFp.prototype.multiply = function (k) {
if (this.isInfinity()) return this;
if (k.signum() == 0) return this.curve.getInfinity();
var e = k;
var h = e.multiply(new BigInteger("3"));
var neg = this.negate();
var R = this;
var i;
for (i = h.bitLength() - 2; i > 0; --i) {
R = R.twice();
var hBit = h.testBit(i);
var eBit = e.testBit(i);
if (hBit != eBit) {
R = R.add(hBit ? this : neg);
}
}
return R;
};
// Compute this*j + x*k (simultaneous multiplication)
ec.PointFp.prototype.multiplyTwo = function (j, x, k) {
var i;
if (j.bitLength() > k.bitLength())
i = j.bitLength() - 1;
else
i = k.bitLength() - 1;
var R = this.curve.getInfinity();
var both = this.add(x);
while (i >= 0) {
R = R.twice();
if (j.testBit(i)) {
if (k.testBit(i)) {
R = R.add(both);
} else {
R = R.add(this);
}
} else {
if (k.testBit(i)) {
R = R.add(x);
}
}
--i;
}
return R;
};
// patched by bitaddress.org and Casascius for use with Bitcoin.ECKey
// patched by coretechs to support compressed public keys
ec.PointFp.prototype.getEncoded = function (compressed) {
var x = this.getX().toBigInteger();
var y = this.getY().toBigInteger();
var len = 32; // integerToBytes will zero pad if integer is less than 32 bytes. 32 bytes length is required by the Bitcoin protocol.
var enc = ec.integerToBytes(x, len);
// when compressed prepend byte depending if y point is even or odd
if (compressed) {
if (y.isEven()) {
enc.unshift(0x02);
} else {
enc.unshift(0x03);
}
} else {
enc.unshift(0x04);
enc = enc.concat(ec.integerToBytes(y, len)); // uncompressed public key appends the bytes of the y point
}
return enc;
};
ec.PointFp.decodeFrom = function (curve, enc) {
var type = enc[0];
var dataLen = enc.length - 1;
// Extract x and y as byte arrays
var xBa = enc.slice(1, 1 + dataLen / 2);
var yBa = enc.slice(1 + dataLen / 2, 1 + dataLen);
// Prepend zero byte to prevent interpretation as negative integer
xBa.unshift(0);
yBa.unshift(0);
// Convert to BigIntegers
var x = new BigInteger(xBa);
var y = new BigInteger(yBa);
// Return point
return new ec.PointFp(curve, curve.fromBigInteger(x), curve.fromBigInteger(y));
};
ec.PointFp.prototype.add2D = function (b) {
if (this.isInfinity()) return b;
if (b.isInfinity()) return this;
if (this.x.equals(b.x)) {
if (this.y.equals(b.y)) {
// this = b, i.e. this must be doubled
return this.twice();
}
// this = -b, i.e. the result is the point at infinity
return this.curve.getInfinity();
}
var x_x = b.x.subtract(this.x);
var y_y = b.y.subtract(this.y);
var gamma = y_y.divide(x_x);
var x3 = gamma.square().subtract(this.x).subtract(b.x);
var y3 = gamma.multiply(this.x.subtract(x3)).subtract(this.y);
return new ec.PointFp(this.curve, x3, y3);
};
ec.PointFp.prototype.twice2D = function () {
if (this.isInfinity()) return this;
if (this.y.toBigInteger().signum() == 0) {
// if y1 == 0, then (x1, y1) == (x1, -y1)
// and hence this = -this and thus 2(x1, y1) == infinity
return this.curve.getInfinity();
}
var TWO = this.curve.fromBigInteger(BigInteger.valueOf(2));
var THREE = this.curve.fromBigInteger(BigInteger.valueOf(3));
var gamma = this.x.square().multiply(THREE).add(this.curve.a).divide(this.y.multiply(TWO));
var x3 = gamma.square().subtract(this.x.multiply(TWO));
var y3 = gamma.multiply(this.x.subtract(x3)).subtract(this.y);
return new ec.PointFp(this.curve, x3, y3);
};
ec.PointFp.prototype.multiply2D = function (k) {
if (this.isInfinity()) return this;
if (k.signum() == 0) return this.curve.getInfinity();
var e = k;
var h = e.multiply(new BigInteger("3"));
var neg = this.negate();
var R = this;
var i;
for (i = h.bitLength() - 2; i > 0; --i) {
R = R.twice();
var hBit = h.testBit(i);
var eBit = e.testBit(i);
if (hBit != eBit) {
R = R.add2D(hBit ? this : neg);
}
}
return R;
};
ec.PointFp.prototype.isOnCurve = function () {
var x = this.getX().toBigInteger();
var y = this.getY().toBigInteger();
var a = this.curve.getA().toBigInteger();
var b = this.curve.getB().toBigInteger();
var n = this.curve.getQ();
var lhs = y.multiply(y).mod(n);
var rhs = x.multiply(x).multiply(x).add(a.multiply(x)).add(b).mod(n);
return lhs.equals(rhs);
};
ec.PointFp.prototype.toString = function () {
return '(' + this.getX().toBigInteger().toString() + ',' + this.getY().toBigInteger().toString() +
')';
};
/**
* Validate an elliptic curve point.
*
* See SEC 1, section 3.2.2.1: Elliptic Curve Public Key Validation Primitive
*/
ec.PointFp.prototype.validate = function () {
var n = this.curve.getQ();
// Check Q != O
if (this.isInfinity()) {
throw new Error("Point is at infinity.");
}
// Check coordinate bounds
var x = this.getX().toBigInteger();
var y = this.getY().toBigInteger();
if (x.compareTo(BigInteger.ONE) < 0 || x.compareTo(n.subtract(BigInteger.ONE)) > 0) {
throw new Error('x coordinate out of bounds');
}
if (y.compareTo(BigInteger.ONE) < 0 || y.compareTo(n.subtract(BigInteger.ONE)) > 0) {
throw new Error('y coordinate out of bounds');
}
// Check y^2 = x^3 + ax + b (mod n)
if (!this.isOnCurve()) {
throw new Error("Point is not on the curve.");
}
// Check nQ = 0 (Q is a scalar multiple of G)
if (this.multiply(n).isInfinity()) {
// TODO: This check doesn't work - fix.
throw new Error("Point is not a scalar multiple of G.");
}
return true;
};
// ----------------
// ECCurveFp constructor
ec.CurveFp = function (q, a, b) {
this.q = q;
this.a = this.fromBigInteger(a);
this.b = this.fromBigInteger(b);
this.infinity = new ec.PointFp(this, null, null);
this.reducer = new Barrett(this.q);
}
ec.CurveFp.prototype.getQ = function () {
return this.q;
};
ec.CurveFp.prototype.getA = function () {
return this.a;
};
ec.CurveFp.prototype.getB = function () {
return this.b;
};
ec.CurveFp.prototype.equals = function (other) {
if (other == this) return true;
return (this.q.equals(other.q) && this.a.equals(other.a) && this.b.equals(other.b));
};
ec.CurveFp.prototype.getInfinity = function () {
return this.infinity;
};
ec.CurveFp.prototype.fromBigInteger = function (x) {
return new ec.FieldElementFp(this.q, x);
};
ec.CurveFp.prototype.reduce = function (x) {
this.reducer.reduce(x);
};
// for now, work with hex strings because they're easier in JS
// compressed support added by bitaddress.org
ec.CurveFp.prototype.decodePointHex = function (s) {
var firstByte = parseInt(s.substr(0, 2), 16);
switch (firstByte) { // first byte
case 0:
return this.infinity;
case 2: // compressed
case 3: // compressed
var yTilde = firstByte & 1;
var xHex = s.substr(2, s.length - 2);
var X1 = new BigInteger(xHex, 16);
return this.decompressPoint(yTilde, X1);
case 4: // uncompressed
case 6: // hybrid
case 7: // hybrid
var len = (s.length - 2) / 2;
var xHex = s.substr(2, len);
var yHex = s.substr(len + 2, len);
return new ec.PointFp(this,
this.fromBigInteger(new BigInteger(xHex, 16)),
this.fromBigInteger(new BigInteger(yHex, 16)));
default: // unsupported
return null;
}
};
ec.CurveFp.prototype.encodePointHex = function (p) {
if (p.isInfinity()) return "00";
var xHex = p.getX().toBigInteger().toString(16);
var yHex = p.getY().toBigInteger().toString(16);
var oLen = this.getQ().toString(16).length;
if ((oLen % 2) != 0) oLen++;
while (xHex.length < oLen) {
xHex = "0" + xHex;
}
while (yHex.length < oLen) {
yHex = "0" + yHex;
}
return "04" + xHex + yHex;
};
/*
* Copyright (c) 2000 - 2011 The Legion Of The Bouncy Castle (http://www.bouncycastle.org)
* Ported to JavaScript by bitaddress.org
*
* Number yTilde
* BigInteger X1
*/
ec.CurveFp.prototype.decompressPoint = function (yTilde, X1) {
var x = this.fromBigInteger(X1);
var alpha = x.multiply(x.square().add(this.getA())).add(this.getB());
var beta = alpha.sqrt();
// if we can't find a sqrt we haven't got a point on the curve - run!
if (beta == null) throw new Error("Invalid point compression");
var betaValue = beta.toBigInteger();
var bit0 = betaValue.testBit(0) ? 1 : 0;
if (bit0 != yTilde) {
// Use the other root
beta = this.fromBigInteger(this.getQ().subtract(betaValue));
}
return new ec.PointFp(this, x, beta, null, true);
};
ec.fromHex = function (s) {
return new BigInteger(s, 16);
};
ec.integerToBytes = function (i, len) {
var bytes = i.toByteArrayUnsigned();
if (len < bytes.length) {
bytes = bytes.slice(bytes.length - len);
} else
while (len > bytes.length) {
bytes.unshift(0);
}
return bytes;
};
// Named EC curves
// ----------------
// X9ECParameters constructor
ec.X9Parameters = function (curve, g, n, h) {
this.curve = curve;
this.g = g;
this.n = n;
this.h = h;
}
ec.X9Parameters.prototype.getCurve = function () {
return this.curve;
};
ec.X9Parameters.prototype.getG = function () {
return this.g;
};
ec.X9Parameters.prototype.getN = function () {
return this.n;
};
ec.X9Parameters.prototype.getH = function () {
return this.h;
};
// secp256k1 is the Curve used by Bitcoin
ec.secNamedCurves = {
// used by Bitcoin
"secp256k1": function () {
// p = 2^256 - 2^32 - 2^9 - 2^8 - 2^7 - 2^6 - 2^4 - 1
var p = ec.fromHex("FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F");
var a = BigInteger.ZERO;
var b = ec.fromHex("7");
var n = ec.fromHex("FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141");
var h = BigInteger.ONE;
var curve = new ec.CurveFp(p, a, b);
var G = curve.decodePointHex("04" +
"79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798" +
"483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8");
return new ec.X9Parameters(curve, G, n, h);
}
};
// secp256k1 called by Bitcoin's ECKEY
ec.getSECCurveByName = function (name) {
if (ec.secNamedCurves[name] == undefined) return null;
return ec.secNamedCurves[name]();
}
})();
</script>
<script type="text/javascript">
// secrets.js - by Alexander Stetsyuk - released under MIT License -- Implementation of Shamir Secret Sharing Scheme
(function (exports, global) {
var defaults = {
bits: 8, // default number of bits
radix: 16, // work with HEX by default
minBits: 3,
maxBits: 20, // this permits 1,048,575 shares, though going this high is NOT recommended in JS!
bytesPerChar: 2,
maxBytesPerChar: 6, // Math.pow(256,7) > Math.pow(2,53)
// Primitive polynomials (in decimal form) for Galois Fields GF(2^n), for 2 <= n <= 30
// The index of each term in the array corresponds to the n for that polynomial
// i.e. to get the polynomial for n=16, use primitivePolynomials[16]
primitivePolynomials: [null, null, 1, 3, 3, 5, 3, 3, 29, 17, 9, 5, 83, 27, 43, 3, 45, 9, 39, 39,
9,
5, 3, 33, 27, 9, 71, 39, 9, 5, 83
],
// warning for insecure PRNG
warning: 'WARNING:\nA secure random number generator was not found.\nUsing Math.random(), which is NOT cryptographically strong!'
};
// Protected settings object
var config = {};
/** @expose **/
exports.getConfig = function () {
return {
'bits': config.bits,
'unsafePRNG': config.unsafePRNG
};
};
function init(bits) {
if (bits && (typeof bits !== 'number' || bits % 1 !== 0 || bits < defaults.minBits || bits >
defaults.maxBits)) {
throw new Error('Number of bits must be an integer between ' + defaults.minBits + ' and ' +
defaults.maxBits + ', inclusive.')
}
config.radix = defaults.radix;
config.bits = bits || defaults.bits;
config.size = Math.pow(2, config.bits);
config.max = config.size - 1;
// Construct the exp and log tables for multiplication.
var logs = [],
exps = [],
x = 1,
primitive = defaults.primitivePolynomials[config.bits];
for (var i = 0; i < config.size; i++) {
exps[i] = x;
logs[x] = i;
x <<= 1;
if (x >= config.size) {
x ^= primitive;
x &= config.max;
}
}
config.logs = logs;
config.exps = exps;
};
/** @expose **/
exports.init = init;
function isInited() {
if (!config.bits || !config.size || !config.max || !config.logs || !config.exps || config.logs.length !==
config.size || config.exps.length !== config.size) {
return false;
}
return true;
};
// Returns a pseudo-random number generator of the form function(bits){}
// which should output a random string of 1's and 0's of length `bits`
function getRNG() {
var randomBits, crypto;
function construct(bits, arr, radix, size) {
var str = '',
i = 0,
len = arr.length - 1;
while (i < len || (str.length < bits)) {
str += padLeft(parseInt(arr[i], radix).toString(2), size);
i++;
}
str = str.substr(-bits);
if ((str.match(/0/g) || []).length === str.length) { // all zeros?
return null;
} else {
return str;
}
}
// node.js crypto.randomBytes()
if (typeof require === 'function' && (crypto = require('crypto')) && (randomBits = crypto[
'randomBytes'])) {
return function (bits) {
var bytes = Math.ceil(bits / 8),
str = null;
while (str === null) {
str = construct(bits, randomBits(bytes).toString('hex'), 16, 4);
}
return str;
}
}
// browsers with window.crypto.getRandomValues()
if (global['crypto'] && typeof global['crypto']['getRandomValues'] === 'function' && typeof global[
'Uint32Array'] === 'function') {
crypto = global['crypto'];
return function (bits) {
var elems = Math.ceil(bits / 32),
str = null,
arr = new global['Uint32Array'](elems);
while (str === null) {
crypto['getRandomValues'](arr);
str = construct(bits, arr, 10, 32);
}
return str;
}
}
// A totally insecure RNG!!! (except in Safari)
// Will produce a warning every time it is called.
config.unsafePRNG = true;
warn();
var bitsPerNum = 32;
var max = Math.pow(2, bitsPerNum) - 1;
return function (bits) {
var elems = Math.ceil(bits / bitsPerNum);
var arr = [],
str = null;
while (str === null) {
for (var i = 0; i < elems; i++) {
arr[i] = Math.floor(Math.random() * max + 1);
}
str = construct(bits, arr, 10, bitsPerNum);
}
return str;
};
};
// Warn about using insecure rng.
// Called when Math.random() is being used.
function warn() {
global['console']['warn'](defaults.warning);
if (typeof global['alert'] === 'function' && config.alert) {
global['alert'](defaults.warning);
}
}
// Set the PRNG to use. If no RNG function is supplied, pick a default using getRNG()
/** @expose **/
exports.setRNG = function (rng, alert) {
if (!isInited()) {
this.init();
}
config.unsafePRNG = false;
rng = rng || getRNG();
// test the RNG (5 times)
if (typeof rng !== 'function' || typeof rng(config.bits) !== 'string' || !parseInt(rng(config.bits),
2) || rng(config.bits).length > config.bits || rng(config.bits).length < config.bits) {
throw new Error(
"Random number generator is invalid. Supply an RNG of the form function(bits){} that returns a string containing 'bits' number of random 1's and 0's."
)
} else {
config.rng = rng;
}
config.alert = !!alert;
return !!config.unsafePRNG;
};
function isSetRNG() {
return typeof config.rng === 'function';
};
// Generates a random bits-length number string using the PRNG
/** @expose **/
exports.random = function (bits) {
if (!isSetRNG()) {
this.setRNG();
}
if (typeof bits !== 'number' || bits % 1 !== 0 || bits < 2) {
throw new Error('Number of bits must be an integer greater than 1.')
}
if (config.unsafePRNG) {
warn();
}
return bin2hex(config.rng(bits));
}
// Divides a `secret` number String str expressed in radix `inputRadix` (optional, default 16)
// into `numShares` shares, each expressed in radix `outputRadix` (optional, default to `inputRadix`),
// requiring `threshold` number of shares to reconstruct the secret.
// Optionally, zero-pads the secret to a length that is a multiple of padLength before sharing.
/** @expose **/
exports.share = function (secret, numShares, threshold, padLength, withoutPrefix) {
if (!isInited()) {
this.init();
}
if (!isSetRNG()) {
this.setRNG();
}
padLength = padLength || 0;
if (typeof secret !== 'string') {
throw new Error('Secret must be a string.');
}
if (typeof numShares !== 'number' || numShares % 1 !== 0 || numShares < 2) {
throw new Error('Number of shares must be an integer between 2 and 2^bits-1 (' + config.max +
'), inclusive.')
}
if (numShares > config.max) {
var neededBits = Math.ceil(Math.log(numShares + 1) / Math.LN2);
throw new Error('Number of shares must be an integer between 2 and 2^bits-1 (' + config.max +
'), inclusive. To create ' + numShares + ' shares, use at least ' + neededBits +
' bits.')
}
if (typeof threshold !== 'number' || threshold % 1 !== 0 || threshold < 2) {
throw new Error('Threshold number of shares must be an integer between 2 and 2^bits-1 (' +
config.max + '), inclusive.');
}
if (threshold > config.max) {
var neededBits = Math.ceil(Math.log(threshold + 1) / Math.LN2);
throw new Error('Threshold number of shares must be an integer between 2 and 2^bits-1 (' +
config.max + '), inclusive. To use a threshold of ' + threshold +
', use at least ' +
neededBits + ' bits.');
}
if (typeof padLength !== 'number' || padLength % 1 !== 0) {
throw new Error('Zero-pad length must be an integer greater than 1.');
}
if (config.unsafePRNG) {
warn();
}
secret = '1' + hex2bin(secret); // append a 1 so that we can preserve the correct number of leading zeros in our secret
secret = split(secret, padLength);
var x = new Array(numShares),
y = new Array(numShares);
for (var i = 0, len = secret.length; i < len; i++) {
var subShares = this._getShares(secret[i], numShares, threshold);
for (var j = 0; j < numShares; j++) {
x[j] = x[j] || subShares[j].x.toString(config.radix);
y[j] = padLeft(subShares[j].y.toString(2)) + (y[j] ? y[j] : '');
}
}
var padding = config.max.toString(config.radix).length;
if (withoutPrefix) {
for (var i = 0; i < numShares; i++) {
x[i] = bin2hex(y[i]);
}
} else {
for (var i = 0; i < numShares; i++) {
x[i] = config.bits.toString(36).toUpperCase() + padLeft(x[i], padding) + bin2hex(y[i]);
}
}
return x;
};
// This is the basic polynomial generation and evaluation function
// for a `config.bits`-length secret (NOT an arbitrary length)
// Note: no error-checking at this stage! If `secrets` is NOT
// a NUMBER less than 2^bits-1, the output will be incorrect!
/** @expose **/
exports._getShares = function (secret, numShares, threshold) {
var shares = [];
var coeffs = [secret];
for (var i = 1; i < threshold; i++) {
coeffs[i] = parseInt(config.rng(config.bits), 2);
}
for (var i = 1, len = numShares + 1; i < len; i++) {
shares[i - 1] = {
x: i,
y: horner(i, coeffs)
}
}
return shares;
};
// Polynomial evaluation at `x` using Horner's Method
// TODO: this can possibly be sped up using other methods
// NOTE: fx=fx * x + coeff[i] -> exp(log(fx) + log(x)) + coeff[i],
// so if fx===0, just set fx to coeff[i] because
// using the exp/log form will result in incorrect value
function horner(x, coeffs) {
var logx = config.logs[x];
var fx = 0;
for (var i = coeffs.length - 1; i >= 0; i--) {
if (fx === 0) {
fx = coeffs[i];
continue;
}
fx = config.exps[(logx + config.logs[fx]) % config.max] ^ coeffs[i];
}
return fx;
};
function inArray(arr, val) {
for (var i = 0, len = arr.length; i < len; i++) {
if (arr[i] === val) {
return true;
}
}
return false;
};
function processShare(share) {
var bits = parseInt(share[0], 36);
if (bits && (typeof bits !== 'number' || bits % 1 !== 0 || bits < defaults.minBits || bits >
defaults.maxBits)) {
throw new Error('Number of bits must be an integer between ' + defaults.minBits + ' and ' +
defaults.maxBits + ', inclusive.')
}
var max = Math.pow(2, bits) - 1;
var idLength = max.toString(config.radix).length;
var id = parseInt(share.substr(1, idLength), config.radix);
if (typeof id !== 'number' || id % 1 !== 0 || id < 1 || id > max) {
throw new Error('Share id must be an integer between 1 and ' + config.max + ', inclusive.');
}
share = share.substr(idLength + 1);
if (!share.length) {
throw new Error('Invalid share: zero-length share.')
}
return {
'bits': bits,
'id': id,
'value': share
};
};
/** @expose **/
exports._processShare = processShare;
// Protected method that evaluates the Lagrange interpolation
// polynomial at x=`at` for individual config.bits-length
// segments of each share in the `shares` Array.
// Each share is expressed in base `inputRadix`. The output
// is expressed in base `outputRadix'
function combine(at, shares) {
var setBits, share, x = [],
y = [],
result = '',
idx;
for (var i = 0, len = shares.length; i < len; i++) {
share = processShare(shares[i]);
if (typeof setBits === 'undefined') {
setBits = share['bits'];
} else if (share['bits'] !== setBits) {
throw new Error('Mismatched shares: Different bit settings.')
}
if (config.bits !== setBits) {
init(setBits);
}
if (inArray(x, share['id'])) { // repeated x value?
continue;
}
idx = x.push(share['id']) - 1;
share = split(hex2bin(share['value']));
for (var j = 0, len2 = share.length; j < len2; j++) {
y[j] = y[j] || [];
y[j][idx] = share[j];
}
}
for (var i = 0, len = y.length; i < len; i++) {
result = padLeft(lagrange(at, x, y[i]).toString(2)) + result;
}
if (at === 0) { // reconstructing the secret
var idx = result.indexOf('1'); //find the first 1
return bin2hex(result.slice(idx + 1));
} else { // generating a new share
return bin2hex(result);
}
};
// Combine `shares` Array into the original secret
/** @expose **/
exports.combine = function (shares) {
return combine(0, shares);
};
// Generate a new share with id `id` (a number between 1 and 2^bits-1)
// `id` can be a Number or a String in the default radix (16)
/** @expose **/
exports.newShare = function (id, shares) {
if (typeof id === 'string') {
id = parseInt(id, config.radix);
}
var share = processShare(shares[0]);
var max = Math.pow(2, share['bits']) - 1;
if (typeof id !== 'number' || id % 1 !== 0 || id < 1 || id > max) {
throw new Error('Share id must be an integer between 1 and ' + config.max + ', inclusive.');
}
var padding = max.toString(config.radix).length;
return config.bits.toString(36).toUpperCase() + padLeft(id.toString(config.radix), padding) +
combine(id, shares);
};
// Evaluate the Lagrange interpolation polynomial at x = `at`
// using x and y Arrays that are of the same length, with
// corresponding elements constituting points on the polynomial.
function lagrange(at, x, y) {
var sum = 0,
product,
i, j;
for (var i = 0, len = x.length; i < len; i++) {
if (!y[i]) {
continue;
}
product = config.logs[y[i]];
for (var j = 0; j < len; j++) {
if (i === j) {
continue;
}
if (at === x[j]) { // happens when computing a share that is in the list of shares used to compute it
product = -1; // fix for a zero product term, after which the sum should be sum^0 = sum, not sum^1
break;
}
product = (product + config.logs[at ^ x[j]] - config.logs[x[i] ^ x[j]] + config.max /* to make sure it's not negative */ ) %
config.max;
}
sum = product === -1 ? sum : sum ^ config.exps[product]; // though exps[-1]= undefined and undefined ^ anything = anything in chrome, this behavior may not hold everywhere, so do the check
}
return sum;
};
/** @expose **/
exports._lagrange = lagrange;
// Splits a number string `bits`-length segments, after first
// optionally zero-padding it to a length that is a multiple of `padLength.
// Returns array of integers (each less than 2^bits-1), with each element
// representing a `bits`-length segment of the input string from right to left,
// i.e. parts[0] represents the right-most `bits`-length segment of the input string.
function split(str, padLength) {
if (padLength) {
str = padLeft(str, padLength)
}
var parts = [];
for (var i = str.length; i > config.bits; i -= config.bits) {
parts.push(parseInt(str.slice(i - config.bits, i), 2));
}
parts.push(parseInt(str.slice(0, i), 2));
return parts;
};
// Pads a string `str` with zeros on the left so that its length is a multiple of `bits`
function padLeft(str, bits) {
bits = bits || config.bits
var missing = str.length % bits;
return (missing ? new Array(bits - missing + 1).join('0') : '') + str;
};
function hex2bin(str) {
var bin = '',
num;
for (var i = str.length - 1; i >= 0; i--) {
num = parseInt(str[i], 16)
if (isNaN(num)) {
throw new Error('Invalid hex character.')
}
bin = padLeft(num.toString(2), 4) + bin;
}
return bin;
}
function bin2hex(str) {
var hex = '',
num;
str = padLeft(str, 4);
for (var i = str.length; i >= 4; i -= 4) {
num = parseInt(str.slice(i - 4, i), 2);
if (isNaN(num)) {
throw new Error('Invalid binary character.')
}
hex = num.toString(16) + hex;
}
return hex;
}
// Converts a given UTF16 character string to the HEX representation.
// Each character of the input string is represented by
// `bytesPerChar` bytes in the output string.
/** @expose **/
exports.str2hex = function (str, bytesPerChar) {
if (typeof str !== 'string') {
throw new Error('Input must be a character string.');
}
bytesPerChar = bytesPerChar || defaults.bytesPerChar;
if (typeof bytesPerChar !== 'number' || bytesPerChar % 1 !== 0 || bytesPerChar < 1 ||
bytesPerChar >
defaults.maxBytesPerChar) {
throw new Error('Bytes per character must be an integer between 1 and ' + defaults.maxBytesPerChar +
', inclusive.')
}
var hexChars = 2 * bytesPerChar;
var max = Math.pow(16, hexChars) - 1;
var out = '',
num;
for (var i = 0, len = str.length; i < len; i++) {
num = str[i].charCodeAt();
if (isNaN(num)) {
throw new Error('Invalid character: ' + str[i]);
} else if (num > max) {
var neededBytes = Math.ceil(Math.log(num + 1) / Math.log(256));
throw new Error('Invalid character code (' + num +
'). Maximum allowable is 256^bytes-1 (' +
max + '). To convert this character, use at least ' + neededBytes + ' bytes.')
} else {
out = padLeft(num.toString(16), hexChars) + out;
}
}
return out;
};
// Converts a given HEX number string to a UTF16 character string.
/** @expose **/
exports.hex2str = function (str, bytesPerChar) {
if (typeof str !== 'string') {
throw new Error('Input must be a hexadecimal string.');
}
bytesPerChar = bytesPerChar || defaults.bytesPerChar;
if (typeof bytesPerChar !== 'number' || bytesPerChar % 1 !== 0 || bytesPerChar < 1 ||
bytesPerChar >
defaults.maxBytesPerChar) {
throw new Error('Bytes per character must be an integer between 1 and ' + defaults.maxBytesPerChar +
', inclusive.')
}
var hexChars = 2 * bytesPerChar;
var out = '';
str = padLeft(str, hexChars);
for (var i = 0, len = str.length; i < len; i += hexChars) {
out = String.fromCharCode(parseInt(str.slice(i, i + hexChars), 16)) + out;
}
return out;
};
// by default, initialize without an RNG
exports.init();
})(typeof module !== 'undefined' && module['exports'] ? module['exports'] : (window['secrets'] = {}), typeof GLOBAL !==
'undefined' ? GLOBAL : window);
</script>
<script type="text/javascript">
// Upstream 'BigInteger' here:
// Original Author: http://www-cs-students.stanford.edu/~tjw/jsbn/
// Follows 'jsbn' on Github: https://github.com/jasondavies/jsbn
// Review and Testing: https://github.com/cryptocoinjs/bigi/
/*!
* Basic JavaScript BN library - subset useful for RSA encryption. v1.4
*
* Copyright (c) 2005 Tom Wu
* All Rights Reserved.
* BSD License
* http://www-cs-students.stanford.edu/~tjw/jsbn/LICENSE
*
* Copyright Stephan Thomas
* Copyright pointbiz
*/
(function () {
// (public) Constructor function of Global BigInteger object
var BigInteger = window.BigInteger = function BigInteger(a, b, c) {
if (!(this instanceof BigInteger))
return new BigInteger(a, b, c);
if (a != null)
if ("number" == typeof a) this.fromNumber(a, b, c);
else if (b == null && "string" != typeof a) this.fromString(a, 256);
else this.fromString(a, b);
};
// Bits per digit
var dbits;
// JavaScript engine analysis
var canary = 0xdeadbeefcafe;
var j_lm = ((canary & 0xffffff) == 0xefcafe);
// return new, unset BigInteger
function nbi() {
return new BigInteger(null);
}
// am: Compute w_j += (x*this_i), propagate carries,
// c is initial carry, returns final carry.
// c < 3*dvalue, x < 2*dvalue, this_i < dvalue
// We need to select the fastest one that works in this environment.
// am1: use a single mult and divide to get the high bits,
// max digit bits should be 26 because
// max internal value = 2*dvalue^2-2*dvalue (< 2^53)
function am1(i, x, w, j, c, n) {
while (--n >= 0) {
var v = x * this[i++] + w[j] + c;
c = Math.floor(v / 0x4000000);
w[j++] = v & 0x3ffffff;
}
return c;
}
// am2 avoids a big mult-and-extract completely.
// Max digit bits should be <= 30 because we do bitwise ops
// on values up to 2*hdvalue^2-hdvalue-1 (< 2^31)
function am2(i, x, w, j, c, n) {
var xl = x & 0x7fff,
xh = x >> 15;
while (--n >= 0) {
var l = this[i] & 0x7fff;
var h = this[i++] >> 15;
var m = xh * l + h * xl;
l = xl * l + ((m & 0x7fff) << 15) + w[j] + (c & 0x3fffffff);
c = (l >>> 30) + (m >>> 15) + xh * h + (c >>> 30);
w[j++] = l & 0x3fffffff;
}
return c;
}
// Alternately, set max digit bits to 28 since some
// browsers slow down when dealing with 32-bit numbers.
function am3(i, x, w, j, c, n) {
var xl = x & 0x3fff,
xh = x >> 14;
while (--n >= 0) {
var l = this[i] & 0x3fff;
var h = this[i++] >> 14;
var m = xh * l + h * xl;
l = xl * l + ((m & 0x3fff) << 14) + w[j] + c;
c = (l >> 28) + (m >> 14) + xh * h;
w[j++] = l & 0xfffffff;
}
return c;
}
if (j_lm && (navigator.appName == "Microsoft Internet Explorer")) {
BigInteger.prototype.am = am2;
dbits = 30;
} else if (j_lm && (navigator.appName != "Netscape")) {
BigInteger.prototype.am = am1;
dbits = 26;
} else { // Mozilla/Netscape seems to prefer am3
BigInteger.prototype.am = am3;
dbits = 28;
}
BigInteger.prototype.DB = dbits;
BigInteger.prototype.DM = ((1 << dbits) - 1);
BigInteger.prototype.DV = (1 << dbits);
var BI_FP = 52;
BigInteger.prototype.FV = Math.pow(2, BI_FP);
BigInteger.prototype.F1 = BI_FP - dbits;
BigInteger.prototype.F2 = 2 * dbits - BI_FP;
// Digit conversions
var BI_RM = "0123456789abcdefghijklmnopqrstuvwxyz";
var BI_RC = new Array();
var rr, vv;
rr = "0".charCodeAt(0);
for (vv = 0; vv <= 9; ++vv) BI_RC[rr++] = vv;
rr = "a".charCodeAt(0);
for (vv = 10; vv < 36; ++vv) BI_RC[rr++] = vv;
rr = "A".charCodeAt(0);
for (vv = 10; vv < 36; ++vv) BI_RC[rr++] = vv;
function int2char(n) {
return BI_RM.charAt(n);
}
function intAt(s, i) {
var c = BI_RC[s.charCodeAt(i)];
return (c == null) ? -1 : c;
}
// return bigint initialized to value
function nbv(i) {
var r = nbi();
r.fromInt(i);
return r;
}
// returns bit length of the integer x
function nbits(x) {
var r = 1,
t;
if ((t = x >>> 16) != 0) {
x = t;
r += 16;
}
if ((t = x >> 8) != 0) {
x = t;
r += 8;
}
if ((t = x >> 4) != 0) {
x = t;
r += 4;
}
if ((t = x >> 2) != 0) {
x = t;
r += 2;
}
if ((t = x >> 1) != 0) {
x = t;
r += 1;
}
return r;
}
// (protected) copy this to r
BigInteger.prototype.copyTo = function (r) {
for (var i = this.t - 1; i >= 0; --i) r[i] = this[i];
r.t = this.t;
r.s = this.s;
};
// (protected) set from integer value x, -DV <= x < DV
BigInteger.prototype.fromInt = function (x) {
this.t = 1;
this.s = (x < 0) ? -1 : 0;
if (x > 0) this[0] = x;
else if (x < -1) this[0] = x + this.DV;
else this.t = 0;
};
// (protected) set from string and radix
BigInteger.prototype.fromString = function (s, b) {
var k;
if (b == 16) k = 4;
else if (b == 8) k = 3;
else if (b == 256) k = 8; // byte array
else if (b == 2) k = 1;
else if (b == 32) k = 5;
else if (b == 4) k = 2;
else {
this.fromRadix(s, b);
return;
}
this.t = 0;
this.s = 0;
var i = s.length,
mi = false,
sh = 0;
while (--i >= 0) {
var x = (k == 8) ? s[i] & 0xff : intAt(s, i);
if (x < 0) {
if (s.charAt(i) == "-") mi = true;
continue;
}
mi = false;
if (sh == 0)
this[this.t++] = x;
else if (sh + k > this.DB) {
this[this.t - 1] |= (x & ((1 << (this.DB - sh)) - 1)) << sh;
this[this.t++] = (x >> (this.DB - sh));
} else
this[this.t - 1] |= x << sh;
sh += k;
if (sh >= this.DB) sh -= this.DB;
}
if (k == 8 && (s[0] & 0x80) != 0) {
this.s = -1;
if (sh > 0) this[this.t - 1] |= ((1 << (this.DB - sh)) - 1) << sh;
}
this.clamp();
if (mi) BigInteger.ZERO.subTo(this, this);
};
// (protected) clamp off excess high words
BigInteger.prototype.clamp = function () {
var c = this.s & this.DM;
while (this.t > 0 && this[this.t - 1] == c) --this.t;
};
// (protected) r = this << n*DB
BigInteger.prototype.dlShiftTo = function (n, r) {
var i;
for (i = this.t - 1; i >= 0; --i) r[i + n] = this[i];
for (i = n - 1; i >= 0; --i) r[i] = 0;
r.t = this.t + n;
r.s = this.s;
};
// (protected) r = this >> n*DB
BigInteger.prototype.drShiftTo = function (n, r) {
for (var i = n; i < this.t; ++i) r[i - n] = this[i];
r.t = Math.max(this.t - n, 0);
r.s = this.s;
};
// (protected) r = this << n
BigInteger.prototype.lShiftTo = function (n, r) {
var bs = n % this.DB;
var cbs = this.DB - bs;
var bm = (1 << cbs) - 1;
var ds = Math.floor(n / this.DB),
c = (this.s << bs) & this.DM,
i;
for (i = this.t - 1; i >= 0; --i) {
r[i + ds + 1] = (this[i] >> cbs) | c;
c = (this[i] & bm) << bs;
}
for (i = ds - 1; i >= 0; --i) r[i] = 0;
r[ds] = c;
r.t = this.t + ds + 1;
r.s = this.s;
r.clamp();
};
// (protected) r = this >> n
BigInteger.prototype.rShiftTo = function (n, r) {
r.s = this.s;
var ds = Math.floor(n / this.DB);
if (ds >= this.t) {
r.t = 0;
return;
}
var bs = n % this.DB;
var cbs = this.DB - bs;
var bm = (1 << bs) - 1;
r[0] = this[ds] >> bs;
for (var i = ds + 1; i < this.t; ++i) {
r[i - ds - 1] |= (this[i] & bm) << cbs;
r[i - ds] = this[i] >> bs;
}
if (bs > 0) r[this.t - ds - 1] |= (this.s & bm) << cbs;
r.t = this.t - ds;
r.clamp();
};
// (protected) r = this - a
BigInteger.prototype.subTo = function (a, r) {
var i = 0,
c = 0,
m = Math.min(a.t, this.t);
while (i < m) {
c += this[i] - a[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
if (a.t < this.t) {
c -= a.s;
while (i < this.t) {
c += this[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
c += this.s;
} else {
c += this.s;
while (i < a.t) {
c -= a[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
c -= a.s;
}
r.s = (c < 0) ? -1 : 0;
if (c < -1) r[i++] = this.DV + c;
else if (c > 0) r[i++] = c;
r.t = i;
r.clamp();
};
// (protected) r = this * a, r != this,a (HAC 14.12)
// "this" should be the larger one if appropriate.
BigInteger.prototype.multiplyTo = function (a, r) {
var x = this.abs(),
y = a.abs();
var i = x.t;
r.t = i + y.t;
while (--i >= 0) r[i] = 0;
for (i = 0; i < y.t; ++i) r[i + x.t] = x.am(0, y[i], r, i, 0, x.t);
r.s = 0;
r.clamp();
if (this.s != a.s) BigInteger.ZERO.subTo(r, r);
};
// (protected) r = this^2, r != this (HAC 14.16)
BigInteger.prototype.squareTo = function (r) {
var x = this.abs();
var i = r.t = 2 * x.t;
while (--i >= 0) r[i] = 0;
for (i = 0; i < x.t - 1; ++i) {
var c = x.am(i, x[i], r, 2 * i, 0, 1);
if ((r[i + x.t] += x.am(i + 1, 2 * x[i], r, 2 * i + 1, c, x.t - i - 1)) >= x.DV) {
r[i + x.t] -= x.DV;
r[i + x.t + 1] = 1;
}
}
if (r.t > 0) r[r.t - 1] += x.am(i, x[i], r, 2 * i, 0, 1);
r.s = 0;
r.clamp();
};
// (protected) divide this by m, quotient and remainder to q, r (HAC 14.20)
// r != q, this != m. q or r may be null.
BigInteger.prototype.divRemTo = function (m, q, r) {
var pm = m.abs();
if (pm.t <= 0) return;
var pt = this.abs();
if (pt.t < pm.t) {
if (q != null) q.fromInt(0);
if (r != null) this.copyTo(r);
return;
}
if (r == null) r = nbi();
var y = nbi(),
ts = this.s,
ms = m.s;
var nsh = this.DB - nbits(pm[pm.t - 1]); // normalize modulus
if (nsh > 0) {
pm.lShiftTo(nsh, y);
pt.lShiftTo(nsh, r);
} else {
pm.copyTo(y);
pt.copyTo(r);
}
var ys = y.t;
var y0 = y[ys - 1];
if (y0 == 0) return;
var yt = y0 * (1 << this.F1) + ((ys > 1) ? y[ys - 2] >> this.F2 : 0);
var d1 = this.FV / yt,
d2 = (1 << this.F1) / yt,
e = 1 << this.F2;
var i = r.t,
j = i - ys,
t = (q == null) ? nbi() : q;
y.dlShiftTo(j, t);
if (r.compareTo(t) >= 0) {
r[r.t++] = 1;
r.subTo(t, r);
}
BigInteger.ONE.dlShiftTo(ys, t);
t.subTo(y, y); // "negative" y so we can replace sub with am later
while (y.t < ys) y[y.t++] = 0;
while (--j >= 0) {
// Estimate quotient digit
var qd = (r[--i] == y0) ? this.DM : Math.floor(r[i] * d1 + (r[i - 1] + e) * d2);
if ((r[i] += y.am(0, qd, r, j, 0, ys)) < qd) { // Try it out
y.dlShiftTo(j, t);
r.subTo(t, r);
while (r[i] < --qd) r.subTo(t, r);
}
}
if (q != null) {
r.drShiftTo(ys, q);
if (ts != ms) BigInteger.ZERO.subTo(q, q);
}
r.t = ys;
r.clamp();
if (nsh > 0) r.rShiftTo(nsh, r); // Denormalize remainder
if (ts < 0) BigInteger.ZERO.subTo(r, r);
};
// (protected) return "-1/this % 2^DB"; useful for Mont. reduction
// justification:
// xy == 1 (mod m)
// xy = 1+km
// xy(2-xy) = (1+km)(1-km)
// x[y(2-xy)] = 1-k^2m^2
// x[y(2-xy)] == 1 (mod m^2)
// if y is 1/x mod m, then y(2-xy) is 1/x mod m^2
// should reduce x and y(2-xy) by m^2 at each step to keep size bounded.
// JS multiply "overflows" differently from C/C++, so care is needed here.
BigInteger.prototype.invDigit = function () {
if (this.t < 1) return 0;
var x = this[0];
if ((x & 1) == 0) return 0;
var y = x & 3; // y == 1/x mod 2^2
y = (y * (2 - (x & 0xf) * y)) & 0xf; // y == 1/x mod 2^4
y = (y * (2 - (x & 0xff) * y)) & 0xff; // y == 1/x mod 2^8
y = (y * (2 - (((x & 0xffff) * y) & 0xffff))) & 0xffff; // y == 1/x mod 2^16
// last step - calculate inverse mod DV directly;
// assumes 16 < DB <= 32 and assumes ability to handle 48-bit ints
y = (y * (2 - x * y % this.DV)) % this.DV; // y == 1/x mod 2^dbits
// we really want the negative inverse, and -DV < y < DV
return (y > 0) ? this.DV - y : -y;
};
// (protected) true iff this is even
BigInteger.prototype.isEven = function () {
return ((this.t > 0) ? (this[0] & 1) : this.s) == 0;
};
// (protected) this^e, e < 2^32, doing sqr and mul with "r" (HAC 14.79)
BigInteger.prototype.exp = function (e, z) {
if (e > 0xffffffff || e < 1) return BigInteger.ONE;
var r = nbi(),
r2 = nbi(),
g = z.convert(this),
i = nbits(e) - 1;
g.copyTo(r);
while (--i >= 0) {
z.sqrTo(r, r2);
if ((e & (1 << i)) > 0) z.mulTo(r2, g, r);
else {
var t = r;
r = r2;
r2 = t;
}
}
return z.revert(r);
};
// (public) return string representation in given radix
BigInteger.prototype.toString = function (b) {
if (this.s < 0) return "-" + this.negate().toString(b);
var k;
if (b == 16) k = 4;
else if (b == 8) k = 3;
else if (b == 2) k = 1;
else if (b == 32) k = 5;
else if (b == 4) k = 2;
else return this.toRadix(b);
var km = (1 << k) - 1,
d, m = false,
r = "",
i = this.t;
var p = this.DB - (i * this.DB) % k;
if (i-- > 0) {
if (p < this.DB && (d = this[i] >> p) > 0) {
m = true;
r = int2char(d);
}
while (i >= 0) {
if (p < k) {
d = (this[i] & ((1 << p) - 1)) << (k - p);
d |= this[--i] >> (p += this.DB - k);
} else {
d = (this[i] >> (p -= k)) & km;
if (p <= 0) {
p += this.DB;
--i;
}
}
if (d > 0) m = true;
if (m) r += int2char(d);
}
}
return m ? r : "0";
};
// (public) -this
BigInteger.prototype.negate = function () {
var r = nbi();
BigInteger.ZERO.subTo(this, r);
return r;
};
// (public) |this|
BigInteger.prototype.abs = function () {
return (this.s < 0) ? this.negate() : this;
};
// (public) return + if this > a, - if this < a, 0 if equal
BigInteger.prototype.compareTo = function (a) {
var r = this.s - a.s;
if (r != 0) return r;
var i = this.t;
r = i - a.t;
if (r != 0) return (this.s < 0) ? -r : r;
while (--i >= 0)
if ((r = this[i] - a[i]) != 0) return r;
return 0;
}
// (public) return the number of bits in "this"
BigInteger.prototype.bitLength = function () {
if (this.t <= 0) return 0;
return this.DB * (this.t - 1) + nbits(this[this.t - 1] ^ (this.s & this.DM));
};
// (public) this mod a
BigInteger.prototype.mod = function (a) {
var r = nbi();
this.abs().divRemTo(a, null, r);
if (this.s < 0 && r.compareTo(BigInteger.ZERO) > 0) a.subTo(r, r);
return r;
}
// (public) this^e % m, 0 <= e < 2^32
BigInteger.prototype.modPowInt = function (e, m) {
var z;
if (e < 256 || m.isEven()) z = new Classic(m);
else z = new Montgomery(m);
return this.exp(e, z);
};
// "constants"
BigInteger.ZERO = nbv(0);
BigInteger.ONE = nbv(1);
// Copyright (c) 2005-2009 Tom Wu
// All Rights Reserved.
// See "LICENSE" for details.
// Extended JavaScript BN functions, required for RSA private ops.
// Version 1.1: new BigInteger("0", 10) returns "proper" zero
// Version 1.2: square() API, isProbablePrime fix
// return index of lowest 1-bit in x, x < 2^31
function lbit(x) {
if (x == 0) return -1;
var r = 0;
if ((x & 0xffff) == 0) {
x >>= 16;
r += 16;
}
if ((x & 0xff) == 0) {
x >>= 8;
r += 8;
}
if ((x & 0xf) == 0) {
x >>= 4;
r += 4;
}
if ((x & 3) == 0) {
x >>= 2;
r += 2;
}
if ((x & 1) == 0) ++r;
return r;
}
// return number of 1 bits in x
function cbit(x) {
var r = 0;
while (x != 0) {
x &= x - 1;
++r;
}
return r;
}
var lowprimes = [2, 3, 5, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 53, 59, 61, 67, 71, 73, 79, 83,
89,
97, 101, 103, 107, 109, 113, 127, 131, 137, 139, 149, 151, 157, 163, 167, 173, 179, 181, 191,
193,
197, 199, 211, 223, 227, 229, 233, 239, 241, 251, 257, 263, 269, 271, 277, 281, 283, 293, 307,
311,
313, 317, 331, 337, 347, 349, 353, 359, 367, 373, 379, 383, 389, 397, 401, 409, 419, 421, 431,
433,
439, 443, 449, 457, 461, 463, 467, 479, 487, 491, 499, 503, 509, 521, 523, 541, 547, 557, 563,
569,
571, 577, 587, 593, 599, 601, 607, 613, 617, 619, 631, 641, 643, 647, 653, 659, 661, 673, 677,
683,
691, 701, 709, 719, 727, 733, 739, 743, 751, 757, 761, 769, 773, 787, 797, 809, 811, 821, 823,
827,
829, 839, 853, 857, 859, 863, 877, 881, 883, 887, 907, 911, 919, 929, 937, 941, 947, 953, 967,
971,
977, 983, 991, 997
];
var lplim = (1 << 26) / lowprimes[lowprimes.length - 1];
// (protected) return x s.t. r^x < DV
BigInteger.prototype.chunkSize = function (r) {
return Math.floor(Math.LN2 * this.DB / Math.log(r));
};
// (protected) convert to radix string
BigInteger.prototype.toRadix = function (b) {
if (b == null) b = 10;
if (this.signum() == 0 || b < 2 || b > 36) return "0";
var cs = this.chunkSize(b);
var a = Math.pow(b, cs);
var d = nbv(a),
y = nbi(),
z = nbi(),
r = "";
this.divRemTo(d, y, z);
while (y.signum() > 0) {
r = (a + z.intValue()).toString(b).substr(1) + r;
y.divRemTo(d, y, z);
}
return z.intValue().toString(b) + r;
};
// (protected) convert from radix string
BigInteger.prototype.fromRadix = function (s, b) {
this.fromInt(0);
if (b == null) b = 10;
var cs = this.chunkSize(b);
var d = Math.pow(b, cs),
mi = false,
j = 0,
w = 0;
for (var i = 0; i < s.length; ++i) {
var x = intAt(s, i);
if (x < 0) {
if (s.charAt(i) == "-" && this.signum() == 0) mi = true;
continue;
}
w = b * w + x;
if (++j >= cs) {
this.dMultiply(d);
this.dAddOffset(w, 0);
j = 0;
w = 0;
}
}
if (j > 0) {
this.dMultiply(Math.pow(b, j));
this.dAddOffset(w, 0);
}
if (mi) BigInteger.ZERO.subTo(this, this);
};
// (protected) alternate constructor
BigInteger.prototype.fromNumber = function (a, b, c) {
if ("number" == typeof b) {
// new BigInteger(int,int,RNG)
if (a < 2) this.fromInt(1);
else {
this.fromNumber(a, c);
if (!this.testBit(a - 1)) // force MSB set
this.bitwiseTo(BigInteger.ONE.shiftLeft(a - 1), op_or, this);
if (this.isEven()) this.dAddOffset(1, 0); // force odd
while (!this.isProbablePrime(b)) {
this.dAddOffset(2, 0);
if (this.bitLength() > a) this.subTo(BigInteger.ONE.shiftLeft(a - 1), this);
}
}
} else {
// new BigInteger(int,RNG)
var x = new Array(),
t = a & 7;
x.length = (a >> 3) + 1;
b.nextBytes(x);
if (t > 0) x[0] &= ((1 << t) - 1);
else x[0] = 0;
this.fromString(x, 256);
}
};
// (protected) r = this op a (bitwise)
BigInteger.prototype.bitwiseTo = function (a, op, r) {
var i, f, m = Math.min(a.t, this.t);
for (i = 0; i < m; ++i) r[i] = op(this[i], a[i]);
if (a.t < this.t) {
f = a.s & this.DM;
for (i = m; i < this.t; ++i) r[i] = op(this[i], f);
r.t = this.t;
} else {
f = this.s & this.DM;
for (i = m; i < a.t; ++i) r[i] = op(f, a[i]);
r.t = a.t;
}
r.s = op(this.s, a.s);
r.clamp();
};
// (protected) this op (1<<n)
BigInteger.prototype.changeBit = function (n, op) {
var r = BigInteger.ONE.shiftLeft(n);
this.bitwiseTo(r, op, r);
return r;
};
// (protected) r = this + a
BigInteger.prototype.addTo = function (a, r) {
var i = 0,
c = 0,
m = Math.min(a.t, this.t);
while (i < m) {
c += this[i] + a[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
if (a.t < this.t) {
c += a.s;
while (i < this.t) {
c += this[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
c += this.s;
} else {
c += this.s;
while (i < a.t) {
c += a[i];
r[i++] = c & this.DM;
c >>= this.DB;
}
c += a.s;
}
r.s = (c < 0) ? -1 : 0;
if (c > 0) r[i++] = c;
else if (c < -1) r[i++] = this.DV + c;
r.t = i;
r.clamp();
};
// (protected) this *= n, this >= 0, 1 < n < DV
BigInteger.prototype.dMultiply = function (n) {
this[this.t] = this.am(0, n - 1, this, 0, 0, this.t);
++this.t;
this.clamp();
};
// (protected) this += n << w words, this >= 0
BigInteger.prototype.dAddOffset = function (n, w) {
if (n == 0) return;
while (this.t <= w) this[this.t++] = 0;
this[w] += n;
while (this[w] >= this.DV) {
this[w] -= this.DV;
if (++w >= this.t) this[this.t++] = 0;
++this[w];
}
};
// (protected) r = lower n words of "this * a", a.t <= n
// "this" should be the larger one if appropriate.
BigInteger.prototype.multiplyLowerTo = function (a, n, r) {
var i = Math.min(this.t + a.t, n);
r.s = 0; // assumes a,this >= 0
r.t = i;
while (i > 0) r[--i] = 0;
var j;
for (j = r.t - this.t; i < j; ++i) r[i + this.t] = this.am(0, a[i], r, i, 0, this.t);
for (j = Math.min(a.t, n); i < j; ++i) this.am(0, a[i], r, i, 0, n - i);
r.clamp();
};
// (protected) r = "this * a" without lower n words, n > 0
// "this" should be the larger one if appropriate.
BigInteger.prototype.multiplyUpperTo = function (a, n, r) {
--n;
var i = r.t = this.t + a.t - n;
r.s = 0; // assumes a,this >= 0
while (--i >= 0) r[i] = 0;
for (i = Math.max(n - this.t, 0); i < a.t; ++i)
r[this.t + i - n] = this.am(n - i, a[i], r, 0, 0, this.t + i - n);
r.clamp();
r.drShiftTo(1, r);
};
// (protected) this % n, n < 2^26
BigInteger.prototype.modInt = function (n) {
if (n <= 0) return 0;
var d = this.DV % n,
r = (this.s < 0) ? n - 1 : 0;
if (this.t > 0)
if (d == 0) r = this[0] % n;
else
for (var i = this.t - 1; i >= 0; --i) r = (d * r + this[i]) % n;
return r;
};
// (protected) true if probably prime (HAC 4.24, Miller-Rabin)
BigInteger.prototype.millerRabin = function (t) {
var n1 = this.subtract(BigInteger.ONE);
var k = n1.getLowestSetBit();
if (k <= 0) return false;
var r = n1.shiftRight(k);
t = (t + 1) >> 1;
if (t > lowprimes.length) t = lowprimes.length;
var a = nbi();
for (var i = 0; i < t; ++i) {
//Pick bases at random, instead of starting at 2
a.fromInt(lowprimes[Math.floor(Math.random() * lowprimes.length)]);
var y = a.modPow(r, this);
if (y.compareTo(BigInteger.ONE) != 0 && y.compareTo(n1) != 0) {
var j = 1;
while (j++ < k && y.compareTo(n1) != 0) {
y = y.modPowInt(2, this);
if (y.compareTo(BigInteger.ONE) == 0) return false;
}
if (y.compareTo(n1) != 0) return false;
}
}
return true;
};
// (public)
BigInteger.prototype.clone = function () {
var r = nbi();
this.copyTo(r);
return r;
};
// (public) return value as integer
BigInteger.prototype.intValue = function () {
if (this.s < 0) {
if (this.t == 1) return this[0] - this.DV;
else if (this.t == 0) return -1;
} else if (this.t == 1) return this[0];
else if (this.t == 0) return 0;
// assumes 16 < DB < 32
return ((this[1] & ((1 << (32 - this.DB)) - 1)) << this.DB) | this[0];
};
// (public) return value as byte
BigInteger.prototype.byteValue = function () {
return (this.t == 0) ? this.s : (this[0] << 24) >> 24;
};
// (public) return value as short (assumes DB>=16)
BigInteger.prototype.shortValue = function () {
return (this.t == 0) ? this.s : (this[0] << 16) >> 16;
};
// (public) 0 if this == 0, 1 if this > 0
BigInteger.prototype.signum = function () {
if (this.s < 0) return -1;
else if (this.t <= 0 || (this.t == 1 && this[0] <= 0)) return 0;
else return 1;
};
// (public) convert to bigendian byte array
BigInteger.prototype.toByteArray = function () {
var i = this.t,
r = new Array();
r[0] = this.s;
var p = this.DB - (i * this.DB) % 8,
d, k = 0;
if (i-- > 0) {
if (p < this.DB && (d = this[i] >> p) != (this.s & this.DM) >> p)
r[k++] = d | (this.s << (this.DB - p));
while (i >= 0) {
if (p < 8) {
d = (this[i] & ((1 << p) - 1)) << (8 - p);
d |= this[--i] >> (p += this.DB - 8);
} else {
d = (this[i] >> (p -= 8)) & 0xff;
if (p <= 0) {
p += this.DB;
--i;
}
}
if ((d & 0x80) != 0) d |= -256;
if (k == 0 && (this.s & 0x80) != (d & 0x80)) ++k;
if (k > 0 || d != this.s) r[k++] = d;
}
}
return r;
};
BigInteger.prototype.equals = function (a) {
return (this.compareTo(a) == 0);
};
BigInteger.prototype.min = function (a) {
return (this.compareTo(a) < 0) ? this : a;
};
BigInteger.prototype.max = function (a) {
return (this.compareTo(a) > 0) ? this : a;
};
// (public) this & a
function op_and(x, y) {
return x & y;
}
BigInteger.prototype.and = function (a) {
var r = nbi();
this.bitwiseTo(a, op_and, r);
return r;
};
// (public) this | a
function op_or(x, y) {
return x | y;
}
BigInteger.prototype.or = function (a) {
var r = nbi();
this.bitwiseTo(a, op_or, r);
return r;
};
// (public) this ^ a
function op_xor(x, y) {
return x ^ y;
}
BigInteger.prototype.xor = function (a) {
var r = nbi();
this.bitwiseTo(a, op_xor, r);
return r;
};
// (public) this & ~a
function op_andnot(x, y) {
return x & ~y;
}
BigInteger.prototype.andNot = function (a) {
var r = nbi();
this.bitwiseTo(a, op_andnot, r);
return r;
};
// (public) ~this
BigInteger.prototype.not = function () {
var r = nbi();
for (var i = 0; i < this.t; ++i) r[i] = this.DM & ~this[i];
r.t = this.t;
r.s = ~this.s;
return r;
};
// (public) this << n
BigInteger.prototype.shiftLeft = function (n) {
var r = nbi();
if (n < 0) this.rShiftTo(-n, r);
else this.lShiftTo(n, r);
return r;
};
// (public) this >> n
BigInteger.prototype.shiftRight = function (n) {
var r = nbi();
if (n < 0) this.lShiftTo(-n, r);
else this.rShiftTo(n, r);
return r;
};
// (public) returns index of lowest 1-bit (or -1 if none)
BigInteger.prototype.getLowestSetBit = function () {
for (var i = 0; i < this.t; ++i)
if (this[i] != 0) return i * this.DB + lbit(this[i]);
if (this.s < 0) return this.t * this.DB;
return -1;
};
// (public) return number of set bits
BigInteger.prototype.bitCount = function () {
var r = 0,
x = this.s & this.DM;
for (var i = 0; i < this.t; ++i) r += cbit(this[i] ^ x);
return r;
};
// (public) true iff nth bit is set
BigInteger.prototype.testBit = function (n) {
var j = Math.floor(n / this.DB);
if (j >= this.t) return (this.s != 0);
return ((this[j] & (1 << (n % this.DB))) != 0);
};
// (public) this | (1<<n)
BigInteger.prototype.setBit = function (n) {
return this.changeBit(n, op_or);
};
// (public) this & ~(1<<n)
BigInteger.prototype.clearBit = function (n) {
return this.changeBit(n, op_andnot);
};
// (public) this ^ (1<<n)
BigInteger.prototype.flipBit = function (n) {
return this.changeBit(n, op_xor);
};
// (public) this + a
BigInteger.prototype.add = function (a) {
var r = nbi();
this.addTo(a, r);
return r;
};
// (public) this - a
BigInteger.prototype.subtract = function (a) {
var r = nbi();
this.subTo(a, r);
return r;
};
// (public) this * a
BigInteger.prototype.multiply = function (a) {
var r = nbi();
this.multiplyTo(a, r);
return r;
};
// (public) this / a
BigInteger.prototype.divide = function (a) {
var r = nbi();
this.divRemTo(a, r, null);
return r;
};
// (public) this % a
BigInteger.prototype.remainder = function (a) {
var r = nbi();
this.divRemTo(a, null, r);
return r;
};
// (public) [this/a,this%a]
BigInteger.prototype.divideAndRemainder = function (a) {
var q = nbi(),
r = nbi();
this.divRemTo(a, q, r);
return new Array(q, r);
};
// (public) this^e % m (HAC 14.85)
BigInteger.prototype.modPow = function (e, m) {
var i = e.bitLength(),
k, r = nbv(1),
z;
if (i <= 0) return r;
else if (i < 18) k = 1;
else if (i < 48) k = 3;
else if (i < 144) k = 4;
else if (i < 768) k = 5;
else k = 6;
if (i < 8)
z = new Classic(m);
else if (m.isEven())
z = new Barrett(m);
else
z = new Montgomery(m);
// precomputation
var g = new Array(),
n = 3,
k1 = k - 1,
km = (1 << k) - 1;
g[1] = z.convert(this);
if (k > 1) {
var g2 = nbi();
z.sqrTo(g[1], g2);
while (n <= km) {
g[n] = nbi();
z.mulTo(g2, g[n - 2], g[n]);
n += 2;
}
}
var j = e.t - 1,
w, is1 = true,
r2 = nbi(),
t;
i = nbits(e[j]) - 1;
while (j >= 0) {
if (i >= k1) w = (e[j] >> (i - k1)) & km;
else {
w = (e[j] & ((1 << (i + 1)) - 1)) << (k1 - i);
if (j > 0) w |= e[j - 1] >> (this.DB + i - k1);
}
n = k;
while ((w & 1) == 0) {
w >>= 1;
--n;
}
if ((i -= n) < 0) {
i += this.DB;
--j;
}
if (is1) { // ret == 1, don't bother squaring or multiplying it
g[w].copyTo(r);
is1 = false;
} else {
while (n > 1) {
z.sqrTo(r, r2);
z.sqrTo(r2, r);
n -= 2;
}
if (n > 0) z.sqrTo(r, r2);
else {
t = r;
r = r2;
r2 = t;
}
z.mulTo(r2, g[w], r);
}
while (j >= 0 && (e[j] & (1 << i)) == 0) {
z.sqrTo(r, r2);
t = r;
r = r2;
r2 = t;
if (--i < 0) {
i = this.DB - 1;
--j;
}
}
}
return z.revert(r);
};
// (public) 1/this % m (HAC 14.61)
BigInteger.prototype.modInverse = function (m) {
var ac = m.isEven();
if (this.signum() === 0) throw new Error('division by zero');
if ((this.isEven() && ac) || m.signum() == 0) return BigInteger.ZERO;
var u = m.clone(),
v = this.clone();
var a = nbv(1),
b = nbv(0),
c = nbv(0),
d = nbv(1);
while (u.signum() != 0) {
while (u.isEven()) {
u.rShiftTo(1, u);
if (ac) {
if (!a.isEven() || !b.isEven()) {
a.addTo(this, a);
b.subTo(m, b);
}
a.rShiftTo(1, a);
} else if (!b.isEven()) b.subTo(m, b);
b.rShiftTo(1, b);
}
while (v.isEven()) {
v.rShiftTo(1, v);
if (ac) {
if (!c.isEven() || !d.isEven()) {
c.addTo(this, c);
d.subTo(m, d);
}
c.rShiftTo(1, c);
} else if (!d.isEven()) d.subTo(m, d);
d.rShiftTo(1, d);
}
if (u.compareTo(v) >= 0) {
u.subTo(v, u);
if (ac) a.subTo(c, a);
b.subTo(d, b);
} else {
v.subTo(u, v);
if (ac) c.subTo(a, c);
d.subTo(b, d);
}
}
if (v.compareTo(BigInteger.ONE) != 0) return BigInteger.ZERO;
while (d.compareTo(m) >= 0) d.subTo(m, d);
while (d.signum() < 0) d.addTo(m, d);
return d;
};
// (public) this^e
BigInteger.prototype.pow = function (e) {
return this.exp(e, new NullExp());
};
// (public) gcd(this,a) (HAC 14.54)
BigInteger.prototype.gcd = function (a) {
var x = (this.s < 0) ? this.negate() : this.clone();
var y = (a.s < 0) ? a.negate() : a.clone();
if (x.compareTo(y) < 0) {
var t = x;
x = y;
y = t;
}
var i = x.getLowestSetBit(),
g = y.getLowestSetBit();
if (g < 0) return x;
if (i < g) g = i;
if (g > 0) {
x.rShiftTo(g, x);
y.rShiftTo(g, y);
}
while (x.signum() > 0) {
if ((i = x.getLowestSetBit()) > 0) x.rShiftTo(i, x);
if ((i = y.getLowestSetBit()) > 0) y.rShiftTo(i, y);
if (x.compareTo(y) >= 0) {
x.subTo(y, x);
x.rShiftTo(1, x);
} else {
y.subTo(x, y);
y.rShiftTo(1, y);
}
}
if (g > 0) y.lShiftTo(g, y);
return y;
};
// (public) test primality with certainty >= 1-.5^t
BigInteger.prototype.isProbablePrime = function (t) {
var i, x = this.abs();
if (x.t == 1 && x[0] <= lowprimes[lowprimes.length - 1]) {
for (i = 0; i < lowprimes.length; ++i)
if (x[0] == lowprimes[i]) return true;
return false;
}
if (x.isEven()) return false;
i = 1;
while (i < lowprimes.length) {
var m = lowprimes[i],
j = i + 1;
while (j < lowprimes.length && m < lplim) m *= lowprimes[j++];
m = x.modInt(m);
while (i < j)
if (m % lowprimes[i++] == 0) return false;
}
return x.millerRabin(t);
};
// JSBN-specific extension
// (public) this^2
BigInteger.prototype.square = function () {
var r = nbi();
this.squareTo(r);
return r;
};
// NOTE: BigInteger interfaces not implemented in jsbn:
// BigInteger(int signum, byte[] magnitude)
// double doubleValue()
// float floatValue()
// int hashCode()
// long longValue()
// static BigInteger valueOf(long val)
// Copyright Stephan Thomas (start) --- //
// https://raw.github.com/bitcoinjs/bitcoinjs-lib/07f9d55ccb6abd962efb6befdd37671f85ea4ff9/src/util.js
// BigInteger monkey patching
BigInteger.valueOf = nbv;
/**
* Returns a byte array representation of the big integer.
*
* This returns the absolute of the contained value in big endian
* form. A value of zero results in an empty array.
*/
BigInteger.prototype.toByteArrayUnsigned = function () {
var ba = this.abs().toByteArray();
if (ba.length) {
if (ba[0] == 0) {
ba = ba.slice(1);
}
return ba.map(function (v) {
return (v < 0) ? v + 256 : v;
});
} else {
// Empty array, nothing to do
return ba;
}
};
/**
* Turns a byte array into a big integer.
*
* This function will interpret a byte array as a big integer in big
* endian notation and ignore leading zeros.
*/
BigInteger.fromByteArrayUnsigned = function (ba) {
if (!ba.length) {
return ba.valueOf(0);
} else if (ba[0] & 0x80) {
// Prepend a zero so the BigInteger class doesn't mistake this
// for a negative integer.
return new BigInteger([0].concat(ba));
} else {
return new BigInteger(ba);
}
};
/**
* Converts big integer to signed byte representation.
*
* The format for this value uses a the most significant bit as a sign
* bit. If the most significant bit is already occupied by the
* absolute value, an extra byte is prepended and the sign bit is set
* there.
*
* Examples:
*
* 0 => 0x00
* 1 => 0x01
* -1 => 0x81
* 127 => 0x7f
* -127 => 0xff
* 128 => 0x0080
* -128 => 0x8080
* 255 => 0x00ff
* -255 => 0x80ff
* 16300 => 0x3fac
* -16300 => 0xbfac
* 62300 => 0x00f35c
* -62300 => 0x80f35c
*/
BigInteger.prototype.toByteArraySigned = function () {
var val = this.abs().toByteArrayUnsigned();
var neg = this.compareTo(BigInteger.ZERO) < 0;
if (neg) {
if (val[0] & 0x80) {
val.unshift(0x80);
} else {
val[0] |= 0x80;
}
} else {
if (val[0] & 0x80) {
val.unshift(0x00);
}
}
return val;
};
/**
* Parse a signed big integer byte representation.
*
* For details on the format please see BigInteger.toByteArraySigned.
*/
BigInteger.fromByteArraySigned = function (ba) {
// Check for negative value
if (ba[0] & 0x80) {
// Remove sign bit
ba[0] &= 0x7f;
return BigInteger.fromByteArrayUnsigned(ba).negate();
} else {
return BigInteger.fromByteArrayUnsigned(ba);
}
};
// Copyright Stephan Thomas (end) --- //
// ****** REDUCTION ******* //
// Modular reduction using "classic" algorithm
var Classic = window.Classic = function Classic(m) {
this.m = m;
}
Classic.prototype.convert = function (x) {
if (x.s < 0 || x.compareTo(this.m) >= 0) return x.mod(this.m);
else return x;
};
Classic.prototype.revert = function (x) {
return x;
};
Classic.prototype.reduce = function (x) {
x.divRemTo(this.m, null, x);
};
Classic.prototype.mulTo = function (x, y, r) {
x.multiplyTo(y, r);
this.reduce(r);
};
Classic.prototype.sqrTo = function (x, r) {
x.squareTo(r);
this.reduce(r);
};
// Montgomery reduction
var Montgomery = window.Montgomery = function Montgomery(m) {
this.m = m;
this.mp = m.invDigit();
this.mpl = this.mp & 0x7fff;
this.mph = this.mp >> 15;
this.um = (1 << (m.DB - 15)) - 1;
this.mt2 = 2 * m.t;
}
// xR mod m
Montgomery.prototype.convert = function (x) {
var r = nbi();
x.abs().dlShiftTo(this.m.t, r);
r.divRemTo(this.m, null, r);
if (x.s < 0 && r.compareTo(BigInteger.ZERO) > 0) this.m.subTo(r, r);
return r;
}
// x/R mod m
Montgomery.prototype.revert = function (x) {
var r = nbi();
x.copyTo(r);
this.reduce(r);
return r;
};
// x = x/R mod m (HAC 14.32)
Montgomery.prototype.reduce = function (x) {
while (x.t <= this.mt2) // pad x so am has enough room later
x[x.t++] = 0;
for (var i = 0; i < this.m.t; ++i) {
// faster way of calculating u0 = x[i]*mp mod DV
var j = x[i] & 0x7fff;
var u0 = (j * this.mpl + (((j * this.mph + (x[i] >> 15) * this.mpl) & this.um) << 15)) & x.DM;
// use am to combine the multiply-shift-add into one call
j = i + this.m.t;
x[j] += this.m.am(0, u0, x, i, 0, this.m.t);
// propagate carry
while (x[j] >= x.DV) {
x[j] -= x.DV;
x[++j]++;
}
}
x.clamp();
x.drShiftTo(this.m.t, x);
if (x.compareTo(this.m) >= 0) x.subTo(this.m, x);
};
// r = "xy/R mod m"; x,y != r
Montgomery.prototype.mulTo = function (x, y, r) {
x.multiplyTo(y, r);
this.reduce(r);
};
// r = "x^2/R mod m"; x != r
Montgomery.prototype.sqrTo = function (x, r) {
x.squareTo(r);
this.reduce(r);
};
// A "null" reducer
var NullExp = window.NullExp = function NullExp() {}
NullExp.prototype.convert = function (x) {
return x;
};
NullExp.prototype.revert = function (x) {
return x;
};
NullExp.prototype.mulTo = function (x, y, r) {
x.multiplyTo(y, r);
};
NullExp.prototype.sqrTo = function (x, r) {
x.squareTo(r);
};
// Barrett modular reduction
var Barrett = window.Barrett = function Barrett(m) {
// setup Barrett
this.r2 = nbi();
this.q3 = nbi();
BigInteger.ONE.dlShiftTo(2 * m.t, this.r2);
this.mu = this.r2.divide(m);
this.m = m;
}
Barrett.prototype.convert = function (x) {
if (x.s < 0 || x.t > 2 * this.m.t) return x.mod(this.m);
else if (x.compareTo(this.m) < 0) return x;
else {
var r = nbi();
x.copyTo(r);
this.reduce(r);
return r;
}
};
Barrett.prototype.revert = function (x) {
return x;
};
// x = x mod m (HAC 14.42)
Barrett.prototype.reduce = function (x) {
x.drShiftTo(this.m.t - 1, this.r2);
if (x.t > this.m.t + 1) {
x.t = this.m.t + 1;
x.clamp();
}
this.mu.multiplyUpperTo(this.r2, this.m.t + 1, this.q3);
this.m.multiplyLowerTo(this.q3, this.m.t + 1, this.r2);
while (x.compareTo(this.r2) < 0) x.dAddOffset(1, this.m.t + 1);
x.subTo(this.r2, x);
while (x.compareTo(this.m) >= 0) x.subTo(this.m, x);
};
// r = x*y mod m; x,y != r
Barrett.prototype.mulTo = function (x, y, r) {
x.multiplyTo(y, r);
this.reduce(r);
};
// r = x^2 mod m; x != r
Barrett.prototype.sqrTo = function (x, r) {
x.squareTo(r);
this.reduce(r);
};
})();
</script>
<script type="text/javascript">
//---------------------------------------------------------------------
// QRCode for JavaScript
//
// Copyright (c) 2009 Kazuhiko Arase
//
// URL: http://www.d-project.com/
//
// Licensed under the MIT license:
// http://www.opensource.org/licenses/mit-license.php
//
// The word "QR Code" is registered trademark of
// DENSO WAVE INCORPORATED
// http://www.denso-wave.com/qrcode/faqpatent-e.html
//
//---------------------------------------------------------------------
(function () {
//---------------------------------------------------------------------
// QRCode
//---------------------------------------------------------------------
var QRCode = window.QRCode = function (typeNumber, errorCorrectLevel) {
this.typeNumber = typeNumber;
this.errorCorrectLevel = errorCorrectLevel;
this.modules = null;
this.moduleCount = 0;
this.dataCache = null;
this.dataList = new Array();
}
QRCode.prototype = {
addData: function (data) {
var newData = new QRCode.QR8bitByte(data);
this.dataList.push(newData);
this.dataCache = null;
},
isDark: function (row, col) {
if (row < 0 || this.moduleCount <= row || col < 0 || this.moduleCount <= col) {
throw new Error(row + "," + col);
}
return this.modules[row][col];
},
getModuleCount: function () {
return this.moduleCount;
},
make: function () {
this.makeImpl(false, this.getBestMaskPattern());
},
makeImpl: function (test, maskPattern) {
this.moduleCount = this.typeNumber * 4 + 17;
this.modules = new Array(this.moduleCount);
for (var row = 0; row < this.moduleCount; row++) {
this.modules[row] = new Array(this.moduleCount);
for (var col = 0; col < this.moduleCount; col++) {
this.modules[row][col] = null; //(col + row) % 3;
}
}
this.setupPositionProbePattern(0, 0);
this.setupPositionProbePattern(this.moduleCount - 7, 0);
this.setupPositionProbePattern(0, this.moduleCount - 7);
this.setupPositionAdjustPattern();
this.setupTimingPattern();
this.setupTypeInfo(test, maskPattern);
if (this.typeNumber >= 7) {
this.setupTypeNumber(test);
}
if (this.dataCache == null) {
this.dataCache = QRCode.createData(this.typeNumber, this.errorCorrectLevel, this.dataList);
}
this.mapData(this.dataCache, maskPattern);
},
setupPositionProbePattern: function (row, col) {
for (var r = -1; r <= 7; r++) {
if (row + r <= -1 || this.moduleCount <= row + r) continue;
for (var c = -1; c <= 7; c++) {
if (col + c <= -1 || this.moduleCount <= col + c) continue;
if ((0 <= r && r <= 6 && (c == 0 || c == 6)) ||
(0 <= c && c <= 6 && (r == 0 || r == 6)) ||
(2 <= r && r <= 4 && 2 <= c && c <= 4)) {
this.modules[row + r][col + c] = true;
} else {
this.modules[row + r][col + c] = false;
}
}
}
},
getBestMaskPattern: function () {
var minLostPoint = 0;
var pattern = 0;
for (var i = 0; i < 8; i++) {
this.makeImpl(true, i);
var lostPoint = QRCode.Util.getLostPoint(this);
if (i == 0 || minLostPoint > lostPoint) {
minLostPoint = lostPoint;
pattern = i;
}
}
return pattern;
},
createMovieClip: function (target_mc, instance_name, depth) {
var qr_mc = target_mc.createEmptyMovieClip(instance_name, depth);
var cs = 1;
this.make();
for (var row = 0; row < this.modules.length; row++) {
var y = row * cs;
for (var col = 0; col < this.modules[row].length; col++) {
var x = col * cs;
var dark = this.modules[row][col];
if (dark) {
qr_mc.beginFill(0, 100);
qr_mc.moveTo(x, y);
qr_mc.lineTo(x + cs, y);
qr_mc.lineTo(x + cs, y + cs);
qr_mc.lineTo(x, y + cs);
qr_mc.endFill();
}
}
}
return qr_mc;
},
setupTimingPattern: function () {
for (var r = 8; r < this.moduleCount - 8; r++) {
if (this.modules[r][6] != null) {
continue;
}
this.modules[r][6] = (r % 2 == 0);
}
for (var c = 8; c < this.moduleCount - 8; c++) {
if (this.modules[6][c] != null) {
continue;
}
this.modules[6][c] = (c % 2 == 0);
}
},
setupPositionAdjustPattern: function () {
var pos = QRCode.Util.getPatternPosition(this.typeNumber);
for (var i = 0; i < pos.length; i++) {
for (var j = 0; j < pos.length; j++) {
var row = pos[i];
var col = pos[j];
if (this.modules[row][col] != null) {
continue;
}
for (var r = -2; r <= 2; r++) {
for (var c = -2; c <= 2; c++) {
if (r == -2 || r == 2 || c == -2 || c == 2 ||
(r == 0 && c == 0)) {
this.modules[row + r][col + c] = true;
} else {
this.modules[row + r][col + c] = false;
}
}
}
}
}
},
setupTypeNumber: function (test) {
var bits = QRCode.Util.getBCHTypeNumber(this.typeNumber);
for (var i = 0; i < 18; i++) {
var mod = (!test && ((bits >> i) & 1) == 1);
this.modules[Math.floor(i / 3)][i % 3 + this.moduleCount - 8 - 3] = mod;
}
for (var i = 0; i < 18; i++) {
var mod = (!test && ((bits >> i) & 1) == 1);
this.modules[i % 3 + this.moduleCount - 8 - 3][Math.floor(i / 3)] = mod;
}
},
setupTypeInfo: function (test, maskPattern) {
var data = (this.errorCorrectLevel << 3) | maskPattern;
var bits = QRCode.Util.getBCHTypeInfo(data);
// vertical
for (var i = 0; i < 15; i++) {
var mod = (!test && ((bits >> i) & 1) == 1);
if (i < 6) {
this.modules[i][8] = mod;
} else if (i < 8) {
this.modules[i + 1][8] = mod;
} else {
this.modules[this.moduleCount - 15 + i][8] = mod;
}
}
// horizontal
for (var i = 0; i < 15; i++) {
var mod = (!test && ((bits >> i) & 1) == 1);
if (i < 8) {
this.modules[8][this.moduleCount - i - 1] = mod;
} else if (i < 9) {
this.modules[8][15 - i - 1 + 1] = mod;
} else {
this.modules[8][15 - i - 1] = mod;
}
}
// fixed module
this.modules[this.moduleCount - 8][8] = (!test);
},
mapData: function (data, maskPattern) {
var inc = -1;
var row = this.moduleCount - 1;
var bitIndex = 7;
var byteIndex = 0;
for (var col = this.moduleCount - 1; col > 0; col -= 2) {
if (col == 6) col--;
while (true) {
for (var c = 0; c < 2; c++) {
if (this.modules[row][col - c] == null) {
var dark = false;
if (byteIndex < data.length) {
dark = (((data[byteIndex] >>> bitIndex) & 1) == 1);
}
var mask = QRCode.Util.getMask(maskPattern, row, col - c);
if (mask) {
dark = !dark;
}
this.modules[row][col - c] = dark;
bitIndex--;
if (bitIndex == -1) {
byteIndex++;
bitIndex = 7;
}
}
}
row += inc;
if (row < 0 || this.moduleCount <= row) {
row -= inc;
inc = -inc;
break;
}
}
}
}
};
QRCode.PAD0 = 0xEC;
QRCode.PAD1 = 0x11;
QRCode.createData = function (typeNumber, errorCorrectLevel, dataList) {
var rsBlocks = QRCode.RSBlock.getRSBlocks(typeNumber, errorCorrectLevel);
var buffer = new QRCode.BitBuffer();
for (var i = 0; i < dataList.length; i++) {
var data = dataList[i];
buffer.put(data.mode, 4);
buffer.put(data.getLength(), QRCode.Util.getLengthInBits(data.mode, typeNumber));
data.write(buffer);
}
// calc num max data.
var totalDataCount = 0;
for (var i = 0; i < rsBlocks.length; i++) {
totalDataCount += rsBlocks[i].dataCount;
}
if (buffer.getLengthInBits() > totalDataCount * 8) {
throw new Error("code length overflow. (" +
buffer.getLengthInBits() +
">" +
totalDataCount * 8 +
")");
}
// end code
if (buffer.getLengthInBits() + 4 <= totalDataCount * 8) {
buffer.put(0, 4);
}
// padding
while (buffer.getLengthInBits() % 8 != 0) {
buffer.putBit(false);
}
// padding
while (true) {
if (buffer.getLengthInBits() >= totalDataCount * 8) {
break;
}
buffer.put(QRCode.PAD0, 8);
if (buffer.getLengthInBits() >= totalDataCount * 8) {
break;
}
buffer.put(QRCode.PAD1, 8);
}
return QRCode.createBytes(buffer, rsBlocks);
};
QRCode.createBytes = function (buffer, rsBlocks) {
var offset = 0;
var maxDcCount = 0;
var maxEcCount = 0;
var dcdata = new Array(rsBlocks.length);
var ecdata = new Array(rsBlocks.length);
for (var r = 0; r < rsBlocks.length; r++) {
var dcCount = rsBlocks[r].dataCount;
var ecCount = rsBlocks[r].totalCount - dcCount;
maxDcCount = Math.max(maxDcCount, dcCount);
maxEcCount = Math.max(maxEcCount, ecCount);
dcdata[r] = new Array(dcCount);
for (var i = 0; i < dcdata[r].length; i++) {
dcdata[r][i] = 0xff & buffer.buffer[i + offset];
}
offset += dcCount;
var rsPoly = QRCode.Util.getErrorCorrectPolynomial(ecCount);
var rawPoly = new QRCode.Polynomial(dcdata[r], rsPoly.getLength() - 1);
var modPoly = rawPoly.mod(rsPoly);
ecdata[r] = new Array(rsPoly.getLength() - 1);
for (var i = 0; i < ecdata[r].length; i++) {
var modIndex = i + modPoly.getLength() - ecdata[r].length;
ecdata[r][i] = (modIndex >= 0) ? modPoly.get(modIndex) : 0;
}
}
var totalCodeCount = 0;
for (var i = 0; i < rsBlocks.length; i++) {
totalCodeCount += rsBlocks[i].totalCount;
}
var data = new Array(totalCodeCount);
var index = 0;
for (var i = 0; i < maxDcCount; i++) {
for (var r = 0; r < rsBlocks.length; r++) {
if (i < dcdata[r].length) {
data[index++] = dcdata[r][i];
}
}
}
for (var i = 0; i < maxEcCount; i++) {
for (var r = 0; r < rsBlocks.length; r++) {
if (i < ecdata[r].length) {
data[index++] = ecdata[r][i];
}
}
}
return data;
};
//---------------------------------------------------------------------
// QR8bitByte
//---------------------------------------------------------------------
QRCode.QR8bitByte = function (data) {
this.mode = QRCode.Mode.MODE_8BIT_BYTE;
this.data = data;
}
QRCode.QR8bitByte.prototype = {
getLength: function (buffer) {
return this.data.length;
},
write: function (buffer) {
for (var i = 0; i < this.data.length; i++) {
// not JIS ...
buffer.put(this.data.charCodeAt(i), 8);
}
}
};
//---------------------------------------------------------------------
// QRMode
//---------------------------------------------------------------------
QRCode.Mode = {
MODE_NUMBER: 1 << 0,
MODE_ALPHA_NUM: 1 << 1,
MODE_8BIT_BYTE: 1 << 2,
MODE_KANJI: 1 << 3
};
//---------------------------------------------------------------------
// QRErrorCorrectLevel
//---------------------------------------------------------------------
QRCode.ErrorCorrectLevel = {
L: 1,
M: 0,
Q: 3,
H: 2
};
//---------------------------------------------------------------------
// QRMaskPattern
//---------------------------------------------------------------------
QRCode.MaskPattern = {
PATTERN000: 0,
PATTERN001: 1,
PATTERN010: 2,
PATTERN011: 3,
PATTERN100: 4,
PATTERN101: 5,
PATTERN110: 6,
PATTERN111: 7
};
//---------------------------------------------------------------------
// QRUtil
//---------------------------------------------------------------------
QRCode.Util = {
PATTERN_POSITION_TABLE: [
[],
[6, 18],
[6, 22],
[6, 26],
[6, 30],
[6, 34],
[6, 22, 38],
[6, 24, 42],
[6, 26, 46],
[6, 28, 50],
[6, 30, 54],
[6, 32, 58],
[6, 34, 62],
[6, 26, 46, 66],
[6, 26, 48, 70],
[6, 26, 50, 74],
[6, 30, 54, 78],
[6, 30, 56, 82],
[6, 30, 58, 86],
[6, 34, 62, 90],
[6, 28, 50, 72, 94],
[6, 26, 50, 74, 98],
[6, 30, 54, 78, 102],
[6, 28, 54, 80, 106],
[6, 32, 58, 84, 110],
[6, 30, 58, 86, 114],
[6, 34, 62, 90, 118],
[6, 26, 50, 74, 98, 122],
[6, 30, 54, 78, 102, 126],
[6, 26, 52, 78, 104, 130],
[6, 30, 56, 82, 108, 134],
[6, 34, 60, 86, 112, 138],
[6, 30, 58, 86, 114, 142],
[6, 34, 62, 90, 118, 146],
[6, 30, 54, 78, 102, 126, 150],
[6, 24, 50, 76, 102, 128, 154],
[6, 28, 54, 80, 106, 132, 158],
[6, 32, 58, 84, 110, 136, 162],
[6, 26, 54, 82, 110, 138, 166],
[6, 30, 58, 86, 114, 142, 170]
],
G15: (1 << 10) | (1 << 8) | (1 << 5) | (1 << 4) | (1 << 2) | (1 << 1) | (1 << 0),
G18: (1 << 12) | (1 << 11) | (1 << 10) | (1 << 9) | (1 << 8) | (1 << 5) | (1 << 2) | (1 << 0),
G15_MASK: (1 << 14) | (1 << 12) | (1 << 10) | (1 << 4) | (1 << 1),
getBCHTypeInfo: function (data) {
var d = data << 10;
while (QRCode.Util.getBCHDigit(d) - QRCode.Util.getBCHDigit(QRCode.Util.G15) >= 0) {
d ^= (QRCode.Util.G15 << (QRCode.Util.getBCHDigit(d) - QRCode.Util.getBCHDigit(
QRCode.Util
.G15)));
}
return ((data << 10) | d) ^ QRCode.Util.G15_MASK;
},
getBCHTypeNumber: function (data) {
var d = data << 12;
while (QRCode.Util.getBCHDigit(d) - QRCode.Util.getBCHDigit(QRCode.Util.G18) >= 0) {
d ^= (QRCode.Util.G18 << (QRCode.Util.getBCHDigit(d) - QRCode.Util.getBCHDigit(
QRCode.Util
.G18)));
}
return (data << 12) | d;
},
getBCHDigit: function (data) {
var digit = 0;
while (data != 0) {
digit++;
data >>>= 1;
}
return digit;
},
getPatternPosition: function (typeNumber) {
return QRCode.Util.PATTERN_POSITION_TABLE[typeNumber - 1];
},
getMask: function (maskPattern, i, j) {
switch (maskPattern) {
case QRCode.MaskPattern.PATTERN000:
return (i + j) % 2 == 0;
case QRCode.MaskPattern.PATTERN001:
return i % 2 == 0;
case QRCode.MaskPattern.PATTERN010:
return j % 3 == 0;
case QRCode.MaskPattern.PATTERN011:
return (i + j) % 3 == 0;
case QRCode.MaskPattern.PATTERN100:
return (Math.floor(i / 2) + Math.floor(j / 3)) % 2 == 0;
case QRCode.MaskPattern.PATTERN101:
return (i * j) % 2 + (i * j) % 3 == 0;
case QRCode.MaskPattern.PATTERN110:
return ((i * j) % 2 + (i * j) % 3) % 2 == 0;
case QRCode.MaskPattern.PATTERN111:
return ((i * j) % 3 + (i + j) % 2) % 2 == 0;
default:
throw new Error("bad maskPattern:" + maskPattern);
}
},
getErrorCorrectPolynomial: function (errorCorrectLength) {
var a = new QRCode.Polynomial([1], 0);
for (var i = 0; i < errorCorrectLength; i++) {
a = a.multiply(new QRCode.Polynomial([1, QRCode.Math.gexp(i)], 0));
}
return a;
},
getLengthInBits: function (mode, type) {
if (1 <= type && type < 10) {
// 1 - 9
switch (mode) {
case QRCode.Mode.MODE_NUMBER:
return 10;
case QRCode.Mode.MODE_ALPHA_NUM:
return 9;
case QRCode.Mode.MODE_8BIT_BYTE:
return 8;
case QRCode.Mode.MODE_KANJI:
return 8;
default:
throw new Error("mode:" + mode);
}
} else if (type < 27) {
// 10 - 26
switch (mode) {
case QRCode.Mode.MODE_NUMBER:
return 12;
case QRCode.Mode.MODE_ALPHA_NUM:
return 11;
case QRCode.Mode.MODE_8BIT_BYTE:
return 16;
case QRCode.Mode.MODE_KANJI:
return 10;
default:
throw new Error("mode:" + mode);
}
} else if (type < 41) {
// 27 - 40
switch (mode) {
case QRCode.Mode.MODE_NUMBER:
return 14;
case QRCode.Mode.MODE_ALPHA_NUM:
return 13;
case QRCode.Mode.MODE_8BIT_BYTE:
return 16;
case QRCode.Mode.MODE_KANJI:
return 12;
default:
throw new Error("mode:" + mode);
}
} else {
throw new Error("type:" + type);
}
},
getLostPoint: function (qrCode) {
var moduleCount = qrCode.getModuleCount();
var lostPoint = 0;
// LEVEL1
for (var row = 0; row < moduleCount; row++) {
for (var col = 0; col < moduleCount; col++) {
var sameCount = 0;
var dark = qrCode.isDark(row, col);
for (var r = -1; r <= 1; r++) {
if (row + r < 0 || moduleCount <= row + r) {
continue;
}
for (var c = -1; c <= 1; c++) {
if (col + c < 0 || moduleCount <= col + c) {
continue;
}
if (r == 0 && c == 0) {
continue;
}
if (dark == qrCode.isDark(row + r, col + c)) {
sameCount++;
}
}
}
if (sameCount > 5) {
lostPoint += (3 + sameCount - 5);
}
}
}
// LEVEL2
for (var row = 0; row < moduleCount - 1; row++) {
for (var col = 0; col < moduleCount - 1; col++) {
var count = 0;
if (qrCode.isDark(row, col)) count++;
if (qrCode.isDark(row + 1, col)) count++;
if (qrCode.isDark(row, col + 1)) count++;
if (qrCode.isDark(row + 1, col + 1)) count++;
if (count == 0 || count == 4) {
lostPoint += 3;
}
}
}
// LEVEL3
for (var row = 0; row < moduleCount; row++) {
for (var col = 0; col < moduleCount - 6; col++) {
if (qrCode.isDark(row, col) &&
!qrCode.isDark(row, col + 1) &&
qrCode.isDark(row, col + 2) &&
qrCode.isDark(row, col + 3) &&
qrCode.isDark(row, col + 4) &&
!qrCode.isDark(row, col + 5) &&
qrCode.isDark(row, col + 6)) {
lostPoint += 40;
}
}
}
for (var col = 0; col < moduleCount; col++) {
for (var row = 0; row < moduleCount - 6; row++) {
if (qrCode.isDark(row, col) &&
!qrCode.isDark(row + 1, col) &&
qrCode.isDark(row + 2, col) &&
qrCode.isDark(row + 3, col) &&
qrCode.isDark(row + 4, col) &&
!qrCode.isDark(row + 5, col) &&
qrCode.isDark(row + 6, col)) {
lostPoint += 40;
}
}
}
// LEVEL4
var darkCount = 0;
for (var col = 0; col < moduleCount; col++) {
for (var row = 0; row < moduleCount; row++) {
if (qrCode.isDark(row, col)) {
darkCount++;
}
}
}
var ratio = Math.abs(100 * darkCount / moduleCount / moduleCount - 50) / 5;
lostPoint += ratio * 10;
return lostPoint;
}
};
//---------------------------------------------------------------------
// QRMath
//---------------------------------------------------------------------
QRCode.Math = {
glog: function (n) {
if (n < 1) {
throw new Error("glog(" + n + ")");
}
return QRCode.Math.LOG_TABLE[n];
},
gexp: function (n) {
while (n < 0) {
n += 255;
}
while (n >= 256) {
n -= 255;
}
return QRCode.Math.EXP_TABLE[n];
},
EXP_TABLE: new Array(256),
LOG_TABLE: new Array(256)
};
for (var i = 0; i < 8; i++) {
QRCode.Math.EXP_TABLE[i] = 1 << i;
}
for (var i = 8; i < 256; i++) {
QRCode.Math.EXP_TABLE[i] = QRCode.Math.EXP_TABLE[i - 4] ^
QRCode.Math.EXP_TABLE[i - 5] ^
QRCode.Math.EXP_TABLE[i - 6] ^
QRCode.Math.EXP_TABLE[i - 8];
}
for (var i = 0; i < 255; i++) {
QRCode.Math.LOG_TABLE[QRCode.Math.EXP_TABLE[i]] = i;
}
//---------------------------------------------------------------------
// QRPolynomial
//---------------------------------------------------------------------
QRCode.Polynomial = function (num, shift) {
if (num.length == undefined) {
throw new Error(num.length + "/" + shift);
}
var offset = 0;
while (offset < num.length && num[offset] == 0) {
offset++;
}
this.num = new Array(num.length - offset + shift);
for (var i = 0; i < num.length - offset; i++) {
this.num[i] = num[i + offset];
}
}
QRCode.Polynomial.prototype = {
get: function (index) {
return this.num[index];
},
getLength: function () {
return this.num.length;
},
multiply: function (e) {
var num = new Array(this.getLength() + e.getLength() - 1);
for (var i = 0; i < this.getLength(); i++) {
for (var j = 0; j < e.getLength(); j++) {
num[i + j] ^= QRCode.Math.gexp(QRCode.Math.glog(this.get(i)) + QRCode.Math.glog(
e.get(
j)));
}
}
return new QRCode.Polynomial(num, 0);
},
mod: function (e) {
if (this.getLength() - e.getLength() < 0) {
return this;
}
var ratio = QRCode.Math.glog(this.get(0)) - QRCode.Math.glog(e.get(0));
var num = new Array(this.getLength());
for (var i = 0; i < this.getLength(); i++) {
num[i] = this.get(i);
}
for (var i = 0; i < e.getLength(); i++) {
num[i] ^= QRCode.Math.gexp(QRCode.Math.glog(e.get(i)) + ratio);
}
// recursive call
return new QRCode.Polynomial(num, 0).mod(e);
}
};
//---------------------------------------------------------------------
// QRRSBlock
//---------------------------------------------------------------------
QRCode.RSBlock = function (totalCount, dataCount) {
this.totalCount = totalCount;
this.dataCount = dataCount;
}
QRCode.RSBlock.RS_BLOCK_TABLE = [
// L
// M
// Q
// H
// 1
[1, 26, 19],
[1, 26, 16],
[1, 26, 13],
[1, 26, 9],
// 2
[1, 44, 34],
[1, 44, 28],
[1, 44, 22],
[1, 44, 16],
// 3
[1, 70, 55],
[1, 70, 44],
[2, 35, 17],
[2, 35, 13],
// 4
[1, 100, 80],
[2, 50, 32],
[2, 50, 24],
[4, 25, 9],
// 5
[1, 134, 108],
[2, 67, 43],
[2, 33, 15, 2, 34, 16],
[2, 33, 11, 2, 34, 12],
// 6
[2, 86, 68],
[4, 43, 27],
[4, 43, 19],
[4, 43, 15],
// 7
[2, 98, 78],
[4, 49, 31],
[2, 32, 14, 4, 33, 15],
[4, 39, 13, 1, 40, 14],
// 8
[2, 121, 97],
[2, 60, 38, 2, 61, 39],
[4, 40, 18, 2, 41, 19],
[4, 40, 14, 2, 41, 15],
// 9
[2, 146, 116],
[3, 58, 36, 2, 59, 37],
[4, 36, 16, 4, 37, 17],
[4, 36, 12, 4, 37, 13],
// 10
[2, 86, 68, 2, 87, 69],
[4, 69, 43, 1, 70, 44],
[6, 43, 19, 2, 44, 20],
[6, 43, 15, 2, 44, 16]
];
QRCode.RSBlock.getRSBlocks = function (typeNumber, errorCorrectLevel) {
var rsBlock = QRCode.RSBlock.getRsBlockTable(typeNumber, errorCorrectLevel);
if (rsBlock == undefined) {
throw new Error("bad rs block @ typeNumber:" + typeNumber + "/errorCorrectLevel:" +
errorCorrectLevel);
}
var length = rsBlock.length / 3;
var list = new Array();
for (var i = 0; i < length; i++) {
var count = rsBlock[i * 3 + 0];
var totalCount = rsBlock[i * 3 + 1];
var dataCount = rsBlock[i * 3 + 2];
for (var j = 0; j < count; j++) {
list.push(new QRCode.RSBlock(totalCount, dataCount));
}
}
return list;
};
QRCode.RSBlock.getRsBlockTable = function (typeNumber, errorCorrectLevel) {
switch (errorCorrectLevel) {
case QRCode.ErrorCorrectLevel.L:
return QRCode.RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 0];
case QRCode.ErrorCorrectLevel.M:
return QRCode.RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 1];
case QRCode.ErrorCorrectLevel.Q:
return QRCode.RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 2];
case QRCode.ErrorCorrectLevel.H:
return QRCode.RSBlock.RS_BLOCK_TABLE[(typeNumber - 1) * 4 + 3];
default:
return undefined;
}
};
//---------------------------------------------------------------------
// QRBitBuffer
//---------------------------------------------------------------------
QRCode.BitBuffer = function () {
this.buffer = new Array();
this.length = 0;
}
QRCode.BitBuffer.prototype = {
get: function (index) {
var bufIndex = Math.floor(index / 8);
return ((this.buffer[bufIndex] >>> (7 - index % 8)) & 1) == 1;
},
put: function (num, length) {
for (var i = 0; i < length; i++) {
this.putBit(((num >>> (length - i - 1)) & 1) == 1);
}
},
getLengthInBits: function () {
return this.length;
},
putBit: function (bit) {
var bufIndex = Math.floor(this.length / 8);
if (this.buffer.length <= bufIndex) {
this.buffer.push(0);
}
if (bit) {
this.buffer[bufIndex] |= (0x80 >>> (this.length % 8));
}
this.length++;
}
};
})();
</script>
<script type="text/javascript">
/*
Copyright (c) 2011 Stefan Thomas
Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*/
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/1a7fc9d063f864058809d06ef4542af40be3558f/src/bitcoin.js
(function (exports) {
var Bitcoin = exports;
})(
'object' === typeof module ? module.exports : (window.Bitcoin = {})
);
</script>
<script type="text/javascript">
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/c952aaeb3ee472e3776655b8ea07299ebed702c7/src/base58.js
(function (Bitcoin) {
Bitcoin.Base58 = {
alphabet: "123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz",
validRegex: /^[1-9A-HJ-NP-Za-km-z]+$/,
base: BigInteger.valueOf(58),
/**
* Convert a byte array to a base58-encoded string.
*
* Written by Mike Hearn for BitcoinJ.
* Copyright (c) 2011 Google Inc.
*
* Ported to JavaScript by Stefan Thomas.
*/
encode: function (input) {
var bi = BigInteger.fromByteArrayUnsigned(input);
var chars = [];
while (bi.compareTo(B58.base) >= 0) {
var mod = bi.mod(B58.base);
chars.unshift(B58.alphabet[mod.intValue()]);
bi = bi.subtract(mod).divide(B58.base);
}
chars.unshift(B58.alphabet[bi.intValue()]);
// Convert leading zeros too.
for (var i = 0; i < input.length; i++) {
if (input[i] == 0x00) {
chars.unshift(B58.alphabet[0]);
} else break;
}
return chars.join('');
},
/**
* Convert a base58-encoded string to a byte array.
*
* Written by Mike Hearn for BitcoinJ.
* Copyright (c) 2011 Google Inc.
*
* Ported to JavaScript by Stefan Thomas.
*/
decode: function (input) {
var bi = BigInteger.valueOf(0);
var leadingZerosNum = 0;
for (var i = input.length - 1; i >= 0; i--) {
var alphaIndex = B58.alphabet.indexOf(input[i]);
if (alphaIndex < 0) {
throw "Invalid character";
}
bi = bi.add(BigInteger.valueOf(alphaIndex)
.multiply(B58.base.pow(input.length - 1 - i)));
// This counts leading zero bytes
if (input[i] == "1") leadingZerosNum++;
else leadingZerosNum = 0;
}
var bytes = bi.toByteArrayUnsigned();
// Add leading zeros
while (leadingZerosNum-- > 0) bytes.unshift(0);
return bytes;
}
};
var B58 = Bitcoin.Base58;
})(
'undefined' != typeof Bitcoin ? Bitcoin : module.exports
);
</script>
<script type="text/javascript">
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/09e8c6e184d6501a0c2c59d73ca64db5c0d3eb95/src/address.js
Bitcoin.Address = function (bytes, networkVersion) {
if ("string" == typeof bytes) {
bytes = Bitcoin.Address.decodeString(bytes);
}
this.hash = bytes;
// changesMadeByAbhishek: add networkVersion dynamically
//this.version = Bitcoin.Address.networkVersion;
this.version = networkVersion;
};
//Bitcoin.Address.networkVersion = 0x23; // (FLO mainnet 0x23, 35D), (Bitcoin Mainnet, 0x00, 0D)
//Bitcoin.Address.networkVersion = 0x73; // (FLO mainnet 0x23, 35D), (Bitcoin Mainnet, 0x00, 0D)
/**
* Serialize this object as a standard Bitcoin address.
*
* Returns the address as a base58-encoded string in the standardized format.
*/
Bitcoin.Address.prototype.toString = function () {
// Get a copy of the hash
var hash = this.hash.slice(0);
// Version
hash.unshift(this.version);
var checksum = Crypto.SHA256(Crypto.SHA256(hash, {
asBytes: true
}), {
asBytes: true
});
var bytes = hash.concat(checksum.slice(0, 4));
return Bitcoin.Base58.encode(bytes);
};
Bitcoin.Address.prototype.getHashBase64 = function () {
return Crypto.util.bytesToBase64(this.hash);
};
/**
* Parse a Bitcoin address contained in a string.
*/
Bitcoin.Address.decodeString = function (string) {
var bytes = Bitcoin.Base58.decode(string);
var hash = bytes.slice(0, 21);
var checksum = Crypto.SHA256(Crypto.SHA256(hash, {
asBytes: true
}), {
asBytes: true
});
if (checksum[0] != bytes[21] ||
checksum[1] != bytes[22] ||
checksum[2] != bytes[23] ||
checksum[3] != bytes[24]) {
throw "Checksum validation failed!";
}
var version = hash.shift();
if (version != 0) {
throw "Version " + version + " not supported!";
}
return hash;
};
</script>
<script type="text/javascript">
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/e90780d3d3b8fc0d027d2bcb38b80479902f223e/src/ecdsa.js
Bitcoin.ECDSA = (function () {
var ecparams = EllipticCurve.getSECCurveByName("secp256k1");
var rng = new SecureRandom();
var P_OVER_FOUR = null;
function implShamirsTrick(P, k, Q, l) {
var m = Math.max(k.bitLength(), l.bitLength());
var Z = P.add2D(Q);
var R = P.curve.getInfinity();
for (var i = m - 1; i >= 0; --i) {
R = R.twice2D();
R.z = BigInteger.ONE;
if (k.testBit(i)) {
if (l.testBit(i)) {
R = R.add2D(Z);
} else {
R = R.add2D(P);
}
} else {
if (l.testBit(i)) {
R = R.add2D(Q);
}
}
}
return R;
};
var ECDSA = {
getBigRandom: function (limit) {
return new BigInteger(limit.bitLength(), rng)
.mod(limit.subtract(BigInteger.ONE))
.add(BigInteger.ONE);
},
sign: function (hash, priv) {
var d = priv;
var n = ecparams.getN();
var e = BigInteger.fromByteArrayUnsigned(hash);
do {
var k = ECDSA.getBigRandom(n);
var G = ecparams.getG();
var Q = G.multiply(k);
var r = Q.getX().toBigInteger().mod(n);
} while (r.compareTo(BigInteger.ZERO) <= 0);
var s = k.modInverse(n).multiply(e.add(d.multiply(r))).mod(n);
return ECDSA.serializeSig(r, s);
},
verify: function (hash, sig, pubkey) {
var r, s;
if (Bitcoin.Util.isArray(sig)) {
var obj = ECDSA.parseSig(sig);
r = obj.r;
s = obj.s;
} else if ("object" === typeof sig && sig.r && sig.s) {
r = sig.r;
s = sig.s;
} else {
throw "Invalid value for signature";
}
var Q;
if (pubkey instanceof ec.PointFp) {
Q = pubkey;
} else if (Bitcoin.Util.isArray(pubkey)) {
Q = EllipticCurve.PointFp.decodeFrom(ecparams.getCurve(), pubkey);
} else {
throw "Invalid format for pubkey value, must be byte array or ec.PointFp";
}
var e = BigInteger.fromByteArrayUnsigned(hash);
return ECDSA.verifyRaw(e, r, s, Q);
},
verifyRaw: function (e, r, s, Q) {
var n = ecparams.getN();
var G = ecparams.getG();
if (r.compareTo(BigInteger.ONE) < 0 ||
r.compareTo(n) >= 0)
return false;
if (s.compareTo(BigInteger.ONE) < 0 ||
s.compareTo(n) >= 0)
return false;
var c = s.modInverse(n);
var u1 = e.multiply(c).mod(n);
var u2 = r.multiply(c).mod(n);
// TODO(!!!): For some reason Shamir's trick isn't working with
// signed message verification!? Probably an implementation
// error!
//var point = implShamirsTrick(G, u1, Q, u2);
var point = G.multiply(u1).add(Q.multiply(u2));
var v = point.getX().toBigInteger().mod(n);
return v.equals(r);
},
/**
* Serialize a signature into DER format.
*
* Takes two BigIntegers representing r and s and returns a byte array.
*/
serializeSig: function (r, s) {
var rBa = r.toByteArraySigned();
var sBa = s.toByteArraySigned();
var sequence = [];
sequence.push(0x02); // INTEGER
sequence.push(rBa.length);
sequence = sequence.concat(rBa);
sequence.push(0x02); // INTEGER
sequence.push(sBa.length);
sequence = sequence.concat(sBa);
sequence.unshift(sequence.length);
sequence.unshift(0x30); // SEQUENCE
return sequence;
},
/**
* Parses a byte array containing a DER-encoded signature.
*
* This function will return an object of the form:
*
* {
* r: BigInteger,
* s: BigInteger
* }
*/
parseSig: function (sig) {
var cursor;
if (sig[0] != 0x30)
throw new Error("Signature not a valid DERSequence");
cursor = 2;
if (sig[cursor] != 0x02)
throw new Error("First element in signature must be a DERInteger");;
var rBa = sig.slice(cursor + 2, cursor + 2 + sig[cursor + 1]);
cursor += 2 + sig[cursor + 1];
if (sig[cursor] != 0x02)
throw new Error("Second element in signature must be a DERInteger");
var sBa = sig.slice(cursor + 2, cursor + 2 + sig[cursor + 1]);
cursor += 2 + sig[cursor + 1];
//if (cursor != sig.length)
// throw new Error("Extra bytes in signature");
var r = BigInteger.fromByteArrayUnsigned(rBa);
var s = BigInteger.fromByteArrayUnsigned(sBa);
return {
r: r,
s: s
};
},
parseSigCompact: function (sig) {
if (sig.length !== 65) {
throw "Signature has the wrong length";
}
// Signature is prefixed with a type byte storing three bits of
// information.
var i = sig[0] - 27;
if (i < 0 || i > 7) {
throw "Invalid signature type";
}
var n = ecparams.getN();
var r = BigInteger.fromByteArrayUnsigned(sig.slice(1, 33)).mod(n);
var s = BigInteger.fromByteArrayUnsigned(sig.slice(33, 65)).mod(n);
return {
r: r,
s: s,
i: i
};
},
/**
* Recover a public key from a signature.
*
* See SEC 1: Elliptic Curve Cryptography, section 4.1.6, "Public
* Key Recovery Operation".
*
* http://www.secg.org/download/aid-780/sec1-v2.pdf
*/
recoverPubKey: function (r, s, hash, i) {
// The recovery parameter i has two bits.
i = i & 3;
// The less significant bit specifies whether the y coordinate
// of the compressed point is even or not.
var isYEven = i & 1;
// The more significant bit specifies whether we should use the
// first or second candidate key.
var isSecondKey = i >> 1;
var n = ecparams.getN();
var G = ecparams.getG();
var curve = ecparams.getCurve();
var p = curve.getQ();
var a = curve.getA().toBigInteger();
var b = curve.getB().toBigInteger();
// We precalculate (p + 1) / 4 where p is if the field order
if (!P_OVER_FOUR) {
P_OVER_FOUR = p.add(BigInteger.ONE).divide(BigInteger.valueOf(4));
}
// 1.1 Compute x
var x = isSecondKey ? r.add(n) : r;
// 1.3 Convert x to point
var alpha = x.multiply(x).multiply(x).add(a.multiply(x)).add(b).mod(p);
var beta = alpha.modPow(P_OVER_FOUR, p);
var xorOdd = beta.isEven() ? (i % 2) : ((i + 1) % 2);
// If beta is even, but y isn't or vice versa, then convert it,
// otherwise we're done and y == beta.
var y = (beta.isEven() ? !isYEven : isYEven) ? beta : p.subtract(beta);
// 1.4 Check that nR is at infinity
var R = new EllipticCurve.PointFp(curve,
curve.fromBigInteger(x),
curve.fromBigInteger(y));
R.validate();
// 1.5 Compute e from M
var e = BigInteger.fromByteArrayUnsigned(hash);
var eNeg = BigInteger.ZERO.subtract(e).mod(n);
// 1.6 Compute Q = r^-1 (sR - eG)
var rInv = r.modInverse(n);
var Q = implShamirsTrick(R, s, G, eNeg).multiply(rInv);
Q.validate();
if (!ECDSA.verifyRaw(e, r, s, Q)) {
throw "Pubkey recovery unsuccessful";
}
var pubKey = new Bitcoin.ECKey();
pubKey.pub = Q;
return pubKey;
},
/**
* Calculate pubkey extraction parameter.
*
* When extracting a pubkey from a signature, we have to
* distinguish four different cases. Rather than putting this
* burden on the verifier, Bitcoin includes a 2-bit value with the
* signature.
*
* This function simply tries all four cases and returns the value
* that resulted in a successful pubkey recovery.
*/
calcPubkeyRecoveryParam: function (address, r, s, hash) {
for (var i = 0; i < 4; i++) {
try {
var pubkey = Bitcoin.ECDSA.recoverPubKey(r, s, hash, i);
if (pubkey.getBitcoinAddress().toString() == address) {
return i;
}
} catch (e) {}
}
throw "Unable to find valid recovery factor";
}
};
return ECDSA;
})();
</script>
<script type="text/javascript">
Bitcoin.KeyPool = (function () {
var KeyPool = function () {
this.keyArray = [];
this.push = function (item) {
if (item == null || item.priv == null) return;
var doAdd = true;
// prevent duplicates from being added to the array
for (var index in this.keyArray) {
var currentItem = this.keyArray[index];
if (currentItem != null && currentItem.priv != null && item.getBitcoinAddress() ==
currentItem.getBitcoinAddress()) {
doAdd = false;
break;
}
}
if (doAdd) this.keyArray.push(item);
};
this.reset = function () {
this.keyArray = [];
};
this.getArray = function () {
// copy array
return this.keyArray.slice(0);
};
this.setArray = function (ka) {
this.keyArray = ka;
};
this.length = function () {
return this.keyArray.length;
};
this.toString = function () {
var keyPoolString = "# = " + this.length() + "\n";
var pool = this.getArray();
for (var index in pool) {
var item = pool[index];
if (Bitcoin.Util.hasMethods(item, 'getBitcoinAddress', 'toString')) {
if (item != null) {
keyPoolString += "\"" + item.getBitcoinAddress() + "\"" + ", \"" + item
.toString(
"wif") + "\"\n";
}
}
}
return keyPoolString;
};
return this;
};
return new KeyPool();
})();
Bitcoin.Bip38Key = (function () {
var Bip38 = function (address, encryptedKey) {
this.address = address;
this.priv = encryptedKey;
};
Bip38.prototype.getBitcoinAddress = function () {
return this.address;
};
Bip38.prototype.toString = function () {
return this.priv;
};
return Bip38;
})();
//https://raw.github.com/pointbiz/bitcoinjs-lib/9b2f94a028a7bc9bed94e0722563e9ff1d8e8db8/src/eckey.js
Bitcoin.ECKey = (function () {
var ECDSA = Bitcoin.ECDSA;
var KeyPool = Bitcoin.KeyPool;
var ecparams = EllipticCurve.getSECCurveByName("secp256k1");
var ECKey = function (input) {
if (!input) {
// Generate new key
var n = ecparams.getN();
this.priv = ECDSA.getBigRandom(n);
} else if (input instanceof BigInteger) {
// Input is a private key value
this.priv = input;
} else if (Bitcoin.Util.isArray(input)) {
// Prepend zero byte to prevent interpretation as negative integer
this.priv = BigInteger.fromByteArrayUnsigned(input);
} else if ("string" == typeof input) {
var bytes = null;
try {
if (ECKey.isWalletImportFormat(input)) {
bytes = ECKey.decodeWalletImportFormat(input);
} else if (ECKey.isCompressedWalletImportFormat(input)) {
bytes = ECKey.decodeCompressedWalletImportFormat(input);
this.compressed = true;
} else if (ECKey.isMiniFormat(input)) {
bytes = Crypto.SHA256(input, {
asBytes: true
});
} else if (ECKey.isHexFormat(input)) {
bytes = Crypto.util.hexToBytes(input);
} else if (ECKey.isBase64Format(input)) {
bytes = Crypto.util.base64ToBytes(input);
}
} catch (exc1) {
this.setError(exc1);
}
if (ECKey.isBase6Format(input)) {
this.priv = new BigInteger(input, 6);
} else if (bytes == null || bytes.length != 32) {
this.priv = null;
} else {
// Prepend zero byte to prevent interpretation as negative integer
this.priv = BigInteger.fromByteArrayUnsigned(bytes);
}
}
this.compressed = (this.compressed == undefined) ? !!ECKey.compressByDefault : this.compressed;
try {
// check not zero
if (this.priv != null && BigInteger.ZERO.compareTo(this.priv) == 0) this.setError(
"Error: BigInteger equal to zero.");
// valid range [0x1, 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364140])
var hexKeyRangeLimit =
"FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364140";
var rangeLimitBytes = Crypto.util.hexToBytes(hexKeyRangeLimit);
var limitBigInt = BigInteger.fromByteArrayUnsigned(rangeLimitBytes);
if (this.priv != null && limitBigInt.compareTo(this.priv) < 0) this.setError(
"Error: BigInteger outside of curve range.")
if (this.priv != null) {
KeyPool.push(this);
}
} catch (exc2) {
this.setError(exc2);
}
};
//FLO Mainnet (0xA3) --- FLO Testnet (0xEF)
// changesMadeByAbhishek: Change below line to flo mainnet (0xA3) when deploying
ECKey.privateKeyPrefix = 0xEF; //(Bitcoin mainnet 0x80 testnet 0xEF) (FLO mainnet 0xA3 163 D)
/**
* Whether public keys should be returned compressed by default.
*/
ECKey.compressByDefault = false;
/**
* Set whether the public key should be returned compressed or not.
*/
ECKey.prototype.setError = function (err) {
this.error = err;
this.priv = null;
return this;
};
/**
* Set whether the public key should be returned compressed or not.
*/
ECKey.prototype.setCompressed = function (v) {
this.compressed = !!v;
if (this.pubPoint) this.pubPoint.compressed = this.compressed;
return this;
};
/*
* Return public key as a byte array in DER encoding
*/
ECKey.prototype.getPub = function () {
if (this.compressed) {
if (this.pubComp) return this.pubComp;
return this.pubComp = this.getPubPoint().getEncoded(1);
} else {
if (this.pubUncomp) return this.pubUncomp;
return this.pubUncomp = this.getPubPoint().getEncoded(0);
}
};
/**
* Return public point as ECPoint object.
*/
ECKey.prototype.getPubPoint = function () {
if (!this.pubPoint) {
this.pubPoint = ecparams.getG().multiply(this.priv);
this.pubPoint.compressed = this.compressed;
}
return this.pubPoint;
};
ECKey.prototype.getPubKeyHex = function () {
if (this.compressed) {
if (this.pubKeyHexComp) return this.pubKeyHexComp;
return this.pubKeyHexComp = Crypto.util.bytesToHex(this.getPub()).toString().toUpperCase();
} else {
if (this.pubKeyHexUncomp) return this.pubKeyHexUncomp;
return this.pubKeyHexUncomp = Crypto.util.bytesToHex(this.getPub()).toString().toUpperCase();
}
};
/**
* Get the pubKeyHash for this key.
*
* This is calculated as RIPE160(SHA256([encoded pubkey])) and returned as
* a byte array.
*/
ECKey.prototype.getPubKeyHash = function () {
if (this.compressed) {
if (this.pubKeyHashComp) return this.pubKeyHashComp;
return this.pubKeyHashComp = Bitcoin.Util.sha256ripe160(this.getPub());
} else {
if (this.pubKeyHashUncomp) return this.pubKeyHashUncomp;
return this.pubKeyHashUncomp = Bitcoin.Util.sha256ripe160(this.getPub());
}
};
ECKey.prototype.getBitcoinAddress = function (networkVersion) {
var hash = this.getPubKeyHash();
var addr = new Bitcoin.Address(hash, networkVersion);
return addr.toString();
};
/*
* Takes a public point as a hex string or byte array
*/
ECKey.prototype.setPub = function (pub) {
// byte array
if (Bitcoin.Util.isArray(pub)) {
pub = Crypto.util.bytesToHex(pub).toString().toUpperCase();
}
var ecPoint = ecparams.getCurve().decodePointHex(pub);
this.setCompressed(ecPoint.compressed);
this.pubPoint = ecPoint;
return this;
};
// Sipa Private Key Wallet Import Format
ECKey.prototype.getBitcoinWalletImportFormat = function () {
var bytes = this.getBitcoinPrivateKeyByteArray();
if (bytes == null) return "";
bytes.unshift(ECKey.privateKeyPrefix); // prepend 0x80 byte
if (this.compressed) bytes.push(0x01); // append 0x01 byte for compressed format
var checksum = Crypto.SHA256(Crypto.SHA256(bytes, {
asBytes: true
}), {
asBytes: true
});
bytes = bytes.concat(checksum.slice(0, 4));
var privWif = Bitcoin.Base58.encode(bytes);
return privWif;
};
// Private Key Hex Format
ECKey.prototype.getBitcoinHexFormat = function () {
return Crypto.util.bytesToHex(this.getBitcoinPrivateKeyByteArray()).toString().toUpperCase();
};
// Private Key Base64 Format
ECKey.prototype.getBitcoinBase64Format = function () {
return Crypto.util.bytesToBase64(this.getBitcoinPrivateKeyByteArray());
};
ECKey.prototype.getBitcoinPrivateKeyByteArray = function () {
if (this.priv == null) return null;
// Get a copy of private key as a byte array
var bytes = this.priv.toByteArrayUnsigned();
// zero pad if private key is less than 32 bytes
while (bytes.length < 32) bytes.unshift(0x00);
return bytes;
};
ECKey.prototype.toString = function (format) {
format = format || "";
if (format.toString().toLowerCase() == "base64" || format.toString().toLowerCase() == "b64") {
return this.getBitcoinBase64Format();
}
// Wallet Import Format
else if (format.toString().toLowerCase() == "wif") {
return this.getBitcoinWalletImportFormat();
} else {
return this.getBitcoinHexFormat();
}
};
ECKey.prototype.sign = function (hash) {
return ECDSA.sign(hash, this.priv);
};
ECKey.prototype.verify = function (hash, sig) {
return ECDSA.verify(hash, sig, this.getPub());
};
/**
* Parse a wallet import format private key contained in a string.
*/
ECKey.decodeWalletImportFormat = function (privStr) {
var bytes = Bitcoin.Base58.decode(privStr);
var hash = bytes.slice(0, 33);
var checksum = Crypto.SHA256(Crypto.SHA256(hash, {
asBytes: true
}), {
asBytes: true
});
if (checksum[0] != bytes[33] ||
checksum[1] != bytes[34] ||
checksum[2] != bytes[35] ||
checksum[3] != bytes[36]) {
throw "Checksum validation failed!";
}
var version = hash.shift();
if (version != ECKey.privateKeyPrefix) {
throw "Version " + version + " not supported!";
}
return hash;
};
/**
* Parse a compressed wallet import format private key contained in a string.
*/
ECKey.decodeCompressedWalletImportFormat = function (privStr) {
var bytes = Bitcoin.Base58.decode(privStr);
var hash = bytes.slice(0, 34);
var checksum = Crypto.SHA256(Crypto.SHA256(hash, {
asBytes: true
}), {
asBytes: true
});
if (checksum[0] != bytes[34] ||
checksum[1] != bytes[35] ||
checksum[2] != bytes[36] ||
checksum[3] != bytes[37]) {
throw "Checksum validation failed!";
}
var version = hash.shift();
if (version != ECKey.privateKeyPrefix) {
throw "Version " + version + " not supported!";
}
hash.pop();
return hash;
};
// 64 characters [0-9A-F]
ECKey.isHexFormat = function (key) {
key = key.toString();
return /^[A-Fa-f0-9]{64}$/.test(key);
};
// 51 characters base58, always starts with a '5'
ECKey.isWalletImportFormat = function (key) {
key = key.toString();
return (ECKey.privateKeyPrefix == 0x80) ?
(/^5[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{50}$/.test(key)) :
(/^9[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{50}$/.test(key));
};
// 52 characters base58
ECKey.isCompressedWalletImportFormat = function (key) {
key = key.toString();
return (ECKey.privateKeyPrefix == 0x80) ?
(/^[LK][123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{51}$/.test(key)) :
(/^c[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{51}$/.test(key));
};
// 44 characters
ECKey.isBase64Format = function (key) {
key = key.toString();
return (/^[ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789=+\/]{44}$/.test(
key));
};
// 99 characters, 1=1, if using dice convert 6 to 0
ECKey.isBase6Format = function (key) {
key = key.toString();
return (/^[012345]{99}$/.test(key));
};
// 22, 26 or 30 characters, always starts with an 'S'
ECKey.isMiniFormat = function (key) {
key = key.toString();
var validChars22 = /^S[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{21}$/.test(
key);
var validChars26 = /^S[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{25}$/.test(
key);
var validChars30 = /^S[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{29}$/.test(
key);
var testBytes = Crypto.SHA256(key + "?", {
asBytes: true
});
return ((testBytes[0] === 0x00 || testBytes[0] === 0x01) && (validChars22 || validChars26 ||
validChars30));
};
return ECKey;
})();
</script>
<script type="text/javascript">
//https://raw.github.com/bitcoinjs/bitcoinjs-lib/09e8c6e184d6501a0c2c59d73ca64db5c0d3eb95/src/util.js
// Bitcoin utility functions
Bitcoin.Util = {
/**
* Cross-browser compatibility version of Array.isArray.
*/
isArray: Array.isArray || function (o) {
return Object.prototype.toString.call(o) === '[object Array]';
},
/**
* Create an array of a certain length filled with a specific value.
*/
makeFilledArray: function (len, val) {
var array = [];
var i = 0;
while (i < len) {
array[i++] = val;
}
return array;
},
/**
* Turn an integer into a "var_int".
*
* "var_int" is a variable length integer used by Bitcoin's binary format.
*
* Returns a byte array.
*/
numToVarInt: function (i) {
if (i < 0xfd) {
// unsigned char
return [i];
} else if (i <= 1 << 16) {
// unsigned short (LE)
return [0xfd, i >>> 8, i & 255];
} else if (i <= 1 << 32) {
// unsigned int (LE)
return [0xfe].concat(Crypto.util.wordsToBytes([i]));
} else {
// unsigned long long (LE)
return [0xff].concat(Crypto.util.wordsToBytes([i >>> 32, i]));
}
},
/**
* Parse a Bitcoin value byte array, returning a BigInteger.
*/
valueToBigInt: function (valueBuffer) {
if (valueBuffer instanceof BigInteger) return valueBuffer;
// Prepend zero byte to prevent interpretation as negative integer
return BigInteger.fromByteArrayUnsigned(valueBuffer);
},
/**
* Format a Bitcoin value as a string.
*
* Takes a BigInteger or byte-array and returns that amount of Bitcoins in a
* nice standard formatting.
*
* Examples:
* 12.3555
* 0.1234
* 900.99998888
* 34.00
*/
formatValue: function (valueBuffer) {
var value = this.valueToBigInt(valueBuffer).toString();
var integerPart = value.length > 8 ? value.substr(0, value.length - 8) : '0';
var decimalPart = value.length > 8 ? value.substr(value.length - 8) : value;
while (decimalPart.length < 8) decimalPart = "0" + decimalPart;
decimalPart = decimalPart.replace(/0*$/, '');
while (decimalPart.length < 2) decimalPart += "0";
return integerPart + "." + decimalPart;
},
/**
* Parse a floating point string as a Bitcoin value.
*
* Keep in mind that parsing user input is messy. You should always display
* the parsed value back to the user to make sure we understood his input
* correctly.
*/
parseValue: function (valueString) {
// TODO: Detect other number formats (e.g. comma as decimal separator)
var valueComp = valueString.split('.');
var integralPart = valueComp[0];
var fractionalPart = valueComp[1] || "0";
while (fractionalPart.length < 8) fractionalPart += "0";
fractionalPart = fractionalPart.replace(/^0+/g, '');
var value = BigInteger.valueOf(parseInt(integralPart));
value = value.multiply(BigInteger.valueOf(100000000));
value = value.add(BigInteger.valueOf(parseInt(fractionalPart)));
return value;
},
/**
* Calculate RIPEMD160(SHA256(data)).
*
* Takes an arbitrary byte array as inputs and returns the hash as a byte
* array.
*/
sha256ripe160: function (data) {
return Crypto.RIPEMD160(Crypto.SHA256(data, {
asBytes: true
}), {
asBytes: true
});
},
// double sha256
dsha256: function (data) {
return Crypto.SHA256(Crypto.SHA256(data, {
asBytes: true
}), {
asBytes: true
});
},
// duck typing method
hasMethods: function (obj /*, method list as strings */ ) {
var i = 1,
methodName;
while ((methodName = arguments[i++])) {
if (typeof obj[methodName] != 'function') {
return false;
}
}
return true;
}
};
</script>
<script type="text/javascript">
/*
* Copyright (c) 2010-2011 Intalio Pte, All Rights Reserved
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
// https://github.com/cheongwy/node-scrypt-js
(function () {
var MAX_VALUE = 2147483647;
var workerUrl = null;
//function scrypt(byte[] passwd, byte[] salt, int N, int r, int p, int dkLen)
/*
* N = Cpu cost
* r = Memory cost
* p = parallelization cost
*
*/
window.Crypto_scrypt = function (passwd, salt, N, r, p, dkLen, callback) {
if (N == 0 || (N & (N - 1)) != 0) throw Error("N must be > 0 and a power of 2");
if (N > MAX_VALUE / 128 / r) throw Error("Parameter N is too large");
if (r > MAX_VALUE / 128 / p) throw Error("Parameter r is too large");
var PBKDF2_opts = {
iterations: 1,
hasher: Crypto.SHA256,
asBytes: true
};
var B = Crypto.PBKDF2(passwd, salt, p * 128 * r, PBKDF2_opts);
try {
var i = 0;
var worksDone = 0;
var makeWorker = function () {
if (!workerUrl) {
var code = '(' + scryptCore.toString() + ')()';
var blob;
try {
blob = new Blob([code], {
type: "text/javascript"
});
} catch (e) {
window.BlobBuilder = window.BlobBuilder || window.WebKitBlobBuilder ||
window.MozBlobBuilder ||
window.MSBlobBuilder;
blob = new BlobBuilder();
blob.append(code);
blob = blob.getBlob("text/javascript");
}
workerUrl = URL.createObjectURL(blob);
}
var worker = new Worker(workerUrl);
worker.onmessage = function (event) {
var Bi = event.data[0],
Bslice = event.data[1];
worksDone++;
if (i < p) {
worker.postMessage([N, r, p, B, i++]);
}
var length = Bslice.length,
destPos = Bi * 128 * r,
srcPos = 0;
while (length--) {
B[destPos++] = Bslice[srcPos++];
}
if (worksDone == p) {
callback(Crypto.PBKDF2(passwd, B, dkLen, PBKDF2_opts));
}
};
return worker;
};
var workers = [makeWorker(), makeWorker()];
workers[0].postMessage([N, r, p, B, i++]);
if (p > 1) {
workers[1].postMessage([N, r, p, B, i++]);
}
} catch (e) {
window.setTimeout(function () {
scryptCore();
callback(Crypto.PBKDF2(passwd, B, dkLen, PBKDF2_opts));
}, 0);
}
// using this function to enclose everything needed to create a worker (but also invokable directly for synchronous use)
function scryptCore() {
var XY = [],
V = [];
if (typeof B === 'undefined') {
onmessage = function (event) {
var data = event.data;
var N = data[0],
r = data[1],
p = data[2],
B = data[3],
i = data[4];
var Bslice = [];
arraycopy32(B, i * 128 * r, Bslice, 0, 128 * r);
smix(Bslice, 0, r, N, V, XY);
postMessage([i, Bslice]);
};
} else {
for (var i = 0; i < p; i++) {
smix(B, i * 128 * r, r, N, V, XY);
}
}
function smix(B, Bi, r, N, V, XY) {
var Xi = 0;
var Yi = 128 * r;
var i;
arraycopy32(B, Bi, XY, Xi, Yi);
for (i = 0; i < N; i++) {
arraycopy32(XY, Xi, V, i * Yi, Yi);
blockmix_salsa8(XY, Xi, Yi, r);
}
for (i = 0; i < N; i++) {
var j = integerify(XY, Xi, r) & (N - 1);
blockxor(V, j * Yi, XY, Xi, Yi);
blockmix_salsa8(XY, Xi, Yi, r);
}
arraycopy32(XY, Xi, B, Bi, Yi);
}
function blockmix_salsa8(BY, Bi, Yi, r) {
var X = [];
var i;
arraycopy32(BY, Bi + (2 * r - 1) * 64, X, 0, 64);
for (i = 0; i < 2 * r; i++) {
blockxor(BY, i * 64, X, 0, 64);
salsa20_8(X);
arraycopy32(X, 0, BY, Yi + (i * 64), 64);
}
for (i = 0; i < r; i++) {
arraycopy32(BY, Yi + (i * 2) * 64, BY, Bi + (i * 64), 64);
}
for (i = 0; i < r; i++) {
arraycopy32(BY, Yi + (i * 2 + 1) * 64, BY, Bi + (i + r) * 64, 64);
}
}
function R(a, b) {
return (a << b) | (a >>> (32 - b));
}
function salsa20_8(B) {
var B32 = new Array(32);
var x = new Array(32);
var i;
for (i = 0; i < 16; i++) {
B32[i] = (B[i * 4 + 0] & 0xff) << 0;
B32[i] |= (B[i * 4 + 1] & 0xff) << 8;
B32[i] |= (B[i * 4 + 2] & 0xff) << 16;
B32[i] |= (B[i * 4 + 3] & 0xff) << 24;
}
arraycopy(B32, 0, x, 0, 16);
for (i = 8; i > 0; i -= 2) {
x[4] ^= R(x[0] + x[12], 7);
x[8] ^= R(x[4] + x[0], 9);
x[12] ^= R(x[8] + x[4], 13);
x[0] ^= R(x[12] + x[8], 18);
x[9] ^= R(x[5] + x[1], 7);
x[13] ^= R(x[9] + x[5], 9);
x[1] ^= R(x[13] + x[9], 13);
x[5] ^= R(x[1] + x[13], 18);
x[14] ^= R(x[10] + x[6], 7);
x[2] ^= R(x[14] + x[10], 9);
x[6] ^= R(x[2] + x[14], 13);
x[10] ^= R(x[6] + x[2], 18);
x[3] ^= R(x[15] + x[11], 7);
x[7] ^= R(x[3] + x[15], 9);
x[11] ^= R(x[7] + x[3], 13);
x[15] ^= R(x[11] + x[7], 18);
x[1] ^= R(x[0] + x[3], 7);
x[2] ^= R(x[1] + x[0], 9);
x[3] ^= R(x[2] + x[1], 13);
x[0] ^= R(x[3] + x[2], 18);
x[6] ^= R(x[5] + x[4], 7);
x[7] ^= R(x[6] + x[5], 9);
x[4] ^= R(x[7] + x[6], 13);
x[5] ^= R(x[4] + x[7], 18);
x[11] ^= R(x[10] + x[9], 7);
x[8] ^= R(x[11] + x[10], 9);
x[9] ^= R(x[8] + x[11], 13);
x[10] ^= R(x[9] + x[8], 18);
x[12] ^= R(x[15] + x[14], 7);
x[13] ^= R(x[12] + x[15], 9);
x[14] ^= R(x[13] + x[12], 13);
x[15] ^= R(x[14] + x[13], 18);
}
for (i = 0; i < 16; ++i) B32[i] = x[i] + B32[i];
for (i = 0; i < 16; i++) {
var bi = i * 4;
B[bi + 0] = (B32[i] >> 0 & 0xff);
B[bi + 1] = (B32[i] >> 8 & 0xff);
B[bi + 2] = (B32[i] >> 16 & 0xff);
B[bi + 3] = (B32[i] >> 24 & 0xff);
}
}
function blockxor(S, Si, D, Di, len) {
var i = len >> 6;
while (i--) {
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
D[Di++] ^= S[Si++];
}
}
function integerify(B, bi, r) {
var n;
bi += (2 * r - 1) * 64;
n = (B[bi + 0] & 0xff) << 0;
n |= (B[bi + 1] & 0xff) << 8;
n |= (B[bi + 2] & 0xff) << 16;
n |= (B[bi + 3] & 0xff) << 24;
return n;
}
function arraycopy(src, srcPos, dest, destPos, length) {
while (length--) {
dest[destPos++] = src[srcPos++];
}
}
function arraycopy32(src, srcPos, dest, destPos, length) {
var i = length >> 5;
while (i--) {
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
dest[destPos++] = src[srcPos++];
}
}
} // scryptCore
}; // window.Crypto_scrypt
})();
</script>
<!-- bitjs.js -->
<script>
function bitjslib(crypto_asset) {
var bitjs = window.bitjs[crypto_asset] = function () {};
if (crypto_asset == "BTC") {
bitjs.priv = 0x80; //mainnet 0x80, testnet:
bitjs.pub = 0x00; //mainnet 0x23, testnet:
} else if (crypto_asset == "BTC_TEST") {
bitjs.priv = 0xEF;
bitjs.pub = 0x6F;
} else if (crypto_asset == "FLO") {
bitjs.priv = 0xA3;
bitjs.pub = 0x23;
} else if (crypto_asset == "FLO_TEST") {
bitjs.priv = 0xEF;
bitjs.pub = 0x73;
} else {
bitjs.priv = 0xEF;
bitjs.pub = 0x6F;
}
/* public vars */
bitjs.compressed = true;
/* provide a privkey and return an WIF */
bitjs.privkey2wif = function (h) {
var r = Crypto.util.hexToBytes(h);
if (bitjs.compressed == true) {
r.push(0x01);
}
r.unshift(bitjs.priv);
var hash = Crypto.SHA256(Crypto.SHA256(r, {
asBytes: true
}), {
asBytes: true
});
var checksum = hash.slice(0, 4);
return B58.encode(r.concat(checksum));
}
/* convert a wif key back to a private key */
bitjs.wif2privkey = function (wif) {
var compressed = false;
var decode = B58.decode(wif);
var key = decode.slice(0, decode.length - 4);
key = key.slice(1, key.length);
if (key.length >= 33 && key[key.length - 1] == 0x01) {
key = key.slice(0, key.length - 1);
compressed = true;
}
return {
'privkey': Crypto.util.bytesToHex(key),
'compressed': compressed
};
}
/* convert a wif to a pubkey */
bitjs.wif2pubkey = function (wif) {
var compressed = bitjs.compressed;
var r = bitjs.wif2privkey(wif);
bitjs.compressed = r['compressed'];
var pubkey = bitjs.newPubkey(r['privkey']);
bitjs.compressed = compressed;
return {
'pubkey': pubkey,
'compressed': r['compressed']
};
}
/* convert a wif to a address */
bitjs.wif2address = function (wif) {
var r = bitjs.wif2pubkey(wif);
return {
'address': bitjs.pubkey2address(r['pubkey']),
'compressed': r['compressed']
};
}
/* generate a public key from a private key */
bitjs.newPubkey = function (hash) {
var privateKeyBigInt = BigInteger.fromByteArrayUnsigned(Crypto.util.hexToBytes(hash));
var curve = EllipticCurve.getSECCurveByName("secp256k1");
var curvePt = curve.getG().multiply(privateKeyBigInt);
var x = curvePt.getX().toBigInteger();
var y = curvePt.getY().toBigInteger();
var publicKeyBytes = EllipticCurve.integerToBytes(x, 32);
publicKeyBytes = publicKeyBytes.concat(EllipticCurve.integerToBytes(y, 32));
publicKeyBytes.unshift(0x04);
if (bitjs.compressed == true) {
var publicKeyBytesCompressed = EllipticCurve.integerToBytes(x, 32)
if (y.isEven()) {
publicKeyBytesCompressed.unshift(0x02)
} else {
publicKeyBytesCompressed.unshift(0x03)
}
return Crypto.util.bytesToHex(publicKeyBytesCompressed);
} else {
return Crypto.util.bytesToHex(publicKeyBytes);
}
}
/* provide a public key and return address */
bitjs.pubkey2address = function (h, byte) {
var r = ripemd160(Crypto.SHA256(Crypto.util.hexToBytes(h), {
asBytes: true
}));
r.unshift(byte || bitjs.pub);
var hash = Crypto.SHA256(Crypto.SHA256(r, {
asBytes: true
}), {
asBytes: true
});
var checksum = hash.slice(0, 4);
return B58.encode(r.concat(checksum));
}
bitjs.transaction = function () {
var btrx = {};
btrx.inputs = [];
btrx.outputs = [];
btrx.locktime = 0;
if (crypto_asset == "FLO" || crypto_asset == "FLO_TEST") {
btrx.version = 2; //flochange look at this version
btrx.floData = ""; //flochange .. look at this
} else if (crypto_asset == "BTC" || crypto_asset == "BTC_TEST") {
btrx.version = 1;
}
btrx.addinput = function (txid, index, scriptPubKey, sequence) {
var o = {};
o.outpoint = {
'hash': txid,
'index': index
};
//o.script = []; Signature and Public Key should be added after singning
o.script = Crypto.util.hexToBytes(scriptPubKey); //push previous output pubkey script
o.sequence = sequence || ((btrx.locktime == 0) ? 4294967295 : 0);
return this.inputs.push(o);
}
btrx.addoutput = function (address, value) {
var o = {};
var buf = [];
var addrDecoded = btrx.addressDecode(address);
o.value = new BigInteger('' + Math.round((value * 1) * 1e8), 10);
buf.push(118); //OP_DUP
buf.push(169); //OP_HASH160
buf.push(addrDecoded.length);
buf = buf.concat(addrDecoded); // address in bytes
buf.push(136); //OP_EQUALVERIFY
buf.push(172); // OP_CHECKSIG
o.script = buf;
return this.outputs.push(o);
}
if (crypto_asset == "FLO" || crypto_asset == "FLO_TEST") {
btrx.addflodata = function (txcomments) { // flochange - this whole function needs to be done
this.floData = txcomments;
return this.floData; //flochange .. returning the txcomments -- check if the function return will assign
}
}
// Only standard addresses
btrx.addressDecode = function (address) {
var bytes = B58.decode(address);
var front = bytes.slice(0, bytes.length - 4);
var back = bytes.slice(bytes.length - 4);
var checksum = Crypto.SHA256(Crypto.SHA256(front, {
asBytes: true
}), {
asBytes: true
}).slice(0, 4);
if (checksum + "" == back + "") {
return front.slice(1);
}
}
/* generate the transaction hash to sign from a transaction input */
btrx.transactionHash = function (index, sigHashType) {
var clone = bitjs.clone(this);
var shType = sigHashType || 1;
/* black out all other ins, except this one */
for (var i = 0; i < clone.inputs.length; i++) {
if (index != i) {
clone.inputs[i].script = [];
}
}
if ((clone.inputs) && clone.inputs[index]) {
/* SIGHASH : For more info on sig hashs see https://en.bitcoin.it/wiki/OP_CHECKSIG
and https://bitcoin.org/en/developer-guide#signature-hash-type */
if (shType == 1) {
//SIGHASH_ALL 0x01
} else if (shType == 2) {
//SIGHASH_NONE 0x02
clone.outputs = [];
for (var i = 0; i < clone.inputs.length; i++) {
if (index != i) {
clone.inputs[i].sequence = 0;
}
}
} else if (shType == 3) {
//SIGHASH_SINGLE 0x03
clone.outputs.length = index + 1;
for (var i = 0; i < index; i++) {
clone.outputs[i].value = -1;
clone.outputs[i].script = [];
}
for (var i = 0; i < clone.inputs.length; i++) {
if (index != i) {
clone.inputs[i].sequence = 0;
}
}
} else if (shType >= 128) {
//SIGHASH_ANYONECANPAY 0x80
clone.inputs = [clone.inputs[index]];
if (shType == 129) {
// SIGHASH_ALL + SIGHASH_ANYONECANPAY
} else if (shType == 130) {
// SIGHASH_NONE + SIGHASH_ANYONECANPAY
clone.outputs = [];
} else if (shType == 131) {
// SIGHASH_SINGLE + SIGHASH_ANYONECANPAY
clone.outputs.length = index + 1;
for (var i = 0; i < index; i++) {
clone.outputs[i].value = -1;
clone.outputs[i].script = [];
}
}
}
var buffer = Crypto.util.hexToBytes(clone.serialize());
buffer = buffer.concat(bitjs.numToBytes(parseInt(shType), 4));
var hash = Crypto.SHA256(buffer, {
asBytes: true
});
var r = Crypto.util.bytesToHex(Crypto.SHA256(hash, {
asBytes: true
}));
return r;
} else {
return false;
}
}
/* generate a signature from a transaction hash */
btrx.transactionSig = function (index, wif, sigHashType, txhash) {
function serializeSig(r, s) {
var rBa = r.toByteArraySigned();
var sBa = s.toByteArraySigned();
var sequence = [];
sequence.push(0x02); // INTEGER
sequence.push(rBa.length);
sequence = sequence.concat(rBa);
sequence.push(0x02); // INTEGER
sequence.push(sBa.length);
sequence = sequence.concat(sBa);
sequence.unshift(sequence.length);
sequence.unshift(0x30); // SEQUENCE
return sequence;
}
var shType = sigHashType || 1;
var hash = txhash || Crypto.util.hexToBytes(this.transactionHash(index, shType));
if (hash) {
var curve = EllipticCurve.getSECCurveByName("secp256k1");
var key = bitjs.wif2privkey(wif);
var priv = BigInteger.fromByteArrayUnsigned(Crypto.util.hexToBytes(key['privkey']));
var n = curve.getN();
var e = BigInteger.fromByteArrayUnsigned(hash);
var badrs = 0
do {
var k = this.deterministicK(wif, hash, badrs);
var G = curve.getG();
var Q = G.multiply(k);
var r = Q.getX().toBigInteger().mod(n);
var s = k.modInverse(n).multiply(e.add(priv.multiply(r))).mod(n);
badrs++
} while (r.compareTo(BigInteger.ZERO) <= 0 || s.compareTo(BigInteger.ZERO) <= 0);
// Force lower s values per BIP62
var halfn = n.shiftRight(1);
if (s.compareTo(halfn) > 0) {
s = n.subtract(s);
};
var sig = serializeSig(r, s);
sig.push(parseInt(shType, 10));
return Crypto.util.bytesToHex(sig);
} else {
return false;
}
}
// https://tools.ietf.org/html/rfc6979#section-3.2
btrx.deterministicK = function (wif, hash, badrs) {
// if r or s were invalid when this function was used in signing,
// we do not want to actually compute r, s here for efficiency, so,
// we can increment badrs. explained at end of RFC 6979 section 3.2
// wif is b58check encoded wif privkey.
// hash is byte array of transaction digest.
// badrs is used only if the k resulted in bad r or s.
// some necessary things out of the way for clarity.
badrs = badrs || 0;
var key = bitjs.wif2privkey(wif);
var x = Crypto.util.hexToBytes(key['privkey'])
var curve = EllipticCurve.getSECCurveByName("secp256k1");
var N = curve.getN();
// Step: a
// hash is a byteArray of the message digest. so h1 == hash in our case
// Step: b
var v = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1
];
// Step: c
var k = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0
];
// Step: d
k = Crypto.HMAC(Crypto.SHA256, v.concat([0]).concat(x).concat(hash), k, {
asBytes: true
});
// Step: e
v = Crypto.HMAC(Crypto.SHA256, v, k, {
asBytes: true
});
// Step: f
k = Crypto.HMAC(Crypto.SHA256, v.concat([1]).concat(x).concat(hash), k, {
asBytes: true
});
// Step: g
v = Crypto.HMAC(Crypto.SHA256, v, k, {
asBytes: true
});
// Step: h1
var T = [];
// Step: h2 (since we know tlen = qlen, just copy v to T.)
v = Crypto.HMAC(Crypto.SHA256, v, k, {
asBytes: true
});
T = v;
// Step: h3
var KBigInt = BigInteger.fromByteArrayUnsigned(T);
// loop if KBigInt is not in the range of [1, N-1] or if badrs needs incrementing.
var i = 0
while (KBigInt.compareTo(N) >= 0 || KBigInt.compareTo(BigInteger.ZERO) <= 0 || i <
badrs) {
k = Crypto.HMAC(Crypto.SHA256, v.concat([0]), k, {
asBytes: true
});
v = Crypto.HMAC(Crypto.SHA256, v, k, {
asBytes: true
});
v = Crypto.HMAC(Crypto.SHA256, v, k, {
asBytes: true
});
T = v;
KBigInt = BigInteger.fromByteArrayUnsigned(T);
i++
};
return KBigInt;
};
/* sign a "standard" input */
btrx.signinput = function (index, wif, sigHashType) {
var key = bitjs.wif2pubkey(wif);
var shType = sigHashType || 1;
var signature = this.transactionSig(index, wif, shType);
var buf = [];
var sigBytes = Crypto.util.hexToBytes(signature);
buf.push(sigBytes.length);
buf = buf.concat(sigBytes);
var pubKeyBytes = Crypto.util.hexToBytes(key['pubkey']);
buf.push(pubKeyBytes.length);
buf = buf.concat(pubKeyBytes);
this.inputs[index].script = buf;
return true;
}
/* sign inputs */
btrx.sign = function (wif, sigHashType) {
var shType = sigHashType || 1;
for (var i = 0; i < this.inputs.length; i++) {
this.signinput(i, wif, shType);
}
return this.serialize();
}
/* serialize a transaction */
btrx.serialize = function () {
if (crypto_asset == "FLO" || crypto_asset == "FLO_TEST") {
var buffer = [];
buffer = buffer.concat(bitjs.numToBytes(parseInt(this.version), 4));
buffer = buffer.concat(bitjs.numToVarInt(this.inputs.length));
for (var i = 0; i < this.inputs.length; i++) {
var txin = this.inputs[i];
buffer = buffer.concat(Crypto.util.hexToBytes(txin.outpoint.hash).reverse());
buffer = buffer.concat(bitjs.numToBytes(parseInt(txin.outpoint.index), 4));
var scriptBytes = txin.script;
buffer = buffer.concat(bitjs.numToVarInt(scriptBytes.length));
buffer = buffer.concat(scriptBytes);
buffer = buffer.concat(bitjs.numToBytes(parseInt(txin.sequence), 4));
}
buffer = buffer.concat(bitjs.numToVarInt(this.outputs.length));
for (var i = 0; i < this.outputs.length; i++) {
var txout = this.outputs[i];
buffer = buffer.concat(bitjs.numToBytes(txout.value, 8));
var scriptBytes = txout.script;
buffer = buffer.concat(bitjs.numToVarInt(scriptBytes.length));
buffer = buffer.concat(scriptBytes);
}
buffer = buffer.concat(bitjs.numToBytes(parseInt(this.locktime), 4));
flohex = ascii_to_hexa(this.floData);
floDataCount = this.floData.length;
//flochange -- creating unique data character count logic for floData. This string is prefixed before actual floData string in Raw Transaction
if (floDataCount <= 16) {
floDataCountString = floDataCount.toString(16);
floDataCountString = "0" + floDataCountString;
} else if (floDataCount < 253) {
floDataCountString = floDataCount.toString(16);
} else if (floDataCount <= 1023) {
floDataCountAdjusted = (floDataCount - 253) + parseInt("0xfd00fd");
floDataCountStringAdjusted = floDataCountAdjusted.toString(16);
floDataCountString = floDataCountStringAdjusted.substr(0, 2) +
floDataCountStringAdjusted.substr(4, 2) + floDataCountStringAdjusted.substr(2,
2);
} else {
floDataCountString = "Character Limit Exceeded";
}
return Crypto.util.bytesToHex(buffer) + floDataCountString + flohex; // flochange -- Addition of floDataCountString and floData in serialization
} else if (crypto_asset == "BTC" || crypto_asset == "BTC_TEST") {
var buffer = [];
buffer = buffer.concat(bitjs.numToBytes(parseInt(this.version), 4));
buffer = buffer.concat(bitjs.numToVarInt(this.inputs.length));
for (var i = 0; i < this.inputs.length; i++) {
var txin = this.inputs[i];
buffer = buffer.concat(Crypto.util.hexToBytes(txin.outpoint.hash).reverse());
buffer = buffer.concat(bitjs.numToBytes(parseInt(txin.outpoint.index), 4));
var scriptBytes = txin.script;
buffer = buffer.concat(bitjs.numToVarInt(scriptBytes.length));
buffer = buffer.concat(scriptBytes);
buffer = buffer.concat(bitjs.numToBytes(parseInt(txin.sequence), 4));
}
buffer = buffer.concat(bitjs.numToVarInt(this.outputs.length));
for (var i = 0; i < this.outputs.length; i++) {
var txout = this.outputs[i];
buffer = buffer.concat(bitjs.numToBytes(txout.value, 8));
var scriptBytes = txout.script;
buffer = buffer.concat(bitjs.numToVarInt(scriptBytes.length));
buffer = buffer.concat(scriptBytes);
}
buffer = buffer.concat(bitjs.numToBytes(parseInt(this.locktime), 4));
return Crypto.util.bytesToHex(buffer);
}
}
return btrx;
}
bitjs.numToBytes = function (num, bytes) {
if (typeof bytes === "undefined") bytes = 8;
if (bytes == 0) {
return [];
} else if (num == -1) {
return Crypto.util.hexToBytes("ffffffffffffffff");
} else {
return [num % 256].concat(bitjs.numToBytes(Math.floor(num / 256), bytes - 1));
}
}
bitjs.numToByteArray = function (num) {
if (num <= 256) {
return [num];
} else {
return [num % 256].concat(bitjs.numToByteArray(Math.floor(num / 256)));
}
}
bitjs.numToVarInt = function (num) {
if (num < 253) {
return [num];
} else if (num < 65536) {
return [253].concat(bitjs.numToBytes(num, 2));
} else if (num < 4294967296) {
return [254].concat(bitjs.numToBytes(num, 4));
} else {
return [255].concat(bitjs.numToBytes(num, 8));
}
}
bitjs.bytesToNum = function (bytes) {
if (bytes.length == 0) return 0;
else return bytes[0] + 256 * bitjs.bytesToNum(bytes.slice(1));
}
/* clone an object */
bitjs.clone = function (obj) {
if (obj == null || typeof (obj) != 'object') return obj;
var temp = new obj.constructor();
for (var key in obj) {
if (obj.hasOwnProperty(key)) {
temp[key] = bitjs.clone(obj[key]);
}
}
return temp;
}
var B58 = bitjs.Base58 = {
alphabet: "123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz",
validRegex: /^[1-9A-HJ-NP-Za-km-z]+$/,
base: BigInteger.valueOf(58),
/**
* Convert a byte array to a base58-encoded string.
*
* Written by Mike Hearn for BitcoinJ.
* Copyright (c) 2011 Google Inc.
*
* Ported to JavaScript by Stefan Thomas.
*/
encode: function (input) {
var bi = BigInteger.fromByteArrayUnsigned(input);
var chars = [];
while (bi.compareTo(B58.base) >= 0) {
var mod = bi.mod(B58.base);
chars.unshift(B58.alphabet[mod.intValue()]);
bi = bi.subtract(mod).divide(B58.base);
}
chars.unshift(B58.alphabet[bi.intValue()]);
// Convert leading zeros too.
for (var i = 0; i < input.length; i++) {
if (input[i] == 0x00) {
chars.unshift(B58.alphabet[0]);
} else break;
}
return chars.join('');
},
/**
* Convert a base58-encoded string to a byte array.
*
* Written by Mike Hearn for BitcoinJ.
* Copyright (c) 2011 Google Inc.
*
* Ported to JavaScript by Stefan Thomas.
*/
decode: function (input) {
var bi = BigInteger.valueOf(0);
var leadingZerosNum = 0;
for (var i = input.length - 1; i >= 0; i--) {
var alphaIndex = B58.alphabet.indexOf(input[i]);
if (alphaIndex < 0) {
throw "Invalid character";
}
bi = bi.add(BigInteger.valueOf(alphaIndex)
.multiply(B58.base.pow(input.length - 1 - i)));
// This counts leading zero bytes
if (input[i] == "1") leadingZerosNum++;
else leadingZerosNum = 0;
}
var bytes = bi.toByteArrayUnsigned();
// Add leading zeros
while (leadingZerosNum-- > 0) bytes.unshift(0);
return bytes;
}
}
return bitjs;
};
</script>
<!-- Shamir's secret (https://github.com/amper5and/secrets.js) -->
<script>
// secrets.js - by Alexander Stetsyuk - released under MIT License
(function (exports, global) {
var defaults = {
bits: 8, // default number of bits
radix: 16, // work with HEX by default
minBits: 3,
maxBits: 20, // this permits 1,048,575 shares, though going this high is NOT recommended in JS!
bytesPerChar: 2,
maxBytesPerChar: 6, // Math.pow(256,7) > Math.pow(2,53)
// Primitive polynomials (in decimal form) for Galois Fields GF(2^n), for 2 <= n <= 30
// The index of each term in the array corresponds to the n for that polynomial
// i.e. to get the polynomial for n=16, use primitivePolynomials[16]
primitivePolynomials: [null, null, 1, 3, 3, 5, 3, 3, 29, 17, 9, 5, 83, 27, 43, 3, 45, 9, 39, 39,
9, 5, 3, 33, 27, 9, 71, 39, 9, 5, 83
],
// warning for insecure PRNG
warning: 'WARNING:\nA secure random number generator was not found.\nUsing Math.random(), which is NOT cryptographically strong!'
};
// Protected settings object
var config = {};
/** @expose **/
exports.getConfig = function () {
return {
'bits': config.bits,
'unsafePRNG': config.unsafePRNG
};
};
function init(bits) {
if (bits && (typeof bits !== 'number' || bits % 1 !== 0 || bits < defaults.minBits || bits >
defaults.maxBits)) {
throw new Error('Number of bits must be an integer between ' + defaults.minBits + ' and ' +
defaults.maxBits + ', inclusive.')
}
config.radix = defaults.radix;
config.bits = bits || defaults.bits;
config.size = Math.pow(2, config.bits);
config.max = config.size - 1;
// Construct the exp and log tables for multiplication.
var logs = [],
exps = [],
x = 1,
primitive = defaults.primitivePolynomials[config.bits];
for (var i = 0; i < config.size; i++) {
exps[i] = x;
logs[x] = i;
x <<= 1;
if (x >= config.size) {
x ^= primitive;
x &= config.max;
}
}
config.logs = logs;
config.exps = exps;
};
/** @expose **/
exports.init = init;
function isInited() {
if (!config.bits || !config.size || !config.max || !config.logs || !config.exps || config.logs.length !==
config.size || config.exps.length !== config.size) {
return false;
}
return true;
};
// Returns a pseudo-random number generator of the form function(bits){}
// which should output a random string of 1's and 0's of length `bits`
function getRNG() {
var randomBits, crypto;
function construct(bits, arr, radix, size) {
var str = '',
i = 0,
len = arr.length - 1;
while (i < len || (str.length < bits)) {
str += padLeft(parseInt(arr[i], radix).toString(2), size);
i++;
}
str = str.substr(-bits);
if ((str.match(/0/g) || []).length === str.length) { // all zeros?
return null;
} else {
return str;
}
}
// node.js crypto.randomBytes()
if (typeof require === 'function' && (crypto = require('crypto')) && (randomBits = crypto[
'randomBytes'])) {
return function (bits) {
var bytes = Math.ceil(bits / 8),
str = null;
while (str === null) {
str = construct(bits, randomBits(bytes).toString('hex'), 16, 4);
}
return str;
}
}
// browsers with window.crypto.getRandomValues()
if (global['crypto'] && typeof global['crypto']['getRandomValues'] === 'function' && typeof global[
'Uint32Array'] === 'function') {
crypto = global['crypto'];
return function (bits) {
var elems = Math.ceil(bits / 32),
str = null,
arr = new global['Uint32Array'](elems);
while (str === null) {
crypto['getRandomValues'](arr);
str = construct(bits, arr, 10, 32);
}
return str;
}
}
// A totally insecure RNG!!! (except in Safari)
// Will produce a warning every time it is called.
config.unsafePRNG = true;
warn();
var bitsPerNum = 32;
var max = Math.pow(2, bitsPerNum) - 1;
return function (bits) {
var elems = Math.ceil(bits / bitsPerNum);
var arr = [],
str = null;
while (str === null) {
for (var i = 0; i < elems; i++) {
arr[i] = Math.floor(Math.random() * max + 1);
}
str = construct(bits, arr, 10, bitsPerNum);
}
return str;
};
};
// Warn about using insecure rng.
// Called when Math.random() is being used.
function warn() {
global['console']['warn'](defaults.warning);
if (typeof global['alert'] === 'function' && config.alert) {
global['alert'](defaults.warning);
}
}
// Set the PRNG to use. If no RNG function is supplied, pick a default using getRNG()
/** @expose **/
exports.setRNG = function (rng, alert) {
if (!isInited()) {
this.init();
}
config.unsafePRNG = false;
rng = rng || getRNG();
// test the RNG (5 times)
if (typeof rng !== 'function' || typeof rng(config.bits) !== 'string' || !parseInt(rng(config.bits),
2) || rng(config.bits).length > config.bits || rng(config.bits).length < config.bits) {
throw new Error(
"Random number generator is invalid. Supply an RNG of the form function(bits){} that returns a string containing 'bits' number of random 1's and 0's."
)
} else {
config.rng = rng;
}
config.alert = !!alert;
return !!config.unsafePRNG;
};
function isSetRNG() {
return typeof config.rng === 'function';
};
// Generates a random bits-length number string using the PRNG
/** @expose **/
exports.random = function (bits) {
if (!isSetRNG()) {
this.setRNG();
}
if (typeof bits !== 'number' || bits % 1 !== 0 || bits < 2) {
throw new Error('Number of bits must be an integer greater than 1.')
}
if (config.unsafePRNG) {
warn();
}
return bin2hex(config.rng(bits));
}
// Divides a `secret` number String str expressed in radix `inputRadix` (optional, default 16)
// into `numShares` shares, each expressed in radix `outputRadix` (optional, default to `inputRadix`),
// requiring `threshold` number of shares to reconstruct the secret.
// Optionally, zero-pads the secret to a length that is a multiple of padLength before sharing.
/** @expose **/
exports.share = function (secret, numShares, threshold, padLength, withoutPrefix) {
if (!isInited()) {
this.init();
}
if (!isSetRNG()) {
this.setRNG();
}
padLength = padLength || 0;
if (typeof secret !== 'string') {
throw new Error('Secret must be a string.');
}
if (typeof numShares !== 'number' || numShares % 1 !== 0 || numShares < 2) {
throw new Error('Number of shares must be an integer between 2 and 2^bits-1 (' + config.max +
'), inclusive.')
}
if (numShares > config.max) {
var neededBits = Math.ceil(Math.log(numShares + 1) / Math.LN2);
throw new Error('Number of shares must be an integer between 2 and 2^bits-1 (' + config.max +
'), inclusive. To create ' + numShares + ' shares, use at least ' + neededBits +
' bits.')
}
if (typeof threshold !== 'number' || threshold % 1 !== 0 || threshold < 2) {
throw new Error('Threshold number of shares must be an integer between 2 and 2^bits-1 (' +
config.max + '), inclusive.');
}
if (threshold > config.max) {
var neededBits = Math.ceil(Math.log(threshold + 1) / Math.LN2);
throw new Error('Threshold number of shares must be an integer between 2 and 2^bits-1 (' +
config.max + '), inclusive. To use a threshold of ' + threshold +
', use at least ' + neededBits + ' bits.');
}
if (typeof padLength !== 'number' || padLength % 1 !== 0) {
throw new Error('Zero-pad length must be an integer greater than 1.');
}
if (config.unsafePRNG) {
warn();
}
secret = '1' + hex2bin(secret); // append a 1 so that we can preserve the correct number of leading zeros in our secret
secret = split(secret, padLength);
var x = new Array(numShares),
y = new Array(numShares);
for (var i = 0, len = secret.length; i < len; i++) {
var subShares = this._getShares(secret[i], numShares, threshold);
for (var j = 0; j < numShares; j++) {
x[j] = x[j] || subShares[j].x.toString(config.radix);
y[j] = padLeft(subShares[j].y.toString(2)) + (y[j] ? y[j] : '');
}
}
var padding = config.max.toString(config.radix).length;
if (withoutPrefix) {
for (var i = 0; i < numShares; i++) {
x[i] = bin2hex(y[i]);
}
} else {
for (var i = 0; i < numShares; i++) {
x[i] = config.bits.toString(36).toUpperCase() + padLeft(x[i], padding) + bin2hex(y[i]);
}
}
return x;
};
// This is the basic polynomial generation and evaluation function
// for a `config.bits`-length secret (NOT an arbitrary length)
// Note: no error-checking at this stage! If `secrets` is NOT
// a NUMBER less than 2^bits-1, the output will be incorrect!
/** @expose **/
exports._getShares = function (secret, numShares, threshold) {
var shares = [];
var coeffs = [secret];
for (var i = 1; i < threshold; i++) {
coeffs[i] = parseInt(config.rng(config.bits), 2);
}
for (var i = 1, len = numShares + 1; i < len; i++) {
shares[i - 1] = {
x: i,
y: horner(i, coeffs)
}
}
return shares;
};
// Polynomial evaluation at `x` using Horner's Method
// TODO: this can possibly be sped up using other methods
// NOTE: fx=fx * x + coeff[i] -> exp(log(fx) + log(x)) + coeff[i],
// so if fx===0, just set fx to coeff[i] because
// using the exp/log form will result in incorrect value
function horner(x, coeffs) {
var logx = config.logs[x];
var fx = 0;
for (var i = coeffs.length - 1; i >= 0; i--) {
if (fx === 0) {
fx = coeffs[i];
continue;
}
fx = config.exps[(logx + config.logs[fx]) % config.max] ^ coeffs[i];
}
return fx;
};
function inArray(arr, val) {
for (var i = 0, len = arr.length; i < len; i++) {
if (arr[i] === val) {
return true;
}
}
return false;
};
function processShare(share) {
var bits = parseInt(share[0], 36);
if (bits && (typeof bits !== 'number' || bits % 1 !== 0 || bits < defaults.minBits || bits >
defaults.maxBits)) {
throw new Error('Number of bits must be an integer between ' + defaults.minBits + ' and ' +
defaults.maxBits + ', inclusive.')
}
var max = Math.pow(2, bits) - 1;
var idLength = max.toString(config.radix).length;
var id = parseInt(share.substr(1, idLength), config.radix);
if (typeof id !== 'number' || id % 1 !== 0 || id < 1 || id > max) {
throw new Error('Share id must be an integer between 1 and ' + config.max + ', inclusive.');
}
share = share.substr(idLength + 1);
if (!share.length) {
throw new Error('Invalid share: zero-length share.')
}
return {
'bits': bits,
'id': id,
'value': share
};
};
/** @expose **/
exports._processShare = processShare;
// Protected method that evaluates the Lagrange interpolation
// polynomial at x=`at` for individual config.bits-length
// segments of each share in the `shares` Array.
// Each share is expressed in base `inputRadix`. The output
// is expressed in base `outputRadix'
function combine(at, shares) {
var setBits, share, x = [],
y = [],
result = '',
idx;
for (var i = 0, len = shares.length; i < len; i++) {
share = processShare(shares[i]);
if (typeof setBits === 'undefined') {
setBits = share['bits'];
} else if (share['bits'] !== setBits) {
throw new Error('Mismatched shares: Different bit settings.')
}
if (config.bits !== setBits) {
init(setBits);
}
if (inArray(x, share['id'])) { // repeated x value?
continue;
}
idx = x.push(share['id']) - 1;
share = split(hex2bin(share['value']));
for (var j = 0, len2 = share.length; j < len2; j++) {
y[j] = y[j] || [];
y[j][idx] = share[j];
}
}
for (var i = 0, len = y.length; i < len; i++) {
result = padLeft(lagrange(at, x, y[i]).toString(2)) + result;
}
if (at === 0) { // reconstructing the secret
var idx = result.indexOf('1'); //find the first 1
return bin2hex(result.slice(idx + 1));
} else { // generating a new share
return bin2hex(result);
}
};
// Combine `shares` Array into the original secret
/** @expose **/
exports.combine = function (shares) {
return combine(0, shares);
};
// Generate a new share with id `id` (a number between 1 and 2^bits-1)
// `id` can be a Number or a String in the default radix (16)
/** @expose **/
exports.newShare = function (id, shares) {
if (typeof id === 'string') {
id = parseInt(id, config.radix);
}
var share = processShare(shares[0]);
var max = Math.pow(2, share['bits']) - 1;
if (typeof id !== 'number' || id % 1 !== 0 || id < 1 || id > max) {
throw new Error('Share id must be an integer between 1 and ' + config.max + ', inclusive.');
}
var padding = max.toString(config.radix).length;
return config.bits.toString(36).toUpperCase() + padLeft(id.toString(config.radix), padding) +
combine(id, shares);
};
// Evaluate the Lagrange interpolation polynomial at x = `at`
// using x and y Arrays that are of the same length, with
// corresponding elements constituting points on the polynomial.
function lagrange(at, x, y) {
var sum = 0,
product,
i, j;
for (var i = 0, len = x.length; i < len; i++) {
if (!y[i]) {
continue;
}
product = config.logs[y[i]];
for (var j = 0; j < len; j++) {
if (i === j) {
continue;
}
if (at === x[j]) { // happens when computing a share that is in the list of shares used to compute it
product = -1; // fix for a zero product term, after which the sum should be sum^0 = sum, not sum^1
break;
}
product = (product + config.logs[at ^ x[j]] - config.logs[x[i] ^ x[j]] + config.max /* to make sure it's not negative */ ) %
config.max;
}
sum = product === -1 ? sum : sum ^ config.exps[product]; // though exps[-1]= undefined and undefined ^ anything = anything in chrome, this behavior may not hold everywhere, so do the check
}
return sum;
};
/** @expose **/
exports._lagrange = lagrange;
// Splits a number string `bits`-length segments, after first
// optionally zero-padding it to a length that is a multiple of `padLength.
// Returns array of integers (each less than 2^bits-1), with each element
// representing a `bits`-length segment of the input string from right to left,
// i.e. parts[0] represents the right-most `bits`-length segment of the input string.
function split(str, padLength) {
if (padLength) {
str = padLeft(str, padLength)
}
var parts = [];
for (var i = str.length; i > config.bits; i -= config.bits) {
parts.push(parseInt(str.slice(i - config.bits, i), 2));
}
parts.push(parseInt(str.slice(0, i), 2));
return parts;
};
// Pads a string `str` with zeros on the left so that its length is a multiple of `bits`
function padLeft(str, bits) {
bits = bits || config.bits
var missing = str.length % bits;
return (missing ? new Array(bits - missing + 1).join('0') : '') + str;
};
function hex2bin(str) {
var bin = '',
num;
for (var i = str.length - 1; i >= 0; i--) {
num = parseInt(str[i], 16)
if (isNaN(num)) {
throw new Error('Invalid hex character.')
}
bin = padLeft(num.toString(2), 4) + bin;
}
return bin;
}
function bin2hex(str) {
var hex = '',
num;
str = padLeft(str, 4);
for (var i = str.length; i >= 4; i -= 4) {
num = parseInt(str.slice(i - 4, i), 2);
if (isNaN(num)) {
throw new Error('Invalid binary character.')
}
hex = num.toString(16) + hex;
}
return hex;
}
// Converts a given UTF16 character string to the HEX representation.
// Each character of the input string is represented by
// `bytesPerChar` bytes in the output string.
/** @expose **/
exports.str2hex = function (str, bytesPerChar) {
if (typeof str !== 'string') {
throw new Error('Input must be a character string.');
}
bytesPerChar = bytesPerChar || defaults.bytesPerChar;
if (typeof bytesPerChar !== 'number' || bytesPerChar % 1 !== 0 || bytesPerChar < 1 ||
bytesPerChar > defaults.maxBytesPerChar) {
throw new Error('Bytes per character must be an integer between 1 and ' + defaults.maxBytesPerChar +
', inclusive.')
}
var hexChars = 2 * bytesPerChar;
var max = Math.pow(16, hexChars) - 1;
var out = '',
num;
for (var i = 0, len = str.length; i < len; i++) {
num = str[i].charCodeAt();
if (isNaN(num)) {
throw new Error('Invalid character: ' + str[i]);
} else if (num > max) {
var neededBytes = Math.ceil(Math.log(num + 1) / Math.log(256));
throw new Error('Invalid character code (' + num +
'). Maximum allowable is 256^bytes-1 (' + max +
'). To convert this character, use at least ' + neededBytes + ' bytes.')
} else {
out = padLeft(num.toString(16), hexChars) + out;
}
}
return out;
};
// Converts a given HEX number string to a UTF16 character string.
/** @expose **/
exports.hex2str = function (str, bytesPerChar) {
if (typeof str !== 'string') {
throw new Error('Input must be a hexadecimal string.');
}
bytesPerChar = bytesPerChar || defaults.bytesPerChar;
if (typeof bytesPerChar !== 'number' || bytesPerChar % 1 !== 0 || bytesPerChar < 1 ||
bytesPerChar > defaults.maxBytesPerChar) {
throw new Error('Bytes per character must be an integer between 1 and ' + defaults.maxBytesPerChar +
', inclusive.')
}
var hexChars = 2 * bytesPerChar;
var out = '';
str = padLeft(str, hexChars);
for (var i = 0, len = str.length; i < len; i += hexChars) {
out = String.fromCharCode(parseInt(str.slice(i, i + hexChars), 16)) + out;
}
return out;
};
// by default, initialize without an RNG
exports.init();
})(typeof module !== 'undefined' && module['exports'] ? module['exports'] : (window['shamirSecretShare'] = {}),
typeof global !== 'undefined' ? global : window);
</script>
<script language="JavaScript">
(function (ellipticCurveType) {
//Defining Elliptic Encryption Object
var ellipticEncryption = window.ellipticCurveEncryption = function () {};
ellipticEncryption.rng = new SecureRandom();
ellipticEncryption.getCurveParameters = function (curveName) {
//Default is secp256k1
curveName = typeof curveName !== 'undefined' ? curveName : "secp256k1";
var c = EllipticCurve.getSECCurveByName(curveName);
var curveDetails = {
Q: "",
A: "",
B: "",
GX: "",
GY: "",
N: ""
};
curveDetails.Q = c.getCurve().getQ().toString();
curveDetails.A = c.getCurve().getA().toBigInteger().toString();
curveDetails.B = c.getCurve().getB().toBigInteger().toString();
curveDetails.GX = c.getG().getX().toBigInteger().toString();
curveDetails.GY = c.getG().getY().toBigInteger().toString();
curveDetails.N = c.getN().toString();
return curveDetails;
}
ellipticEncryption.selectedCurve = ellipticEncryption.getCurveParameters(ellipticCurveType);
ellipticEncryption.get_curve = function () {
return new EllipticCurve.CurveFp(new BigInteger(this.selectedCurve.Q),
new BigInteger(this.selectedCurve.A),
new BigInteger(this.selectedCurve.B));
}
ellipticEncryption.get_G = function (curve) {
return new EllipticCurve.PointFp(curve,
curve.fromBigInteger(new BigInteger(this.selectedCurve.GX)),
curve.fromBigInteger(new BigInteger(this.selectedCurve.GY)));
}
ellipticEncryption.pick_rand = function () {
var n = new BigInteger(this.selectedCurve.N);
var n1 = n.subtract(BigInteger.ONE);
var r = new BigInteger(n.bitLength(), this.rng);
return r.mod(n1).add(BigInteger.ONE);
}
ellipticEncryption.senderRandom = function () {
var r = this.pick_rand();
return r.toString();
};
ellipticEncryption.receiverRandom = function () {
//This is receivers private key. For now we will use random. CHANGE IT LATER
var r = this.pick_rand();
return r.toString();
}
ellipticEncryption.senderPublicString = function (senderPrivateKey) {
var senderKeyECData = {};
var curve = this.get_curve();
var G = this.get_G(curve);
var a = new BigInteger(senderPrivateKey);
var P = G.multiply(a);
senderKeyECData.XValuePublicString = P.getX().toBigInteger().toString();
senderKeyECData.YValuePublicString = P.getY().toBigInteger().toString();
return senderKeyECData;
}
//In real life ellipticEncryption.receiverPublicString is the public key of the receiver.
//you don't have to run receiverRandom and the bottom function
ellipticEncryption.receiverPublicString = function (receiverPublicKey) {
var receiverKeyECData = {};
var curve = this.get_curve();
var G = this.get_G(curve);
var a = new BigInteger(receiverPublicKey);
var P = G.multiply(a);
receiverKeyECData.XValuePublicString = P.getX().toBigInteger().toString();
receiverKeyECData.YValuePublicString = P.getY().toBigInteger().toString();
return receiverKeyECData;
}
ellipticEncryption.senderSharedKeyDerivation = function (receiverPublicStringXValue,
receiverPublicStringYValue, senderPrivateKey) {
var senderDerivedKey = {};
var curve = this.get_curve();
var P = new EllipticCurve.PointFp(curve,
curve.fromBigInteger(new BigInteger(receiverPublicStringXValue)),
curve.fromBigInteger(new BigInteger(receiverPublicStringYValue)));
var a = new BigInteger(senderPrivateKey);
var S = P.multiply(a);
senderDerivedKey.XValue = S.getX().toBigInteger().toString();
senderDerivedKey.YValue = S.getY().toBigInteger().toString();
return senderDerivedKey;
}
ellipticEncryption.receiverSharedKeyDerivation = function (senderPublicStringXValue,
senderPublicStringYValue, receiverPrivateKey) {
var receiverDerivedKey = {};
var curve = this.get_curve();
var P = new EllipticCurve.PointFp(curve,
curve.fromBigInteger(new BigInteger(senderPublicStringXValue)),
curve.fromBigInteger(new BigInteger(senderPublicStringYValue)));
var a = new BigInteger(receiverPrivateKey);
var S = P.multiply(a);
receiverDerivedKey.XValue = S.getX().toBigInteger().toString();
receiverDerivedKey.YValue = S.getY().toBigInteger().toString();
return receiverDerivedKey;
}
})("secp256k1"); // End of EllipticCurveEncryption Object
</script>
<!-- Kademelia -->
<script>
/*Kademlia DHT K-bucket implementation as a binary tree.*/
if (typeof reactor == "undefined" || !reactor) {
(function () {
function Event(name) {
this.name = name;
this.callbacks = [];
}
Event.prototype.registerCallback = function (callback) {
this.callbacks.push(callback);
};
function Reactor() {
this.events = {};
}
Reactor.prototype.registerEvent = function (eventName) {
var event = new Event(eventName);
this.events[eventName] = event;
};
Reactor.prototype.dispatchEvent = function (eventName, eventArgs) {
this.events[eventName].callbacks.forEach(function (callback) {
callback(eventArgs);
});
};
Reactor.prototype.addEventListener = function (eventName, callback) {
this.events[eventName].registerCallback(callback);
};
window.reactor = new Reactor();
})();
}
reactor.registerEvent('added');
reactor.addEventListener('added', function (someObject) {
console.log('Added fired with data ' + someObject);
});
reactor.registerEvent('removed');
reactor.addEventListener('removed', function (someObject) {
console.log('Removed fired with data ' + someObject);
});
reactor.registerEvent('updated');
reactor.addEventListener('updated', function (someObject) {
console.log('Updated fired with data ' + someObject);
});
reactor.registerEvent('bucket_full');
reactor.addEventListener('bucket_full', function (someObject) {
console.log('Bucket full ' + someObject);
});
/*
//Sample Usage
//Creating and defining the event
reactor.registerEvent('big bang');
reactor.addEventListener('big bang', function(someObject){
console.log('This is big bang listener yo!'+ someObject.a);
});
//Firing the event
reactor.dispatchEvent('big bang');
reactor.dispatchEvent('big bang',{a:1});
reactor.dispatchEvent('big bang',{a:55});
*/
//Checking if existing NodeID can be used
//This first block of if will initialize the configuration of KBucket
//Add Events, Messaging between different K-Buckets, and attach relevant distributed data
/**
* @param {Uint8Array} array1
* @param {Uint8Array} array2
* @return {Boolean}
*/
function arrayEquals(array1, array2) {
if (array1 === array2) {
return true
}
if (array1.length !== array2.length) {
return false
}
for (let i = 0, length = array1.length; i < length; ++i) {
if (array1[i] !== array2[i]) {
return false
}
}
return true
}
function createNode() {
return {
contacts: [],
dontSplit: false,
left: null,
right: null
}
}
function ensureInt8(name, val) {
if (!(val instanceof Uint8Array)) {
throw new TypeError(name + ' is not a Uint8Array')
}
}
/**
* Implementation of a Kademlia DHT k-bucket used for storing
* contact (peer node) information.
*
* @extends EventEmitter
*/
function BuildKBucket(options = {}) {
/**
* `options`:
* `distance`: Function
* `function (firstId, secondId) { return distance }` An optional
* `distance` function that gets two `id` Uint8Arrays
* and return distance (as number) between them.
* `arbiter`: Function (Default: vectorClock arbiter)
* `function (incumbent, candidate) { return contact; }` An optional
* `arbiter` function that givent two `contact` objects with the same `id`
* returns the desired object to be used for updating the k-bucket. For
* more details, see [arbiter function](#arbiter-function).
* `localNodeId`: Uint8Array An optional Uint8Array representing the local node id.
* If not provided, a local node id will be created via `randomBytes(20)`.
* `metadata`: Object (Default: {}) Optional satellite data to include
* with the k-bucket. `metadata` property is guaranteed not be altered by,
* it is provided as an explicit container for users of k-bucket to store
* implementation-specific data.
* `numberOfNodesPerKBucket`: Integer (Default: 20) The number of nodes
* that a k-bucket can contain before being full or split.
* `numberOfNodesToPing`: Integer (Default: 3) The number of nodes to
* ping when a bucket that should not be split becomes full. KBucket will
* emit a `ping` event that contains `numberOfNodesToPing` nodes that have
* not been contacted the longest.
*
* @param {Object=} options optional
*/
this.localNodeId = options.localNodeId || window.crypto.getRandomValues(new Uint8Array(20))
this.numberOfNodesPerKBucket = options.numberOfNodesPerKBucket || 20
this.numberOfNodesToPing = options.numberOfNodesToPing || 3
this.distance = options.distance || this.distance
// use an arbiter from options or vectorClock arbiter by default
this.arbiter = options.arbiter || this.arbiter
this.metadata = Object.assign({}, options.metadata)
ensureInt8('option.localNodeId as parameter 1', this.localNodeId)
this.root = createNode()
/**
* Default arbiter function for contacts with the same id. Uses
* contact.vectorClock to select which contact to update the k-bucket with.
* Contact with larger vectorClock field will be selected. If vectorClock is
* the same, candidat will be selected.
*
* @param {Object} incumbent Contact currently stored in the k-bucket.
* @param {Object} candidate Contact being added to the k-bucket.
* @return {Object} Contact to updated the k-bucket with.
*/
this.arbiter = function (incumbent, candidate) {
return incumbent.vectorClock > candidate.vectorClock ? incumbent : candidate
}
/**
* Default distance function. Finds the XOR
* distance between firstId and secondId.
*
* @param {Uint8Array} firstId Uint8Array containing first id.
* @param {Uint8Array} secondId Uint8Array containing second id.
* @return {Number} Integer The XOR distance between firstId
* and secondId.
*/
this.distance = function (firstId, secondId) {
let distance = 0
let i = 0
const min = Math.min(firstId.length, secondId.length)
const max = Math.max(firstId.length, secondId.length)
for (; i < min; ++i) {
distance = distance * 256 + (firstId[i] ^ secondId[i])
}
for (; i < max; ++i) distance = distance * 256 + 255
return distance
}
/**
* Adds a contact to the k-bucket.
*
* @param {Object} contact the contact object to add
*/
this.add = function (contact) {
ensureInt8('contact.id', (contact || {}).id)
let bitIndex = 0
let node = this.root
while (node.contacts === null) {
// this is not a leaf node but an inner node with 'low' and 'high'
// branches; we will check the appropriate bit of the identifier and
// delegate to the appropriate node for further processing
node = this._determineNode(node, contact.id, bitIndex++)
}
// check if the contact already exists
const index = this._indexOf(node, contact.id)
if (index >= 0) {
this._update(node, index, contact)
return this
}
if (node.contacts.length < this.numberOfNodesPerKBucket) {
node.contacts.push(contact)
reactor.dispatchEvent('added', contact)
return this
}
// the bucket is full
if (node.dontSplit) {
// we are not allowed to split the bucket
// we need to ping the first this.numberOfNodesToPing
// in order to determine if they are alive
// only if one of the pinged nodes does not respond, can the new contact
// be added (this prevents DoS flodding with new invalid contacts)
reactor.dispatchEvent('bucket_full', {1: node.contacts.slice(0, this.numberOfNodesToPing),2: contact})
return this
}
this._split(node, bitIndex)
return this.add(contact)
}
/**
* Get the n closest contacts to the provided node id. "Closest" here means:
* closest according to the XOR metric of the contact node id.
*
* @param {Uint8Array} id Contact node id
* @param {Number=} n Integer (Default: Infinity) The maximum number of
* closest contacts to return
* @return {Array} Array Maximum of n closest contacts to the node id
*/
this.closest = function (id, n = Infinity) {
ensureInt8('id', id)
if ((!Number.isInteger(n) && n !== Infinity) || n <= 0) {
throw new TypeError('n is not positive number')
}
let contacts = []
for (let nodes = [this.root], bitIndex = 0; nodes.length > 0 && contacts.length < n;) {
const node = nodes.pop()
if (node.contacts === null) {
const detNode = this._determineNode(node, id, bitIndex++)
nodes.push(node.left === detNode ? node.right : node.left)
nodes.push(detNode)
} else {
contacts = contacts.concat(node.contacts)
}
}
return contacts
.map(a => [this.distance(a.id, id), a])
.sort((a, b) => a[0] - b[0])
.slice(0, n)
.map(a => a[1])
}
/**
* Counts the total number of contacts in the tree.
*
* @return {Number} The number of contacts held in the tree
*/
this.count = function () {
// return this.toArray().length
let count = 0
for (const nodes = [this.root]; nodes.length > 0;) {
const node = nodes.pop()
if (node.contacts === null) nodes.push(node.right, node.left)
else count += node.contacts.length
}
return count
}
/**
* Determines whether the id at the bitIndex is 0 or 1.
* Return left leaf if `id` at `bitIndex` is 0, right leaf otherwise
*
* @param {Object} node internal object that has 2 leafs: left and right
* @param {Uint8Array} id Id to compare localNodeId with.
* @param {Number} bitIndex Integer (Default: 0) The bit index to which bit
* to check in the id Uint8Array.
* @return {Object} left leaf if id at bitIndex is 0, right leaf otherwise.
*/
this._determineNode = function (node, id, bitIndex) {
// *NOTE* remember that id is a Uint8Array and has granularity of
// bytes (8 bits), whereas the bitIndex is the bit index (not byte)
// id's that are too short are put in low bucket (1 byte = 8 bits)
// (bitIndex >> 3) finds how many bytes the bitIndex describes
// bitIndex % 8 checks if we have extra bits beyond byte multiples
// if number of bytes is <= no. of bytes described by bitIndex and there
// are extra bits to consider, this means id has less bits than what
// bitIndex describes, id therefore is too short, and will be put in low
// bucket
const bytesDescribedByBitIndex = bitIndex >> 3
const bitIndexWithinByte = bitIndex % 8
if ((id.length <= bytesDescribedByBitIndex) && (bitIndexWithinByte !== 0)) {
return node.left
}
const byteUnderConsideration = id[bytesDescribedByBitIndex]
// byteUnderConsideration is an integer from 0 to 255 represented by 8 bits
// where 255 is 11111111 and 0 is 00000000
// in order to find out whether the bit at bitIndexWithinByte is set
// we construct (1 << (7 - bitIndexWithinByte)) which will consist
// of all bits being 0, with only one bit set to 1
// for example, if bitIndexWithinByte is 3, we will construct 00010000 by
// (1 << (7 - 3)) -> (1 << 4) -> 16
if (byteUnderConsideration & (1 << (7 - bitIndexWithinByte))) {
return node.right
}
return node.left
}
/**
* Get a contact by its exact ID.
* If this is a leaf, loop through the bucket contents and return the correct
* contact if we have it or null if not. If this is an inner node, determine
* which branch of the tree to traverse and repeat.
*
* @param {Uint8Array} id The ID of the contact to fetch.
* @return {Object|Null} The contact if available, otherwise null
*/
this.get = function (id) {
ensureInt8('id', id)
let bitIndex = 0
let node = this.root
while (node.contacts === null) {
node = this._determineNode(node, id, bitIndex++)
}
// index of uses contact id for matching
const index = this._indexOf(node, id)
return index >= 0 ? node.contacts[index] : null
}
/**
* Returns the index of the contact with provided
* id if it exists, returns -1 otherwise.
*
* @param {Object} node internal object that has 2 leafs: left and right
* @param {Uint8Array} id Contact node id.
* @return {Number} Integer Index of contact with provided id if it
* exists, -1 otherwise.
*/
this._indexOf = function (node, id) {
for (let i = 0; i < node.contacts.length; ++i) {
if (arrayEquals(node.contacts[i].id, id)) return i
}
return -1
}
/**
* Removes contact with the provided id.
*
* @param {Uint8Array} id The ID of the contact to remove.
* @return {Object} The k-bucket itself.
*/
this.remove = function (id) {
ensureInt8('the id as parameter 1', id)
let bitIndex = 0
let node = this.root
while (node.contacts === null) {
node = this._determineNode(node, id, bitIndex++)
}
const index = this._indexOf(node, id)
if (index >= 0) {
const contact = node.contacts.splice(index, 1)[0]
reactor.dispatchEvent('removed', contact)
}
return this
}
/**
* Splits the node, redistributes contacts to the new nodes, and marks the
* node that was split as an inner node of the binary tree of nodes by
* setting this.root.contacts = null
*
* @param {Object} node node for splitting
* @param {Number} bitIndex the bitIndex to which byte to check in the
* Uint8Array for navigating the binary tree
*/
this._split = function (node, bitIndex) {
node.left = createNode()
node.right = createNode()
// redistribute existing contacts amongst the two newly created nodes
for (const contact of node.contacts) {
this._determineNode(node, contact.id, bitIndex).contacts.push(contact)
}
node.contacts = null // mark as inner tree node
// don't split the "far away" node
// we check where the local node would end up and mark the other one as
// "dontSplit" (i.e. "far away")
const detNode = this._determineNode(node, this.localNodeId, bitIndex)
const otherNode = node.left === detNode ? node.right : node.left
otherNode.dontSplit = true
}
/**
* Returns all the contacts contained in the tree as an array.
* If this is a leaf, return a copy of the bucket. `slice` is used so that we
* don't accidentally leak an internal reference out that might be
* accidentally misused. If this is not a leaf, return the union of the low
* and high branches (themselves also as arrays).
*
* @return {Array} All of the contacts in the tree, as an array
*/
this.toArray = function () {
let result = []
for (const nodes = [this.root]; nodes.length > 0;) {
const node = nodes.pop()
if (node.contacts === null) nodes.push(node.right, node.left)
else result = result.concat(node.contacts)
}
return result
}
/**
* Updates the contact selected by the arbiter.
* If the selection is our old contact and the candidate is some new contact
* then the new contact is abandoned (not added).
* If the selection is our old contact and the candidate is our old contact
* then we are refreshing the contact and it is marked as most recently
* contacted (by being moved to the right/end of the bucket array).
* If the selection is our new contact, the old contact is removed and the new
* contact is marked as most recently contacted.
*
* @param {Object} node internal object that has 2 leafs: left and right
* @param {Number} index the index in the bucket where contact exists
* (index has already been computed in a previous
* calculation)
* @param {Object} contact The contact object to update.
*/
this._update = function (node, index, contact) {
// sanity check
if (!arrayEquals(node.contacts[index].id, contact.id)) {
throw new Error('wrong index for _update')
}
const incumbent = node.contacts[index]
/***************Change made by Abhishek*************/
const selection = this.arbiter(incumbent, contact)
//const selection = localbitcoinplusplus.kademlia.arbiter(incumbent, contact);
// if the selection is our old contact and the candidate is some new
// contact, then there is nothing to do
if (selection === incumbent && incumbent !== contact) return
node.contacts.splice(index, 1) // remove old contact
node.contacts.push(selection) // add more recent contact version
/***************Change made by Abhishek*************/
reactor.dispatchEvent('updated', {
...incumbent,
...selection
})
//reactor.dispatchEvent('updated', incumbent.concat(selection))
}
}
</script>
<!----------------------------------------------------------------------------------
localbitcoinplusplus Code starts
----------------------------------------------------------------------------------->
<script type="text/javascript">
var localbitcoinplusplus = {
wallets: {},
trade: {},
rpc: {},
master_configurations: {}
};
Object.defineProperty(localbitcoinplusplus, 'server', {
value: {
btc_mainnet: "https://blockexplorer.com",
btc_testnet: "https://testnet.blockexplorer.com",
flo_mainnet: "http://flosight.duckdns.org",
//flo_testnet: "http://testnet-flosight.duckdns.org"
flo_testnet: "https://testnet.flocha.in"
},
writable: false,
configurable: false,
enumerable: false
});
Object.defineProperty(localbitcoinplusplus, 'RM_FLO_SENDING_ADDR', {
value: "oUbQYNBo7hWRcVN4dnx2ZQPfumfnTS7NsP",
writable: false,
configurable: false,
enumerable: true
});
localbitcoinplusplus.privateKey = {
isPrivateKey: function (key) {
return (
Bitcoin.ECKey.isWalletImportFormat(key) ||
Bitcoin.ECKey.isCompressedWalletImportFormat(key) ||
Bitcoin.ECKey.isHexFormat(key) ||
Bitcoin.ECKey.isBase64Format(key) ||
Bitcoin.ECKey.isMiniFormat(key)
);
},
getECKeyFromAdding: function (privKey1, privKey2) {
var n = EllipticCurve.getSECCurveByName("secp256k1").getN();
var ecKey1 = new Bitcoin.ECKey(privKey1);
var ecKey2 = new Bitcoin.ECKey(privKey2);
// if both keys are the same return null
if (ecKey1.getBitcoinHexFormat() == ecKey2.getBitcoinHexFormat()) return null;
if (ecKey1 == null || ecKey2 == null) return null;
var combinedPrivateKey = new Bitcoin.ECKey(ecKey1.priv.add(ecKey2.priv).mod(n));
// compressed when both keys are compressed
if (ecKey1.compressed && ecKey2.compressed) combinedPrivateKey.setCompressed(true);
return combinedPrivateKey;
},
getECKeyFromMultiplying: function (privKey1, privKey2) {
var n = EllipticCurve.getSECCurveByName("secp256k1").getN();
var ecKey1 = new Bitcoin.ECKey(privKey1);
var ecKey2 = new Bitcoin.ECKey(privKey2);
// if both keys are the same return null
if (ecKey1.getBitcoinHexFormat() == ecKey2.getBitcoinHexFormat()) return null;
if (ecKey1 == null || ecKey2 == null) return null;
var combinedPrivateKey = new Bitcoin.ECKey(ecKey1.priv.multiply(ecKey2.priv).mod(n));
// compressed when both keys are compressed
if (ecKey1.compressed && ecKey2.compressed) combinedPrivateKey.setCompressed(true);
return combinedPrivateKey;
},
// 58 base58 characters starting with 6P
isBIP38Format: function (key) {
key = key.toString();
return (/^6P[123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz]{56}$/.test(key));
},
BIP38EncryptedKeyToByteArrayAsync: function (base58Encrypted, passphrase, callback) {
var hex;
try {
hex = Bitcoin.Base58.decode(base58Encrypted);
} catch (e) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
// 43 bytes: 2 bytes prefix, 37 bytes payload, 4 bytes checksum
if (hex.length != 43) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
// first byte is always 0x01
else if (hex[0] != 0x01) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
var expChecksum = hex.slice(-4);
hex = hex.slice(0, -4);
var checksum = Bitcoin.Util.dsha256(hex);
if (checksum[0] != expChecksum[0] || checksum[1] != expChecksum[1] || checksum[2] !=
expChecksum[2] ||
checksum[3] != expChecksum[3]) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
var isCompPoint = false;
var isECMult = false;
var hasLotSeq = false;
// second byte for non-EC-multiplied key
if (hex[1] == 0x42) {
// key should use compression
if (hex[2] == 0xe0) {
isCompPoint = true;
}
// key should NOT use compression
else if (hex[2] != 0xc0) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
}
// second byte for EC-multiplied key
else if (hex[1] == 0x43) {
isECMult = true;
isCompPoint = (hex[2] & 0x20) != 0;
hasLotSeq = (hex[2] & 0x04) != 0;
if ((hex[2] & 0x24) != hex[2]) {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
} else {
callback(new Error(localbitcoinplusplus.translator.get("detailalertnotvalidprivatekey")));
return;
}
var decrypted;
var AES_opts = {
mode: new Crypto.mode.ECB(Crypto.pad.NoPadding),
asBytes: true
};
var verifyHashAndReturn = function () {
var tmpkey = new Bitcoin.ECKey(decrypted); // decrypted using closure
var base58AddrText = tmpkey.setCompressed(isCompPoint).getBitcoinAddress(); // isCompPoint using closure
checksum = Bitcoin.Util.dsha256(base58AddrText); // checksum using closure
if (checksum[0] != hex[3] || checksum[1] != hex[4] || checksum[2] != hex[5] || checksum[
3] !=
hex[6]) {
callback(new Error(localbitcoinplusplus.translator.get(
"bip38alertincorrectpassphrase"))); // callback using closure
return;
}
callback(tmpkey.getBitcoinPrivateKeyByteArray()); // callback using closure
};
if (!isECMult) {
var addresshash = hex.slice(3, 7);
Crypto_scrypt(passphrase, addresshash, 16384, 8, 8, 64, function (derivedBytes) {
var k = derivedBytes.slice(32, 32 + 32);
decrypted = Crypto.AES.decrypt(hex.slice(7, 7 + 32), k, AES_opts);
for (var x = 0; x < 32; x++) decrypted[x] ^= derivedBytes[x];
verifyHashAndReturn(); //TODO: pass in 'decrypted' as a param
});
} else {
var ownerentropy = hex.slice(7, 7 + 8);
var ownersalt = !hasLotSeq ? ownerentropy : ownerentropy.slice(0, 4);
Crypto_scrypt(passphrase, ownersalt, 16384, 8, 8, 32, function (prefactorA) {
var passfactor;
if (!hasLotSeq) { // hasLotSeq using closure
passfactor = prefactorA;
} else {
var prefactorB = prefactorA.concat(ownerentropy); // ownerentropy using closure
passfactor = Bitcoin.Util.dsha256(prefactorB);
}
// remove this ECKey from the pool (because user does not see it)
var userKeyPool = Bitcoin.KeyPool.getArray();
var kp = new Bitcoin.ECKey(passfactor);
var passpoint = kp.setCompressed(true).getPub();
Bitcoin.KeyPool.setArray(userKeyPool);
var encryptedpart2 = hex.slice(23, 23 + 16);
var addresshashplusownerentropy = hex.slice(3, 3 + 12);
Crypto_scrypt(passpoint, addresshashplusownerentropy, 1024, 1, 1, 64, function (
derived) {
var k = derived.slice(32);
var unencryptedpart2 = Crypto.AES.decrypt(encryptedpart2, k,
AES_opts);
for (var i = 0; i < 16; i++) {
unencryptedpart2[i] ^= derived[i + 16];
}
var encryptedpart1 = hex.slice(15, 15 + 8).concat(unencryptedpart2.slice(
0, 0 + 8));
var unencryptedpart1 = Crypto.AES.decrypt(encryptedpart1, k,
AES_opts);
for (var i = 0; i < 16; i++) {
unencryptedpart1[i] ^= derived[i];
}
var seedb = unencryptedpart1.slice(0, 0 + 16).concat(
unencryptedpart2.slice(
8, 8 + 8));
var factorb = Bitcoin.Util.dsha256(seedb);
var ps = EllipticCurve.getSECCurveByName("secp256k1");
var privateKey = BigInteger.fromByteArrayUnsigned(passfactor).multiply(
BigInteger.fromByteArrayUnsigned(factorb)).remainder(ps.getN());
decrypted = privateKey.toByteArrayUnsigned();
verifyHashAndReturn();
});
});
}
},
BIP38PrivateKeyToEncryptedKeyAsync: function (base58Key, passphrase, compressed, callback) {
var privKey = new Bitcoin.ECKey(base58Key);
var privKeyBytes = privKey.getBitcoinPrivateKeyByteArray();
var address = privKey.setCompressed(compressed).getBitcoinAddress();
// compute sha256(sha256(address)) and take first 4 bytes
var salt = Bitcoin.Util.dsha256(address).slice(0, 4);
// derive key using scrypt
var AES_opts = {
mode: new Crypto.mode.ECB(Crypto.pad.NoPadding),
asBytes: true
};
Crypto_scrypt(passphrase, salt, 16384, 8, 8, 64, function (derivedBytes) {
for (var i = 0; i < 32; ++i) {
privKeyBytes[i] ^= derivedBytes[i];
}
// 0x01 0x42 + flagbyte + salt + encryptedhalf1 + encryptedhalf2
var flagByte = compressed ? 0xe0 : 0xc0;
var encryptedKey = [0x01, 0x42, flagByte].concat(salt);
encryptedKey = encryptedKey.concat(Crypto.AES.encrypt(privKeyBytes, derivedBytes.slice(
32), AES_opts));
encryptedKey = encryptedKey.concat(Bitcoin.Util.dsha256(encryptedKey).slice(0, 4));
callback(Bitcoin.Base58.encode(encryptedKey));
});
},
BIP38GenerateIntermediatePointAsync: function (passphrase, lotNum, sequenceNum, callback) {
var noNumbers = lotNum === null || sequenceNum === null;
var rng = new SecureRandom();
var ownerEntropy, ownerSalt;
if (noNumbers) {
ownerSalt = ownerEntropy = new Array(8);
rng.nextBytes(ownerEntropy);
} else {
// 1) generate 4 random bytes
ownerSalt = new Array(4);
rng.nextBytes(ownerSalt);
// 2) Encode the lot and sequence numbers as a 4 byte quantity (big-endian):
// lotnumber * 4096 + sequencenumber. Call these four bytes lotsequence.
var lotSequence = BigInteger(4096 * lotNum + sequenceNum).toByteArrayUnsigned();
// 3) Concatenate ownersalt + lotsequence and call this ownerentropy.
var ownerEntropy = ownerSalt.concat(lotSequence);
}
// 4) Derive a key from the passphrase using scrypt
Crypto_scrypt(passphrase, ownerSalt, 16384, 8, 8, 32, function (prefactor) {
// Take SHA256(SHA256(prefactor + ownerentropy)) and call this passfactor
var passfactorBytes = noNumbers ? prefactor : Bitcoin.Util.dsha256(prefactor.concat(
ownerEntropy));
var passfactor = BigInteger.fromByteArrayUnsigned(passfactorBytes);
// 5) Compute the elliptic curve point G * passfactor, and convert the result to compressed notation (33 bytes)
var ellipticCurve = EllipticCurve.getSECCurveByName("secp256k1");
var passpoint = ellipticCurve.getG().multiply(passfactor).getEncoded(1);
// 6) Convey ownersalt and passpoint to the party generating the keys, along with a checksum to ensure integrity.
// magic bytes "2C E9 B3 E1 FF 39 E2 51" followed by ownerentropy, and then passpoint
var magicBytes = [0x2C, 0xE9, 0xB3, 0xE1, 0xFF, 0x39, 0xE2, 0x51];
if (noNumbers) magicBytes[7] = 0x53;
var intermediate = magicBytes.concat(ownerEntropy).concat(passpoint);
// base58check encode
intermediate = intermediate.concat(Bitcoin.Util.dsha256(intermediate).slice(0, 4));
callback(Bitcoin.Base58.encode(intermediate));
});
},
BIP38GenerateECAddressAsync: function (intermediate, compressed, callback) {
// decode IPS
var x = Bitcoin.Base58.decode(intermediate);
//if(x.slice(49, 4) !== Bitcoin.Util.dsha256(x.slice(0,49)).slice(0,4)) {
// callback({error: 'Invalid intermediate passphrase string'});
//}
var noNumbers = (x[7] === 0x53);
var ownerEntropy = x.slice(8, 8 + 8);
var passpoint = x.slice(16, 16 + 33);
// 1) Set flagbyte.
// set bit 0x20 for compressed key
// set bit 0x04 if ownerentropy contains a value for lotsequence
var flagByte = (compressed ? 0x20 : 0x00) | (noNumbers ? 0x00 : 0x04);
// 2) Generate 24 random bytes, call this seedb.
var seedB = new Array(24);
var rng = new SecureRandom();
rng.nextBytes(seedB);
// Take SHA256(SHA256(seedb)) to yield 32 bytes, call this factorb.
var factorB = Bitcoin.Util.dsha256(seedB);
// 3) ECMultiply passpoint by factorb. Use the resulting EC point as a public key and hash it into a Bitcoin
// address using either compressed or uncompressed public key methodology (specify which methodology is used
// inside flagbyte). This is the generated Bitcoin address, call it generatedaddress.
var ec = EllipticCurve.getSECCurveByName("secp256k1").getCurve();
var generatedPoint = ec.decodePointHex(localbitcoinplusplus.publicKey.getHexFromByteArray(
passpoint));
var generatedBytes = generatedPoint.multiply(BigInteger.fromByteArrayUnsigned(factorB)).getEncoded(
compressed);
var generatedAddress = (new Bitcoin.Address(Bitcoin.Util.sha256ripe160(generatedBytes))).toString();
// 4) Take the first four bytes of SHA256(SHA256(generatedaddress)) and call it addresshash.
var addressHash = Bitcoin.Util.dsha256(generatedAddress).slice(0, 4);
// 5) Now we will encrypt seedb. Derive a second key from passpoint using scrypt
Crypto_scrypt(passpoint, addressHash.concat(ownerEntropy), 1024, 1, 1, 64, function (
derivedBytes) {
// 6) Do AES256Encrypt(seedb[0...15]] xor derivedhalf1[0...15], derivedhalf2), call the 16-byte result encryptedpart1
for (var i = 0; i < 16; ++i) {
seedB[i] ^= derivedBytes[i];
}
var AES_opts = {
mode: new Crypto.mode.ECB(Crypto.pad.NoPadding),
asBytes: true
};
var encryptedPart1 = Crypto.AES.encrypt(seedB.slice(0, 16), derivedBytes.slice(32),
AES_opts);
// 7) Do AES256Encrypt((encryptedpart1[8...15] + seedb[16...23]) xor derivedhalf1[16...31], derivedhalf2), call the 16-byte result encryptedseedb.
var message2 = encryptedPart1.slice(8, 8 + 8).concat(seedB.slice(16, 16 + 8));
for (var i = 0; i < 16; ++i) {
message2[i] ^= derivedBytes[i + 16];
}
var encryptedSeedB = Crypto.AES.encrypt(message2, derivedBytes.slice(32), AES_opts);
// 0x01 0x43 + flagbyte + addresshash + ownerentropy + encryptedpart1[0...7] + encryptedpart2
var encryptedKey = [0x01, 0x43, flagByte].concat(addressHash).concat(ownerEntropy).concat(
encryptedPart1.slice(0, 8)).concat(encryptedSeedB);
// base58check encode
encryptedKey = encryptedKey.concat(Bitcoin.Util.dsha256(encryptedKey).slice(0, 4));
callback(generatedAddress, Bitcoin.Base58.encode(encryptedKey));
});
}
};
localbitcoinplusplus.publicKey = {
isPublicKeyHexFormat: function (key) {
key = key.toString();
return localbitcoinplusplus.publicKey.isUncompressedPublicKeyHexFormat(key) ||
localbitcoinplusplus.publicKey.isCompressedPublicKeyHexFormat(
key);
},
// 130 characters [0-9A-F] starts with 04
isUncompressedPublicKeyHexFormat: function (key) {
key = key.toString();
return /^04[A-Fa-f0-9]{128}$/.test(key);
},
// 66 characters [0-9A-F] starts with 02 or 03
isCompressedPublicKeyHexFormat: function (key) {
key = key.toString();
return /^0[2-3][A-Fa-f0-9]{64}$/.test(key);
},
getBitcoinAddressFromByteArray: function (pubKeyByteArray) {
var pubKeyHash = Bitcoin.Util.sha256ripe160(pubKeyByteArray);
var addr = new Bitcoin.Address(pubKeyHash);
return addr.toString();
},
getHexFromByteArray: function (pubKeyByteArray) {
return Crypto.util.bytesToHex(pubKeyByteArray).toString().toUpperCase();
},
getByteArrayFromAdding: function (pubKeyHex1, pubKeyHex2) {
var ecparams = EllipticCurve.getSECCurveByName("secp256k1");
var curve = ecparams.getCurve();
var ecPoint1 = curve.decodePointHex(pubKeyHex1);
var ecPoint2 = curve.decodePointHex(pubKeyHex2);
// if both points are the same return null
if (ecPoint1.equals(ecPoint2)) return null;
var compressed = (ecPoint1.compressed && ecPoint2.compressed);
var pubKey = ecPoint1.add(ecPoint2).getEncoded(compressed);
return pubKey;
},
getByteArrayFromMultiplying: function (pubKeyHex, ecKey) {
var ecparams = EllipticCurve.getSECCurveByName("secp256k1");
var ecPoint = ecparams.getCurve().decodePointHex(pubKeyHex);
var compressed = (ecPoint.compressed && ecKey.compressed);
// if both points are the same return null
ecKey.setCompressed(false);
if (ecPoint.equals(ecKey.getPubPoint())) {
return null;
}
var bigInt = ecKey.priv;
var pubKey = ecPoint.multiply(bigInt).getEncoded(compressed);
return pubKey;
},
// used by unit test
getDecompressedPubKeyHex: function (pubKeyHexComp) {
var ecparams = EllipticCurve.getSECCurveByName("secp256k1");
var ecPoint = ecparams.getCurve().decodePointHex(pubKeyHexComp);
var pubByteArray = ecPoint.getEncoded(0);
var pubHexUncompressed = localbitcoinplusplus.publicKey.getHexFromByteArray(pubByteArray);
return pubHexUncompressed;
}
};
localbitcoinplusplus.actions = {
parse_flo_comments: function (callback) {
if (this.floAddress == null) {
return false;
}
var request = new XMLHttpRequest();
request.open('GET',
`${localbitcoinplusplus.server.flo_testnet}/api/txs/?address=${this.floAddress}`, true);
request.onload = function () {
// Begin accessing JSON data here
var data = JSON.parse(this.response);
if (request.status >= 200 && request.status < 400) {
data.txs.forEach(tx => {
if (typeof tx !== "undefined" && typeof tx.floData == 'string' && tx.floData
.length > 0) {
callback(tx.floData);
}
});
} else {
console.log('error');
}
}
request.send();
},
fetch_configs: function (callback) {
this.floAddress = localbitcoinplusplus.RM_FLO_SENDING_ADDR;
this.parse_flo_comments(function (floData) {
let RMAssets = floData.slice(5);
// remove this line later
// btcTradeMargin is tolerable difference between Crypto trader should deposit and cryptos he actually deposited
RMAssets =
`masterFLOPubKey=029EF7838D4D103E62262394B5417E8ABFD75539D19E61CA5FD0C2051B69B29910
#!#tradableAsset1=BTC,FLO,BTC_TEST,FLO_TEST#!#tradableAsset2=INR,USD,BTC,FLO,BTC_TEST,FLO_TEST,
#!#validTradingAmount=10000,50000,100000,#!#btcTradeMargin=5000
#!#supernodesPubKeys=0315C3A20FE7096CC2E0F81A80D5F1A687B8F9EFA65242A0B0881E1BA3EE7D7D53,
03F7493F11B8E44B9798CD434D20FBE7FA34B9779D144984889D11A17C56A18742,039B4AA00DBFC0A6631DE6DA83526611A0E6B857D3579DF840BBDEAE8B6898E3B6,
#!#externalFiles={"d3js":"58f54395efa8346e8e94d12609770f66b916897e7f4e05f6c98780cffa5c70a3"},
#!#ShamirsMaxShares=8#!#supernodeSeeds={"ranchimall1":{"ip":"127.0.0.1","port":"9001","kbucketId":"oZxHcbSf1JC8t5GjutopWYXs7C6Fe9p7ps"},
"ranchimall2":{"ip":"127.0.0.1","port":"9002","kbucketId":"oTWjPupy3Z7uMdPcu5uXd521HBkcsLuSuM"},
"ranchimall3":{"ip":"127.0.0.1","port":"9003","kbucketId":"odYA6KagmbokSh9GY7yAfeTUZRtZLwecY1"}}`;
// RMAssets =
// `tradableAsset1=BTC,FLO,BTC_TEST,FLO_TEST#!#tradableAsset2=INR,USD,BTC,FLO,BTC_TEST,FLO_TEST,
// #!#supernodes=127.0.0.1,212.88.88.2#!#MASTER_NODE=023B9F60692A17FAC805D012C5C8ADA3DD19A980A3C5F0D8A5B3500CC54D6E8B75
// #!#MASTER_RECEIVING_ADDRESS=oVRq2nka1GtALQT8pbuLHAGjqAQ7PAo6uy#!#validTradingAmount=10000,50000,100000,#!#btcTradeMargin=5000
// #!#supernodesPubKeys=03692E641440795B6279F548C7156775EB624CC8A27FDA94C5E3B8945EC94DE1F1,02F22822D5E887ABBDA3D5E3A51574C547FEAAC00BF01185AA56858D4C9B00334F,
// #!#externalFiles={"d3js":"58f54395efa8346e8e94d12609770f66b916897e7f4e05f6c98780cffa5c70a3"},
// #!#ShamirsMaxShares=8#!#supernodeSeeds={"ranchimall1":{"ip":"ranchimall1.duckdns.org","port":"9002","kbucketId":"oURVEZQ6sPT8mwDVTGiBVPqJYqjctXYfF3"},
// "ranchimall2":{"ip":"ranchimall1.duckdns.org","port":"9003","kbucketId":"oapBngvTbcNCSfQfzJ9RS1QYfb4ppSQ9KQ"}}`;
let floAssetsArray = RMAssets.split('#!#');
if (floAssetsArray.length > 0 && typeof floAssetsArray[0] !== undefined &&
floAssetsArray[0].trim() !== "" && typeof floAssetsArray[1] !== undefined &&
floAssetsArray[1].trim() !== "") {
try {
floAssetsArray.map(function (assets_string) {
let k = assets_string.split('=');
if (k[1].indexOf(',') > 0) {
k[1] = k[1].split(',')
.map(val => !isNaN(val) ? parseFloat(val) : val.trim())
.filter(v => ![null, "", undefined, NaN].includes(v));
} else if (!isNaN(k[1])) {
k[1] = parseFloat(k[1]);
}
return Object.defineProperty(localbitcoinplusplus.master_configurations,
k[0], {
value: k[1],
writable: false,
configurable: false,
enumerable: true
});
});
deepFreeze(localbitcoinplusplus.master_configurations);
return callback(localbitcoinplusplus);
} catch (error) {
console.error('FATAL ERROR: Failed to fetch master configuration: ', error);
}
}
return false;
});
},
sync_with_supernode: function (trader_flo_address) {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"sync_with_supernode", {
"trader_flo_address": trader_flo_address,
"job": "SYNC_MY_LOCAL_DB_WITH_SUPERNODE_DB",
"receiver_flo_address": localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}).then(sync_request=>doSend(sync_request));
},
sync_primary_supernode_from_backup_supernode: function (primary_su="", backup_su="") {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"sync_primary_supernode_from_backup_supernode", {
"trader_flo_address": primary_su,
"job": "SYNC_PRIMARY_SUPERNODE_DB_WITH_BACKUP_SUPERNODE_DB",
"receiver_flo_address": backup_su,
}).then(sync_request=>doSend(sync_request, primary_su));
},
get_sharable_db_data: async function (dbTableNamesArray, backup_db="") {
let arr = {};
if (typeof backup_db=="string" && backup_db.length>0) {
let _readAllDB = readAllDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_readAllDB = foreign_db.backup_readAllDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
for (const elem of dbTableNamesArray) {
await _readAllDB(elem).then(e => arr[elem] = e);
}
return arr;
},
get_sharable_db_data_for_single_user: async function (dbTableNamesArray, backup_db="") {
let arr = {};
let _readDBbyIndex = readDBbyIndex;
if (typeof backup_db=="string" && backup_db.length>0) {
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_readDBbyIndex = foreign_db.backup_readDBbyIndex.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
for (const elem of dbTableNamesArray) {
await _readDBbyIndex(elem).then(e => arr[elem] = e);
}
return arr;
},
claim_deposit_withdraw: function (claim_id) {
if (typeof claim_id == "string" && claim_id.length > 0) {
try {
let deposit_withdraw_user_claim_obj = {
claim_id: claim_id
}
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_RPC = new localbitcoinplusplus.rpc;
let deposit_withdraw_user_claim_str = JSON.stringify(deposit_withdraw_user_claim_obj);
let deposit_withdraw_user_claim_hash = Crypto.SHA256(deposit_withdraw_user_claim_str);
let deposit_withdraw_user_claim_sign = RM_WALLET.sign(deposit_withdraw_user_claim_hash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
deposit_withdraw_user_claim_obj.userPubKey = localbitcoinplusplus.wallets.my_local_flo_public_key;
deposit_withdraw_user_claim_obj.trader_flo_address = localbitcoinplusplus.wallets.my_;
deposit_withdraw_user_claim_obj.hash = deposit_withdraw_user_claim_hash;
deposit_withdraw_user_claim_obj.sign = deposit_withdraw_user_claim_sign;
deposit_withdraw_user_claim_obj.receiver_flo_address = localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS;
RM_RPC
.send_rpc
.call(
this,
"deposit_withdraw_user_claim",
deposit_withdraw_user_claim_obj
).then(deposit_withdraw_claim=>doSend(deposit_withdraw_claim));
} catch (error) {
console.log(error);
}
}
},
build_deposit_withdraw_table: function(withdraw_data) {
if (typeof withdraw_data == "object" && withdraw_data.length>0) {
let action_req = ``;
let t = `<table>
<tr>
<th>Withdrawer Flo Id</th>
<th>Depositor Flo Id</th>
<th>Amount</th>
<th>Action required</th>
</tr>`;
withdraw_data.filter(wdf=>(wdf.status==2 || wdf.status==3)).map(wd=>{
if(typeof localbitcoinplusplus.wallets.my_local_flo_address=="string") {
let claim_id = `${wd.id}!!${localbitcoinplusplus.wallets.my_local_flo_address}`;
if (localbitcoinplusplus.wallets.my_local_flo_address==wd.trader_flo_address) {
action_req += `<p>Please click the button below only if you received the cash.</p>`;
action_req += `<button onclick="localbitcoinplusplus.actions.claim_deposit_withdraw('${claim_id}')">I received the money.</button>`;
} else if(localbitcoinplusplus.wallets.my_local_flo_address==wd.depositor_flo_id) {
action_req += `<p>Please click the button below only if you actually deposited the money.
Any fake claim can cause a heavy penalty.</p>`;
action_req += `<button onclick="localbitcoinplusplus.actions.claim_deposit_withdraw('${claim_id}')" >I deposited the money.</button>`;
}
}
t += `<tr>
<td>${wd.trader_flo_address}</td>
<td>${wd.depositor_flo_id}</td>
<td>${wd.withdraw_amount}</td>
<td>${action_req}</td>`;
t += `</tr>`;
});
t += `</table>`;
modalWindow(t);
}
},
reset_flo_keys: () => {
const promise1 = updateinDB('localbitcoinUser', {
id: "00-01",
myLocalFLOAddress: "",
myLocalFLOPublicKey: "",
myAddressTrustLevel: 1,
}, "00-01")
const promise2 = removeAllinDB('my_supernode_private_key_chunks');
return Promise.all([promise1, promise2]).then(() => true).catch(e => false);
},
// https://stackoverflow.com/a/39538518/5348972
delay: (t, v) => {
return new Promise(function(resolve) {
setTimeout(resolve.bind(null, v), t)
});
},
checkIfAllPreviousSupernodesAreDeadForAUserNode: (userFLoID="") => {
return new Promise(async (resolve, reject)=>{
if (typeof userFLoID !== "string" || userFLoID.length<1) {
console.warn(`Invalid FLO Id`);
return;
}
const s_id = await localbitcoinplusplus.kademlia.determineClosestSupernode(userFLoID);
const primarySuFloId = s_id[0].data.id;
let getSupernodeClosestSuObj = await localbitcoinplusplus.kademlia
.determineClosestSupernode("", 3, supernodeKBucket, primarySuFloId);
let promises = [];
let leaving_supernode_flo_id = "";
for (let index = 0; index < getSupernodeClosestSuObj.length; index++) {
const element = getSupernodeClosestSuObj[index];
if (element.data.id==localbitcoinplusplus.wallets.my_local_flo_address) break;
promises.push(readDBbyIndex('myClosestSupernodes', 'trader_flo_address', element.data.id));
leaving_supernode_flo_id = element.data.id;
}
Promise.all(promises).then(cs=>{
let isPreviousSupernodesLive = cs.map((su_status, index)=>
(typeof su_status[index] !== "object" || su_status[index].is_live == true )
);
if (!isPreviousSupernodesLive.includes(true)) {
resolve(true); // Every previous supernode is dead
} else {
resolve(false); // At least one previous supernode is alive
}
}).catch(e=>reject(e));
});
}
}
/*Modified functions from https://github.com/tristanls/k-bucket */
localbitcoinplusplus.kademlia = {
decodeBase58Address: function (blockchain, address) {
let k = bitjs[blockchain].Base58.decode(address)
k.shift()
k.splice(-4, 4)
return Crypto.util.bytesToHex(k)
},
launchKBucket: function(flo_id) {
return new Promise((resolve, reject)=>{
try {
const KBucketId = localbitcoinplusplus.kademlia.floIdToKbucketId('FLO_TEST', flo_id);
const kbOptions = { localNodeId: KBucketId }
window.KBucket = new BuildKBucket(kbOptions);
const master_flo_pubKey = localbitcoinplusplus.master_configurations.masterFLOPubKey;
const master_flo_addr = bitjs.FLO_TEST.pubkey2address(master_flo_pubKey);
if(typeof master_flo_pubKey !== "string") return reject(false);
const SuKBucketId = localbitcoinplusplus.kademlia.floIdToKbucketId('FLO_TEST', master_flo_addr);
const SukbOptions = { localNodeId: SuKBucketId }
window.supernodeKBucket = new BuildKBucket(SukbOptions);
resolve(true);
} catch (error) {
reject(error);
}
});
},
launchSupernodesKBucket: function() {
localbitcoinplusplus.master_configurations.supernodesPubKeys.map(pubKey=>{
return new Promise((resolve, reject)=>{
try {
let flo_id = bitjs.FLO_TEST.pubkey2address(pubKey);
let kname = `SKBucket_${pubKey}`;
const KBucketId = localbitcoinplusplus.kademlia.floIdToKbucketId('FLO_TEST', flo_id)
const kbOptions = { localNodeId: KBucketId }
window[kname] = new BuildKBucket(kbOptions);
resolve(true);
} catch (error) {
reject(error);
}
})
})
},
addContact: function (id, data, KB=KBucket) {
const contact = {
id: id,
data: data
};
KB.add(contact)
},
addNewUserNodeInKbucket: function(blockchain, address, data, KB=KBucket) {
let decodedId = address;
try {
decodedId = this.floIdToKbucketId(blockchain, address);
} catch(e) {
decodedId = address;
}
const addNewUserNode = this.addContact(decodedId, data, KB);
return {decodedId:decodedId, data:data};
},
addNewUserNodeInKbucketAndDB: function (blockchain, address, data, KB=KBucket) {
let closestSupernodePubKey = localbitcoinplusplus.master_configurations
.supernodesPubKeys.filter(j=>bitjs.FLO_TEST.pubkey2address(j)==data.id);
let kbuck = this.addNewUserNodeInKbucket(blockchain, address, data, KB);
readDB('kBucketStore', kbuck.decodedId).then(kres=>{
if (typeof kres=="object") {
kres.data = data;
kres.primary_supernode_flo_public_key = closestSupernodePubKey[0]
} else {
kbuckObj={
id: kbuck.decodedId,
vectorClock: 0,
data: kbuck.data,
primary_supernode_flo_public_key: closestSupernodePubKey[0],
last_updated_on: + new Date(),
}
kres = kbuckObj;
}
updateinDB('kBucketStore', kres)
.then(ms=>showMessage(`INFO: Added/Updated a node in DB.`))
.catch(e=>{showMessage(`ERROR: Failed to add a node in DB.`)});
return Promise.resolve(kbuck);
});
},
addFullKBDataInKBucketAndDB: function(full_data, KB) {
let userKBId = '';
let isFloIdUint8 = full_data.id instanceof Uint8Array;
if (!isFloIdUint8) {
userKBId = this.floIdToKbucketId('FLO_TEST', full_data.data.id);
this.addContact(userKBId, full_data.data, KB);
full_data.id = userKBId;
} else {
this.addContact(full_data.id, full_data.data, KB);
}
updateinDB('kBucketStore', full_data)
.then(ms=>showMessage(`INFO: Added/Updated a node in DB.`))
.catch(e=>{showMessage(`ERROR: Failed to add a node in DB.`)});
},
floIdToKbucketId: function (blockchain, address) {
const decodedId = this.decodeBase58Address(blockchain, address);
const nodeIdBigInt = new BigInteger(decodedId, 16);
const nodeIdBytes = nodeIdBigInt.toByteArrayUnsigned();
const nodeIdNewInt8Array = new Uint8Array(nodeIdBytes);
return nodeIdNewInt8Array;
},
arbiter: function (incumbent, candidate) {
// we create a new object so that our selection is guaranteed to replace
// the incumbent
const merged = {
id: incumbent.id, // incumbent.id === candidate.id within an arbiter
data: incumbent.data
}
Object.keys(candidate.data).forEach(workerNodeId => {
merged.data[workerNodeId] = candidate.data[workerNodeId];
})
return merged;
},
newBase64DiscoverId: function (pubKey) {
let pubKeyBytes = Crypto.util.hexToBytes(pubKey);
return Crypto.util.bytesToBase64(pubKeyBytes);
},
restoreKbucket: function(flo_addr, blockchain="FLO_TEST", KB=KBucket) {
return new Promise((resolve, reject)=>{
readAllDB('kBucketStore')
.then(dbObject => {
if (typeof dbObject=="object") {
let su_flo_addr_array = localbitcoinplusplus.master_configurations.supernodesPubKeys
.map(pubk=>bitjs.FLO_TEST.pubkey2address(pubk));
// Prevent supernode to re-added in kbucket
dbObject
.filter(f=>!su_flo_addr_array.includes(f.data.id))
.map(dbObj=>{
this.addNewUserNodeInKbucket(blockchain, flo_addr, dbObj.data, KB);
});
} else {
reject(`Failed to restore kBucket.`);
}
resolve(dbObject);
});
})
},
restoreSupernodeKBucket: function() {
return new Promise((resolve, reject)=>{
const supernodeSeeds = localbitcoinplusplus.master_configurations.supernodeSeeds;
if (typeof supernodeSeeds !== "object") reject("Failed to get supernode seeds.");
let supernodeSeedsObj = JSON.parse(supernodeSeeds);
Object.entries(supernodeSeedsObj).map(seedObj=>{
let kbuck = this.addNewUserNodeInKbucket("FLO_TEST", seedObj[1].kbucketId,
{ id: seedObj[1].kbucketId }, supernodeKBucket);
});
resolve(true);
})
},
updateClosestSupernodeSeeds: function(flo_addr) {
return new Promise(async (resolve, reject) => {
await removeAllinDB('myClosestSupernodes');
let nearestSupernodeAddresslist = await localbitcoinplusplus.kademlia.addClosestSupernodeInDB(flo_addr);
nearestSupernodeAddresslist.map((nearestSupernodeAddress, index)=>{
updateinDB('myClosestSupernodes', {
id: index+1,
ip: nearestSupernodeAddress.ip,
port: nearestSupernodeAddress.port,
trader_flo_address: nearestSupernodeAddress.kbucketId,
is_live: true
}).then(updatedClosestSupernodes=>{
readAllDB('myClosestSupernodes').then(nearestSupernodeAddresslist=>{
showMessage(`INFO: Updated closest supernodes list successfully.`);
resolve(nearestSupernodeAddresslist);
});
});
});
});
},
getSupernodeSeed: function (flo_addr) {
return new Promise(async (resolve, reject) => {
let nearestSupernodeAddresslist = await readAllDB('myClosestSupernodes');
if (nearestSupernodeAddresslist.length<1) {
nearestSupernodeAddresslist = await this.updateClosestSupernodeSeeds(flo_addr);
}
resolve(nearestSupernodeAddresslist);
});
},
isNodePresentInMyKbucket: function(flo_id, KB=KBucket) {
return new Promise((resolve, reject)=>{
let kArray = KB.toArray();
let kArrayFloIds = kArray.map(k=>k.data.id);
if (kArrayFloIds.includes(flo_id)) {
resolve(true);
} else {
reject(false);
}
});
},
determineClosestSupernode: function(flo_addr="", n=1, KB=supernodeKBucket, su="") {
return new Promise((resolve, reject)=>{
let msg = ``;
if (typeof supernodeKBucket !== "object") {
msg = `ERROR: Supernode KBucket not found.`;
showMessage(msg);
reject(msg);
return false;
}
if (su.length>0) {
try {
let closestSupernodeMasterList = supernodeKBucket.closest(supernodeKBucket.localNodeId);
const index = closestSupernodeMasterList.findIndex(f=>f.data.id==su);
let tail = closestSupernodeMasterList.splice(0, index);
const newClosestSupernodeMasterList = closestSupernodeMasterList.concat(tail);
resolve(newClosestSupernodeMasterList);
return true;
} catch (error) {
reject(error);
}
return false;
}
try {
if(flo_addr.length < 0) {
showMessage(`WARNING: No Flo Id provided to determine closest Supenode.`);
return;
}
let isFloIdUint8 = flo_addr instanceof Uint8Array;
if (!isFloIdUint8) {
flo_addr = localbitcoinplusplus.kademlia.floIdToKbucketId('FLO_TEST', flo_addr);
}
const closestSupernode = supernodeKBucket.closest(flo_addr, n);
resolve(closestSupernode);
return true;
} catch (error) {
showMessage(error);
reject(error);
return false;
}
})
},
addClosestSupernodeInDB: function(flo_addr, KB=KBucket) {
return new Promise(async (resolve, reject)=>{
const supernodeSeeds = localbitcoinplusplus.master_configurations.supernodeSeeds;
if (typeof supernodeSeeds !== "object") reject("Failed to get supernode seeds.");
let supernodeSeedsObj = JSON.parse(supernodeSeeds);
Object.entries(supernodeSeedsObj).map(seedObj=>{
console.log(seedObj);
localbitcoinplusplus.kademlia.addNewUserNodeInKbucketAndDB(
"FLO_TEST", seedObj[1].kbucketId,
{ id: seedObj[1].kbucketId });
});
let primarySu = await this.determineClosestSupernode(flo_addr);
let nearestSupernode = await this.determineClosestSupernode(flo_addr="", n=1, supernodeKBucket, primarySu[0].data.id);
let nearestSupernodeIds = nearestSupernode.map(f=>f.data.id);
let supernodeSeedsArray = Object.values(supernodeSeedsObj)
.filter(seed=>nearestSupernodeIds.includes(seed.kbucketId))
.sort(function(a, b){
return nearestSupernodeIds.indexOf(a.kbucketId) - nearestSupernodeIds.indexOf(b.kbucketId);
});
if (supernodeSeedsArray.length>0) {
resolve(supernodeSeedsArray);
} else {
reject(false);
}
})
}
}
</script>
<!-- Encryption -->
<script>
localbitcoinplusplus.encrypt = {
p: BigInteger("FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F", 16),
exponent1: function () {
return localbitcoinplusplus.encrypt.p.add(BigInteger.ONE).divide(BigInteger("4"))
},
calculateY: function (x) {
let p = localbitcoinplusplus.encrypt.p;
let exp = localbitcoinplusplus.encrypt.exponent1();
// x is x value of public key in BigInteger format without 02 or 03 or 04 prefix
return x.modPow(BigInteger("3"), p).add(BigInteger("7")).mod(p).modPow(exp, p)
},
// Insert a compressed public key
getUncompressedPublicKey: function (compressedPublicKey) {
const p = localbitcoinplusplus.encrypt.p;
// Fetch x from compressedPublicKey
let pubKeyBytes = Crypto.util.hexToBytes(compressedPublicKey);
const prefix = pubKeyBytes.shift() // remove prefix
let prefix_modulus = prefix % 2;
pubKeyBytes.unshift(0) // add prefix 0
let x = new BigInteger(pubKeyBytes)
let xDecimalValue = x.toString()
// Fetch y
let y = localbitcoinplusplus.encrypt.calculateY(x);
let yDecimalValue = y.toString();
// verify y value
let resultBigInt = y.mod(BigInteger("2"));
let check = resultBigInt.toString() % 2;
if (prefix_modulus !== check) {
yDecimalValue = y.negate().mod(p).toString();
}
return {
x: xDecimalValue,
y: yDecimalValue
};
},
getSenderPublicKeyString: function () {
privateKey = ellipticCurveEncryption.senderRandom();
senderPublicKeyString = ellipticCurveEncryption.senderPublicString(privateKey);
return {
privateKey: privateKey,
senderPublicKeyString: senderPublicKeyString
}
},
deriveSharedKeySender: function (receiverCompressedPublicKey, senderPrivateKey) {
try {
let receiverPublicKeyString = localbitcoinplusplus.encrypt.getUncompressedPublicKey(
receiverCompressedPublicKey);
var senderDerivedKey = {
XValue: "",
YValue: ""
};
senderDerivedKey = ellipticCurveEncryption.senderSharedKeyDerivation(
receiverPublicKeyString.x,
receiverPublicKeyString.y, senderPrivateKey);
return senderDerivedKey;
} catch (error) {
return new Error(error);
}
},
deriveReceiverSharedKey: function (senderPublicKeyString, receiverPrivateKey) {
return ellipticCurveEncryption.receiverSharedKeyDerivation(
senderPublicKeyString.XValuePublicString, senderPublicKeyString.YValuePublicString,
receiverPrivateKey);
},
getReceiverPublicKeyString: function (privateKey) {
return ellipticCurveEncryption.receiverPublicString(privateKey);
},
deriveSharedKeyReceiver: function (senderPublicKeyString, receiverPrivateKey) {
try {
return ellipticCurveEncryption.receiverSharedKeyDerivation(senderPublicKeyString.XValuePublicString,
senderPublicKeyString.YValuePublicString, receiverPrivateKey);
} catch (error) {
return new Error(error);
}
},
encryptMessage: function (data, receiverCompressedPublicKey) {
var senderECKeyData = localbitcoinplusplus.encrypt.getSenderPublicKeyString();
var senderDerivedKey = {
XValue: "",
YValue: ""
};
var senderPublicKeyString = {};
senderDerivedKey = localbitcoinplusplus.encrypt.deriveSharedKeySender(
receiverCompressedPublicKey, senderECKeyData.privateKey);
console.log("senderDerivedKey", senderDerivedKey);
let senderKey = senderDerivedKey.XValue + senderDerivedKey.YValue;
let secret = Crypto.AES.encrypt(data, senderKey);
return {
secret: secret,
senderPublicKeyString: senderECKeyData.senderPublicKeyString
};
},
decryptMessage: function (secret, senderPublicKeyString) {
var receiverDerivedKey = {
XValue: "",
YValue: ""
};
var receiverECKeyData = {};
let myPrivateKey = localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY;
if (typeof myPrivateKey !== "string") throw new Error("No private key found.");
const RM_WALLET = new localbitcoinplusplus.wallets;
let privateKey = RM_WALLET.wifToDecimal(myPrivateKey, true);
if (typeof privateKey.privateKeyDecimal !== "string") throw new Error(
"Failed to detremine your private key.");
receiverECKeyData.privateKey = privateKey.privateKeyDecimal;
receiverDerivedKey = localbitcoinplusplus.encrypt.deriveReceiverSharedKey(senderPublicKeyString,
receiverECKeyData.privateKey);
console.log("receiverDerivedKey", receiverDerivedKey);
let receiverKey = receiverDerivedKey.XValue + receiverDerivedKey.YValue;
let decryptMsg = Crypto.AES.decrypt(secret, receiverKey);
return decryptMsg;
},
// This function is only useful when sender and receiver are both online.
// If receiver is not online he might never get the message
messageBroadcasting: function (message, flo_id, rpc_subject="messageBroadcasting") {
readDB('userPublicData', flo_id).then((res) => {
pubKey = res.trader_flo_pubKey;
let data = localbitcoinplusplus.encrypt.encryptMessage(message, pubKey);
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, rpc_subject, {data: data,
receiver_flo_address: flo_id,
trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address
}).then(bar=>doSend(bar));
});
},
transmitMessageToMiddleMan: function (dataToBeSentToReceiver, receiverFloAddress) {
const RM_RPC = new localbitcoinplusplus.rpc;
dataToBeSentToReceiver.sender_flo_address = localbitcoinplusplus.wallets.my_local_flo_address;
dataToBeSentToReceiver.trader_flo_address = localbitcoinplusplus.wallets.my_local_flo_address
RM_RPC
.send_rpc
.call(this, "MessageForMiddleman", dataToBeSentToReceiver)
.then(bar=>doSend(bar));
}
}
</script>
<!-- Misc functions -->
<script>
// log event in the console
function LogEvent(msg) {
log.textContent += "> " + msg + "\n";
var ot = log.scrollHeight - log.clientHeight;
if (ot > 0) log.scrollTop = ot;
}
function showMessage(msg='', t=10000) {
if (msg.length>0) LogEvent(msg);
displayMessages();
setTimeout(function(){
closeMessage();
clearTimeout();
}, t);
}
function displayMessages() {
document.getElementById("mySidebar").style.width = "98%";
document.getElementById("mySidebar").style.display = "block";
}
function closeMessage() {
document.getElementById("mySidebar").style.display = "none";
}
function rand(a, b, multiple) {
return Math.floor(Math.random(a, b) * multiple);
}
/*https://developer.mozilla.org/en-US/docs/Web/JavaScript/Reference/Global_Objects/Object/freeze*/
function deepFreeze(object) {
// Retrieve the property names defined on object
var propNames = Object.getOwnPropertyNames(object);
// Freeze properties before freezing self
for (let name of propNames) {
let value = object[name];
object[name] = value && typeof value === "object" ?
deepFreeze(value) : value;
}
return Object.freeze(object);
}
function randomNoRepeats(array) {
var copy = array.slice(0);
return function () {
if (copy.length < 1) {
copy = array.slice(0);
}
var index = Math.floor(Math.random() * copy.length);
var item = copy[index];
copy.splice(index, 1);
return item;
};
}
function duplicatesInArray(arr) {
arr.reduce(function (acc, el, i, arr) {
if (arr.indexOf(el) !== i && acc.indexOf(el) < 0) acc.push(el);
return acc;
}, []);
}
/* Function to load files to db */
function readBlob(file_name) {
var files = document.getElementById('upload_file_db').files;
if (!files.length) return ('Please select a file!');
if (typeof file_name !== "string") {
let err_msg='Please provide a valid file name.';
showMessage(err_msg);
throw new Error(err_msg);
};
var file = files[0];
var start = 0;
var stop = file.size - 1;
var reader = new FileReader();
// If we use onloadend, we need to check the readyState.
reader.onloadend = function (evt) {
if (evt.target.readyState == FileReader.DONE) { // DONE == 2
let data = evt.target.result;
let hash = Crypto.SHA256(data);
updateinDB("external_files", {
filename: file_name,
filehash: hash,
content: data,
});
};
};
var blob = file.slice(start, stop + 1);
reader.readAsBinaryString(blob);
}
function uploadFileToDB() {
const d3div = document.getElementById('d3div');
const fileUploadDiv = document.createElement('div');
const dbFileLabel = document.createElement('label');
const dbFileDivText = document.createTextNode('Choose File');
dbFileLabel.appendChild(dbFileDivText);
dbFileLabel.className += ` button bg-purple mg-5 `;
const dbFile = document.createElement('input');
dbFile.className += ` hidden `;
dbFile.setAttribute("type", "file");
dbFile.setAttribute("id", "upload_file_db");
const readBytesButtons = document.createElement("input");
readBytesButtons.type = 'button';
readBytesButtons.className += ` button bg-purple mg-5 `;
readBytesButtons.setAttribute("id", "uploadFileButton");
readBytesButtons.value = "Upload File";
dbFileLabel.appendChild(dbFile);
d3div.appendChild(dbFileLabel);
d3div.appendChild(readBytesButtons);
d3div.appendChild(fileUploadDiv);
document.querySelector('#uploadFileButton').addEventListener('click', function (evt) {
if (evt.target.tagName.toLowerCase() == 'button') {
let fname = prompt("Enter name of this file.");
readBlob(fname);
}
}, false);
}
function modalWindow(message) {
var modal = document.getElementById('myModal');
var msg = document.getElementById("modal_msg");
msg.innerHTML = message;
// Get the <span> element that closes the modal
var span = document.getElementsByClassName("close")[0];
// When the user clicks on <span> (x), close the modal
span.onclick = function () {
modal.style.display = "none";
}
// When the user clicks anywhere outside of the modal, close it
window.onclick = function (event) {
if (event.target == modal) {
modal.style.display = "none";
}
}
modal.style.display = "block";
}
</script>
<!-- Wallet Operations (Generate, Sign and Verify) -->
<script>
var wallets = localbitcoinplusplus.wallets = function (wallets) {};
const MY_PRIVATE_KEY_SHAMIRS_SHARES = localbitcoinplusplus.wallets.private_key_shamirs_secrets_shares = [];
wallets.prototype = {
ecparams: EllipticCurve.getSECCurveByName("secp256k1"),
generateFloKeys: function (pk, crypto = "FLO_TEST") {
if (crypto == "BTC") {
privKeyPrefix = 0x80; //mainnet 0x80, testnet: 0xEF
networkVersion = 0x00; //mainnet 0x23, testnet: 0x6F
} else if (crypto == "BTC_TEST") {
privKeyPrefix = 0xEF;
networkVersion = 0x6F;
} else if (crypto == "FLO") {
privKeyPrefix = 0xA3; //mainnet 0xa3, testnet: 0xef
networkVersion = 0x23; //mainnet 0x23, testnet: 0x73
} else if (crypto == "FLO_TEST") {
privKeyPrefix = 0xEF;
networkVersion = 0x73;
} else {
privKeyPrefix = 0xEF;
networkVersion = 0x73;
}
var privateKey = pk || Bitcoin.ECDSA.getBigRandom(EllipticCurve.getSECCurveByName("secp256k1")
.getN());
// changesMadeByAbhishek: Change private key prefix before initing key
Bitcoin.ECKey.privateKeyPrefix = privKeyPrefix;
var key = new Bitcoin.ECKey(privateKey);
key.setCompressed(true);
var privateKeyHex = key.getBitcoinHexFormat();
var privateKeyWIF = key.getBitcoinWalletImportFormat();
var publicKeyHex = localbitcoinplusplus.publicKey.getHexFromByteArray(key.getPubPoint().getEncoded(
1)).toString().toUpperCase();
var pubKeyHash = key.getPubKeyHash();
var pubKeyHex = key.getPubKeyHex();
var address = key.getBitcoinAddress(networkVersion);
return {
privateKeyWIF,
pubKeyHex,
address
};
},
sign: function (msg, privateKeyHex) {
if (crypto == "BTC") {
privKeyPrefix = 0x80; //mainnet 0x80, testnet: 0xEF
networkVersion = 0x00; //mainnet 0x23, testnet: 0x6F
} else if (crypto == "BTC_TEST") {
privKeyPrefix = 0xEF;
networkVersion = 0x6F;
} else if (crypto == "FLO") {
privKeyPrefix = 0xA3; //mainnet 0xa3, testnet: 0xef
networkVersion = 0x23; //mainnet 0x23, testnet: 0x73
} else if (crypto == "FLO_TEST") {
privKeyPrefix = 0xEF;
networkVersion = 0x73;
} else {
privKeyPrefix = 0xEF;
networkVersion = 0x73;
}
Bitcoin.ECKey.privateKeyPrefix = privKeyPrefix;
var key = new Bitcoin.ECKey(privateKeyHex);
key.setCompressed(true);
var privateKeyArr = key.getBitcoinPrivateKeyByteArray(privateKeyHex);
privateKey = BigInteger.fromByteArrayUnsigned(privateKeyArr);
var messageHash = Crypto.SHA256(msg);
var messageHashBigInteger = new BigInteger(messageHash);
var messageSign = Bitcoin.ECDSA.sign(messageHashBigInteger, privateKey);
var sighex = Crypto.util.bytesToHex(messageSign);
return sighex;
},
verify: function (msg, signatureHex, publicKeyHex) {
var msgHash = Crypto.SHA256(msg);
var messageHashBigInteger = new BigInteger(msgHash);
var sigBytes = Crypto.util.hexToBytes(signatureHex);
var signature = Bitcoin.ECDSA.parseSig(sigBytes);
var publicKeyPoint = this.ecparams.getCurve().decodePointHex(publicKeyHex);
var verify = Bitcoin.ECDSA.verifyRaw(messageHashBigInteger, signature.r, signature.s,
publicKeyPoint);
return verify;
},
createShamirsSecretShares: function (str, total_shares, threshold_limit) {
if (str.length > 0) {
// convert the text into a hex string
var strHex = secrets.str2hex(str);
// split into total_shares shares, with a threshold of threshold_limit
var shares = secrets.share(strHex, total_shares, threshold_limit);
return shares;
}
return false;
},
verifyShamirsSecret: function (sharesArray, str) {
// combine sharesArray:
var comb = secrets.combine(sharesArray);
//convert back to UTF string:
comb = secrets.hex2str(comb);
return comb === str;
},
retrieveShamirSecret: function (sharesArray) {
if (sharesArray.length > 0) {
// combine sharesArray:
var comb = secrets.combine(sharesArray.slice(0, sharesArray.length));
//convert back to UTF string:
comb = secrets.hex2str(comb);
return comb;
}
return false;
},
manually_assign_my_private_key: function() {
readDB('localbitcoinUser', '00-01').then(usr=>{
if (typeof usr=="object" && usr.myLocalFLOAddress.length>0) {
const RM_WALLET = new localbitcoinplusplus.wallets;
const pk_manual = prompt("Please enter your private key: ");
let gen_new_keys = RM_WALLET.generateFloKeys(pk_manual);
if (gen_new_keys.address==usr.myLocalFLOAddress) {
Object.defineProperty(localbitcoinplusplus.wallets, 'MY_SUPERNODE_PRIVATE_KEY', {
value: gen_new_keys.privateKeyWIF,
writable: false,
configurable: false,
enumerable: false
});
if (localbitcoinplusplus.is_ui_loaded==false) {
loadExternalFiles();
dataBaseUIOperations();
}
Promise.resolve(true);
} else {
let mes = `WARNING: Failed to build your private key. You can reset keys and generate new keys from keys section below.`;
showMessage(mes);
Promise.reject(mes);
}
}
}).catch(e=>{
let mes = `WARNING: Failed to build your private key. You can reset keys and generate new keys from keys section below.`;
showMessage(mes);
Promise.reject(mes);
});
},
rebuild_my_private_key: function (transactionKey) {
const RM_WALLET = new localbitcoinplusplus.wallets;
let my_pvt_key = RM_WALLET.rebuild_private_key(MY_PRIVATE_KEY_SHAMIRS_SHARES, transactionKey);
if (typeof my_pvt_key == "undefined") return this.manually_assign_my_private_key();
Object.defineProperty(localbitcoinplusplus.wallets, 'MY_SUPERNODE_PRIVATE_KEY', {
value: my_pvt_key,
writable: false,
configurable: false,
enumerable: false
});
},
rebuild_private_key: function (private_key_shamirs_shares, transactionKey) {
let decoded_shares = private_key_shamirs_shares.map(encryptedShares => {
return Crypto.AES.decrypt(encryptedShares, transactionKey);
});
let my_pvt_key = this.retrieveShamirSecret(decoded_shares);
return my_pvt_key;
},
getUserPublicKey: function (flo_address, callback) {
readDB('userPublicData', flo_address).then(function (res) {
if (typeof res == "object" && typeof res.trader_flo_pubKey == "string") {
return callback(res.trader_flo_pubKey);
} else {
return callback();
}
});
},
getSuperNodePublicKey: async function (user_flo_address) {
try {
let getUserData = await readDB("userPublicData", user_flo_address);
if (typeof getUserData == "object") return getUserData.supernode_flo_public_key;
return false;
} catch (error) {
return false;
}
},
wifToDecimal(pk_wif, isPubKeyCompressed = false) {
let pk = Bitcoin.Base58.decode(pk_wif)
pk.shift()
pk.splice(-4, 4)
//If the private key corresponded to a compressed public key, also drop the last byte (it should be 0x01).
if (isPubKeyCompressed == true) pk.pop()
pk.unshift(0)
privateKeyDecimal = BigInteger(pk).toString()
privateKeyHex = Crypto.util.bytesToHex(pk)
return {
privateKeyDecimal: privateKeyDecimal,
privateKeyHex: privateKeyHex
}
},
distributeShamirsSecretShares: function (users_entered_private_key) {
if (users_entered_private_key.length < 0) throw new Error("Private key is empty.");
const RM_WALLET = new localbitcoinplusplus.wallets;
let publicKey_for_users_entered_private_key;
try {
publicKey_for_users_entered_private_key = RM_WALLET.generateFloKeys(
users_entered_private_key).pubKeyHex;
} catch (error) {
throw new Error(error);
}
let pvt_key_shamirs_secret_shares = RM_WALLET.createShamirsSecretShares(
users_entered_private_key, 10, 5);
if (typeof pvt_key_shamirs_secret_shares == "object" && pvt_key_shamirs_secret_shares.length >
0) {
// Add suprnode's own private keys to DB
let supernode_transaction_key = Crypto.util.randomBytes(64);
let pvt_key_shamirs_secret_shares_array = pvt_key_shamirs_secret_shares.map(chunks => {
let chunk_ids = Crypto.util.bytesToHex(Crypto.util.randomBytes(64));
let chunk_array = {
"id": chunk_ids,
"privateKeyChunks": Crypto.AES.encrypt(chunks,
supernode_transaction_key)
};
try {
addDB("my_supernode_private_key_chunks", {
id: chunk_ids,
supernode_transaction_key: supernode_transaction_key
});
} catch (error) {
throw new Error(error);
}
return chunk_array;
});
// Send chunks of private keys to other supernodes
pvt_key_shamirs_secret_shares_array.map(shares => {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "store_shamirs_secret_pvtkey_shares", shares)
.then(store_pvtkey_req=>doSend(store_pvtkey_req));
});
return Promise.resolve(true);
}
},
getSupernodePublicKeyFromFloId: function(flo_id='') {
let su_arr = localbitcoinplusplus.master_configurations.supernodesPubKeys
.map(s=>[s, bitjs.FLO_TEST.pubkey2address(s)])
.filter(f=>f[1]==flo_id);
return su_arr[0];
},
}
</script>
<!-- RPC Object -->
<script>
var Rpc = localbitcoinplusplus.rpc = function () {
this.rpc_req_id;
this.valid_job = ["trade_buy", "trade_sell", "sync"];
}
Rpc.prototype = {
send_rpc(method, ...params) {
return new Promise((resolve, reject)=>{
var request = new JSON_RPC.Request(method, params);
var id = request.id;
this.rpc_req_id = id;
(async function(request) {
if (typeof localbitcoinplusplus.wallets.my_local_flo_address == "string") {
request.globalParams.senderFloId = localbitcoinplusplus.wallets.my_local_flo_address;
if (typeof params[0].trader_flo_address !=="string") {
const my_closest_su = await localbitcoinplusplus.kademlia
.determineClosestSupernode(localbitcoinplusplus.wallets.my_local_flo_address);
if (typeof my_closest_su=="object") {
request.globalParams.primarySupernode = my_closest_su[0].data.id;
}
}
} else {
const resObj = await readDB('localbitcoinUser', '00-01');
if(typeof resObj !== "object" || typeof resObj.myLocalFLOAddress !== "string") return;
request.globalParams.senderFloId = resObj.myLocalFLOAddress;
if (typeof params[0].trader_flo_address !=="string") {
const my_closest_su = await localbitcoinplusplus.kademlia
.determineClosestSupernode(resObj.myLocalFLOAddress);
if (typeof my_closest_su=="object") {
request.globalParams.primarySupernode = my_closest_su[0].data.id;
}
}
}
if (typeof params[0].receiver_flo_address == "string") {
request.globalParams.receiverFloId = params[0].receiver_flo_address;
}
return resolve(request.toString());
})(request);
})
},
filter_legit_requests: function (flo_id=null, callback) {
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY === "string" &&
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY.length > 0
) {
const RM_WALLET = new localbitcoinplusplus.wallets;
let user_keys = RM_WALLET.generateFloKeys(localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
if (typeof user_keys == "object" && typeof user_keys.pubKeyHex == "string") {
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(user_keys.pubKeyHex)) {
if (typeof flo_id !== null || typeof flo_id !== 'undefined') {
localbitcoinplusplus.kademlia.determineClosestSupernode(flo_id, 4)
.then(my_closest_su=>{
if (user_keys.address === my_closest_su[0].data.id) {
return callback(true);
} else {
let su_arr = my_closest_su.map(m=>m.data.id);
if(su_arr.includes(flo_id)) {
return callback(true);
} else {
return callback(false);
}
}
});
} else {
return callback(false);
}
}
}
} else {
return callback(false);
}
},
filter_legit_backup_requests: function (flo_id=null, callback) {
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY === "string" &&
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY.length > 0
) {
const RM_WALLET = new localbitcoinplusplus.wallets;
let user_keys = RM_WALLET.generateFloKeys(localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
if (typeof user_keys == "object" && typeof user_keys.pubKeyHex == "string") {
if (localbitcoinplusplus.master_configurations
.supernodesPubKeys.includes(user_keys.pubKeyHex)) {
return callback(true);
} else {
return callback(false);
}
}
} else {
return callback(false);
}
},
async receive_rpc_response(request) {
var request = JSON.parse(request);
var params = request.params[0];
var method = request.method;
if (typeof params == "object" && typeof method == "string") {
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
let respective_trader_id = '';
if (typeof params.trader_flo_address == "string") respective_trader_id = params.trader_flo_address;
request.response = {};
let err_msg;
if (method=="sync_with_supernode") {
RM_RPC.filter_legit_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request === true && params.job ==
"SYNC_MY_LOCAL_DB_WITH_SUPERNODE_DB" && params.trader_flo_address.length >
0) {
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "userPublicData"
];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray).then(
function (su_db_data) {
if (typeof su_db_data == "object") {
su_db_data.trader_flo_address = params.trader_flo_address;
su_db_data.receiver_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this, "server_sync_response", su_db_data)
.then(server_sync_response=>doSend(server_sync_response))
}
});
}
});
}
RM_RPC.filter_legit_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
try {
// CHECK HERE IF USER IS INDULGED IN ANY MORE TRADE. IF TRUE RETURN ERROR
await readAllDB("deposit").then(function (res) {
if (typeof res == "object" && res.length > 0) {
let canUserTrade = res.filter(function (user) {
return (respective_trader_id == user.trader_flo_address
&& user.status==1);
});
if (canUserTrade.includes(true)) {
request.response =
`Trader id ${respective_trader_id} is not clear for trade currently.
You must finish your previous pending orders to qualify again to trade.`;
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "supernode_message", {
"trader_flo_address": respective_trader_id,
"receiver_flo_address": respective_trader_id,
"server_msg": request.response
}).thn(server_response=>doSend(server_response));
showMessage(request.response);
throw new Error(request.response);
return false;
}
}
});
// Check if user id is in deposit or withdraw. If true prevent him from trading
await readAllDB('withdraw_cash').then(function (res) {
if (typeof res == "object") {
let check_deposit_withdraw_id_array = res.filter(f => f.status === 2)
.map(m => {
if (m.trader_flo_address == respective_trader_id || m.deposit_withdraw_id_array ==
respective_trader_id) {
let server_msg =
`Trader id ${respective_trader_id} is not clear for trade currently.
You must finish your previous pending deposit/withdraw action to qualify again to trade.`;
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "supernode_message", {
"trader_flo_address": respective_trader_id,
"receiver_flo_address": respective_trader_id,
"server_msg": server_msg
}).then(server_response=>doSend(server_response));
showMessage(server_msg);
throw new Error(
"User has not finished previous pending actions."
);
}
});
}
});
} catch (error) {
throw new Error(error);
}
});
switch (method) {
case "trade_buy":
RM_RPC.filter_legit_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency);
if (typeof trade_margin.remaining_crypto_credit == "number" &&
typeof trade_margin.remaining_fiat_credit == "number") {
if (trade_margin.remaining_fiat_credit > 0 && trade_margin.remaining_fiat_credit >=
params.buy_price) {
request.response = RM_TRADE.trade_buy.call(this,
...request.params,
function (supernode_signed_res) {
supernode_signed_res.receiver_flo_address = params.trader_flo_address;
if (typeof supernode_signed_res == "object") {
RM_RPC
.send_rpc
.call(this,
"trade_buy_request_response",
supernode_signed_res)
.then(buy_request_response=>doSend(buy_request_response));
// Init trading
RM_TRADE.createTradePipes(params.currency);
return true;
}
});
} else {
err_msg = `Trade Margin Check Failed: You can only trade upto ${params.currency} ${trade_margin.remaining_fiat_credit}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Invalid trade margin figures.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "trade_sell":
RM_RPC.filter_legit_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency);
if (typeof trade_margin.remaining_crypto_credit == "number" &&
typeof trade_margin.remaining_fiat_credit == "number") {
let eqCrypto = RM_TRADE.calculateCryptoEquivalentOfCash(params.buy_price);
if (trade_margin.remaining_crypto_credit > 0 && trade_margin.remaining_crypto_credit >=
eqCrypto) {
request.response = RM_TRADE.trade_sell.call(
this, ...request.params,
function (supernode_signed_res) {
if (typeof supernode_signed_res == "object") {
supernode_signed_res.receiver_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this,
"trade_sell_request_response",
supernode_signed_res)
.then(sell_request_response=>doSend(sell_request_response));
// Init trading
RM_TRADE.createTradePipes(params.currency);
return true;
}
}
);
} else {
err_msg = `WARNING: Trade Margin Check Failed:
You can only trade upto ${params.currency} ${trade_margin.remaining_fiat_credit}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Invalid trade margin figures.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "sync_with_supernode":
// already processed above
break;
case "deposit_asset_request":
RM_RPC.filter_legit_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request !== true) return false;
// This code will only run for supernodes
if (typeof params.product !== "undefined" &&
(localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product) ||
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.product)) &&
typeof params.depositing_amount !== "undefined" &&
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.currency) &&
typeof localbitcoinplusplus.master_configurations.validTradingAmount !==
'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(
parseFloat(params.depositing_amount)) &&
typeof params.trader_flo_address == "string" &&
params.trader_flo_address.length > 0
) {
RM_WALLET.getUserPublicKey(params.trader_flo_address,
async function (requester_public_key) {
if (requester_public_key == undefined ||
requester_public_key == null) {
err_msg = 'Failed to get public key of the user.';
showMessage(err_msg);
throw new Error(err_msg);
}
params.depositor_public_key = requester_public_key;
await RM_TRADE.resolve_current_crypto_price_in_fiat(
params.product, params.currency);
if (localbitcoinplusplus.master_configurations.tradableAsset1
.includes(params.product)) {
let generate_btc_keys_for_requester = RM_WALLET
.generateFloKeys(null, params.product);
params.id = helper_functions.unique_id();
params.status = 1;
params.btc_address =
generate_btc_keys_for_requester.address;
params.bitcoinToBePaid = RM_TRADE.calculateCryptoEquivalentOfCash(
params.depositing_amount, params.currency,
params.product);
let receivedTradeInfo = { ...params };
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY ==
"undefined") {
err_msg = 'Failed to determine Super node signing key.';
showMessage(err_msg);
throw new Error(err_msg);
}
readDB("localbitcoinUser", "00-01").then(
function (su_data) {
if (typeof su_data == "object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys
.includes(su_data.myLocalFLOPublicKey)
) {
let receivedTradeInfoHash =
Crypto.SHA256(JSON.stringify(receivedTradeInfo));
receivedTradeInfo["depositDataHash"] = receivedTradeInfoHash;
receivedTradeInfo["order_validator_sign"] =
RM_WALLET.sign(receivedTradeInfoHash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
receivedTradeInfo["order_validator_public_key"] = su_data.myLocalFLOPublicKey;
try {
const this_btc_pvt_key =
generate_btc_keys_for_requester.privateKeyWIF;
const this_btc_tx_key =
Crypto.util.randomBytes(64);
const
this_btc_pvt_key_shamirs_secret =
RM_WALLET.createShamirsSecretShares(this_btc_pvt_key, 10, 5);
if (typeof this_btc_pvt_key_shamirs_secret ==
"object" &&
this_btc_pvt_key_shamirs_secret
.length > 0) {
addDB("deposit", receivedTradeInfo);
// Send the address to the requester
let
deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Please send ${params.product} ${params.bitcoinToBePaid} to the following addres: ${generate_btc_keys_for_requester.address}.`,
data: receivedTradeInfo
};
deposit_response_object.receiver_flo_address = params.trader_flo_address;
deposit_response_object.trader_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
let
this_btc_pvt_key_shamirs_secret_array =
this_btc_pvt_key_shamirs_secret
.map(chunks => {
let
chunk_ids =
Crypto.util
.bytesToHex(
Crypto
.util
.randomBytes(
64
));
let
chunk_array = {
"id": chunk_ids,
"privateKeyChunks": Crypto
.AES
.encrypt(
chunks,
this_btc_tx_key
),
"trader_flo_address": params.trader_flo_address
};
return chunk_array;
});
// Send chunks of private keys to other supernodes
this_btc_pvt_key_shamirs_secret_array
.map(shares => {
RM_RPC
.send_rpc
.call(
this,
"store_shamirs_secret_pvtkey_shares",
shares
).then(store_pvtkey_req=>doSend(store_pvtkey_req));
});
if (typeof localbitcoinplusplus
.wallets.my_local_flo_address ==
"string" &&
typeof localbitcoinplusplus
.wallets.my_local_flo_public_key ==
"string" &&
typeof localbitcoinplusplus
.master_configurations
.supernodesPubKeys ==
"object" &&
localbitcoinplusplus
.master_configurations
.supernodesPubKeys.includes(
localbitcoinplusplus
.wallets.my_local_flo_public_key
)) {
try {
let
this_btc_pvt_key_shamirs_secret__id_array =
this_btc_pvt_key_shamirs_secret_array
.map(i => i.id);
let
btc_private_key_shamirs_id =
this_btc_pvt_key_shamirs_secret__id_array;
let
supernode_transaction_key =
this_btc_tx_key;
const
system_btc_reserves_private_keys_object = {
id: helper_functions.unique_id(),
product: params.product,
btc_address: params.btc_address,
balance: null,
trader_flo_address: params.trader_flo_address,
btc_private_key_shamirs_id: btc_private_key_shamirs_id,
supernode_transaction_key: supernode_transaction_key
}
addDB(
"system_btc_reserves_private_keys",
system_btc_reserves_private_keys_object
);
} catch (error) {
throw new Error( error);
}
}
return true;
}
} catch (error) {
throw new Error(error);
}
// Send the address to the requester
let deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Please send the ${params.product} to ${generate_btc_keys_for_requester.address}.`,
data: receivedTradeInfo,
receiver_flo_address: params.trader_flo_address,
trader_flo_address: params.trader_flo_address,
};
RM_RPC.send_rpc
.call(this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
}
});
return false;
} else if (!localbitcoinplusplus.master_configurations
.tradableAsset1.includes(params.product)) {
params.id = helper_functions.unique_id();
params.status = 1;
// IMPORTANT - If deposit is a fiat make sure product and currency are both same
params.currency = params.product;
let receivedTradeInfo = { ...params };
readDB("localbitcoinUser", "00-01").then(
function (su_data) {
if (typeof su_data == "object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys
.includes(su_data.myLocalFLOPublicKey)
) {
let receivedTradeInfoHash =
Crypto.SHA256(JSON.stringify(
receivedTradeInfo));
receivedTradeInfo[
"depositDataHash"] =
receivedTradeInfoHash;
receivedTradeInfo[
"order_validator_sign"] =
RM_WALLET.sign(
receivedTradeInfoHash,
localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY
);
receivedTradeInfo[
"order_validator_public_key"
] = su_data.myLocalFLOPublicKey;
// YOU NEED TO DETERMINE A BANK ACCOUNT HERE IF NO ONE IS WITHDRAWING
try {
addDB("deposit",
receivedTradeInfo);
readDBbyIndex(
"withdraw_cash",
"status", 1).then(
function (
withdrawers_list
) {
if (typeof withdrawers_list ==
"object") {
if (
withdrawers_list.length > 0) {
withdrawers_list.filter(
wd => wd.currency ==
params.currency).map(
function (withdrawer) {
if (
withdrawer.withdraw_amount ==
params.depositing_amount &&
withdrawer.currency ==
params.currency
) {
withdrawer.status = 2; // A depositor has been asked to deposit money
withdrawer.depositor_found_at = + new Date();
withdrawer.depositor_flo_id = receivedTradeInfo.trader_flo_address;
updateinDB ("withdraw_cash", withdrawer, withdrawer.trader_flo_address);
receivedTradeInfo.status = 2; // withdrawer found. Now deposit money to his account
updateinDB(
"deposit",
receivedTradeInfo,
receivedTradeInfo.trader_flo_address
);
let withdrawer_bank_account = withdrawer.receivinAddress;
let deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Plese send the money to following bank address: "${withdrawer_bank_account}"`,
data: receivedTradeInfo,
withdrawer_data: withdrawer,
receiver_flo_address: receivedTradeInfo.trader_flo_address,
trader_flo_address: receivedTradeInfo.trader_flo_address,
};
RM_RPC.send_rpc.call(
this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
} else {
err_msg = "Deposit request failed: We could not find a withdrawer.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
);
} else {
//No one is withdrawing so provide your bank details
let
deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Plese send the money to following bank address: "System determined bank".`,
data: receivedTradeInfo,
receiver_flo_address: receivedTradeInfo.trader_flo_address,
trader_flo_address: receivedTradeInfo.trader_flo_address,
};
receivedTradeInfo.status = 2; // withdrawer found. Now deposit money to his account
updateinDB
(
"deposit",
receivedTradeInfo,
receivedTradeInfo
.trader_flo_address
);
RM_RPC
.send_rpc
.call(
this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
}
}
});
} catch (error) {
err_msg = "Deposit request failed: We could not find a withdrawer. Come again later.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
}
});
} else {
err_msg = "deposit asset request error";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "withdraw_request_method":
RM_RPC.filter_legit_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.product !== "undefined" &&
(localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product) ||
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.currency)) &&
typeof params.withdrawing_amount !== "undefined" &&
typeof localbitcoinplusplus.master_configurations.validTradingAmount !==
'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(
parseFloat(params.withdrawing_amount)) &&
typeof params.trader_flo_address == "string" && params.trader_flo_address
.length > 0 &&
typeof params.receivinAddress == "string" && params.receivinAddress
.length >
0 && typeof params.currency == "string"
) {
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency
);
if (localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product)) {
let eqCrypto = RM_TRADE.calculateCryptoEquivalentOfCash(
params.withdrawing_amount);
if (trade_margin.remaining_crypto_credit < 0 &&
trade_margin.remaining_crypto_credit < eqCrypto) {
err_msg = `Insufficient crypto balance to withdraw. You can withdraw upto: ${params.product} ${trade_margin.remaining_crypto_credit}`
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
if (trade_margin.remaining_fiat_credit < 0 && trade_margin.remaining_fiat_credit <
params.withdrawing_amount) {
err_msg = `Insufficient fiat balance to withdraw. You can withdraw upto: ${params.currency} ${trade_margin.remaining_fiat_credit}`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
params.id = helper_functions.unique_id();
params.status = 1;
if (localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product)) {
// Check how much cryptos the user can withdraw
let withdrawer_btc_id =
`${params.trader_flo_address}_${params.product}`;
readDB("crypto_balances", withdrawer_btc_id).then(function (
btc_balance_res) {
if (typeof btc_balance_res == "object" &&
typeof btc_balance_res
.trader_flo_address == "string" &&
btc_balance_res.crypto_balance > 0) {
let withdrawer_btc_balance = parseFloat(
btc_balance_res.crypto_balance);
let withdrawing_btc_amount_in_cash =
parseFloat(params.withdrawing_amount);
if (!localbitcoinplusplus.master_configurations
.tradableAsset2.includes(params.currency)
) {
err_msg = "Invalid or unsupported currency.";
showMessage(err_msg);
throw new Error(err_msg);
}
let eqBTC = RM_TRADE.calculateCryptoEquivalentOfCash(
withdrawing_btc_amount_in_cash,
params.currency, params.product);
eqBTC = Number(parseFloat(eqBTC).toFixed(8));
let withdrawer_new_btc_balance =
withdrawer_btc_balance - eqBTC;
if (withdrawer_new_btc_balance > 0 &&
withdrawer_btc_balance > 0 &&
withdrawing_btc_amount_in_cash > 0 &&
eqBTC > 0 && eqBTC <=
withdrawer_btc_balance) {
// Now details of Bitcoins can be sent to withdrawer
/****************************************************************************
***********IMPORTANT: CHANGE RECEIVING ADDRESS TO BTC THAN FLO HERE**********
***********AND DO SOMETHING ABOUT PRIVATE KEY BELOW**************************
****************************************************************************/
let sum_total_btc = 0;
let valid_utxo_list = [];
let receiverBTCAddress = params.receivinAddress
.trim();
readAllDB("deposit").then(function (
deposit_list) {
if (typeof deposit_list ==
"object" &&
deposit_list.length > 0
) {
deposit_list =
deposit_list.filter(
deposits =>
deposits.status ==
2 &&
localbitcoinplusplus
.master_configurations
.tradableAsset1
.includes(
deposits.product
) &&
params.product ==
deposits.product
);
for (const dl in
deposit_list) {
if (deposit_list.hasOwnProperty(
dl)) {
const deposit_dl =
deposit_list[
dl];
sum_total_btc +=
parseFloat(
deposit_dl
.bitcoinToBePaid
);
if (eqBTC <=
sum_total_btc
) {
valid_utxo_list
.push(
deposit_dl
);
break;
} else {
valid_utxo_list
.push(
deposit_dl
);
}
}
}
let valid_btc_list =
valid_utxo_list.map(
deposit_arr => {
deposit_arr
.status =
3 // Deposited Bitcoin is under process
updateinDB(
"deposit",
deposit_arr,
deposit_arr
.trader_flo_address
);
// save the address and id in a table
let
withdraw_id =
helper_functions
.unique_id();
const
withdraw_btc_order_object = {
id: withdraw_id,
trader_flo_address: params
.trader_flo_address,
utxo_addr: deposit_arr
.btc_address,
receiverBTCAddress: params
.receivinAddress,
receiverBTCEquivalentInCash: withdrawing_btc_amount_in_cash,
currency: params
.currency,
product: params
.product,
change_adress: deposit_arr
.btc_address,
timestamp: + new Date()
}
addDB(
'withdraw_btc',
withdraw_btc_order_object
);
return {
withdraw_id: withdraw_id,
deposited_btc_address: deposit_arr
.btc_address
};
});
// doSend btc_private_key_shamirs_id from system_btc_reserves_private_keys
valid_btc_list.map(vbl => {
readDBbyIndex
(
'system_btc_reserves_private_keys',
'btc_address',
vbl
.deposited_btc_address
).then(
function (res) {
let retrieve_pvtkey_req_id = res[0].id;
res[0]
.btc_private_key_shamirs_id
.map(
bpks => {
RM_RPC
.send_rpc
.call(
this,
"send_back_shamirs_secret_btc_pvtkey", {
retrieve_pvtkey_req_id: retrieve_pvtkey_req_id,
chunk_val: bpks,
withdraw_id: vbl.withdraw_id
}
).then(retrieve_pvtkey_req=>doSend(retrieve_pvtkey_req));
}
);
});
});
}
});
} else {
err_msg = `Withdrawal request failed: You are trying to withdraw more Bitcoins than you have.`;
showMessage(err_msg);
throw new Error(err_msg);
// Return error to the requester
return {
error: true,
method: "withdrawal_request_response",
data: "Withdrawal request failed: You are trying to withdraw more Bitcoins than you have."
};
}
} else {
err_msg =
`Withdrawal request failed: You don't seem to have any Bitcoin balance in the system yet.
Please buy some Bitcoins to withdraw.`;
showMessage(err_msg);
// Return error to the requester
return {
error: true,
method: "withdrawal_request_response",
data: `Withdrawal request failed: You don't seem to have any Bitcoin balance in the system yet.
Please buy some Bitcoins to withdraw.`
};
}
});
} else if (!localbitcoinplusplus.master_configurations.tradableAsset1
.includes(params.product)) {
// Check if there's no already a withdraw cash order of this user
/*ONLY DELETE A WITHDRAW ORDER WHEN A DEPOSITOR HAS CONFIRMED DEPOSIT
AND RECEIVER HAS CONFIRMED WITHDRAW*/
// Check how much Cash user can withdraw
const trader_cash_id =
`${params.trader_flo_address}_${params.currency}`;
readDB("cash_balances", trader_cash_id).then(function (
cash_balances_res) {
if (typeof cash_balances_res == "object" &&
typeof cash_balances_res
.trader_flo_address == "string" &&
typeof cash_balances_res.cash_balance ==
"number" &&
cash_balances_res.cash_balance > 0) {
let withdrawer_cash_balance = parseFloat(
cash_balances_res.cash_balance);
let withdrawing_cash_amount = parseFloat(
params.withdrawing_amount);
let bank_details = params.receivinAddress.trim();
if (withdrawer_cash_balance > 0 &&
withdrawing_cash_amount > 0 &&
withdrawer_cash_balance >=
withdrawing_cash_amount) {
// Add it to cash withdrawal table
let withdraw_request_db_object = {
id: helper_functions.unique_id(),
trader_flo_address: params.trader_flo_address,
withdraw_amount: withdrawing_cash_amount,
currency: params.currency,
receivinAddress: bank_details,
status: 1, // withdraw request called
}
readDB("localbitcoinUser", "00-01").then(
function (
su_data) {
if (typeof su_data ==
"object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey
.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys.includes(
su_data.myLocalFLOPublicKey
)) {
let
withdraw_request_db_object_hash =
Crypto.SHA256(JSON.stringify(
withdraw_request_db_object
));
withdraw_request_db_object
["withdrawDataHash"] =
withdraw_request_db_object_hash;
withdraw_request_db_object
[
"order_validator_sign"
] =
RM_WALLET
.sign(
withdraw_request_db_object_hash,
localbitcoinplusplus
.wallets.MY_SUPERNODE_PRIVATE_KEY
);
withdraw_request_db_object
[
"order_validator_public_key"
] = su_data.myLocalFLOPublicKey;
try {
// add the request to supernode db
addDB(
"withdraw_cash",
withdraw_request_db_object
);
// return back the response to client
withdraw_request_db_object.receiver_flo_address =
params.trader_flo_address;
withdraw_request_db_object.trader_flo_address =
params.trader_flo_address;
RM_RPC.send_rpc
.call(this,
"withdrawal_request_response",
withdraw_request_db_object
).then(withdrawal_request_response=>doSend(withdrawal_request_response));
return true;
} catch (error) {
console.log(error);
}
}
});
} else {
// Return error to the requester
err_msg = "Withdrawal request failed: You are trying to withdraw more cash than you have in localbitcoinplusplus account.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
} else {
err_msg = "withdraw request error";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
break;
case "retrieve_shamirs_secret_btc_pvtkey":
RM_RPC.filter_legit_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.btc_private_key_array !== "string" || typeof params.retrieve_pvtkey_req_id !==
"string") return false;
let btc_private_key_str = params.btc_private_key_array;
let retrieve_pvtkey_req_id = params.retrieve_pvtkey_req_id;
let withdraw_id = params.withdraw_id;
try {
let btc_private_key_object = JSON.parse(btc_private_key_str);
let btc_pk_shares_array = btc_private_key_object.map(pkChunks => {
if (typeof pkChunks.private_key_chunk !== "undefined")
return pkChunks.private_key_chunk.privateKeyChunks;
}).filter(val => val !== undefined);
console.log(btc_pk_shares_array);
readDB('withdraw_btc', withdraw_id).then(function (withdraw_res) {
if (typeof withdraw_res == "object") {
readDB('system_btc_reserves_private_keys',
retrieve_pvtkey_req_id).then(async function (
btc_reserves) {
if (typeof btc_reserves == "object") {
// Ideally this line should never run.
if (btc_reserves.product !==
withdraw_res.product) throw new Error(
"Mismatch of assets in withdrawal request."
);
await RM_TRADE.resolve_current_crypto_price_in_fiat(
withdraw_res.product,
withdraw_res.currency);
const EqCryptoWd = RM_TRADE.calculateCryptoEquivalentOfCash(
withdraw_res.receiverBTCEquivalentInCash,
withdraw_res.currency,
withdraw_res.product);
let transaction_key =
btc_reserves.supernode_transaction_key;
if (transaction_key.length > 0) {
let btc_private_key =
RM_WALLET.rebuild_private_key(
btc_pk_shares_array,
transaction_key);
console.log(btc_private_key);
RM_TRADE.sendTransaction(
withdraw_res.product,
withdraw_res.utxo_addr,
btc_private_key,
withdraw_res.receiverBTCAddress,
withdraw_res.receiverBTCEquivalentInCash,
withdraw_res.currency,
withdraw_res.change_adress,
async function (res) {
console.log(
res
);
if (typeof res ==
"string" &&
res.length >
0) {
try {
let
resp_obj =
JSON
.parse(
res
);
let
resp_txid =
resp_obj
.txid
.result ||
resp_obj
.txid;
let
msg =
`Transaction Id for your withdrawn crypto asset: ${resp_txid}`;
readDB
(
'crypto_balances',
withdraw_res
.id
)
.then(
res_bal => {
// btc_eq_receiving_amount
// =
// Number(parseFloat(EqCryptoWd).toFixed(8));
res_bal
.crypto_balance -=
EqCryptoWd;
updateinDB
(
'crypto_balances',
res_bal,
withdraw_res
.id
)
.then(
res_obj => {
const
res_obj_str =
JSON
.stringify(
res_obj
);
const
res_obj_hash =
Crypto
.SHA256(
res_obj_str
);
const
res_obj_sign =
RM_WALLET
.sign(
res_obj_hash,
localbitcoinplusplus
.wallets
.MY_SUPERNODE_PRIVATE_KEY
);
const
updateUserCryptoBalanceObject = {
updatedBTCBalanceObject: res_bal,
updatedBTCBalanceObjectSign: res_obj_sign,
trader_flo_address: withdraw_res.trader_flo_address,
receiver_flo_address: withdraw_res.trader_flo_address,
}
RM_RPC
.send_rpc(
"updateUserCryptoBalanceRequest",
updateUserCryptoBalanceObject
).then(updateUserCryptoBalanceRequestObject=>
doSend(updateUserCryptoBalanceRequestObject));
}
)
}
);
} catch (
error
) {
console.warn(error);
showMessage(error);
}
}
// Check if there's BTC left in deposited BTC. If yes update its status to 2 else delete it
/***********************************************************************************************************************************
*******************CHECK ACTUAL BTC BALANCE HERE THROUGH AN API AND UPDATE DEPOSIT TABLE****************************************************
************************************************************************************************************************************/
readDBbyIndex
(
'deposit',
'btc_address',
withdraw_res
.utxo_addr
).then(
function (
deposit_arr_resp
) {
if (
typeof deposit_arr_resp ==
"object"
) {
deposit_arr_resp
.map(
deposit_arr => {
deposit_arr
.bitcoinToBePaid -=
EqCryptoWd;
if (
deposit_arr
.bitcoinToBePaid >
0
) {
// update deposits in db
deposit_arr
.status =
2; // UTXO ready to be used again
updateinDB
(
"deposit",
deposit_arr,
deposit_arr
.trader_flo_address
);
} else {
// delete entry in deposits in db
removeinDB
(
"deposit",
deposit_arr
.trader_flo_address
);
}
}
);
return true;
}
});
});
}
}
});
}
});
} catch (error) {
throw new Error(error);
}
});
break;
case "superNodeSignedAddUserPublicData":
if (typeof params == "object" && typeof params.data == "object") {
RM_RPC.filter_legit_requests(params.data.trader_flo_address,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.su_pubKey == "string" && localbitcoinplusplus
.master_configurations.supernodesPubKeys.includes(params.su_pubKey)) {
let res_data_obj = {
trader_flo_address: params.data.trader_flo_address,
trader_flo_pubKey: params.data.trader_flo_pubKey,
trader_status: params.data.trader_status,
timestamp: params.data.timestamp
};
let res_data_hash = Crypto.SHA256(JSON.stringify(res_data_obj));
let res_data_verification = RM_WALLET
.verify(res_data_hash, params.sign, params.su_pubKey);
if ((res_data_verification == true) && res_data_hash == params.data_hash) {
addDB('userPublicData', params.data);
return true;
}
}
});
}
break;
case "update_external_file_server_response":
if (typeof params == "object") {
if (params.filename == "UPDATE_ALL_FILES") {
let file_details_str = JSON.stringify(params.file_updated);
if (RM_WALLET.verify(file_details_str,
params.server_sign, params.server_pubkey)) {
params.file_updated.map(new_file => {
updateinDB("external_files", new_file);
createScript(new_file.filename, new_file.content);
});
return true;
}
} else {
let file_details_string = JSON.stringify(params.file_updated);
if (RM_WALLET.verify(file_details_string,
params.server_sign, params.server_pubkey)) {
updateinDB("external_files", params.file_updated);
createScript(params.file_updated.filename, params.file_updated.content);
return true;
}
}
showMessage(`WARNING: Failed to update external files from server.`);
}
break;
default:
showMessage("WARNING: Unknown method called for execution.");
break;
}
}
return request.toString(); // return to client
},
async backup_receive_rpc_response(request) {
var request = JSON.parse(request);
var params = request.params[0];
var method = request.method;
if (typeof params == "object" && typeof method == "string") {
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
let respective_trader_id = '';
if (typeof params.trader_flo_address == "string") respective_trader_id = params.trader_flo_address;
request.response = {};
let err_msg;
if(typeof params.trader_flo_address !="string") return;
const my_closest_su_list = await localbitcoinplusplus.kademlia.determineClosestSupernode(params.trader_flo_address);
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
if (method=="sync_with_supernode") {
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request === true && params.job ==
"SYNC_MY_LOCAL_DB_WITH_SUPERNODE_DB" && params.trader_flo_address.length >
0) {
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "userPublicData"
];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray).then(
function (su_db_data) {
if (typeof su_db_data == "object") {
su_db_data.trader_flo_address = params.trader_flo_address;
su_db_data.receiver_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this, "server_sync_response",
su_db_data)
.then(server_sync_response=>
doSend(server_sync_response));
}
});
}
});
}
if (method=="sync_primary_supernode_from_backup_supernode") {
// params.trader_flo_address -> primary supernode flo id
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request === true && params.job ==
"SYNC_PRIMARY_SUPERNODE_DB_WITH_BACKUP_SUPERNODE_DB" && params.trader_flo_address.length >
0) {
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc", "cash_balances", "crypto_balances"];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray, params.trader_flo_address).then(
function (su_db_data) {
if (typeof su_db_data == "object") {
su_db_data.trader_flo_address = params.trader_flo_address;
su_db_data.receiver_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this, "sync_primary_supernode_from_backup_supernode_response",
su_db_data)
.then(server_sync_response=>
doSend(server_sync_response));
}
});
}
});
}
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
try {
// CHECK HERE IF USER IS INDULGED IN ANY MORE TRADE. IF TRUE RETURN ERROR
await backup_server_db_instance.backup_readAllDB("deposit").then(function (res) {
if (typeof res == "object" && res.length > 0) {
let canUserTrade = res.filter(function (user) {
return (respective_trader_id == user.trader_flo_address
&& user.status==1);
});
if (canUserTrade.includes(true)) {
request.response =
`Trader id ${respective_trader_id} is not clear for trade currently.
You must finish your previous pending orders to qualify again to trade.`;
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "supernode_message", {
"trader_flo_address": respective_trader_id,
"receiver_flo_address": respective_trader_id,
"server_msg": request.response
}).then(server_response=>
doSend(server_response));
showMessage(request.response);
throw new Error(request.response);
return false;
}
}
});
// Check if user id is in deposit or withdraw. If true prevent him from trading
await backup_server_db_instance.backup_readAllDB('withdraw_cash').then(function (res) {
if (typeof res == "object") {
let check_deposit_withdraw_id_array = res.filter(f => f.status === 2)
.map(m => {
if (m.trader_flo_address == respective_trader_id || m.deposit_withdraw_id_array ==
respective_trader_id) {
let server_msg =
`Trader id ${respective_trader_id} is not clear for trade currently.
You must finish your previous pending deposit/withdraw action to qualify again to trade.`;
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "supernode_message", {
"trader_flo_address": respective_trader_id,
"receiver_flo_address": respective_trader_id,
"server_msg": server_msg
}).then(server_response=>
doSend(server_response));
showMessage(server_msg);
throw new Error(
"User has not finished previous pending actions."
);
}
});
}
});
} catch (error) {
throw new Error(error);
}
});
switch (method) {
case "trade_buy":
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
const get_requester_primary_supernode = await localbitcoinplusplus.kademlia
.determineClosestSupernode(params.trader_flo_address);
const primarySupernodeForThisUser = get_requester_primary_supernode[0].data.id;
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency, primarySupernodeForThisUser);
if (typeof trade_margin.remaining_crypto_credit == "number" &&
typeof trade_margin.remaining_fiat_credit == "number") {
if (trade_margin.remaining_fiat_credit > 0 && trade_margin.remaining_fiat_credit >=
params.buy_price) {
request.response = RM_TRADE.trade_buy.call(this,
...request.params,
function (supernode_signed_res) {
supernode_signed_res.receiver_flo_address = params.trader_flo_address;
if (typeof supernode_signed_res == "object") {
RM_RPC
.send_rpc
.call(this,
"trade_buy_request_response",
supernode_signed_res)
.then(buy_request_response=>
doSend(buy_request_response));
// Init trading
RM_TRADE.createTradePipes(params.currency, primarySupernodeForThisUser);
return true;
}
}, primarySupernodeForThisUser);
} else {
err_msg = `Trade Margin Check Failed: You can only trade upto ${params.currency} ${trade_margin.remaining_fiat_credit}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Invalid trade margin figures.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "trade_sell":
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
const get_requester_primary_supernode = await localbitcoinplusplus.kademlia
.determineClosestSupernode(params.trader_flo_address);
const primarySupernodeForThisUser = get_requester_primary_supernode[0].data.id;
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency, primarySupernodeForThisUser);
if (typeof trade_margin.remaining_crypto_credit == "number" &&
typeof trade_margin.remaining_fiat_credit == "number") {
let eqCrypto = RM_TRADE.calculateCryptoEquivalentOfCash(params.buy_price);
if (trade_margin.remaining_crypto_credit > 0 && trade_margin.remaining_crypto_credit >=
eqCrypto) {
request.response = RM_TRADE.trade_sell.call(
this, ...request.params,
function (supernode_signed_res) {
if (typeof supernode_signed_res == "object") {
supernode_signed_res.receiver_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this,
"trade_sell_request_response",
supernode_signed_res)
.then(sell_request_response=>
doSend(sell_request_response));
// Init trading
RM_TRADE.createTradePipes(params.currency, primarySupernodeForThisUser);
return true;
}
}, primarySupernodeForThisUser
);
} else {
err_msg = `WARNING: Trade Margin Check Failed:
You can only trade upto ${params.currency} ${trade_margin.remaining_fiat_credit}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Invalid trade margin figures.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "sync_with_supernode":
// already processed above
break;
case "deposit_asset_request":
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request !== true) return false;
// This code will only run for supernodes
if (typeof params.product !== "undefined" &&
(localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product) ||
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.product)) &&
typeof params.depositing_amount !== "undefined" &&
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.currency) &&
typeof localbitcoinplusplus.master_configurations.validTradingAmount !==
'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(
parseFloat(params.depositing_amount)) &&
typeof params.trader_flo_address == "string" &&
params.trader_flo_address.length > 0
) {
RM_WALLET.getUserPublicKey(params.trader_flo_address,
async function (requester_public_key) {
if (requester_public_key == undefined ||
requester_public_key == null) {
err_msg = 'Failed to get public key of the user.';
showMessage(err_msg);
throw new Error(err_msg);
}
params.depositor_public_key = requester_public_key;
await RM_TRADE.resolve_current_crypto_price_in_fiat(
params.product, params.currency);
if (localbitcoinplusplus.master_configurations.tradableAsset1
.includes(params.product)) {
let generate_btc_keys_for_requester = RM_WALLET
.generateFloKeys(null, params.product);
params.id = helper_functions.unique_id();
params.status = 1;
params.btc_address =
generate_btc_keys_for_requester.address;
params.bitcoinToBePaid = RM_TRADE.calculateCryptoEquivalentOfCash(
params.depositing_amount, params.currency,
params.product);
let receivedTradeInfo = { ...params };
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY ==
"undefined") {
err_msg = 'Failed to determine Super node signing key.';
showMessage(err_msg);
throw new Error(err_msg);
}
backup_server_db_instance.backup_readDB("localbitcoinUser", "00-01").then(
function (su_data) {
if (typeof su_data == "object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys
.includes(su_data.myLocalFLOPublicKey)
) {
let receivedTradeInfoHash =
Crypto.SHA256(JSON.stringify(receivedTradeInfo));
receivedTradeInfo["depositDataHash"] = receivedTradeInfoHash;
receivedTradeInfo["order_validator_sign"] =
RM_WALLET.sign(receivedTradeInfoHash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
receivedTradeInfo["order_validator_public_key"] = su_data.myLocalFLOPublicKey;
try {
const this_btc_pvt_key =
generate_btc_keys_for_requester.privateKeyWIF;
const this_btc_tx_key =
Crypto.util.randomBytes(64);
const
this_btc_pvt_key_shamirs_secret =
RM_WALLET.createShamirsSecretShares(this_btc_pvt_key, 10, 5);
if (typeof this_btc_pvt_key_shamirs_secret ==
"object" &&
this_btc_pvt_key_shamirs_secret
.length > 0) {
backup_server_db_instance.backup_addDB("deposit", receivedTradeInfo);
// Send the address to the requester
let
deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Please send ${params.product} ${params.bitcoinToBePaid} to the following addres: ${generate_btc_keys_for_requester.address}.`,
data: receivedTradeInfo
};
deposit_response_object.receiver_flo_address = params.trader_flo_address;
deposit_response_object.trader_flo_address = params.trader_flo_address;
RM_RPC
.send_rpc
.call(this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
let
this_btc_pvt_key_shamirs_secret_array =
this_btc_pvt_key_shamirs_secret
.map(chunks => {
let
chunk_ids =
Crypto.util
.bytesToHex(
Crypto
.util
.randomBytes(
64
));
let
chunk_array = {
"id": chunk_ids,
"privateKeyChunks": Crypto
.AES
.encrypt(
chunks,
this_btc_tx_key
),
"trader_flo_address": params.trader_flo_address
};
return chunk_array;
});
// Send chunks of private keys to other supernodes
this_btc_pvt_key_shamirs_secret_array
.map(shares => {
RM_RPC
.send_rpc
.call(
this,
"store_shamirs_secret_pvtkey_shares",
shares
).then(store_pvtkey_req=>
doSend(store_pvtkey_req));
});
if (typeof localbitcoinplusplus
.wallets.my_local_flo_address ==
"string" &&
typeof localbitcoinplusplus
.wallets.my_local_flo_public_key ==
"string" &&
typeof localbitcoinplusplus
.master_configurations
.supernodesPubKeys ==
"object" &&
localbitcoinplusplus
.master_configurations
.supernodesPubKeys.includes(
localbitcoinplusplus
.wallets.my_local_flo_public_key
)) {
try {
let
this_btc_pvt_key_shamirs_secret__id_array =
this_btc_pvt_key_shamirs_secret_array
.map(i => i.id);
let
btc_private_key_shamirs_id =
this_btc_pvt_key_shamirs_secret__id_array;
let
supernode_transaction_key =
this_btc_tx_key;
const
system_btc_reserves_private_keys_object = {
id: helper_functions
.unique_id(),
product: params
.product,
btc_address: params
.btc_address,
balance: null,
trader_flo_address: params
.trader_flo_address,
btc_private_key_shamirs_id: btc_private_key_shamirs_id,
supernode_transaction_key: supernode_transaction_key
}
backup_server_db_instance.backup_addDB(
"system_btc_reserves_private_keys",
system_btc_reserves_private_keys_object
);
} catch (error) {
throw new Error( error);
}
}
return true;
}
} catch (error) {
throw new Error(error);
}
// Send the address to the requester
let deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Please send the ${params.product} to ${generate_btc_keys_for_requester.address}.`,
data: receivedTradeInfo,
receiver_flo_address: params.trader_flo_address,
trader_flo_address: params.trader_flo_address,
};
RM_RPC.send_rpc
.call(this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
}
});
return false;
} else if (!localbitcoinplusplus.master_configurations
.tradableAsset1.includes(params.product)) {
params.id = helper_functions.unique_id();
params.status = 1;
// IMPORTANT - If deposit is a fiat make sure product and currency are both same
params.currency = params.product;
let receivedTradeInfo = { ...params };
backup_server_db_instance.backup_readDB("localbitcoinUser", "00-01").then(
function (su_data) {
if (typeof su_data == "object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys
.includes(su_data.myLocalFLOPublicKey)
) {
let receivedTradeInfoHash =
Crypto.SHA256(JSON.stringify(
receivedTradeInfo));
receivedTradeInfo[
"depositDataHash"] =
receivedTradeInfoHash;
receivedTradeInfo[
"order_validator_sign"] =
RM_WALLET.sign(
receivedTradeInfoHash,
localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY
);
receivedTradeInfo[
"order_validator_public_key"
] = su_data.myLocalFLOPublicKey;
// YOU NEED TO DETERMINE A BANK ACCOUNT HERE IF NO ONE IS WITHDRAWING
try {
backup_server_db_instance.backup_addDB("deposit",
receivedTradeInfo);
backup_server_db_instance.backup_readDBbyIndex(
"withdraw_cash",
"status", 1).then(
function (
withdrawers_list
) {
if (typeof withdrawers_list ==
"object") {
if (
withdrawers_list.length > 0) {
withdrawers_list.filter(
wd => wd.currency ==
params.currency).map(
function (withdrawer) {
if (
withdrawer.withdraw_amount ==
params.depositing_amount &&
withdrawer.currency ==
params.currency
) {
withdrawer.status = 2; // A depositor has been asked to deposit money
withdrawer.depositor_found_at = + new Date();
withdrawer.depositor_flo_id = receivedTradeInfo.trader_flo_address;
backup_server_db_instance.backup_updateinDB ("withdraw_cash", withdrawer, withdrawer.trader_flo_address);
receivedTradeInfo.status = 2; // withdrawer found. Now deposit money to his account
backup_server_db_instance.backup_updateinDB(
"deposit",
receivedTradeInfo,
receivedTradeInfo.trader_flo_address
);
let withdrawer_bank_account = withdrawer.receivinAddress;
let deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Plese send the money to following bank address: "${withdrawer_bank_account}"`,
data: receivedTradeInfo,
withdrawer_data: withdrawer,
receiver_flo_address: receivedTradeInfo.trader_flo_address,
trader_flo_address: receivedTradeInfo.trader_flo_address,
};
RM_RPC.send_rpc.call(
this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
} else {
err_msg = "Deposit request failed: We could not find a withdrawer.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
);
} else {
//No one is withdrawing so provide your bank details
let
deposit_response_object = {
error: false,
method: "deposit_asset_request_response",
msg: `Plese send the money to following bank address: "System determined bank".`,
data: receivedTradeInfo,
receiver_flo_address: receivedTradeInfo.trader_flo_address,
trader_flo_address: receivedTradeInfo.trader_flo_address,
};
receivedTradeInfo.status = 2; // withdrawer found. Now deposit money to his account
updateinDB
(
"deposit",
receivedTradeInfo,
receivedTradeInfo
.trader_flo_address
);
RM_RPC
.send_rpc
.call(
this,
"deposit_asset_request_response",
deposit_response_object
).then(deposit_request_response=>
doSend(deposit_request_response));
return true;
}
}
});
} catch (error) {
err_msg = "Deposit request failed: We could not find a withdrawer. Come again later.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
}
});
} else {
err_msg = "deposit asset request error";
showMessage(err_msg);
throw new Error(err_msg);
}
});
break;
case "withdraw_request_method":
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, async function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.product !== "undefined" &&
(localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product) ||
localbitcoinplusplus.master_configurations.tradableAsset2.includes(
params.currency)) &&
typeof params.withdrawing_amount !== "undefined" &&
typeof localbitcoinplusplus.master_configurations.validTradingAmount !==
'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(
parseFloat(params.withdrawing_amount)) &&
typeof params.trader_flo_address == "string" && params.trader_flo_address
.length > 0 &&
typeof params.receivinAddress == "string" && params.receivinAddress
.length >
0 && typeof params.currency == "string"
) {
await RM_TRADE.resolve_current_crypto_price_in_fiat(params.product,
params.currency);
const get_requester_primary_supernode = await localbitcoinplusplus.kademlia
.determineClosestSupernode(params.trader_flo_address);
const primarySupernodeForThisUser = get_requester_primary_supernode[0].data.id;
let trade_margin = await RM_TRADE.getAssetTradeAndWithdrawLimit(
params.trader_flo_address, params.product, params.currency,
primarySupernodeForThisUser
);
if (localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product)) {
let eqCrypto = RM_TRADE.calculateCryptoEquivalentOfCash(
params.withdrawing_amount);
if (trade_margin.remaining_crypto_credit < 0 &&
trade_margin.remaining_crypto_credit < eqCrypto) {
err_msg = `Insufficient crypto balance to withdraw. You can withdraw upto: ${params.product} ${trade_margin.remaining_crypto_credit}`
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
if (trade_margin.remaining_fiat_credit < 0 && trade_margin.remaining_fiat_credit <
params.withdrawing_amount) {
err_msg = `Insufficient fiat balance to withdraw. You can withdraw upto: ${params.currency} ${trade_margin.remaining_fiat_credit}`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
params.id = helper_functions.unique_id();
params.status = 1;
if (localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product)) {
// Check how much cryptos the user can withdraw
let withdrawer_btc_id =
`${params.trader_flo_address}_${params.product}`;
backup_server_db_instance.backup_readDB("crypto_balances", withdrawer_btc_id).then(function (
btc_balance_res) {
if (typeof btc_balance_res == "object" &&
typeof btc_balance_res
.trader_flo_address == "string" &&
btc_balance_res.crypto_balance > 0) {
let withdrawer_btc_balance = parseFloat(
btc_balance_res.crypto_balance);
let withdrawing_btc_amount_in_cash =
parseFloat(params.withdrawing_amount);
if (!localbitcoinplusplus.master_configurations
.tradableAsset2.includes(params.currency)
) {
err_msg = "Invalid or unsupported currency.";
showMessage(err_msg);
throw new Error(err_msg);
}
let eqBTC = RM_TRADE.calculateCryptoEquivalentOfCash(
withdrawing_btc_amount_in_cash,
params.currency, params.product);
eqBTC = Number(parseFloat(eqBTC).toFixed(8));
let withdrawer_new_btc_balance =
withdrawer_btc_balance - eqBTC;
if (withdrawer_new_btc_balance > 0 &&
withdrawer_btc_balance > 0 &&
withdrawing_btc_amount_in_cash > 0 &&
eqBTC > 0 && eqBTC <=
withdrawer_btc_balance) {
// Now details of Bitcoins can be sent to withdrawer
/****************************************************************************
***********IMPORTANT: CHANGE RECEIVING ADDRESS TO BTC THAN FLO HERE**********
***********AND DO SOMETHING ABOUT PRIVATE KEY BELOW**************************
****************************************************************************/
let sum_total_btc = 0;
let valid_utxo_list = [];
let receiverBTCAddress = params.receivinAddress
.trim();
backup_server_db_instance.backup_readAllDB("deposit").then(function (
deposit_list) {
if (typeof deposit_list ==
"object" &&
deposit_list.length > 0
) {
deposit_list =
deposit_list.filter(
deposits =>
deposits.status ==
2 &&
localbitcoinplusplus
.master_configurations
.tradableAsset1
.includes(
deposits.product
) &&
params.product ==
deposits.product
);
for (const dl in
deposit_list) {
if (deposit_list.hasOwnProperty(
dl)) {
const deposit_dl =
deposit_list[
dl];
sum_total_btc +=
parseFloat(
deposit_dl
.bitcoinToBePaid
);
if (eqBTC <=
sum_total_btc
) {
valid_utxo_list
.push(
deposit_dl
);
break;
} else {
valid_utxo_list
.push(
deposit_dl
);
}
}
}
let valid_btc_list =
valid_utxo_list.map(
deposit_arr => {
deposit_arr
.status =
3 // Deposited Bitcoin is under process
backup_server_db_instance.backup_updateinDB(
"deposit",
deposit_arr,
deposit_arr
.trader_flo_address
);
// save the address and id in a table
let
withdraw_id =
helper_functions
.unique_id();
const
withdraw_btc_order_object = {
id: withdraw_id,
trader_flo_address: params
.trader_flo_address,
utxo_addr: deposit_arr
.btc_address,
receiverBTCAddress: params
.receivinAddress,
receiverBTCEquivalentInCash: withdrawing_btc_amount_in_cash,
currency: params
.currency,
product: params
.product,
change_adress: deposit_arr
.btc_address,
timestamp: + new Date()
}
backup_server_db_instance.backup_addDB(
'withdraw_btc',
withdraw_btc_order_object
);
return {
withdraw_id: withdraw_id,
deposited_btc_address: deposit_arr
.btc_address
};
});
// doSend btc_private_key_shamirs_id from system_btc_reserves_private_keys
valid_btc_list.map(vbl => {
readDBbyIndex
(
'system_btc_reserves_private_keys',
'btc_address',
vbl
.deposited_btc_address
).then(
function (res) {
let retrieve_pvtkey_req_id = res[0].id;
res[0]
.btc_private_key_shamirs_id
.map(
bpks => {
RM_RPC
.send_rpc
.call(
this,
"send_back_shamirs_secret_btc_pvtkey", {
retrieve_pvtkey_req_id: retrieve_pvtkey_req_id,
chunk_val: bpks,
withdraw_id: vbl.withdraw_id
}
).then(retrieve_pvtkey_req=>
doSend(retrieve_pvtkey_req));
}
);
});
});
}
});
} else {
err_msg = `Withdrawal request failed: You are trying to withdraw more Bitcoins than you have.`;
showMessage(err_msg);
throw new Error(err_msg);
// Return error to the requester
return {
error: true,
method: "withdrawal_request_response",
data: "Withdrawal request failed: You are trying to withdraw more Bitcoins than you have."
};
}
} else {
err_msg =
`Withdrawal request failed: You don't seem to have any Bitcoin balance in the system yet.
Please buy some Bitcoins to withdraw.`;
showMessage(err_msg);
// Return error to the requester
return {
error: true,
method: "withdrawal_request_response",
data: `Withdrawal request failed: You don't seem to have any Bitcoin balance in the system yet.
Please buy some Bitcoins to withdraw.`
};
}
});
} else if (!localbitcoinplusplus.master_configurations.tradableAsset1
.includes(params.product)) {
// Check if there's no already a withdraw cash order of this user
/*ONLY DELETE A WITHDRAW ORDER WHEN A DEPOSITOR HAS CONFIRMED DEPOSIT
AND RECEIVER HAS CONFIRMED WITHDRAW*/
// Check how much Cash user can withdraw
const trader_cash_id =
`${params.trader_flo_address}_${params.currency}`;
backup_server_db_instance.backup_readDB("cash_balances", trader_cash_id).then(function (
cash_balances_res) {
if (typeof cash_balances_res == "object" &&
typeof cash_balances_res
.trader_flo_address == "string" &&
typeof cash_balances_res.cash_balance ==
"number" &&
cash_balances_res.cash_balance > 0) {
let withdrawer_cash_balance = parseFloat(
cash_balances_res.cash_balance);
let withdrawing_cash_amount = parseFloat(
params.withdrawing_amount);
let bank_details = params.receivinAddress.trim();
if (withdrawer_cash_balance > 0 &&
withdrawing_cash_amount > 0 &&
withdrawer_cash_balance >=
withdrawing_cash_amount) {
// Add it to cash withdrawal table
let withdraw_request_db_object = {
id: helper_functions.unique_id(),
trader_flo_address: params.trader_flo_address,
withdraw_amount: withdrawing_cash_amount,
currency: params.currency,
receivinAddress: bank_details,
status: 1, // withdraw request called
}
backup_server_db_instance.backup_readDB("localbitcoinUser", "00-01").then(
function (
su_data) {
if (typeof su_data ==
"object" &&
typeof su_data.myLocalFLOPublicKey ==
"string" &&
su_data.myLocalFLOPublicKey
.length >
0 &&
localbitcoinplusplus.master_configurations
.supernodesPubKeys.includes(
su_data.myLocalFLOPublicKey
)) {
let
withdraw_request_db_object_hash =
Crypto.SHA256(JSON.stringify(
withdraw_request_db_object
));
withdraw_request_db_object
["withdrawDataHash"] =
withdraw_request_db_object_hash;
withdraw_request_db_object
[
"order_validator_sign"
] =
RM_WALLET
.sign(
withdraw_request_db_object_hash,
localbitcoinplusplus
.wallets.MY_SUPERNODE_PRIVATE_KEY
);
withdraw_request_db_object
[
"order_validator_public_key"
] = su_data.myLocalFLOPublicKey;
try {
// add the request to supernode db
backup_server_db_instance.backup_addDB(
"withdraw_cash",
withdraw_request_db_object
);
// return back the response to client
withdraw_request_db_object.receiver_flo_address =
params.trader_flo_address;
withdraw_request_db_object.trader_flo_address =
params.trader_flo_address;
RM_RPC.send_rpc
.call(this,
"withdrawal_request_response",
withdraw_request_db_object
).then(withdrawal_request_response=>
doSend(withdrawal_request_response));
return true;
} catch (error) {
console.log(error);
}
}
});
} else {
// Return error to the requester
err_msg = "Withdrawal request failed: You are trying to withdraw more cash than you have in localbitcoinplusplus account.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
} else {
err_msg = "withdraw request error";
showMessage(err_msg);
throw new Error(err_msg);
}
}
});
break;
case "retrieve_shamirs_secret_btc_pvtkey":
RM_RPC.filter_legit_backup_requests(params.trader_flo_address, function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.btc_private_key_array !== "string" || typeof params.retrieve_pvtkey_req_id !==
"string") return false;
let btc_private_key_str = params.btc_private_key_array;
let retrieve_pvtkey_req_id = params.retrieve_pvtkey_req_id;
let withdraw_id = params.withdraw_id;
try {
let btc_private_key_object = JSON.parse(btc_private_key_str);
let btc_pk_shares_array = btc_private_key_object.map(pkChunks => {
if (typeof pkChunks.private_key_chunk !== "undefined")
return pkChunks.private_key_chunk.privateKeyChunks;
}).filter(val => val !== undefined);
console.log(btc_pk_shares_array);
backup_server_db_instance.backup_readDB('withdraw_btc', withdraw_id).then(function (withdraw_res) {
if (typeof withdraw_res == "object") {
backup_server_db_instance.backup_readDB('system_btc_reserves_private_keys',
retrieve_pvtkey_req_id).then(async function (
btc_reserves) {
if (typeof btc_reserves == "object") {
// Ideally this line should never run.
if (btc_reserves.product !==
withdraw_res.product) throw new Error(
"Mismatch of assets in withdrawal request."
);
await RM_TRADE.resolve_current_crypto_price_in_fiat(
withdraw_res.product,
withdraw_res.currency);
const EqCryptoWd = RM_TRADE.calculateCryptoEquivalentOfCash(
withdraw_res.receiverBTCEquivalentInCash,
withdraw_res.currency,
withdraw_res.product);
EqCryptoWd = parseFloat(EqCryptoWd);
let transaction_key =
btc_reserves.supernode_transaction_key;
if (transaction_key.length > 0) {
let btc_private_key =
RM_WALLET.rebuild_private_key(
btc_pk_shares_array,
transaction_key);
//console.log(btc_private_key);
RM_TRADE.sendTransaction(
withdraw_res.product,
withdraw_res.utxo_addr,
btc_private_key,
withdraw_res.receiverBTCAddress,
withdraw_res.receiverBTCEquivalentInCash,
withdraw_res.currency,
withdraw_res.change_adress,
async function (res) {
console.log(
res
);
if (typeof res ==
"string" &&
res.length >
0) {
try {
let
resp_obj =
JSON
.parse(
res
);
let
resp_txid =
resp_obj
.txid
.result ||
resp_obj
.txid;
let
msg =
`Transaction Id for your withdrawn crypto asset: ${resp_txid}`;
backup_server_db_instance.backup_readDB
(
'crypto_balances',
withdraw_res
.id
)
.then(
res_bal => {
// btc_eq_receiving_amount
// =
// Number(parseFloat(
// btc_eq_receiving_amount
// )
// .toFixed(
// 8
// ));
res_bal
.crypto_balance -=
EqCryptoWd;
backup_server_db_instance.backup_updateinDB
(
'crypto_balances',
res_bal,
withdraw_res
.id
)
.then(
res_obj => {
const
res_obj_str =
JSON
.stringify(
res_obj
);
const
res_obj_hash =
Crypto
.SHA256(
res_obj_str
);
const
res_obj_sign =
RM_WALLET
.sign(
res_obj_hash,
localbitcoinplusplus
.wallets
.MY_SUPERNODE_PRIVATE_KEY
);
const
updateUserCryptoBalanceObject = {
updatedBTCBalanceObject: res_bal,
updatedBTCBalanceObjectSign: res_obj_sign,
trader_flo_address: withdraw_res.trader_flo_address,
receiver_flo_address: withdraw_res.trader_flo_address,
}
RM_RPC
.send_rpc(
"updateUserCryptoBalanceRequest",
updateUserCryptoBalanceObject
).then(updateUserCryptoBalanceRequestObject=>
doSend(updateUserCryptoBalanceRequestObject));
}
)
}
);
} catch (
error
) {
console.warn(error);
showMessage(error);
}
}
// Check if there's BTC left in deposited BTC. If yes update its status to 2 else delete it
/***********************************************************************************************************************************
*******************CHECK ACTUAL BTC BALANCE HERE THROUGH AN API AND UPDATE DEPOSIT TABLE****************************************************
************************************************************************************************************************************/
backup_server_db_instance.backup_readDBbyIndex
(
'deposit',
'btc_address',
withdraw_res
.utxo_addr
).then(
function (
deposit_arr_resp
) {
if (
typeof deposit_arr_resp ==
"object"
) {
deposit_arr_resp
.map(
deposit_arr => {
deposit_arr
.bitcoinToBePaid -=
EqCryptoWd;
if (
deposit_arr
.bitcoinToBePaid >
0
) {
// update deposits in db
deposit_arr
.status =
2; // UTXO ready to be used again
backup_server_db_instance.backup_updateinDB
(
"deposit",
deposit_arr,
deposit_arr
.trader_flo_address
);
} else {
// delete entry in deposits in db
backup_server_db_instance.backup_removeinDB
(
"deposit",
deposit_arr
.trader_flo_address
);
}
}
);
return true;
}
});
});
}
}
});
}
});
} catch (error) {
throw new Error(error);
}
});
break;
case "superNodeSignedAddUserPublicData":
if (typeof params == "object" && typeof params.data == "object") {
RM_RPC.filter_legit_backup_requests(params.data.trader_flo_address,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof params.su_pubKey == "string" && localbitcoinplusplus
.master_configurations.supernodesPubKeys.includes(params.su_pubKey)) {
let res_data_obj = {
trader_flo_address: params.data.trader_flo_address,
trader_flo_pubKey: params.data.trader_flo_pubKey,
trader_status: params.data.trader_status,
timestamp: params.data.timestamp
};
let res_data_hash = Crypto.SHA256(JSON.stringify(res_data_obj));
let res_data_verification = RM_WALLET
.verify(res_data_hash, params.sign, params.su_pubKey);
if ((res_data_verification == true) && res_data_hash == params.data_hash) {
backup_server_db_instance.backup_addDB('userPublicData', params.data);
return true;
}
}
});
}
break;
case "update_external_file_server_response":
if (typeof params == "object") {
if (params.filename == "UPDATE_ALL_FILES") {
let file_details_str = JSON.stringify(params.file_updated);
if (RM_WALLET.verify(file_details_str,
params.server_sign, params.server_pubkey)) {
params.file_updated.map(new_file => {
backup_server_db_instance.backup_updateinDB("external_files", new_file);
createScript(new_file.filename, new_file.content);
});
return true;
}
} else {
let file_details_string = JSON.stringify(params.file_updated);
if (RM_WALLET.verify(file_details_string,
params.server_sign, params.server_pubkey)) {
backup_server_db_instance.backup_updateinDB("external_files", params.file_updated);
createScript(params.file_updated.filename, params.file_updated.content);
return true;
}
}
showMessage(`WARNING: Failed to update external files from server.`);
}
break;
default:
showMessage("WARNING: Unknown method called for execution.");
break;
}
}
return request.toString(); // return to client
},
parse_server_rpc_response(request) {
var request = JSON_RPC.parse(request);
var response;
if (request.id == this.rpc_req_id) { // the request ID is maintained
response = request.response; // if successful
}
console.log("res:", response);
return response;
}
}
</script>
<!-- Trade Object -->
<script>
/*Initiate trade level with 0*/
var Trade = localbitcoinplusplus.trade = function processTrade() {
this.errors = [];
this.level = 0; // default
this.order_type = null;
this.valid_order_type = ["buy", "sell"];
this.product = null;
this.currency = null;
this.buy_price = null;
this.buyer_public_key = null;
this.buyer_key_signature = null;
this.order_validator_public_key = null;
this.rpc_job = null;
this.floAddress = null;
this.user_flo_address = null;
this.sorted_trade_list = [];
}
Trade.prototype = {
getTrustLevel() {
return this.level
},
setTrustLevel(level) {
if (typeof level === "number" && level === parseInt(level, 10) && level > 0 && level < 6) {
this.level = level;
}
},
validate_order(order_type, user_flo_address, product, currency, buy_price) {
if (this.valid_order_type.indexOf(order_type) >= 0) {
this.order_type = order_type;
} else {
this.errors.push("Inavlid trade type value.");
}
if (user_flo_address.trim() !== "") {
this.user_flo_address = user_flo_address;
} else {
this.errors.push("No receiving BTC or Bank address provided.");
}
if (typeof localbitcoinplusplus.master_configurations.tradableAsset1 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset1.indexOf(product) >= 0) {
this.product = product;
} else {
this.errors.push("Invalid trading product.");
}
if (typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset2.indexOf(currency) >= 0) {
this.currency = currency;
} else {
this.errors.push("Invalid exchanging currency or asset.");
}
if (localbitcoinplusplus.master_configurations.validTradingAmount.includes(buy_price)) {
this.buy_price = buy_price;
} else {
this.errors.push("Invalid buying price. Please place a valid buy amount.");
}
if (this.errors.length > 0) {
return this.errors;
}
return true;
},
place_order(order_type, user_flo_address, product, currency, buy_price) {
var is_valid_order = this.validate_order(order_type, user_flo_address, product,
currency, buy_price);
if (is_valid_order === true) {
this.rpc_job = 'trade_' + this.order_type;
let newOrderDataObj = {
"order_type": this.order_type,
"trader_flo_address": this.user_flo_address,
"product": this.product,
"currency": this.currency,
"buy_price": this.buy_price,
"receiver_flo_address":localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}
const RM_RPC = new localbitcoinplusplus.rpc;
let placeNewOrder = RM_RPC.send_rpc.call(this, this
.rpc_job, newOrderDataObj);
return placeNewOrder;
} else if (typeof is_valid_order == "object") {
var err;
for (err = 0; err < is_valid_order.length; err++) {
showMessage(`ERROR: ${is_valid_order[err]}`);
}
return false;
}
},
trade_buy(params, callback, backup_db="") {
let err_msg;
for (var key in params) {
if (params.hasOwnProperty(key)) {
if (typeof key == undefined || key.trim() == "" || key == null) {
err_msg = "Incomplete or invalid request!";
showMessage(err_msg);
throw new Error(err_msg);
}
}
}
if (params.order_type != "buy" || !localbitcoinplusplus.master_configurations.tradableAsset1.includes(
params.product) ||
!localbitcoinplusplus.master_configurations.tradableAsset2.includes(params.currency) ||
params.currency == params.product) {
err_msg = "WARNING: Invalid buy request.";
showMessage(err_msg);
throw new Error(err_msg);
}
if (typeof backup_db=="string" && backup_db.length>0) {
let _addDB = addDB;
let _readDB = readDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_addDB = foreign_db.backup_addDB.bind(foreign_db);
_readDB = foreign_db.backup_readDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
//Check buyer's fiat balance
const trader_cash_id = `${params.trader_flo_address}_${params.currency}`;
_readDB("cash_balances", trader_cash_id).then(function (res) {
if (typeof res !== "undefined" && typeof res.cash_balance == "number" && !isNaN(res.cash_balance)) {
let buyer_cash_balance = parseFloat(res.cash_balance);
let buy_price_btc = parseFloat(params.buy_price);
if (buyer_cash_balance < buy_price_btc) {
err_msg = "WARNING: Insufficient balance of buyer.";
showMessage(err_msg);
throw new Error(err_msg);
}
// calculate equivalent BTC for x amount of Cash
let eqBTC = RM_TRADE.calculateCryptoEquivalentOfCash(buy_price_btc, params.currency,
params.product);
eqBTC = parseFloat(eqBTC);
if (typeof eqBTC == "number" && eqBTC > 0) {
let res_btc;
// supernode data query
_readDB('localbitcoinUser', '00-01').then(function (user_data) {
if (typeof user_data == "object" && typeof localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY ==
"string" && localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
.length >
0) {
try {
// Add buy oder
params['id'] = helper_functions.unique_id();
let hashed_data = Crypto.SHA256(JSON.stringify(params));
// Signing of the data by Supernode
let signed_data = RM_WALLET
.sign(hashed_data, localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
params["data_hash"] = hashed_data;
params["supernode_sign"] = signed_data;
params["supernodePubKey"] = user_data.myLocalFLOPublicKey;
params["status"] = 1;
_addDB("buyOrders", params);
// Send data for further action
callback(params);
} catch (error) {
console.error(error);
callback(false);
}
}
});
callback(false);
} else {
err_msg = "Failed to fetch current BTC price.";
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Failed to read cash balance from DB.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
},
trade_sell(params, callback, backup_db="") {
let err_msg;
for (var key in params) {
if (params.hasOwnProperty(key)) {
if (typeof key == "undefined" || key.trim() == "" || key == null) {
err_msg = "Incomplete or invalid request!";
showMessage(err_msg);
throw new Error(err_msg);
}
}
}
if (params.order_type != "sell" ||
!localbitcoinplusplus.master_configurations.tradableAsset1.includes(params.product) ||
!localbitcoinplusplus.master_configurations.tradableAsset2.includes(params.currency) ||
params.currency == params.product) {
err_msg = "Invalid sell request.";
showMessage(err_msg);
throw new Error(err_msg);
}
if (typeof backup_db=="string" && backup_db.length>0) {
let _addDB = addDB;
let _readDB = readDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_addDB = foreign_db.backup_addDB.bind(foreign_db);
_readDB = foreign_db.backup_readDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
// Check crypto balance of the seller
let seller_btc_id = `${params.trader_flo_address}_${params.product}`;
_readDB("crypto_balances", seller_btc_id).then(function (res) {
if (typeof res !== "undefined" && typeof res.trader_flo_address == "string" && res.trader_flo_address
.length > 0 && res.crypto_balance > 0) {
let seller_btc_balance = parseFloat(res.crypto_balance);
let sell_price_in_inr = parseFloat(params.buy_price);
let eqBTC = RM_TRADE.calculateCryptoEquivalentOfCash(sell_price_in_inr, params.currency,
params.product);
eqBTC = parseFloat(eqBTC);
if (typeof eqBTC == "number" && eqBTC > 0) {
if (seller_btc_balance < eqBTC) {
err_msg = "Insufficient BTC balance.";
showMessage(err_msg);
throw new Error(err_msg);
}
// supernode data query
_readDB('localbitcoinUser', '00-01').then(function (user_data) {
if (typeof user_data == "object" && typeof localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY ==
"string" && localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
.length > 0) {
//Add cash balance
params['id'] = helper_functions.unique_id();
let hashed_data = Crypto.SHA256(JSON.stringify(params));
// Signing of the data by Supernode
let signed_data = RM_WALLET
.sign(hashed_data, localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
params["data_hash"] = hashed_data;
params["supernode_sign"] = signed_data;
params["supernodePubKey"] = user_data.myLocalFLOPublicKey;
params["status"] = 1;
_addDB("sellOrders", params);
callback(params);
}
});
callback(false);
} else {
err_msg = "Failed to fetch current BTC price.";
showMessage(err_msg);
throw new Error(err_msg);
}
} else {
err_msg = "Failed to read BTC balance from DB.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
},
depositAsset(assetType, amount, currency, userFLOaddress) {
if (typeof localbitcoinplusplus.master_configurations.tradableAsset1 == 'undefined' ||
typeof localbitcoinplusplus.master_configurations.tradableAsset2 == 'undefined' ||
(!localbitcoinplusplus.master_configurations.tradableAsset1.includes(assetType) &&
!localbitcoinplusplus.master_configurations.tradableAsset2.includes(assetType))) {
err_msg = "Invalid asset error";
showMessage(err_msg);
throw new Error(err_msg);
} else if (parseFloat(amount) <= 0) {
err_msg = "Invalid amount error.";
showMessage(err_msg);
throw new Error(err_msg);
} else if (userFLOaddress.length < 0) {
err_msg = "User address required.";
showMessage(err_msg);
throw new Error(err_msg);
}
let deposit_request_object = {
trader_flo_address: userFLOaddress,
depositing_amount: amount,
currency: currency,
depositor_key_signature: null,
depositor_public_key: null,
operation_type: "deposit",
order_validator_public_key: null,
product: assetType,
receiver_flo_address:localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"deposit_asset_request", deposit_request_object)
.then(deposit_request=>doSend(deposit_request));
},
withdrawAsset(assetType, amount, receivinAddress, userFLOaddress, currency, callback) {
let err_msg;
if (typeof localbitcoinplusplus.master_configurations.tradableAsset1 == 'undefined' ||
typeof localbitcoinplusplus.master_configurations.tradableAsset2 == 'undefined' ||
(!localbitcoinplusplus.master_configurations.tradableAsset1.includes(assetType) &&
!localbitcoinplusplus.master_configurations.tradableAsset2.includes(assetType) &&
!localbitcoinplusplus.master_configurations.tradableAsset1.includes(currency))) {
err_msg = "Invalid asset error";
showMessage(err_msg);
throw new Error(err_msg);
} else if (parseFloat(amount) <= 0) {
err_msg = "Invalid amount error.";
showMessage(err_msg);
throw new Error(err_msg);
} else if (userFLOaddress.length < 0) {
err_msg = "User address required.";
showMessage(err_msg);
throw new Error(err_msg);
} else if (receivinAddress.trim() == "") {
err_msg = "You must provide a vaid Bitcoin address to receive funds.";
showMessage(err_msg);
throw new Error(err_msg);
}
let withdraw_request_object = {
trader_flo_address: userFLOaddress,
receivinAddress: receivinAddress,
withdrawing_amount: amount,
wihdrawer_key_signature: null,
wihdrawer_public_key: null,
operation_type: "withdraw",
order_validator_public_key: null,
product: assetType,
currency: currency,
receiver_flo_address:localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"withdraw_request_method", withdraw_request_object)
.then(withdraw_request=>doSend(withdraw_request))
},
calculateCryptoEquivalentOfCash(price, currency = "USD", crypto_code) {
if (localbitcoinplusplus.master_configurations.validTradingAmount.includes(price)) {
if (!localbitcoinplusplus.master_configurations.tradableAsset1.includes(crypto_code)) return false;
if (!localbitcoinplusplus.master_configurations.tradableAsset2.includes(currency)) return false;
const RM_TRADE = new localbitcoinplusplus.trade;
let current_crypto_price = RM_TRADE.get_current_crypto_price_in_fiat(crypto_code, currency);
if (typeof current_crypto_price == "object" && current_crypto_price.rate > 0) {
return Number(parseFloat(price / current_crypto_price.rate).toFixed(8));
}
}
let err_msg = `WARNING: Failed to calculate crypto equivalent of cash.`;
showMessage(err_msg);
throw new Error(err_msg);
},
get_current_crypto_price_in_fiat(crypto_code, currency_code) {
return localbitcoinplusplus.trade[`current_${crypto_code}_price_in_${currency_code}`];
},
async resolve_current_crypto_price_in_fiat(crypto_code, currency_code) {
let today = + new Date();
const RM_TRADE = new localbitcoinplusplus.trade;
let last_update_of_fiat_price_obj = RM_TRADE.get_current_crypto_price_in_fiat(crypto_code,
currency_code);
if (typeof last_update_of_fiat_price_obj !== "object" ||
(today - last_update_of_fiat_price_obj.timestamp > 3600000)) {
last_update_of_fiat_price_obj = await RM_TRADE.set_current_crypto_price_in_fiat(crypto_code,
currency_code);
return last_update_of_fiat_price_obj;
} else {
return last_update_of_fiat_price_obj;
}
},
async set_current_crypto_price_in_fiat(crypto_code, currency_code) {
if (!localbitcoinplusplus.master_configurations.tradableAsset1.includes(crypto_code) ||
!localbitcoinplusplus.master_configurations.tradableAsset2.includes(currency_code)) return false;
let new_price = 1000000;
/**************************
Fetch latest rates here
***************************/
// if(crypto_code=="BTC" || crypto_code=="BTC_TEST") {
// new_price = (currency_code=="USD") ? 3540 : 300000;
// } else if(crypto_code=="FLO" || crypto_code=="FLO_TEST") {
// new_price = (currency_code=="USD") ? 0.08 : 5.8;
// }
Object.defineProperty(localbitcoinplusplus.trade,
`current_${crypto_code}_price_in_${currency_code}`, {
value: {
rate: new_price,
timestamp: +new Date()
},
writable: true,
configurable: false,
enumerable: true
});
return localbitcoinplusplus.trade[`current_${crypto_code}_price_in_${currency_code}`];
},
sendTransaction(crypto_type, utxo_addr, utxo_addr_wif, receiver_address, receiving_amount,
receiving_amount_currency = null, change_adress, callback) {
let blockchain_explorer;
if (crypto_type == "BTC") {
blockchain_explorer = localbitcoinplusplus.server.btc_mainnet;
} else if (crypto_type == "BTC_TEST") {
blockchain_explorer = localbitcoinplusplus.server.btc_testnet;
} else if (crypto_type == "FLO") {
blockchain_explorer = localbitcoinplusplus.server.flo_mainnet;
} else if (crypto_type == "FLO_TEST") {
blockchain_explorer = localbitcoinplusplus.server.flo_testnet;
}
if(typeof blockchain_explorer !== "string") {
showMessage(`WARNING: Please select cryptocurrency/fiat value from select bar.`);
return false;
}
let url = `${blockchain_explorer}/api/addr/${utxo_addr}/utxo`;
console.log(url);
let err_msg;
helper_functions.ajaxGet(url).then(utxo_list => {
if (utxo_list.length > 0) {
try {
let btc_eq_receiving_amount = receiving_amount;
if (typeof receiving_amount_currency == "string") {
if (!localbitcoinplusplus.master_configurations.validTradingAmount.includes(
receiving_amount)) {
err_msg = `ERROR: Amount value is invalid.`;
showMessage(err_msg);
throw new Error(err_msg);
}
const RM_TRADE = new localbitcoinplusplus.trade;
btc_eq_receiving_amount = RM_TRADE.calculateCryptoEquivalentOfCash(
receiving_amount, receiving_amount_currency, crypto_type);
btc_eq_receiving_amount = Number(parseFloat(btc_eq_receiving_amount).toFixed(8));
}
let trx = bitjs[crypto_type].transaction();
let sum = 0;
const miners_fee = 0.00030000;
for (var key in utxo_list) {
if (utxo_list[key].confirmations !== 0) {
var obj = utxo_list[key];
sum += obj.amount;
if (btc_eq_receiving_amount <= (sum-miners_fee)) {
trx.addinput(obj.txid, obj.vout, obj.scriptPubKey);
break;
} else {
trx.addinput(obj.txid, obj.vout, obj.scriptPubKey);
}
}
}
let change_amount = 0;
if (sum - btc_eq_receiving_amount - miners_fee>0) {
change_amount = sum - btc_eq_receiving_amount - miners_fee;
}
trx.addoutput(receiver_address, btc_eq_receiving_amount);
if (change_amount>0) {
trx.addoutput(change_adress, change_amount);
}
var sendFloData =
`localbitcoinpluslus tx: Send ${btc_eq_receiving_amount} satoshis to ${receiver_address}.`; //flochange adding place for flodata -- need a validation of 1024 chars
if (crypto_type == "FLO" || crypto_type == "FLO_TEST") {
trx.addflodata(sendFloData); // flochange .. create this function
}
try {
console.log(trx);
let signedTxHash = trx.sign(utxo_addr_wif, 1); //SIGHASH_ALL DEFAULT 1
showMessage(`Signed Transaction Hash: ${signedTxHash}`);
var http = new XMLHttpRequest();
var tx_send_url = `${blockchain_explorer}/api/tx/send`;
var params = `{"rawtx":"${signedTxHash}"}`;
http.open('POST', tx_send_url, true);
http.setRequestHeader('Content-type', 'application/json');
http.onreadystatechange = function () { //Call a function when the state changes.
if (http.readyState == 4 && http.status == 200) {
showMessage(http.responseText);
callback(http.responseText);
}
}
http.send(params);
} catch (error) {
showMessage(error);
throw new Error(error);
}
} catch (error) {
throw new Error(error);
}
}
}).catch(e => console.error(`No balance found in ${utxo_addr}: ${e}`));
},
/*Finds the best buy sell id match for a trade*/
createTradePipes(trading_currency = "USD", backup_db="") {
if (typeof backup_db=="string" && backup_db.length>0) {
let _readAllDB = readAllDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_readAllDB = foreign_db.backup_readAllDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
try {
_readAllDB("sellOrders").then(function (sellOrdersList) {
if (sellOrdersList.length > 0) {
sellOrdersList = sellOrdersList.filter(sellOrder => sellOrder.currency ==
trading_currency);
_readAllDB("buyOrders").then(function (buyOrdersList) {
if (buyOrdersList.length > 0) {
buyOrdersList = buyOrdersList.filter(buyOrder => buyOrder.currency ==
trading_currency);
let buy = [];
let sell = [];
let buysell = [];
let buysellArray = [];
let buyPipe = [];
let sellPipe = [];
localbitcoinplusplus.master_configurations.validTradingAmount.map(
li => {
buy[li] = buyOrdersList.filter(buyOrder => buyOrder
.buy_price == li);
sell[li] = sellOrdersList.filter(sellOrder =>
sellOrder.buy_price == li);
buysell[li] = {
"buy": buy[li],
"sell": sell[li]
};
buysellArray[li] = Object.entries(buysell[li]).map(
([key, value]) => ({
key,
value
}));
buyPipe = buysellArray[li][0];
sellPipe = buysellArray[li][1];
let n = buyPipe.value.length < sellPipe.value.length ?
buyPipe.value.length : sellPipe.value.length;
if (buyPipe.value.length > 0 && sellPipe.value.length > 0) {
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
for (let i = 0; i < n; i++) {
RM_TRADE.launchTrade(
buyPipe.value[i], sellPipe.value[i],
function (supernode_res) {
if (typeof supernode_res ==
"object") {
RM_RPC.send_rpc.call(
this,
"trade_balance_updates",
supernode_res)
.then(server_res=>doSend(server_res))
}
}, backup_db);
}
}
});
}
});
}
});
} catch (e) {
console.error(e);
}
},
launchTrade(buyPipeObj, sellPipeObj, callback, backup_db="") {
if (typeof backup_db=="string" && backup_db.length>0) {
let _addDB = addDB;
let _readDB = readDB;
let _readDBbyIndex = readDBbyIndex;
let _readAllDB = readAllDB;
let _updateinDB = updateinDB;
let _removeinDB = removeinDB;
let _removeByIndex = removeByIndex;
let _removeAllinDB = removeAllinDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_addDB = foreign_db.backup_addDB.bind(foreign_db);
_readDB = foreign_db.backup_readDB.bind(foreign_db);
_readDBbyIndex = foreign_db.backup_readDBbyIndex.bind(foreign_db);
_readAllDB = foreign_db.backup_readAllDB.bind(foreign_db);
_updateinDB = foreign_db.backup_updateinDB.bind(foreign_db);
_removeinDB = foreign_db.backup_removeinDB.bind(foreign_db);
_removeByIndex = foreign_db.backup_removeByIndex.bind(foreign_db);
_removeAllinDB = foreign_db.backup_removeAllinDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
if (buyPipeObj.order_type == "buy" && sellPipeObj.order_type == "sell" &&
buyPipeObj.buy_price == sellPipeObj.buy_price &&
buyPipeObj.currency == sellPipeObj.currency &&
buyPipeObj.product == sellPipeObj.product
) {
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_WALLET = new localbitcoinplusplus.wallets;
let err_msg;
// Check buyer's cash balance
const buyer_cash_id = `${buyPipeObj.trader_flo_address}_${buyPipeObj.currency}`;
_readDB("cash_balances", buyer_cash_id).then(function (buyPipeCashRes) {
if (typeof buyPipeCashRes == "object" && typeof buyPipeCashRes.cash_balance ==
"number") {
let buyer_cash_balance = parseFloat(buyPipeCashRes.cash_balance);
let buy_price_btc = parseFloat(buyPipeObj.buy_price);
if (buyer_cash_balance < buy_price_btc) {
err_msg = "Insufficient cash balance of buyer.";
showMessage(err_msg);
throw new Error(err_msg);
}
// calculate equivalent BTC for x amount of Cash
let eqBTCBuyer = RM_TRADE.calculateCryptoEquivalentOfCash(buy_price_btc,
buyPipeObj.currency, buyPipeObj.product);
if (!isNaN(eqBTCBuyer) && eqBTCBuyer != "" && eqBTCBuyer != undefined) {
eqBTCBuyer = parseFloat(eqBTCBuyer);
}
// Check seller's crypto balance
let seller_btc_id = `${sellPipeObj.trader_flo_address}_${sellPipeObj.product}`;
_readDB("crypto_balances", seller_btc_id).then(function (sellPipeBTCRes) {
if (typeof sellPipeBTCRes == "object" && typeof sellPipeBTCRes.crypto_balance ==
"number") {
let seller_btc_balance = Number(parseFloat(sellPipeBTCRes.crypto_balance)
.toFixed(8));
let sell_price_in_inr = parseFloat(sellPipeObj.buy_price);
let eqBTCSeller = RM_TRADE.calculateCryptoEquivalentOfCash(
sell_price_in_inr, buyPipeObj.currency, buyPipeObj.product
);
if (!isNaN(eqBTCSeller) && eqBTCSeller != "" && eqBTCSeller !=
undefined) {
eqBTCSeller = parseFloat(eqBTCSeller);
if (seller_btc_balance < eqBTCSeller) {
err_msg = "Insufficient BTC balance of seller.";
showMessage(err_msg);
throw new Error(err_msg);
}
// Increase buyer's crypto balance
let buyerBTCResponseObject;
let buyer_btc_id =
`${buyPipeObj.trader_flo_address}_${buyPipeObj.product}`;
_readDB("crypto_balances", buyPipeObj.trader_flo_address).then(
function (buyPipeBTCRes) {
if (typeof buyPipeBTCRes == "object" && typeof buyPipeBTCRes
.crypto_balance == "number") {
buyPipeBTCRes.crypto_balance = parseFloat(
buyPipeBTCRes.crypto_balance) +
eqBTCBuyer;
buyerBTCResponseObject = buyPipeBTCRes;
} else {
// The user bought BTC for first time
buyerBTCResponseObject = {
id: `${buyPipeObj.trader_flo_address}_${buyPipeObj.product}`,
trader_flo_address: buyPipeObj.trader_flo_address,
crypto_balance: eqBTCBuyer,
crypto_currency: buyPipeObj.product
}
}
// Decrease buyer cash balance
let buyer_new_cash_balance = buyer_cash_balance -
buy_price_btc;
let buyerCashResponseObject = {
id: buyer_cash_id,
currency: buyPipeObj.currency,
trader_flo_address: buyPipeObj.trader_flo_address,
cash_balance: buyer_new_cash_balance
}
// Increase seller's Cash balance
let sellerCashResponseObject;
const seller_cash_id =
`${sellPipeObj.trader_flo_address}_${buyPipeObj.currency}`;
_readDB("cash_balances", seller_cash_id).then(
function (sellPipeCashRes) {
if (typeof sellPipeCashRes ==
"object" && typeof sellPipeCashRes
.cash_balance == "number" &&
!isNaN(sellPipeCashRes.cash_balance)
) {
sellPipeCashRes.cash_balance =
parseFloat(sellPipeCashRes.cash_balance) +
sell_price_in_inr;
sellerCashResponseObject =
sellPipeCashRes;
} else {
// User got cash for the first time
let seller_cash_id =
`${sellPipeObj.trader_flo_address}_${buyPipeObj.currency}`;
sellerCashResponseObject = {
id: seller_cash_id,
trader_flo_address: sellPipeObj
.trader_flo_address,
currency: buyPipeObj.currency,
cash_balance: sell_price_in_inr
}
}
// Decrease seller BTC balance
let new_seller_btc_balance =
seller_btc_balance -
eqBTCSeller;
new_seller_btc_balance = Number(parseFloat(new_seller_btc_balance).toFixed(8));
let sellerBTCResponseObject = {
id: `${sellPipeObj.trader_flo_address}_${sellPipeObj.product}`,
trader_flo_address: sellPipeObj
.trader_flo_address,
crypto_balance: new_seller_btc_balance,
crypto_currency: sellPipeObj
.product
}
// supernode data query
_readDB('localbitcoinUser', '00-01')
.then(
function (user_data) {
if (typeof user_data ==
"object" && typeof localbitcoinplusplus
.wallets.MY_SUPERNODE_PRIVATE_KEY ==
"string" &&
localbitcoinplusplus
.wallets.MY_SUPERNODE_PRIVATE_KEY
.length > 0) {
// Delete orders
try {
_removeinDB(
"buyOrders",
buyPipeObj
.id);
_removeinDB(
"sellOrders",
sellPipeObj
.id);
} catch (error) {
callback(false);
showMessage(`WARNING: Failed to delete respective buy and sell orders in an operation.`);
throw new Error(error);
}
// Update balances
try {
_updateinDB(
"cash_balances",
buyerCashResponseObject,
buyPipeObj
.trader_flo_address
);
_updateinDB(
"cash_balances",
sellerCashResponseObject,
sellPipeObj
.trader_flo_address
);
_updateinDB(
"crypto_balances",
buyerBTCResponseObject,
buyPipeObj
.trader_flo_address
);
_updateinDB(
"crypto_balances",
sellerBTCResponseObject,
sellPipeObj
.trader_flo_address
);
} catch (error) {
showMessage(`WARNING: Failed to update cash and crypto balances during launch trade operation.`);
callback(false);
throw new Error(error);
}
// Prepare response
let trade_infos = {
"buy_order_id": buyPipeObj
.id,
"sell_order_id": sellPipeObj
.id,
"buyer_flo_id": buyPipeObj
.trader_flo_address,
"seller_flo_id": sellPipeObj
.trader_flo_address
}
let trade_infos_str =
JSON.stringify(
trade_infos
);
let
buyerCashResponseObjectStr =
JSON.stringify(
buyerCashResponseObject
);
let
sellerCashResponseObjectStr =
JSON.stringify(
sellerCashResponseObject
);
let
buyerBTCResponseObjectStr =
JSON.stringify(
buyerBTCResponseObject
);
let
sellerBTCResponseObjectStr =
JSON.stringify(
sellerBTCResponseObject
);
let res_str =
`${trade_infos_str}${buyerCashResponseObjectStr}${sellerCashResponseObjectStr}${buyerBTCResponseObjectStr}${sellerBTCResponseObjectStr}`;
let hashed_data =
Crypto.SHA256(
res_str);
// Signing of the data by Supernode
let signed_data =
RM_WALLET
.sign(
hashed_data,
localbitcoinplusplus
.wallets.MY_SUPERNODE_PRIVATE_KEY
);
let
response_for_client = {
"trade_infos": trade_infos,
"buyer_cash_data": buyerCashResponseObject,
"seller_cash_data": sellerCashResponseObject,
"buyer_btc_data": buyerBTCResponseObject,
"seller_btc_data": sellerBTCResponseObject,
"data_hash": hashed_data,
"supernode_sign": signed_data,
"supernodePubKey": user_data.myLocalFLOPublicKey,
"trader_flo_address": buyPipeObj.trader_flo_address,
}
callback(response_for_client);
return true;
}
});
});
});
}
}
});
}
});
callback(false);
}
},
cancelTrade(trade_id, trader_flo_address, trade_type) {
if (typeof trade_id !== "string") {
showMessage("WARNING: Failed to cancel the trade.");
return false;
}
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_RPC = new localbitcoinplusplus.rpc;
const signed_trade_id = RM_WALLET.sign(trade_id, localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
const cancel_trade_request_object = {
job: `cancel_trade_request`,
trade_id: trade_id,
signed_trade_id: signed_trade_id,
trader_flo_address: trader_flo_address,
trade_type: trade_type,
receiver_flo_address:localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}
RM_RPC.send_rpc.call(this,
"cancel_trade", cancel_trade_request_object)
.then(cancel_trade_request=>doSend(cancel_trade_request));
},
getAssetTradeAndWithdrawLimit(flo_id, crypto, fiat, backup_db="") {
if (typeof backup_db=="string" && backup_db.length>0) {
let _readDB = readDB;
let _readDBbyIndex = readDBbyIndex;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_readDB = foreign_db.backup_readDB.bind(foreign_db);
_readDBbyIndex = foreign_db.backup_readDBbyIndex.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
const RM_TRADE = new localbitcoinplusplus.trade;
let user_crypto_id = `${flo_id}_${crypto}`;
let user_fiat_id = `${flo_id}_${fiat}`;
const user_balance_crypto_promise = _readDB("crypto_balances", user_crypto_id);
const user_balance_fiat_promise = _readDB("cash_balances", user_fiat_id);
const user_sell_orders_promise = _readDBbyIndex("sellOrders", "trader_flo_address", flo_id)
.then((res) => res.filter(resp => resp.currency == fiat && resp.product == crypto));
const user_buy_orders_promise = _readDBbyIndex("buyOrders", "trader_flo_address", flo_id)
.then((res) => res.filter(resp => resp.currency == fiat && resp.product == crypto));
const user_fiat_withdraw_request_promise = _readDBbyIndex("withdraw_cash", "trader_flo_address",
flo_id);
const user_crypto_withdraw_request_promise = _readDBbyIndex("withdraw_btc", "trader_flo_address",
flo_id);
return Promise.all([user_balance_crypto_promise, user_balance_fiat_promise,
user_sell_orders_promise, user_buy_orders_promise,
user_fiat_withdraw_request_promise, user_crypto_withdraw_request_promise
]).then(resp => {
let user_balance_crypto = resp[0];
let user_balance_fiat = resp[1];
let user_sell_orders = resp[2];
let user_buy_orders = resp[3];
let user_fiat_withdraw_request = resp[4];
let user_crypto_withdraw_request = resp[5];
let remaining_crypto_credit = 0;
let remaining_fiat_credit = 0;
let user_crypto_balance_value = (typeof user_balance_crypto == "undefined") ? 0 :
user_balance_crypto.crypto_balance;
let user_cash_balance_value = (typeof user_balance_fiat == "undefined") ? 0 :
user_balance_fiat.cash_balance;
let sell_order_crypto_equivalent = 0;
user_sell_orders.map(sell_orders => {
sell_order_crypto_eq = RM_TRADE.calculateCryptoEquivalentOfCash(
sell_orders.buy_price, sell_orders.currency, sell_orders.product);
sell_order_crypto_equivalent += Number(sell_order_crypto_eq);
});
let withdraw_crypto_equivalent = 0;
user_crypto_withdraw_request.map(req => {
withdraw_crypto_eq = RM_TRADE.calculateCryptoEquivalentOfCash(req.receiverBTCEquivalentInCash,
req.currency, req.product);
withdraw_crypto_equivalent += Number(withdraw_crypto_eq);
});
remaining_crypto_credit = user_crypto_balance_value - sell_order_crypto_equivalent -
withdraw_crypto_equivalent;
let total_buy_orders_cash = 0;
user_buy_orders.map(buy_order => total_buy_orders_cash += buy_order.buy_price);
let withdraw_cash_equivalent = 0;
user_fiat_withdraw_request.map(req => {
withdraw_cash_equivalent += req.withdraw_amount;
});
remaining_fiat_credit = user_cash_balance_value - total_buy_orders_cash -
withdraw_cash_equivalent;
return {
remaining_crypto_credit: remaining_crypto_credit,
remaining_fiat_credit: remaining_fiat_credit
};
}).catch(e => console.warn(e));
},
}
</script>
<!-- Helper functions -->
<script>
let helper_functions = {
// AJAX Get
ajaxGet: async function (url) {
try {
//await the response of the fetch call
let response = await fetch(url);
//proceed once the first promise is resolved.
let data = await response.json()
//proceed only when the second promise is resolved
return data;
} catch (error) {
showMessage(`WARNING: Failed to get data from ${url}.`);
throw new Error(error);
}
},
//AJAX Post
ajaxPost: function (url = ``, data = {}) {
return fetch(url, {
method: "POST", // *GET, POST, PUT, DELETE, etc.
mode: "cors", // no-cors, cors, *same-origin
cache: "no-cache", // *default, no-cache, reload, force-cache, only-if-cached
credentials: "same-origin", // include, *same-origin, omit
headers: {
"Content-Type": "application/json",
// "Content-Type": "application/x-www-form-urlencoded",
},
redirect: "follow", // manual, *follow, error
referrer: "no-referrer", // no-referrer, *client
body: JSON.stringify(data), // body data type must match "Content-Type" header
})
.then(response => response.json()); // parses response to JSON
},
// Create unique id
unique_id: function () {
return `${+new Date()}_${Math.random().toString(36).substr(2, 9)}`;
},
}
</script>
<!-- JSON RPC Library Starts (https://github.com/oliver-moran/json-rpc) -->
<script language="javascript" type="text/javascript">
var JSON_RPC = {};
var id = 0,
callbacks = {};
/**
* Constructs a new JSON-RPC Request
* @param method A String containing the name of the method to be invoked.
* @param params (optional) A Structured value that holds the parameter values to be used during the invocation of the method.
*/
JSON_RPC.Request = function (method, params, globalParams={}) {
this.jsonrpc = "2.0";
this.method = method;
if (typeof params !== "undefined") {
this.params = params;
}
this.globalParams = globalParams;
this.id = id++;
};
// Implements getters and setters for the result of a JSON-RPC Request.
// The result may be an any Object or primitive
Object.defineProperty(JSON_RPC.Request.prototype, "result", {
get: function () {
return this._result;
},
set: function (result) {
delete this.method; // remove the method name
delete this.params; // remove the params
delete this.error; // remove error state if it exists
delete this.globalParams; // remove globalParams
this._result = result;
}
});
// Implements getters and setters for the error state of a JSON-RPC Request.
// Error should be a JSON_RPC.Error object
Object.defineProperty(JSON_RPC.Request.prototype, "error", {
get: function () {
return this._error;
},
set: function (error) {
delete this.method; // remove the method name
delete this.params; // remove the params
delete this.result; // remove result state if it exists
delete this.globalParams; // remove globalParams if it exists
this._error = error;
}
});
/**
* Returns a String representation of a JSON-RPC Request
* @returns A JSON String
*/
JSON_RPC.Request.prototype.toString = function () {
var rpc = {
jsonrpc: this.jsonrpc,
id: this.id
};
if (this.method !== undefined) rpc.method = this.method;
if (this.params !== undefined) rpc.params = this.params;
if (this.result !== undefined) rpc.result = this.result;
if (this.error !== undefined) rpc.error = this.error;
if (this.globalParams !== undefined) rpc.globalParams = this.globalParams;
return JSON.stringify(rpc);
};
/**
* Constructs a new JSON-RPC Notification
* @param method A String containing the name of the method to be invoked.
* @param params (optional) A Structured value that holds the parameter values to be used during the invocation of the method.
*/
JSON_RPC.Notification = function (method, params, globalParams) {
this.jsonrpc = "2.0";
this.method = method;
if (typeof params !== "undefined") {
this.params = params;
}
if (typeof globalParams !== "undefined") {
this.globalParams = globalParams;
}
};
/**
* Returns a String representation of a JSON-RPC Notification
* @returns A JSON String
*/
JSON_RPC.Notification.prototype.toString = function () {
var rpc = {
jsonrpc: this.jsonrpc,
method: this.method,
params: this.params,
globalParams: this.globalParams,
};
return JSON.stringify(rpc);
};
/**
* Constructs a new JSON-RPC Errror object
* @params code A Number that indicates the error type that occurred. -32768 to -32000 are reserved.
* @param message (optional) A String providing a short description of the error.
* @param data (optional) A Primitive or Structured value that contains additional information about the error.
*/
JSON_RPC.Error = function (code, message, data) {
this.code = code;
if (typeof message == "string") this.message = message;
if (data !== undefined) this.data = data;
};
// stock errors
JSON_RPC.PARSE_ERROR = new JSON_RPC.Error(-32700,
"An error occurred on the server while parsing the JSON text.");
JSON_RPC.INVALID_REQUEST = new JSON_RPC.Error(-32600, "The JSON sent is not a valid Request object.");
JSON_RPC.METHOD_NOT_FOUND = new JSON_RPC.Error(-32601, "The method does not exist / is not available.");
JSON_RPC.INVALID_PARAMS = new JSON_RPC.Error(-32602, "Invalid method parameter(s).");
JSON_RPC.INTERNAL_ERROR = new JSON_RPC.Error(-32603, "Internal JSON-RPC error.");
/**
* Parses a JSON-RPC string and converts to a JSON-RPC object or an Array of such strings.
* @params rpc A String or Array to parse to a JSON-RPC object.
*/
JSON_RPC.parse = function (rpc) {
// batch?
if (rpc.constructor === Array) {
var arr = [];
rpc.forEach(function (el) {
arr.push(JSON_RPC.parse(el));
});
return arr;
}
// parsable?
var rpc;
try {
rpc = JSON.parse(rpc);
} catch (err) {
var obj = new JSON_RPC.Request();
obj.result = JSON_RPC.PARSE_ERROR;
obj.id = null;
return obj;
}
// 2.0?
if (rpc.jsonrpc !== "2.0") {
var obj = new JSON_RPC.Request();
obj.result = JSON_RPC.INVALID_REQUEST;
obj.id = null;
return obj;
}
// request or notification?
var obj = (rpc.id === undefined) ?
new JSON_RPC.Notification(rpc.method, rpc.params) :
new JSON_RPC.Request(rpc.method, rpc.params);
// have an ID?
if (rpc.id !== undefined) obj.id = rpc.id;
// is it a result?
if (rpc.result !== undefined) obj.result = rpc.result;
// is it a error?
if (rpc.error !== undefined) {
obj.error = new JSON_RPC.Error(
rpc.error.code,
rpc.error.message,
rpc.error.data
);
}
// parsed :-)
return obj;
};
/* JSON RPC Library Ends */
/*******************************************************
Custom Localbitcoin++ JSON-RPC code starts here
*********************************************************/
/* Websocket Code Starts here */
var output;
function kickInit() {
output = document.getElementById("output_div");
const RM_WALLET = new localbitcoinplusplus.wallets;
const BACKUP_DB = localbitcoinplusplus.newBackupDatabase.db = [];
const backUpSupernodesWS = localbitcoinplusplus.backupWS = [];
return new Promise(resolve => {
readDB("localbitcoinUser", "00-01").then(async function (idbData) {
if (typeof idbData.myLocalFLOPublicKey == "undefined" || idbData.myLocalFLOPublicKey
.trim() == '') {
let user_pvt_key = prompt(
"Please Enter a valid FLO private key if you have any. Else leave blank."
);
if (user_pvt_key.trim() == "" || user_pvt_key.length < 1) user_pvt_key = null;
let newKeys = RM_WALLET.generateFloKeys(user_pvt_key);
if (typeof newKeys == 'object' && newKeys.privateKeyWIF.length > 0 &&
newKeys.address.length > 0) {
localbitcoinplusplusObj.myLocalFLOAddress = newKeys.address;
localbitcoinplusplusObj.myLocalFLOPublicKey = newKeys.pubKeyHex;
localbitcoinplusplusObj.lastConnectedTime = + new Date();
await updateinDB("localbitcoinUser", localbitcoinplusplusObj);
// launch KBuckets
launchKBuckects = await localbitcoinplusplus.kademlia.launchKBucket(newKeys.address);
if (!launchKBuckects) {
const kmsg = `ERROR: Failed to build KBuckets. System cannot proceed further.`;
showMessage(kmsg);
throw new Error(kmsg);
}
await localbitcoinplusplus.kademlia.restoreSupernodeKBucket();
wsUri = await localbitcoinplusplus.kademlia.getSupernodeSeed(
localbitcoinplusplusObj.myLocalFLOAddress);
// Add close supernodes to KBucket
wsUri.map(d=>{
localbitcoinplusplus.kademlia.addNewUserNodeInKbucket(
"FLO_TEST", d.trader_flo_address, { id: d.trader_flo_address })
showMessage(`INFO: Added Supernode Id ${d.trader_flo_address} to KBucket.`);
});
await startWebSocket(`ws://${wsUri[0].ip}:${wsUri[0].port}`);
RM_WALLET.distributeShamirsSecretShares(newKeys.privateKeyWIF)
.then(() => privateKeyBuilder())
.finally(()=>{
setTimeout(function(){
if ((typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY!=='string'
|| localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY.length<1)
) {
RM_WALLET.manually_assign_my_private_key();
loadExternalFiles();
dataBaseUIOperations();
} else if(typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string' &&
localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
}
clearTimeout();
}, 10000);
});
// Connect with backup supernodes
wsUri.filter((uri, index)=>{
if(index>0 && localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplusObj.myLocalFLOPublicKey)) {
return uri;
}
}).map((uri, index)=>{
console.log(uri);
backUpSupernodesWS[uri.trader_flo_address] = new backupSupernodesWebSocketObject(`ws://${uri.ip}:${uri.port}`);
backUpSupernodesWS[uri.trader_flo_address].connectWS();
let dbname = `su_backup_${uri.trader_flo_address}`;
BACKUP_DB[uri.trader_flo_address] = new newBackupDB(dbname);
BACKUP_DB[uri.trader_flo_address].createNewDB();
});
localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS = wsUri[0].trader_flo_address;
resolve(true);
return;
} else {
err_msg = "Failed to generate new FLO keys. Please retry.";
showMessage(err_msg);
throw new Error(err_msg);
}
}
// launch KBucekts
launchKBuckects = await localbitcoinplusplus.kademlia.launchKBucket(idbData.myLocalFLOAddress);
if (!launchKBuckects) {
const kmsg = `ERROR: Failed to build KBuckets. System cannot proceed further.`;
showMessage(kmsg);
throw new Error(kmsg);
}
await localbitcoinplusplus.kademlia.restoreSupernodeKBucket();
wsUri = await localbitcoinplusplus.kademlia.getSupernodeSeed(idbData.myLocalFLOAddress);
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(idbData.myLocalFLOPublicKey)) {
const getClosestSuList = await readAllDB('myClosestSupernodes');
if (wsUri[0].trader_flo_address !== idbData.myLocalFLOAddress || getClosestSuList.length < 3) {
showMessage(`INFO: Invalid connection. Refreshing the closest supernode list in DB.`);
wsUri = await localbitcoinplusplus.kademlia.updateClosestSupernodeSeeds(idbData.myLocalFLOAddress);
}
}
// Add close supernodes to KBucket
wsUri.map(d=>{
localbitcoinplusplus.kademlia.addNewUserNodeInKbucket(
"FLO_TEST", d.trader_flo_address, { id: d.trader_flo_address })
showMessage(`INFO: Added Supernode Id ${d.trader_flo_address} to KBucket.`);
});
// Connect with primary supernodes
await startWebSocket(`ws://${wsUri[0].ip}:${wsUri[0].port}`);
// Check last connected supernode, if not primary then
// update the user data from other su first
if (typeof idbData.lastConnectedSupernode == "string"
&& idbData.lastConnectedSupernode !== wsUri[0].trader_flo_address) {
showMessage(`INFO: We are fetching your latest data. This could take some time. Do not close the window until then.`);
// Get data for deposits and withdraw from last (currently alive) backup supernode
readAllDB('myClosestSupernodes').then(cs=>{
for (let index = cs.length; index > 0; index--) {
const element = cs[index];
localbitcoinplusplus.actions
.sync_primary_supernode_from_backup_supernode(primarySupernode, getPrimarySuObj[element].data.id);
}
});
}
// rebuild private key
await privateKeyBuilder();
setTimeout(function() {
if ((typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY!=='string'
|| localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY.length<1)
) {
RM_WALLET.manually_assign_my_private_key();
loadExternalFiles();
dataBaseUIOperations();
} else if(typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string' &&
localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
}
}, 10000);
localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS = wsUri[0].trader_flo_address;
// Connect with backup supernodes
wsUri.filter((uri, index)=>{
if(index>0 && localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(idbData.myLocalFLOPublicKey)) {
return uri;
}
}).map((uri, index)=>{
console.log(uri);
backUpSupernodesWS[uri.trader_flo_address] = new backupSupernodesWebSocketObject(`ws://${uri.ip}:${uri.port}`);
backUpSupernodesWS[uri.trader_flo_address].connectWS();
});
// Init backup db for rest supernodes
localbitcoinplusplus.master_configurations.supernodesPubKeys
.map(p=>bitjs.FLO_TEST.pubkey2address(p))
.filter(f=>f!==localbitcoinplusplus.wallets.my_local_flo_address)
.map(m=>{
let dbname = `su_backup_${m}`;
BACKUP_DB[m] = new newBackupDB(dbname);
BACKUP_DB[m].createNewDB();
});
resolve(true);
});
});
}
const backupSupernodesWebSocketObject = localbitcoinplusplus.backupWS = function(ws_url) {
this.ws_url = ws_url;
this.ws_connection = null;
}
backupSupernodesWebSocketObject.prototype = {
async handle_backup_server_messages(evt) {
var response = evt.data;
writeToScreen('backup response: '+response);
let isItANodeLeavingMessage = response.search(`\\-- left`);
if(isItANodeLeavingMessage >= 0) {
reactor.dispatchEvent('fireNodeGoodByeEvent', response);
}
var res_pos = response.indexOf('{');
if (res_pos >= 0) {
let isRequestToLinkIp = response.search("linkMyLocalIPToMyFloId");
let isRequestToLinkOthersIp = response.search("link_Others_Local_IP_To_Their_Flo_Id");
let incoming_msg_local_ip = ``;
if (isRequestToLinkIp>=0 || isRequestToLinkOthersIp>=0) {
let index_of_ip = response.indexOf(' ');
if (incoming_msg_local_ip>=0) {
incoming_msg_local_ip = response.substr(0, index_of_ip);
}
}
var res = response.substr(res_pos);
try {
const isIncomingMessageValid = await validateIncomingMessage(res);
console.log("isIncomingMessageValid (Backup): ", isIncomingMessageValid);
var res_obj = JSON.parse(res);
if (typeof res_obj.method !== "undefined") {
let response_from_sever;
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
switch (res_obj.method) {
case "give_me_your_backup":
if (typeof res_obj.params == "object"
&& typeof res_obj.params[0] == "object") {
let received_resp = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(received_resp.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request || received_resp.JOB!=="BACKUP_SERVER_REQUEST") return;
const requester_supernode_pubkey = received_resp.requesters_pub_key;
const requester_supernode_flo_address = received_resp.trader_flo_address;
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "userPublicData"
];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray).then(
function (su_db_data) {
if (typeof su_db_data == "object") {
su_db_data.trader_flo_address = localbitcoinplusplus.wallets.my_local_flo_address;
su_db_data.receiver_flo_address = requester_supernode_flo_address;
RM_RPC
.send_rpc
.call(this, "backup_server_sync_response",
su_db_data)
.then(server_sync_response=>doSend(server_sync_response));
}
});
});
}
break;
case "server_sync_response":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let su_backup_db_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(su_backup_db_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
(async function () {
for (let tableStoreName in su_backup_db_data) {
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address' || !su_backup_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_backup_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"]
.includes(tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await backup_server_db_instance.backup_updateinDB(tableStoreName,
obj[prop], obj[prop].trader_flo_address);
}
}
} else {
let resdbdata = await backup_server_db_instance.backup_removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await backup_server_db_instance.backup_addDB(resdbdata, obj[prop]);
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
});
break;
case "trade_buy_request_response":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let buyOrders_data = res_obj.params[0];
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
buyOrders_data.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(buyOrders_data.data_hash, buyOrders_data.supernode_sign,
buyOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
// Add buy order
backup_server_db_instance.backup_addDB("buyOrders", buyOrders_data).then(() => {
showMessage(`Your buy order is placed successfully.`);
});
}
}
break;
case "trade_sell_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let sellOrders_data = res_obj.params[0];
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(sellOrders_data.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(sellOrders_data.data_hash, sellOrders_data.supernode_sign,
sellOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
// Add buy order
backup_server_db_instance.backup_addDB("sellOrders", sellOrders_data).then(() => {
showMessage(`Your sell order is placed successfully.`);
});
}
}
}
break;
case "deposit_asset_request_response":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let deposit_res_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(deposit_res_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object"
&& typeof res_obj.params[0].data == "object") {
let resp = res_obj.params[0];
if (RM_WALLET
.verify(resp.data.depositDataHash, resp.data.order_validator_sign, resp.data.order_validator_public_key)
) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_addDB('deposit', resp.data);
if (typeof resp.withdrawer_data == "object") {
backup_server_db_instance.backup_updateinDB("withdraw_cash", resp.withdrawer_data, resp.withdrawer_data.trader_flo_address);
}
backup_server_db_instance.backup_readDB("localbitcoinUser", "00-01").then(function (user) {
if (typeof user == "object" && user.myLocalFLOAddress == resp.data.trader_flo_address) {
let counterTraderAccountAddress =
`<p><strong>Please pay the amount to following address:</strong></p>
<p>${resp.msg}</p>`;
showMessage(counterTraderAccountAddress);
modalWindow(counterTraderAccountAddress);
}
});
}
}
});
break;
case "withdrawal_request_response":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let withdrawal_res_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(withdrawal_res_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if (RM_WALLET
.verify(res_obj.params[0].withdrawDataHash, res_obj.params[0].order_validator_sign,
res_obj.params[0].order_validator_public_key)) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_addDB('withdraw_cash', res_obj.params[0]).then(() => {
showMessage(`Your cash withdrawal request is placed successfully.`);
});
}
}
});
break;
case "cancel_trade":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let cancel_res_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(cancel_res_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let cancel_request = res_obj.params[0];
if (cancel_request.job == "cancel_trade_request") {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("userPublicData", cancel_request.trader_flo_address).then((trader_data) => {
if (typeof trader_data.trader_flo_address !== "string" || typeof trader_data
.trader_flo_pubKey !== "string") {
err_msg="ERROR: Failed to cancel the trade. User is unknown.";
showMessage(err_msg);
throw new Error(err_msg);
}
tradeDB = cancel_request.trade_type == "buy" ? "buyOrders" :
"sellOrders";
if (RM_WALLET
.verify(cancel_request.trade_id, cancel_request.signed_trade_id,
trader_data.trader_flo_pubKey)) {
backup_server_db_instance.backup_removeinDB(tradeDB, cancel_request.trade_id)
.then((id) => showMessage(`Trade Id ${id} deleted.`));
} else {
showMessage(
`Failed to verify trade for trade id ${cancel_request.trade_id}`
);
}
})
} else {
showMessage("Failed to cancel trade.");
}
}
});
break;
case "trade_balance_updates":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const trade_balance_res = res_obj.params[0];
// Verify data
let trade_info_str = JSON.stringify(trade_balance_res.trade_infos);
let buyer_cash_data_str = JSON.stringify(trade_balance_res.buyer_cash_data);
let seller_cash_data_str = JSON.stringify(trade_balance_res.seller_cash_data);
let buyer_btc_data_str = JSON.stringify(trade_balance_res.buyer_btc_data);
let seller_btc_data_str = JSON.stringify(trade_balance_res.seller_btc_data);
let res_str =
`${trade_info_str}${buyer_cash_data_str}${seller_cash_data_str}${buyer_btc_data_str}${seller_btc_data_str}`;
let hashed_data = Crypto.SHA256(res_str);
RM_RPC.filter_legit_backup_requests(trade_balance_res.trade_infos.buyer_flo_id,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
trade_balance_res.supernodePubKey)) {
if (RM_WALLET.verify(hashed_data,
trade_balance_res.supernode_sign, trade_balance_res.supernodePubKey)) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
// Delete orders in clients DB
try {
backup_server_db_instance.backup_removeinDB("buyOrders", trade_balance_res.trade_infos.buy_order_id);
backup_server_db_instance.backup_removeinDB("sellOrders", trade_balance_res.trade_infos.sell_order_id);
} catch (error) {
callback(false);
throw new Error(error);
}
// Update balances in clients DB
try {
backup_server_db_instance.backup_updateinDB("cash_balances", trade_balance_res.buyer_cash_data,
trade_balance_res.trade_infos.buyer_flo_id);
backup_server_db_instance.backup_updateinDB("cash_balances", trade_balance_res.seller_cash_data,
trade_balance_res.trade_infos.seller_flo_id);
backup_server_db_instance.backup_updateinDB("crypto_balances", trade_balance_res.buyer_btc_data,
trade_balance_res.trade_infos.buyer_flo_id);
backup_server_db_instance.backup_updateinDB("crypto_balances", trade_balance_res.seller_btc_data,
trade_balance_res.trade_infos.seller_flo_id);
} catch (error) {
callback(false);
throw new Error(error);
}
}
}
});
}
break;
case "update_all_withdraw_cash_depositor_claim":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let withdraw_caim_res_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(withdraw_caim_res_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let depositor_claim_response_object = res_obj.params[0];
let update_withdraw_cash_obj_data_res = {
depositor_claim: depositor_claim_response_object.depositor_claim
};
let update_withdraw_cash_obj_data_res_str = JSON.stringify(
update_withdraw_cash_obj_data_res);
let depositor_claim_response_data_hash = Crypto.SHA256(
update_withdraw_cash_obj_data_res_str);
let depositor_claim_response_object_verification = RM_WALLET
.verify(depositor_claim_response_data_hash, depositor_claim_response_object.sign,
depositor_claim_response_object.publicKey);
if ((depositor_claim_response_data_hash == depositor_claim_response_object.hash) &&
(depositor_claim_response_object_verification == true)) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_updateinDB('withdraw_cash', depositor_claim_response_object.depositor_claim,
depositor_claim_response_object.depositor_claim.id);
return true;
}
return false;
}
});
break;
case "update_all_deposit_withdraw_success":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let update_deposit_withdraw_claim_data = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(update_deposit_withdraw_claim_data.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let withdraw_success_response = res_obj.params[0];
let update_cash_balance_obj_res = {
depositor_cash_data: withdraw_success_response.depositor_cash_data
}
let update_cash_balance_obj_res_str = JSON.stringify(update_cash_balance_obj_res);
let update_cash_balance_obj_res_hash = Crypto.SHA256(
update_cash_balance_obj_res_str);
let update_cash_balance_obj_res_verification = RM_WALLET
.verify(update_cash_balance_obj_res_hash, withdraw_success_response.sign,
withdraw_success_response.publicKey);
if ((update_cash_balance_obj_res_hash == withdraw_success_response.hash) &&
update_cash_balance_obj_res_verification == true) {
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_updateinDB('cash_balances', withdraw_success_response.depositor_cash_data);
backup_server_db_instance.backup_updateinDB('cash_balances', withdraw_success_response.withdrawer_cash_data);
backup_server_db_instance.backup_removeByIndex('deposit', 'trader_flo_address', withdraw_success_response.depositor_cash_data
.trader_flo_address);
backup_server_db_instance.backup_removeinDB('withdraw_cash', withdraw_success_response.withdraw_id);
return true;
}
return false;
}
});
break;
case "requestSupernodesToRemoveAUserFloIdFromTheirKBucket":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let removeUserFromKBData = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(removeUserFromKBData.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const removeKBReq = res_obj.params[0];
const currentSupernodeFloIdOfUser = removeKBReq.currentSupernodeFloId;
if(localbitcoinplusplus.wallets.my_local_flo_address == currentSupernodeFloIdOfUser) return;
const userKbucketObject_id_array = Object.values(removeKBReq.redundantKbucketNodeU8Id);
const userKBId = new Uint8Array(userKbucketObject_id_array);
KBucket.remove(userKBId);
return true;
}
});
break;
case "requestSupernodesKBucketData":
if (typeof res_obj.params !== "object"
|| typeof res_obj.params[0] !== "object") return;
let reqSuKBData = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(reqSuKBData.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
if(typeof res_obj.globalParams.senderFloId !=="string") return;
let sender = res_obj.globalParams.senderFloId;
readAllDB('kBucketStore')
.then(myKBData=>{
myKBData.receiver_flo_address = sender;
localbitcoinplusplus.rpc.prototype
.send_rpc
.call(this, "SupernodesKBucketDataResponse", myKBData)
.then(sendBackMySupernodeKBucket=>
doSend(sendBackMySupernodeKBucket));
})
}
);
break;
case "SupernodesKBucketDataResponse":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const reqSuKBResponseData = res_obj.params[0];
RM_RPC.filter_legit_backup_requests(reqSuKBResponseData.trader_flo_address,
function (is_valid_request) {
if(!is_valid_request) return false;
reqSuKBResponseData.map(kd=> {
let kb = window[`SKBucket_${kd.primary_supernode_flo_public_key}`];
localbitcoinplusplus.kademlia.addFullKBDataInKBucketAndDB(kd, kb)})
});
}
break;
case "link_My_Local_IP_To_My_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
}).finally(()=>{
linkBackOthersLocalIPToTheirFloId();
});
}
break;
case "link_Others_Local_IP_To_Their_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
});
}
break;
case "add_user_public_data":
let supernode_flo_public_key = localbitcoinplusplus.wallets.my_local_flo_public_key;
RM_RPC.filter_legit_backup_requests(res_obj.params[0].trader_flo_address,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let req_data = res_obj.params[0];
try {
let flo_address = bitjs.FLO_TEST.pubkey2address(req_data.trader_flo_pubKey);
if (flo_address == req_data.trader_flo_address && req_data.trader_flo_address
.length > 0) {
let public_req_object = {
trader_flo_address: req_data.trader_flo_address,
trader_flo_pubKey: req_data.trader_flo_pubKey,
supernode_flo_public_key: supernode_flo_public_key,
trader_status: 0,
timestamp: +new Date()
}
addDB('userPublicData', public_req_object);
}
} catch (error) {
throw new Error('Invalid public key and flo address combination.');
}
}
});
break;
case "send_back_shamirs_secret_btc_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(typeof res_obj.globalParams.senderFloId !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.globalParams.senderFloId)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("supernode_private_key_chunks", res_obj.params[0].chunk_val).then(function (
res) {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_btc_pvtkey", {
retrieve_pvtkey_req_id: res_obj.params[0].retrieve_pvtkey_req_id,
private_key_chunk: res,
withdraw_id: res_obj.params[0].withdraw_id,
receiver_flo_address: res_obj.globalParams.senderFloId,
}).then(send_pvtkey_req=>doSend(send_pvtkey_req, res_obj.globalParams.senderFloId));
});
});
}
break;
case "store_shamirs_secret_pvtkey_shares":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
delete res_obj.params[0].trader_flo_address;
backup_server_db_instance.backup_addDB("supernode_private_key_chunks", res_obj.params[0]);
});
}
break;
case "updateUserCryptoBalanceRequest":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let updateUserCryptoBalanceResponseObject = res_obj.params[0];
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
let SuPubKey = backup_server_db_instance.backup_readDB('userPublicData', updateUserCryptoBalanceResponseObject.trader_flo_address)
.then(user_data => {
if (typeof user_data !== "object" || user_data.supernode_flo_public_key.length <
1)
throw new Error(`No such user exists.`);
let updateUserCryptoBalanceResponseString = JSON.stringify(
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject);
let isBalanceLegit = RM_WALLET.verify(updateUserCryptoBalanceResponseString,
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObjectSign,
user_data.supernode_flo_public_key
);
if (isBalanceLegit) {
backup_server_db_instance.backup_updateinDB("crypto_balances", updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject,
user_data.trader_flo_address);
if (localbitcoinplusplus.wallets.my_local_flo_address ==
updateUserCryptoBalanceResponseObject.trader_flo_address) {
displayBalances(updateUserCryptoBalanceResponseObject.trader_flo_address);
showMessage(`INFO: Your balance is updated.`);
}
return true;
} else {
showMessage(`WARNING: Failed to update balance in your DB. Please refresh.`);
}
});
});
}
break;
default:
break;
}
}
} catch(e) {
console.warn(e);
}
}
},
connectWS() {
this.ws_connection = new WebSocket(this.ws_url);
const switchMyWS = new backupSupernodesWebSocketObject();
this.ws_connection.onopen = function (evt) {
reactor.addEventListener('backup_supernode_up', async function() {
showMessage(`Connected to backup Supernode sever: ${evt.srcElement.url}.`);
switchMyWS.updateSupernodeAvailabilityStatus(evt.srcElement.url, true);
let my_local_data = await readDB('localbitcoinUser', '00-01');
if (typeof my_local_data == "object"
&& localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(my_local_data.myLocalFLOAddress)) {
const conn_su_flo_id = await switchMyWS.getFloIdFromWSUrl(evt.srcElement.url);
if (typeof conn_su_flo_id == "string") {
my_local_data.lastConnectedTime = + new Date();
my_local_data.lastConnectedSupernode = conn_su_flo_id;
updateinDB('localbitcoinUser', my_local_data);
} else {
mss = `WARNING: Failed to update current supernode connected status in localbitcoinUser.`;
showMessage(mss);
throw new Error(mss);
}
}
});
reactor.dispatchEvent('backup_supernode_up');
}.bind(this);
this.ws_connection.onclose = function (evt) {
reactor.addEventListener('backup_supernode_down', function() {
showMessage(`Disconnected to backup Supernode sever: ${evt.srcElement.url}.`);
switchMyWS.updateSupernodeAvailabilityStatus(evt.srcElement.url, false);
});
reactor.dispatchEvent('backup_supernode_down');
}.bind(this);
this.ws_connection.onmessage = function (evt) {
this.handle_backup_server_messages(evt);
}.bind(this);
this.ws_connection.onerror = function (evt) {
console.error(evt);
};
},
async getFloIdFromWSUrl(ws_url) {
ws_url = ws_url.replace(/\/$/, '');
const my_closest_su_list = await readAllDB('myClosestSupernodes');
const disconnected_su = my_closest_su_list
.filter((my_closest_su_url_list, index)=>{
let my_closest_su_url = `ws://${my_closest_su_url_list.ip}:${my_closest_su_url_list.port}`;
return my_closest_su_url==ws_url;
});
if (typeof disconnected_su[0].trader_flo_address=="string") {
return Promise.resolve(disconnected_su[0].trader_flo_address)
} else {
return Promise.reject(false)
}
},
async updateSupernodeAvailabilityStatus(ws_url, status) {
const disconnected_su_flo_id = await this.getFloIdFromWSUrl(ws_url);
const get_disconnected_su_details_list = await readDBbyIndex('myClosestSupernodes', 'trader_flo_address', disconnected_su_flo_id);
const get_disconnected_su_details = get_disconnected_su_details_list[0];
if(typeof get_disconnected_su_details !== "object") {
showMessage(`WARNING: Failed to update status of "${ws_url}" to ${status}.`);
return;
}
get_disconnected_su_details.is_live = status;
get_disconnected_su_details.timestamp = + new Date();
updateinDB('myClosestSupernodes', get_disconnected_su_details).then((myClosestSupernodesStatusRes)=>{
let su_status = status === true ? 'connected' : 'disconnected';
showMessage(`INFO: Supernode ${ws_url} is now ${su_status}.`);
});
},
async switchToBackupWS(disconnected_url='') {
const user_data = await readDB('localbitcoinUser', '00-01');
const user_flo_address = user_data.myLocalFLOAddress;
disconnected_url = disconnected_url.replace(/\/$/, '');
let last_connect_supernode_flo_id = user_data.last_connect_supernode_flo_id;
// Only User nodes can switch websocket connections
if(typeof user_flo_address !== "string"
|| localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(user_flo_address)) return false;
let ideal_supernode = '';
const myClosestSupernodesArray = await readAllDB(`myClosestSupernodes`);
let nextClosestSupernodeElem = myClosestSupernodesArray
.filter((wew, index)=>{
let ww = `ws://${wew.ip}:${wew.port}`;
if(typeof z =='boolean' && z) {
z = false;
localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS = wew.trader_flo_address;
return ww;
}
if(ww==disconnected_url) z = true;
});
ideal_supernode = `ws://${nextClosestSupernodeElem[0].ip}:${nextClosestSupernodeElem[0].port}`;
await startWebSocket(ideal_supernode);
if(websocket.readyState===1) {
// Meanwhile, request backup supernodes to sync data for down supernode in their resp. db.
if (!localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
// Connection established, build private key and UI
await privateKeyBuilder();
localbitcoinplusplus.actions.delay(10000).then(()=>{
if ((typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY!=='string'
|| localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY.length<1)
) {
const RM_WALLET = new localbitcoinplusplus.wallets;
RM_WALLET.manually_assign_my_private_key();
loadExternalFiles();
dataBaseUIOperations();
} else if(typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string' &&
localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
}
});
}
return Promise.resolve(true)
} else {
let ms = `Error: Failed to connect to any supernode.`;
showMessage(ms)
return Promise.reject(ms);
}
},
}
function startWebSocket(wsUri) {
return new Promise((resolve, reject) => {
websocket = new WebSocket(wsUri);
websocket.onopen = function (evt) {
resolve(onOpen(evt))
};
websocket.onclose = function (evt) {
reject(onClose(evt))
};
websocket.onmessage = function (evt) {
resolve(onMessage(evt))
};
websocket.onerror = function (evt) {
reject(onError(evt))
};
})
}
function onOpen(evt) {
localbitcoinplusplus.amIreadyToServePrimaryUsers = false;
reactor.dispatchEvent('new_supernode_connected', evt);
}
function onClose(evt) {
reactor.dispatchEvent('primary_supernode_down', evt);
}
async function onMessage(evt) {
var response = evt.data;
writeToScreen('<span style="color: blue;">RESPONSE: ' + response + '</span>');
// If the message is about leaving of a node determine its FLO Id
// and fire respective events
let isItANodeLeavingMessage = response.search(`\\-- left`);
if(isItANodeLeavingMessage >= 0) {
reactor.dispatchEvent('fireNodeGoodByeEvent', response);
}
var res_pos = response.indexOf('{');
if (res_pos >= 0) {
// Link Temporary IP Address to FLO ID
let isRequestToLinkIp = response.search("linkMyLocalIPToMyFloId");
let isRequestToLinkOthersIp = response.search("link_Others_Local_IP_To_Their_Flo_Id");
let incoming_msg_local_ip = ``;
if (isRequestToLinkIp>=0 || isRequestToLinkOthersIp>=0) {
let index_of_ip = response.indexOf(' ');
if (index_of_ip>=0) {
incoming_msg_local_ip = response.substr(0, index_of_ip);
}
}
var res = response.substr(res_pos);
try {
var res_obj = JSON.parse(res);
if (typeof res_obj.method !== "string"
|| typeof res_obj.globalParams !== "object"
|| typeof res_obj.globalParams.receiverFloId !== "string"
|| res_obj.globalParams.receiverFloId !==
localbitcoinplusplus.wallets.my_local_flo_address) {
console.warn(`WARNING: Incomplete onMessage request received.`);
//return;
}
const isIncomingMessageValid = await validateIncomingMessage(res);
console.log("isIncomingMessageValid: ", isIncomingMessageValid);
if (!isIncomingMessageValid) return;
if(typeof res_obj.globalParams.senderFloId !=="string")
throw new Error(`WARNING: The request did not contain sender FLO Id. Request Aborted.`);
// Check if request is from primary user or backup user
// If request is from backup user, divert the request to backup onmessage event
let get_requester_supernode = '';
if(typeof res_obj.params[0].trader_flo_address == "string") {
get_requester_supernode = await localbitcoinplusplus.kademlia
.determineClosestSupernode(res_obj.params[0].trader_flo_address);
res_obj.globalParams.primarySupernode = get_requester_supernode[0].data.id;
}
if ((typeof get_requester_supernode[0] !== "object"
|| typeof get_requester_supernode[0].data.id !=="string") &&
typeof res_obj.globalParams.primarySupernode !=="string") {
console.log("******NEED TO ADD PRIMARY SU IN BELOW METHOD******: ");
console.log(res_obj);
}
if(get_requester_supernode.length>0 && get_requester_supernode[0].data.id !==
localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS) {
processBackupUserOnMesssageRequest(response);
return;
} else if(typeof res_obj.globalParams.primarySupernode=="string"
&& res_obj.globalParams.primarySupernode !== localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS) {
if (typeof res_obj.globalParams.receiverFloId !== 'string' ||
res_obj.globalParams.receiverFloId !== localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS) {
processBackupUserOnMesssageRequest(response);
return;
}
}
if (typeof res_obj.method !== "undefined") {
let response_from_sever;
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
switch (res_obj.method) {
case "supernode_message":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let received_resp = res_obj.params[0];
try {
if (received_resp.trader_flo_address.length > 0 && received_resp.server_msg.length >
0) {
readDB("localbitcoinUser", "00-01").then(function (res) {
if (typeof res == "object" && res.myLocalFLOAddress.length > 0) {
if (res.myLocalFLOAddress === received_resp.trader_flo_address) {
showMessage(received_resp.server_msg);
return false;
}
}
});
}
} catch (error) {
throw new Error(error);
}
}
break;
case "trade_buy":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "trade_buy_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let buyOrders_data = res_obj.params[0];
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
buyOrders_data.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(buyOrders_data.data_hash, buyOrders_data.supernode_sign,
buyOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
// Add buy order
addDB("buyOrders", buyOrders_data).then(() => {
showMessage(`Your buy order is placed successfully.`);
});
}
}
}
break;
case "trade_sell":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "trade_sell_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let sellOrders_data = res_obj.params[0];
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
sellOrders_data
.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(sellOrders_data.data_hash, sellOrders_data.supernode_sign,
sellOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
// Add buy order
addDB("sellOrders", sellOrders_data).then(() => {
showMessage(`Your sell order is placed successfully.`);
});;
}
}
}
break;
case "sync_with_supernode":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "server_sync_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let su_db_data = res_obj.params[0];
if (typeof localbitcoinplusplus.wallets.my_local_flo_address !== "string" ||
su_db_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address
) return false;
(async function () {
for (let tableStoreName in su_db_data) {
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address' || !su_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"].includes(
tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await updateinDB(tableStoreName, obj[prop], obj[
prop].trader_flo_address);
}
}
} else {
let resdbdata = await removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await addDB(resdbdata, obj[prop]);
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
// Pass data to build_deposit_withdraw_table function
try {
console.log(su_db_data.withdraw_cash);
localbitcoinplusplus.actions.build_deposit_withdraw_table(su_db_data.withdraw_cash);
} catch (error) {
console.error(error);
}
}
break;
case "deposit_asset_request":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
case "deposit_asset_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" && typeof res_obj
.params[0].data == "object") {
let resp = res_obj.params[0];
if (RM_WALLET
.verify(resp.data.depositDataHash, resp.data.order_validator_sign, resp.data.order_validator_public_key)
) {
addDB('deposit', resp.data);
if (typeof resp.withdrawer_data == "object") {
updateinDB("withdraw_cash", resp.withdrawer_data, resp.withdrawer_data.trader_flo_address);
}
readDB("localbitcoinUser", "00-01").then(function (user) {
if (typeof user == "object" && user.myLocalFLOAddress == resp.data.trader_flo_address) {
let counterTraderAccountAddress =
`<p><strong>Please pay the amount to following address:</strong></p>
<p>${resp.msg}</p>`;
showMessage(counterTraderAccountAddress);
modalWindow(counterTraderAccountAddress);
}
});
}
}
break;
case "withdraw_request_method":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "withdrawal_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if (RM_WALLET
.verify(res_obj.params[0].withdrawDataHash, res_obj.params[0].order_validator_sign,
res_obj.params[0].order_validator_public_key)) {
addDB('withdraw_cash', res_obj.params[0]).then(() => {
showMessage(`Your cash withdrawal request is placed successfully.`);
});
}
}
break;
case "cancel_trade":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let cancel_request = res_obj.params[0];
if (cancel_request.job == "cancel_trade_request") {
readDB("userPublicData", cancel_request.trader_flo_address).then((trader_data) => {
if (typeof trader_data.trader_flo_address !== "string" || typeof trader_data
.trader_flo_pubKey !== "string") {
err_msg="ERROR: Failed to cancel the trade. User is unknown.";
showMessage(err_msg);
throw new Error(err_msg);
}
tradeDB = cancel_request.trade_type == "buy" ? "buyOrders" :
"sellOrders";
if (RM_WALLET
.verify(cancel_request.trade_id, cancel_request.signed_trade_id,
trader_data.trader_flo_pubKey)) {
removeinDB(tradeDB, cancel_request.trade_id)
.then((id) => showMessage(`Trade Id ${id} deleted.`));
} else {
showMessage(
`Failed to verify trade for trade id ${cancel_request.trade_id}`
);
}
})
} else {
showMessage("Failed to cancel trade.");
}
}
break;
case "trade_balance_updates":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const trade_balance_res = res_obj.params[0];
// Verify data
let trade_info_str = JSON.stringify(trade_balance_res.trade_infos);
let buyer_cash_data_str = JSON.stringify(trade_balance_res.buyer_cash_data);
let seller_cash_data_str = JSON.stringify(trade_balance_res.seller_cash_data);
let buyer_btc_data_str = JSON.stringify(trade_balance_res.buyer_btc_data);
let seller_btc_data_str = JSON.stringify(trade_balance_res.seller_btc_data);
let res_str =
`${trade_info_str}${buyer_cash_data_str}${seller_cash_data_str}${buyer_btc_data_str}${seller_btc_data_str}`;
let hashed_data = Crypto.SHA256(res_str);
RM_RPC.filter_legit_requests(trade_balance_res.trade_infos.buyer_flo_id,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
trade_balance_res.supernodePubKey)) {
if (RM_WALLET.verify(hashed_data,
trade_balance_res.supernode_sign, trade_balance_res.supernodePubKey)) {
// Delete orders in clients DB
try {
removeinDB("buyOrders", trade_balance_res.trade_infos.buy_order_id);
removeinDB("sellOrders", trade_balance_res.trade_infos.sell_order_id);
} catch (error) {
callback(false);
throw new Error(error);
}
// Update balances in clients DB
try {
updateinDB("cash_balances", trade_balance_res.buyer_cash_data,
trade_balance_res.trade_infos.buyer_flo_id);
updateinDB("cash_balances", trade_balance_res.seller_cash_data,
trade_balance_res.trade_infos.seller_flo_id);
updateinDB("crypto_balances", trade_balance_res.buyer_btc_data,
trade_balance_res.trade_infos.buyer_flo_id);
updateinDB("crypto_balances", trade_balance_res.seller_btc_data,
trade_balance_res.trade_infos.seller_flo_id);
} catch (error) {
callback(false);
throw new Error(error);
}
}
}
});
}
break;
case "store_shamirs_secret_pvtkey_shares":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
addDB("supernode_private_key_chunks", res_obj.params[0]);
}
break;
case "send_back_shamirs_secret_supernode_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
readDB("supernode_private_key_chunks", res_obj.params[0].chunk_val)
.then(function (res) {
if (typeof res=="object") {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_supernode_pvtkey", {
private_key_chunk: res
}).then(send_pvtkey_req=>doSend(send_pvtkey_req));
} else {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_supernode_pvtkey", "")
.then(send_pvtkey_req=>doSend(send_pvtkey_req));
}
});
}
break;
case "retrieve_shamirs_secret_supernode_pvtkey":
if(typeof retrieve_pvtkey_counter=="undefined") retrieve_pvtkey_counter = 0;
let runUIFunc = false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" &&
typeof res_obj.params[0].private_key_chunk == "object" &&
typeof localbitcoinplusplus.wallets.supernode_transaction_key == "object") {
let share = res_obj.params[0].private_key_chunk.privateKeyChunks;
if (typeof share !== "undefined" && !MY_PRIVATE_KEY_SHAMIRS_SHARES.includes(share)) {
MY_PRIVATE_KEY_SHAMIRS_SHARES.push(share);
}
if (MY_PRIVATE_KEY_SHAMIRS_SHARES.length == 5) {
RM_WALLET.rebuild_my_private_key(localbitcoinplusplus.wallets.supernode_transaction_key);
runUIFunc = true;
}
} else {
if (retrieve_pvtkey_counter==10
&& typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY == "undefined"
) {
RM_WALLET.manually_assign_my_private_key();
runUIFunc = true;
retrieve_pvtkey_counter++;
}
}
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string' &&
localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
return;
}
retrieve_pvtkey_counter++;
break;
case "send_back_shamirs_secret_btc_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
readDB("supernode_private_key_chunks", res_obj.params[0].chunk_val).then(function (
res) {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_btc_pvtkey", {
retrieve_pvtkey_req_id: res_obj.params[0].retrieve_pvtkey_req_id,
private_key_chunk: res,
withdraw_id: res_obj.params[0].withdraw_id,
receiver_flo_address: res_obj.globalParams.senderFloId
}).then(send_pvtkey_req=>doSend(send_pvtkey_req, res_obj.globalParams.senderFloId));
});
}
break;
case "retrieve_shamirs_secret_btc_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" &&
typeof res_obj.params[0].private_key_chunk == "object" &&
typeof res_obj.params[0].retrieve_pvtkey_req_id == "string" &&
typeof res_obj.params[0].withdraw_id == "string") {
let shamirs_shares_response = res_obj.params[0];
let retrieve_pvtkey_req_id = res_obj.params[0].retrieve_pvtkey_req_id;
let withdraw_id = res_obj.params[0].withdraw_id;
if (typeof btc_pvt_arr !== "object") btc_pvt_arr = [];
if (typeof btc_pvt_arr[retrieve_pvtkey_req_id] == "undefined") btc_pvt_arr[
retrieve_pvtkey_req_id] = [];
btc_pvt_arr[retrieve_pvtkey_req_id].push(shamirs_shares_response);
if (btc_pvt_arr[retrieve_pvtkey_req_id].length === localbitcoinplusplus.master_configurations
.ShamirsMaxShares) {
delete res_obj.params[0].private_key_chunk;
res_obj.params[0].btc_private_key_array = JSON.stringify(btc_pvt_arr[
retrieve_pvtkey_req_id]);
res_obj.params[0].trader_flo_address = localbitcoinplusplus.wallets.my_local_flo_address;
RM_RPC.receive_rpc_response.call(this, JSON.stringify(res_obj));
btc_pvt_arr[retrieve_pvtkey_req_id] = []; // Unset the object
}
}
break;
case "deposit_withdraw_user_claim":
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY ==
"undefined") throw new Error("Supernode Private Keys is undefined.");
if (typeof res_obj.params == "object" && typeof res_obj.params[0] ==
"object") {
let user_claim_request = res_obj.params[0];
let user_claim_id = user_claim_request.claim_id.split('!!');
let withdraw_order_id = user_claim_id[0];
let user_id = user_claim_id[1];
RM_RPC.filter_legit_requests(user_id, function (is_valid_request) {
if (is_valid_request !== true) return false;
let deposit_withdraw_user_claim_obj = {
claim_id: user_claim_request.claim_id
}
let deposit_withdraw_user_claim_str = JSON.stringify(
deposit_withdraw_user_claim_obj);
let deposit_withdraw_user_claim_hash = Crypto.SHA256(
deposit_withdraw_user_claim_str);
if (deposit_withdraw_user_claim_hash == user_claim_request.hash &&
RM_WALLET.verify(deposit_withdraw_user_claim_hash,
user_claim_request.sign, user_claim_request.userPubKey)) {
//If the request is valid, find out if the requester is depositor or withdrawer
readDB("withdraw_cash", withdraw_order_id).then(async function (
withdraw_data) {
if (typeof withdraw_data == "object") {
if (withdraw_data.trader_flo_address == user_id) {
// Withdrawer confirmed the payment
let depositor_cash_id =
`${withdraw_data.depositor_flo_id}_${withdraw_data.currency}`;
let withdrawer_cash_id =
`${withdraw_data.trader_flo_address}_${withdraw_data.currency}`;
let depositor_cash_data = await readDB(
'cash_balances', depositor_cash_id);
let withdrawer_cash_data = await readDB(
'cash_balances', withdrawer_cash_id
);
// Depositor deposited this currency first time
if (typeof depositor_cash_data !== "object" ||
typeof depositor_cash_data ==
"undefined") {
depositor_cash_data = {
id: depositor_cash_id,
cash_balance: 0,
trader_flo_address: withdraw_data
.depositor_flo_id,
currency: withdraw_data.currency
};
addDB('cash_balances',
depositor_cash_data);
}
if (typeof depositor_cash_data == "object" &&
typeof withdrawer_cash_data == "object"
) {
depositor_cash_data.cash_balance +=
parseFloat(withdraw_data.withdraw_amount);
withdrawer_cash_data.cash_balance -=
parseFloat(withdraw_data.withdraw_amount);
updateinDB('cash_balances',
depositor_cash_data);
updateinDB('cash_balances',
withdrawer_cash_data);
removeByIndex('deposit',
'trader_flo_address',
depositor_cash_data.trader_flo_address
);
removeinDB('withdraw_cash',
withdraw_data.id);
let update_cash_balance_obj = {
depositor_cash_data: depositor_cash_data,
withdrawer_cash_data: withdrawer_cash_data
}
let update_cash_balance_str = JSON.stringify(
update_cash_balance_obj);
let update_cash_balance_hash = Crypto.SHA256(
update_cash_balance_str);
let update_cash_balance_sign =
RM_WALLET
.sign(update_cash_balance_hash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
update_cash_balance_obj.publicKey =
localbitcoinplusplus.wallets.my_local_flo_public_key;
update_cash_balance_obj.sign =
update_cash_balance_sign;
update_cash_balance_obj.hash =
update_cash_balance_hash;
update_cash_balance_obj.withdraw_id =
withdraw_data.id;
update_cash_balance_obj.receiver_flo_address = user_id;
update_cash_balance_obj.trader_flo_address = user_id;
RM_RPC
.send_rpc
.call(this,
"update_all_deposit_withdraw_success",
update_cash_balance_obj)
.then(update_cash_balance_req=>
doSend(update_cash_balance_req));
}
}
else if (withdraw_data.depositor_flo_id == user_id) {
// Depositor claimed to deposit the cash
withdraw_data.status = 3;
updateinDB('withdraw_cash', withdraw_data,
withdraw_data.id);
let update_withdraw_cash_obj_data = {
depositor_claim: withdraw_data
};
let update_withdraw_cash_obj_data_str =
JSON.stringify(
update_withdraw_cash_obj_data);
let update_withdraw_cash_obj_data_hash =
Crypto.SHA256(
update_withdraw_cash_obj_data_str);
let update_withdraw_cash_obj_data_sign =
RM_WALLET
.sign(
update_withdraw_cash_obj_data_hash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
update_withdraw_cash_obj_data.hash =
update_withdraw_cash_obj_data_hash;
update_withdraw_cash_obj_data.sign =
update_withdraw_cash_obj_data_sign;
update_withdraw_cash_obj_data.publicKey =
localbitcoinplusplus.wallets.my_local_flo_public_key;
update_withdraw_cash_obj_data.receiver_flo_address = user_id;
update_withdraw_cash_obj_data.trader_flo_address = user_id;
RM_RPC
.send_rpc
.call(this,
"update_all_withdraw_cash_depositor_claim",
update_withdraw_cash_obj_data)
.then(update_withdraw_cash_obj=>
doSend(update_withdraw_cash_obj));
}
return true;
}
});
}
});
}
break;
case "update_all_withdraw_cash_depositor_claim":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let depositor_claim_response_object = res_obj.params[0];
let update_withdraw_cash_obj_data_res = {
depositor_claim: depositor_claim_response_object.depositor_claim
};
let update_withdraw_cash_obj_data_res_str = JSON.stringify(
update_withdraw_cash_obj_data_res);
let depositor_claim_response_data_hash = Crypto.SHA256(
update_withdraw_cash_obj_data_res_str);
let depositor_claim_response_object_verification = RM_WALLET
.verify(depositor_claim_response_data_hash, depositor_claim_response_object.sign,
depositor_claim_response_object.publicKey);
if ((depositor_claim_response_data_hash == depositor_claim_response_object.hash) &&
(depositor_claim_response_object_verification == true)) {
updateinDB('withdraw_cash', depositor_claim_response_object.depositor_claim,
depositor_claim_response_object.depositor_claim.id);
return true;
}
return false;
}
break;
case "update_all_deposit_withdraw_success":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let withdraw_success_response = res_obj.params[0];
let update_cash_balance_obj_res = {
depositor_cash_data: withdraw_success_response.depositor_cash_data
}
let update_cash_balance_obj_res_str = JSON.stringify(update_cash_balance_obj_res);
let update_cash_balance_obj_res_hash = Crypto.SHA256(
update_cash_balance_obj_res_str);
let update_cash_balance_obj_res_verification = RM_WALLET
.verify(update_cash_balance_obj_res_hash, withdraw_success_response.sign,
withdraw_success_response.publicKey);
if ((update_cash_balance_obj_res_hash == withdraw_success_response.hash) &&
update_cash_balance_obj_res_verification == true) {
updateinDB('cash_balances', withdraw_success_response.depositor_cash_data);
updateinDB('cash_balances', withdraw_success_response.withdrawer_cash_data);
removeByIndex('deposit', 'trader_flo_address', withdraw_success_response.depositor_cash_data
.trader_flo_address);
removeinDB('withdraw_cash', withdraw_success_response.withdraw_id);
return true;
}
return false;
}
break;
case "add_user_public_data":
let supernode_flo_public_key = localbitcoinplusplus.wallets.my_local_flo_public_key;
RM_RPC.filter_legit_requests(res_obj.params[0].trader_flo_address,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let req_data = res_obj.params[0];
try {
let flo_address = bitjs.FLO_TEST.pubkey2address(req_data.trader_flo_pubKey);
if (flo_address == req_data.trader_flo_address && req_data.trader_flo_address
.length > 0) {
let public_req_object = {
trader_flo_address: req_data.trader_flo_address,
trader_flo_pubKey: req_data.trader_flo_pubKey,
supernode_flo_public_key: supernode_flo_public_key,
trader_status: 0,
timestamp: +new Date()
}
addDB('userPublicData', public_req_object);
}
} catch (error) {
throw new Error('Invalid public key and flo address combination.');
}
}
});
break;
case "superNodeSignedAddUserPublicData":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
doSend(JSON.stringify(response_from_sever)); // send response to client
break;
case "refresh_deposit_status_request":
RM_RPC.filter_legit_requests(res_obj.params[0].trader_flo_address, is_valid_request => {
if (is_valid_request !== true) return false;
readDBbyIndex("deposit", 'status', 1).then(function (res) {
res.map(function (deposit_trade) {
if (localbitcoinplusplus.master_configurations.tradableAsset1
.includes(deposit_trade.product)) {
validateDepositedBTCBalance(deposit_trade);
}
});
});
});
break;
case "update_external_file_request":
RM_RPC.filter_legit_requests(res_obj.params[0].trader_flo_address, is_valid_request => {
if (is_valid_request !== true) return false;
let update_script_request = res_obj.params[0];
if (typeof update_script_request.trader_flo_address !== "string") throw new Error(
"Unknown user");
let server_pubkey = localbitcoinplusplus.wallets.my_local_flo_public_key;
if (typeof update_script_request.file_to_update == "string") {
readDB("external_files", update_script_request.file_to_update).then(
file_details => {
if (typeof file_details !== "undefined"
&& typeof file_details.content == "string" && file_details
.content.length > 0) {
let file_details_string = JSON.stringify(file_details);
let server_sign = RM_WALLET
.sign(file_details_string, localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY);
RM_RPC.send_rpc
.call(this, "update_external_file_server_response", {
trader_flo_address: update_script_request.trader_flo_address,
file_updated: file_details,
server_sign: server_sign,
server_pubkey: server_pubkey,
filename: update_script_request.file_to_update,
trader_flo_address: update_script_request.trader_flo_address,
receiver_flo_address: update_script_request.trader_flo_address
}).then(response_from_sever=>doSend(response_from_sever));
}
});
} else {
readAllDB("external_files").then(file_details => {
if (file_details.length > 0) {
let file_details_str = JSON.stringify(file_details);
let server_sign = RM_WALLET
.sign(file_details_str, localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY);
RM_RPC.send_rpc
.call(this, "update_external_file_server_response", {
trader_flo_address: update_script_request.trader_flo_address,
file_updated: file_details,
server_sign: server_sign,
server_pubkey: server_pubkey,
filename: "UPDATE_ALL_FILES",
receiver_flo_address: update_script_request.trader_flo_address,
trader_flo_address: update_script_request.trader_flo_address,
}).then(response_from_sever=>doSend(response_from_sever));
}
});
}
});
break;
case "update_external_file_server_response":
response_from_sever = RM_RPC.receive_rpc_response.call(this,
JSON.stringify(res_obj));
doSend(JSON.stringify(response_from_sever)); // send response to client
break;
case "updateUserCryptoBalanceRequest":
let updateUserCryptoBalanceResponseObject = res_obj.params[0];
let SuPubKey = readDB('userPublicData', updateUserCryptoBalanceResponseObject.trader_flo_address)
.then(user_data => {
if (typeof user_data !== "object" || user_data.supernode_flo_public_key.length <
1)
throw new Error(`No such user exists.`);
let updateUserCryptoBalanceResponseString = JSON.stringify(
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject);
let isBalanceLegit = RM_WALLET.verify(updateUserCryptoBalanceResponseString,
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObjectSign,
user_data.supernode_flo_public_key
);
if (isBalanceLegit) {
updateinDB("crypto_balances", updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject,
user_data.trader_flo_address);
if (localbitcoinplusplus.wallets.my_local_flo_address ==
updateUserCryptoBalanceResponseObject.trader_flo_address) {
displayBalances(updateUserCryptoBalanceResponseObject.trader_flo_address);
showMessage(`INFO: Your balance is updated.`);
}
return true;
} else {
showMessage(`WARNING: Failed to update balance in your DB. Please refresh.`);
}
});
break;
case "addNewKbucketNode":
if (!localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) return;
try {
let mss = '';
let tid = res_obj.params[0].trader_flo_address || res_obj.globalParams.senderFloId;
localbitcoinplusplus.kademlia.determineClosestSupernode(tid)
.then(async my_closest_su=>{
const newKbucketObjectObj = res_obj.params[0];
if (typeof newKbucketObjectObj.newKbucketNode == "object") {
newKbucketObject = newKbucketObjectObj.newKbucketNode;
newKbucketObject_id_array = Object.values(newKbucketObject.id);
newKbucketObject_idu8 = new Uint8Array(newKbucketObject_id_array);
localbitcoinplusplus.kademlia.addNewUserNodeInKbucketAndDB("FLO_TEST",
newKbucketObject_idu8, newKbucketObject.data);
localbitcoinplusplus.rpc.prototype
.send_rpc
.call(this, "requestSupernodesToRemoveAUserFloIdFromTheirKBucket", {
redundantKbucketNodeU8Id: newKbucketObject_idu8,
currentSupernodeFloId: localbitcoinplusplus.wallets.my_local_flo_address,
trader_flo_address: res_obj.globalParams.senderFloId,
}).then(removeRedundantKNode=>doSend(removeRedundantKNode));
} else {
mss = `WARNING: Failed to add ${res_obj.globalParams.senderFloId} to KBucket.`;
showMessage(mss)
console.warn(mss);
}
});
} catch (error) {
console.error(error);
}
break;
case "queryKbucket":
try {
const kBucketQuery = res_obj.params[0];
const kfrom = kBucketQuery.query.from;
const kto = kBucketQuery.query.to;
const kmsg = kBucketQuery.query.msg;
buckId = localbitcoinplusplus.kademlia.floIdToKbucketId("FLO_TEST", kto);
const getItem = KBucket.get(buckId);
const getData = getItem.data;
} catch (error) {
console.error(error);
}
break;
case "link_My_Local_IP_To_My_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
}).finally(()=>{
linkBackOthersLocalIPToTheirFloId();
});
}
break;
case "link_Others_Local_IP_To_Their_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
});
}
break;
case "supernode_to_supernode_backup_request":
// RM_RPC.filter_legit_requests(function (is_valid_request) {
// if (is_valid_request === true) {
let data = res_obj.params[0];
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "userPublicData"
];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray)
.then(function (su_db_data) {
su_db_data.trader_flo_address = data.trader_flo_address;
let msg_sha256 = Crypto.SHA256(JSON.stringify(su_db_data));
localbitcoinplusplus.encrypt
.messageBroadcasting(msg_sha256, data.trader_flo_address,
"supernode_to_supernode_backup_response");
// if (typeof su_db_data == "object") {
// su_db_data.trader_flo_address = data.trader_flo_address;
// let server_sync_response = RM_RPC
// .send_rpc
// .call(this, "supernode_to_supernode_backup_response",
// su_db_data);
// doSend(server_sync_response);
// }
})
// }
// })
break;
case "supernode_to_supernode_backup_response":
console.log(res_obj.params[0]);
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let su_db_data = res_obj.params[0];
let db_data = localbitcoinplusplus.encrypt.decryptMessage(su_db_data.secret, su_db_data.senderPublicKeyString);
console.log(db_data);
return;
if (typeof localbitcoinplusplus.wallets.my_local_flo_address !== "string" ||
su_db_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address
) return false;
// const BACKUP_DB = new newBackupDB();
// BACKUP_DB.createNewDB();
(async function () {
for (let tableStoreName in su_db_data) {
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address' || !su_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"].includes(
tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await BACKUP_DB.backup_updateinDB(tableStoreName, obj[prop], obj[
prop].trader_flo_address);
}
}
} else {
let resdbdata = await BACKUP_DB.backup_removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await BACKUP_DB.backup_addDB(resdbdata, obj[prop]);
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
}
break;
case "messageBroadcasting":
console.log(res_obj);
try {
let response = res_obj.params[0];
let msg = localbitcoinplusplus.encrypt.decryptMessage(response.data.secret, response.data.senderPublicKeyString);
console.log(msg);
} catch (error) {
console.error(error);
}
break;
case "MessageForMiddleman":
RM_RPC.filter_legit_requests(dataToBeSentToReceiver.sender_flo_address,
function (is_valid_request) {
console.log(is_valid_request);
}
);
break;
case "backup_server_sync_response":
console.log(res_obj);
break;
case "sync_data_by_vector_clock":
if (localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
try {
(async function() {
let getPrimarySuObj = await localbitcoinplusplus.kademlia
.determineClosestSupernode(res_obj.params[0].trader_flo_address);
let primarySupernode = getPrimarySuObj[0].data.id;
if (localbitcoinplusplus.wallets.my_local_flo_address!==primarySupernode) return;
let req_dt = res_obj.params[0];
let dbTable = req_dt.dbTable;
let data = req_dt.data;
let subjectUser = data.trader_flo_address;
let mss = '';
if (typeof data.id !== "string" && typeof data.id !== "number") {
mss = `WARNING: Failed to sync data by vector clock as id field could not be found.`;
showMessage(mss);
throw new Error(mss);
}
let myOwnDBData = await readDB(dbTable, data.id);
if (typeof myOwnDBData.vectorClock !== "number") {
mss = `WARNING: Failed to sync data by vector clock as id field could not be found.`;
showMessage(mss);
throw new Error(mss);
}
if(data.vectorClock > myOwnDBData.vectorClock) {
// You have old data, update respective DB.
data.increaseVectorClock = false;
updateinDB(dbTable, data).then(()=>{
showMessage(`INFO: Data updated in ${dbTable} for id ${data.id}.`);
});
}
})()
} catch (error) {
throw new Error(error);
}
}
}
break;
case "sync_primary_supernode_from_backup_supernode":
if (localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
}
break;
case "sync_primary_supernode_from_backup_supernode_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let su_db_data = res_obj.params[0];
if (typeof localbitcoinplusplus.wallets.my_local_flo_address !== "string" ||
su_db_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address
) return false;
(async function () {
let i = 0;
for (let tableStoreName in su_db_data) {
i++;
if (i==su_db_data.length-2) {
// Get data for crypto and fiat balances based on vector clock from all backup supernodes
reactor.dispatchEvent('primarySupernodeUpdatingLatestDataForItsUserFromOtherSupernodes',
{ requesting_user_id: idbData.myLocalFLOAddress});
await localbitcoinplusplus.actions.delay(180000).then(()=>{
showMessage(`INFO: Balance syncing is complete.`);
localbitcoinplusplus.amIreadyToServePrimaryUsers = true;
const RM_RPC = new localbitcoinplusplus.rpc;
// Method 1: Inform user nodes they can now trade
RM_RPC
.send_rpc
.call(this, "supernode_message", {
"trader_flo_address": respective_trader_id,
"receiver_flo_address": "", // message for all
"server_msg": `Your primary Supernode is live and synced. You can start using the system.`,
}).thn(server_response=>doSend(server_response));
// Method 2: Now inform all backup supernodes you are back and request to stop serving your users
// RM_RPC
// .send_rpc
// .call(this, "update_supernode_status", {
// trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address,
// trader_pub_key: localbitcoinplusplus.wallets.my_local_flo_public_key,
// su_status: true,
// }).then(server_response=>
// doSend(server_response, nextSu.data.id));
});
}
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address'
|| tableStoreName == 'receiver_flo_address'
|| !su_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"].includes(
tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await updateinDB(tableStoreName, obj[prop], obj[
prop].trader_flo_address).then(()=>{
showMessage(`INFO: "${tableStoreName}" datastore syncing is complete.`);
});
}
}
} else {
let resdbdata = await removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await addDB(resdbdata, obj[prop]).then(()=>{
showMessage(`INFO: "${resdbdata}" datastore syncing is complete.`);
});
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
}
break;
default:
break;
}
}
} catch (error) {
console.error(error);
return;
}
}
}
async function processBackupUserOnMesssageRequest(response) {
writeToScreen('<span style="color: blue;">RESPONSE: ' + response + '</span>');
// If the message is about leaving of a node determine its FLO Id
// and fire respective events
let isItANodeLeavingMessage = response.search(`\\-- left`);
if(isItANodeLeavingMessage >= 0) {
reactor.dispatchEvent('fireNodeGoodByeEvent', response);
}
var res_pos = response.indexOf('{');
if (res_pos >= 0) {
// Link Temporary IP Address to FLO ID
let isRequestToLinkIp = response.search("linkMyLocalIPToMyFloId");
let isRequestToLinkOthersIp = response.search("link_Others_Local_IP_To_Their_Flo_Id");
let incoming_msg_local_ip = ``;
if (isRequestToLinkIp>=0 || isRequestToLinkOthersIp>=0) {
let index_of_ip = response.indexOf(' ');
if (index_of_ip>=0) {
incoming_msg_local_ip = response.substr(0, index_of_ip);
}
}
var res = response.substr(res_pos);
try {
var res_obj = JSON.parse(res);
if (typeof res_obj.globalParams.receiverFloId=="string"
&& res_obj.globalParams.receiverFloId !==
localbitcoinplusplus.wallets.my_local_flo_address) {
return;
}
const isIncomingMessageValid = await validateIncomingMessage(res);
console.log("isIncomingMessageValid: ", isIncomingMessageValid);
if (!isIncomingMessageValid) return;
// Check if request is from primary user or backup user
// If request is from backup user, divert the request to backup onmessage event
let get_requester_supernode = '';
if(typeof res_obj.params[0].trader_flo_address == "string") {
get_requester_supernode = await localbitcoinplusplus.kademlia
.determineClosestSupernode(res_obj.params[0].trader_flo_address);
res_obj.globalParams.primarySupernode = get_requester_supernode[0].data.id;
} else if(typeof res_obj.globalParams.primarySupernode !== "string") {
console.log("---- ('processBackupUserOnMesssageRequest'): NEED TO ADD PRIMARY SU IN BELOW METHOD: ");
console.log(res_obj);
return;
}
if (localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
let ifAllPrevSuAreDead = await localbitcoinplusplus.actions
.checkIfAllPreviousSupernodesAreDeadForAUserNode(res_obj.params[0].trader_flo_address);
console.log("ifAllPrevSuAreDead: ", ifAllPrevSuAreDead);
if (ifAllPrevSuAreDead !== true) {
console.log(res_obj);
showMessage(`INFO: "checkIfAllPreviousSupernodesAreDeadForAUserNode" check failed.`)
return;
}
}
if (typeof res_obj.method !== "undefined") {
let response_from_sever;
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
switch (res_obj.method) {
case "supernode_message":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let received_resp = res_obj.params[0];
if(typeof res_obj.params[0].trader_flo_address =="string") return;
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
try {
if (received_resp.trader_flo_address.length > 0 && received_resp.server_msg.length >
0) {
readDB("localbitcoinUser", "00-01").then(function (res) {
if (typeof res == "object" && res.myLocalFLOAddress.length > 0) {
if (res.myLocalFLOAddress === received_resp.trader_flo_address) {
showMessage(received_resp.server_msg);
return false;
}
}
});
}
} catch (error) {
throw new Error(error);
}
}
break;
case "trade_buy":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "trade_buy_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let buyOrders_data = res_obj.params[0];
// Only the relevent user node should get response
if(buyOrders_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
buyOrders_data.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(buyOrders_data.data_hash, buyOrders_data.supernode_sign,
buyOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
// Add buy order
addDB("buyOrders", buyOrders_data).then(() => {
showMessage(`Your buy order is placed successfully.`);
});
}
}
}
break;
case "trade_sell":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "trade_sell_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let sellOrders_data = res_obj.params[0];
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
if (typeof localbitcoinplusplus.master_configurations.supernodesPubKeys == "object" &&
localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
sellOrders_data
.supernodePubKey)) {
let isDataSignedBySuperNode = RM_WALLET
.verify(sellOrders_data.data_hash, sellOrders_data.supernode_sign,
sellOrders_data.supernodePubKey);
if (isDataSignedBySuperNode === true) {
// Add buy order
addDB("sellOrders", sellOrders_data).then(() => {
showMessage(`Your sell order is placed successfully.`);
});;
}
}
}
break;
case "sync_with_supernode":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
break;
case "server_sync_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let su_db_data = res_obj.params[0];
if (typeof localbitcoinplusplus.wallets.my_local_flo_address !== "string" ||
su_db_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address
) return false;
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
(async function () {
for (let tableStoreName in su_db_data) {
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address' || !su_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"].includes(
tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await updateinDB(tableStoreName, obj[prop], obj[
prop].trader_flo_address);
}
}
} else {
let resdbdata = await removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await addDB(resdbdata, obj[prop]);
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
// Pass data to build_deposit_withdraw_table function
try {
console.log(su_db_data.withdraw_cash);
localbitcoinplusplus.actions.build_deposit_withdraw_table(su_db_data.withdraw_cash);
} catch (error) {
console.error(error);
}
}
break;
case "deposit_asset_request":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
case "deposit_asset_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" && typeof res_obj
.params[0].data == "object") {
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
let resp = res_obj.params[0];
if (RM_WALLET
.verify(resp.data.depositDataHash, resp.data.order_validator_sign, resp.data.order_validator_public_key)
) {
addDB('deposit', resp.data);
if (typeof resp.withdrawer_data == "object") {
updateinDB("withdraw_cash", resp.withdrawer_data, resp.withdrawer_data.trader_flo_address);
}
readDB("localbitcoinUser", "00-01").then(function (user) {
if (typeof user == "object" && user.myLocalFLOAddress == resp.data.trader_flo_address) {
let counterTraderAccountAddress =
`<p><strong>Please pay the amount to following address:</strong></p>
<p>${resp.msg}</p>`;
showMessage(counterTraderAccountAddress);
modalWindow(counterTraderAccountAddress);
}
});
}
}
break;
case "withdraw_request_method":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
//doSend(JSON.stringify(response_from_sever)); // send response to client
break;
case "withdrawal_request_response":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
if (RM_WALLET
.verify(res_obj.params[0].withdrawDataHash, res_obj.params[0].order_validator_sign,
res_obj.params[0].order_validator_public_key)) {
addDB('withdraw_cash', res_obj.params[0]).then(() => {
showMessage(`Your cash withdrawal request is placed successfully.`);
});
}
}
break;
case "cancel_trade":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let cancel_request = res_obj.params[0];
if (cancel_request.job == "cancel_trade_request") {
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("userPublicData", cancel_request.trader_flo_address).then((trader_data) => {
if (typeof trader_data.trader_flo_address !== "string" || typeof trader_data
.trader_flo_pubKey !== "string") {
err_msg="ERROR: Failed to cancel the trade. User is unknown.";
showMessage(err_msg);
throw new Error(err_msg);
}
tradeDB = cancel_request.trade_type == "buy" ? "buyOrders" :
"sellOrders";
if (RM_WALLET
.verify(cancel_request.trade_id, cancel_request.signed_trade_id,
trader_data.trader_flo_pubKey)) {
backup_server_db_instance.backup_removeinDB(tradeDB, cancel_request.trade_id)
.then((id) => showMessage(`Trade Id ${id} deleted.`));
} else {
showMessage(
`Failed to verify trade for trade id ${cancel_request.trade_id}`
);
}
})
})
} else {
showMessage("Failed to cancel trade.");
}
}
break;
case "trade_balance_updates":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const trade_balance_res = res_obj.params[0];
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
// Verify data
let trade_info_str = JSON.stringify(trade_balance_res.trade_infos);
let buyer_cash_data_str = JSON.stringify(trade_balance_res.buyer_cash_data);
let seller_cash_data_str = JSON.stringify(trade_balance_res.seller_cash_data);
let buyer_btc_data_str = JSON.stringify(trade_balance_res.buyer_btc_data);
let seller_btc_data_str = JSON.stringify(trade_balance_res.seller_btc_data);
let res_str =
`${trade_info_str}${buyer_cash_data_str}${seller_cash_data_str}${buyer_btc_data_str}${seller_btc_data_str}`;
let hashed_data = Crypto.SHA256(res_str);
RM_RPC.filter_legit_requests(trade_balance_res.trade_infos.buyer_flo_id,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
trade_balance_res.supernodePubKey)) {
if (RM_WALLET.verify(hashed_data,
trade_balance_res.supernode_sign, trade_balance_res.supernodePubKey)) {
// Delete orders in clients DB
try {
removeinDB("buyOrders", trade_balance_res.trade_infos.buy_order_id);
removeinDB("sellOrders", trade_balance_res.trade_infos.sell_order_id);
} catch (error) {
callback(false);
throw new Error(error);
}
// Update balances in clients DB
try {
updateinDB("cash_balances", trade_balance_res.buyer_cash_data,
trade_balance_res.trade_infos.buyer_flo_id);
updateinDB("cash_balances", trade_balance_res.seller_cash_data,
trade_balance_res.trade_infos.seller_flo_id);
updateinDB("crypto_balances", trade_balance_res.buyer_btc_data,
trade_balance_res.trade_infos.buyer_flo_id);
updateinDB("crypto_balances", trade_balance_res.seller_btc_data,
trade_balance_res.trade_infos.seller_flo_id);
} catch (error) {
callback(false);
throw new Error(error);
}
}
}
});
}
break;
case "store_shamirs_secret_pvtkey_shares":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
delete res_obj.params[0].trader_flo_address;
backup_server_db_instance.backup_addDB("supernode_private_key_chunks", res_obj.params[0]);
});
}
break;
case "send_back_shamirs_secret_supernode_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(typeof res_obj.globalParams.primarySupernode !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.globalParams.primarySupernode)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("supernode_private_key_chunks", res_obj.params[0].chunk_val)
.then(function (res) {
if (typeof res=="object") {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_supernode_pvtkey", {
private_key_chunk: res
}).then(send_pvtkey_req=>doSend(send_pvtkey_req));
} else {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_supernode_pvtkey", "")
.then(send_pvtkey_req=>doSend(send_pvtkey_req));
}
});
});
}
break;
case "retrieve_shamirs_secret_supernode_pvtkey":
if(typeof retrieve_pvtkey_counter=="undefined") retrieve_pvtkey_counter = 0;
let runUIFunc = false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" &&
typeof res_obj.params[0].private_key_chunk == "object" &&
typeof localbitcoinplusplus.wallets.supernode_transaction_key == "object") {
let share = res_obj.params[0].private_key_chunk.privateKeyChunks;
if (typeof share !== "undefined" && !MY_PRIVATE_KEY_SHAMIRS_SHARES.includes(share)) {
MY_PRIVATE_KEY_SHAMIRS_SHARES.push(share);
}
if (MY_PRIVATE_KEY_SHAMIRS_SHARES.length == 5) {
RM_WALLET.rebuild_my_private_key(localbitcoinplusplus.wallets.supernode_transaction_key);
runUIFunc = true;
}
} else {
if (retrieve_pvtkey_counter==10
&& typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY == "undefined"
) {
RM_WALLET.manually_assign_my_private_key();
runUIFunc = true;
retrieve_pvtkey_counter++;
}
}
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string' &&
localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
return;
}
retrieve_pvtkey_counter++;
break;
case "send_back_shamirs_secret_btc_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
if(typeof res_obj.globalParams.primarySupernode !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.globalParams.primarySupernode)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("supernode_private_key_chunks", res_obj.params[0].chunk_val).then(function (
res) {
RM_RPC
.send_rpc
.call(this, "retrieve_shamirs_secret_btc_pvtkey", {
retrieve_pvtkey_req_id: res_obj.params[0].retrieve_pvtkey_req_id,
private_key_chunk: res,
withdraw_id: res_obj.params[0].withdraw_id,
receiver_flo_address: res_obj.globalParams.senderFloId,
}).then(send_pvtkey_req=>doSend(send_pvtkey_req, res_obj.globalParams.senderFloId));
});
});
}
break;
case "retrieve_shamirs_secret_btc_pvtkey":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object" &&
typeof res_obj.params[0].private_key_chunk == "object" &&
typeof res_obj.params[0].retrieve_pvtkey_req_id == "string" &&
typeof res_obj.params[0].withdraw_id == "string") {
let shamirs_shares_response = res_obj.params[0];
let retrieve_pvtkey_req_id = res_obj.params[0].retrieve_pvtkey_req_id;
let withdraw_id = res_obj.params[0].withdraw_id;
if (typeof btc_pvt_arr !== "object") btc_pvt_arr = [];
if (typeof btc_pvt_arr[retrieve_pvtkey_req_id] == "undefined") btc_pvt_arr[
retrieve_pvtkey_req_id] = [];
btc_pvt_arr[retrieve_pvtkey_req_id].push(shamirs_shares_response);
if (btc_pvt_arr[retrieve_pvtkey_req_id].length === localbitcoinplusplus.master_configurations
.ShamirsMaxShares) {
delete res_obj.params[0].private_key_chunk;
res_obj.params[0].btc_private_key_array = JSON.stringify(btc_pvt_arr[
retrieve_pvtkey_req_id]);
res_obj.params[0].trader_flo_address = localbitcoinplusplus.wallets.my_local_flo_address;
RM_RPC.backup_receive_rpc_response.call(this, JSON.stringify(res_obj));
btc_pvt_arr[retrieve_pvtkey_req_id] = []; // Unset the object
}
}
break;
case "deposit_withdraw_user_claim":
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY ==
"undefined") throw new Error("Supernode Private Keys is undefind.");
if (typeof res_obj.params == "object" && typeof res_obj.params[0] ==
"object") {
let user_claim_request = res_obj.params[0];
let user_claim_id = user_claim_request.claim_id.split('!!');
let withdraw_order_id = user_claim_id[0];
let user_id = user_claim_id[1];
RM_RPC.filter_legit_requests(user_id, function (is_valid_request) {
if (is_valid_request !== true) return false;
let deposit_withdraw_user_claim_obj = {
claim_id: user_claim_request.claim_id
}
let deposit_withdraw_user_claim_str = JSON.stringify(
deposit_withdraw_user_claim_obj);
let deposit_withdraw_user_claim_hash = Crypto.SHA256(
deposit_withdraw_user_claim_str);
if (deposit_withdraw_user_claim_hash == user_claim_request.hash &&
RM_WALLET.verify(deposit_withdraw_user_claim_hash,
user_claim_request.sign, user_claim_request.userPubKey)) {
//If the request is valid, find out if the requester is depositor or withdrawer
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDB("withdraw_cash", withdraw_order_id).then(async function (
withdraw_data) {
if (typeof withdraw_data == "object") {
if (withdraw_data.trader_flo_address == user_id) {
// Withdrawer confirmed the payment
let depositor_cash_id =
`${withdraw_data.depositor_flo_id}_${withdraw_data.currency}`;
let withdrawer_cash_id =
`${withdraw_data.trader_flo_address}_${withdraw_data.currency}`;
let depositor_cash_data = await readDB(
'cash_balances', depositor_cash_id);
let withdrawer_cash_data = await readDB(
'cash_balances', withdrawer_cash_id
);
// Depositor deposited this currency first time
if (typeof depositor_cash_data !== "object" ||
typeof depositor_cash_data ==
"undefined") {
depositor_cash_data = {
id: depositor_cash_id,
cash_balance: 0,
trader_flo_address: withdraw_data
.depositor_flo_id,
currency: withdraw_data.currency
};
backup_server_db_instance.backup_addDB('cash_balances',
depositor_cash_data);
}
if (typeof depositor_cash_data == "object" &&
typeof withdrawer_cash_data == "object"
) {
depositor_cash_data.cash_balance +=
parseFloat(withdraw_data.withdraw_amount);
withdrawer_cash_data.cash_balance -=
parseFloat(withdraw_data.withdraw_amount);
backup_server_db_instance.backup_updateinDB('cash_balances',
depositor_cash_data);
backup_server_db_instance.backup_updateinDB('cash_balances',
withdrawer_cash_data);
backup_server_db_instance.backup_removeByIndex('deposit',
'trader_flo_address',
depositor_cash_data.trader_flo_address
);
backup_server_db_instance.backup_removeinDB('withdraw_cash',
withdraw_data.id);
let update_cash_balance_obj = {
depositor_cash_data: depositor_cash_data,
withdrawer_cash_data: withdrawer_cash_data
}
let update_cash_balance_str = JSON.stringify(
update_cash_balance_obj);
let update_cash_balance_hash = Crypto.SHA256(
update_cash_balance_str);
let update_cash_balance_sign =
RM_WALLET
.sign(update_cash_balance_hash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
update_cash_balance_obj.publicKey =
localbitcoinplusplus.wallets.my_local_flo_public_key;
update_cash_balance_obj.sign =
update_cash_balance_sign;
update_cash_balance_obj.hash =
update_cash_balance_hash;
update_cash_balance_obj.withdraw_id =
withdraw_data.id;
update_cash_balance_obj.receiver_flo_address = user_id;
RM_RPC
.send_rpc
.call(this,
"update_all_deposit_withdraw_success",
update_cash_balance_obj)
.then(update_cash_balance_req=>
doSend(update_cash_balance_req));
}
}
else if (withdraw_data.depositor_flo_id == user_id) {
// Depositor claimed to deposit the cash
withdraw_data.status = 3;
backup_server_db_instance.backup_updateinDB('withdraw_cash', withdraw_data,
withdraw_data.id);
let update_withdraw_cash_obj_data = {
depositor_claim: withdraw_data
};
let update_withdraw_cash_obj_data_str =
JSON.stringify(
update_withdraw_cash_obj_data);
let update_withdraw_cash_obj_data_hash =
Crypto.SHA256(
update_withdraw_cash_obj_data_str);
let update_withdraw_cash_obj_data_sign =
RM_WALLET
.sign(
update_withdraw_cash_obj_data_hash,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
update_withdraw_cash_obj_data.hash =
update_withdraw_cash_obj_data_hash;
update_withdraw_cash_obj_data.sign =
update_withdraw_cash_obj_data_sign;
update_withdraw_cash_obj_data.publicKey =
localbitcoinplusplus.wallets.my_local_flo_public_key;
update_withdraw_cash_obj_data.receiver_flo_address = user_id;
RM_RPC
.send_rpc
.call(this,
"update_all_withdraw_cash_depositor_claim",
update_withdraw_cash_obj_data)
.then(update_withdraw_cash_obj=>
doSend(update_withdraw_cash_obj));
}
}
});
});
}
});
}
break;
case "update_all_withdraw_cash_depositor_claim":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
let depositor_claim_response_object = res_obj.params[0];
let update_withdraw_cash_obj_data_res = {
depositor_claim: depositor_claim_response_object.depositor_claim
};
let update_withdraw_cash_obj_data_res_str = JSON.stringify(
update_withdraw_cash_obj_data_res);
let depositor_claim_response_data_hash = Crypto.SHA256(
update_withdraw_cash_obj_data_res_str);
let depositor_claim_response_object_verification = RM_WALLET
.verify(depositor_claim_response_data_hash, depositor_claim_response_object.sign,
depositor_claim_response_object.publicKey);
if ((depositor_claim_response_data_hash == depositor_claim_response_object.hash) &&
(depositor_claim_response_object_verification == true)) {
updateinDB('withdraw_cash', depositor_claim_response_object.depositor_claim,
depositor_claim_response_object.depositor_claim.id);
return true;
}
return false;
}
break;
case "update_all_deposit_withdraw_success":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let withdraw_success_response = res_obj.params[0];
// Only the relevent user node should get response
if(res_obj.params[0].trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address) return;
let update_cash_balance_obj_res = {
depositor_cash_data: withdraw_success_response.depositor_cash_data
}
let update_cash_balance_obj_res_str = JSON.stringify(update_cash_balance_obj_res);
let update_cash_balance_obj_res_hash = Crypto.SHA256(
update_cash_balance_obj_res_str);
let update_cash_balance_obj_res_verification = RM_WALLET
.verify(update_cash_balance_obj_res_hash, withdraw_success_response.sign,
withdraw_success_response.publicKey);
if ((update_cash_balance_obj_res_hash == withdraw_success_response.hash) &&
update_cash_balance_obj_res_verification == true) {
updateinDB('cash_balances', withdraw_success_response.depositor_cash_data);
updateinDB('cash_balances', withdraw_success_response.withdrawer_cash_data);
removeByIndex('deposit', 'trader_flo_address', withdraw_success_response.depositor_cash_data
.trader_flo_address);
removeinDB('withdraw_cash', withdraw_success_response.withdraw_id);
return true;
}
return false;
}
break;
case "add_user_public_data":
let supernode_flo_public_key = localbitcoinplusplus.wallets.my_local_flo_public_key;
RM_RPC.filter_legit_requests(res_obj.params[0].trader_flo_address,
function (is_valid_request) {
if (is_valid_request !== true) return false;
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let req_data = res_obj.params[0];
try {
let flo_address = bitjs.FLO_TEST.pubkey2address(req_data.trader_flo_pubKey);
if (flo_address == req_data.trader_flo_address && req_data.trader_flo_address
.length > 0) {
let public_req_object = {
trader_flo_address: req_data.trader_flo_address,
trader_flo_pubKey: req_data.trader_flo_pubKey,
supernode_flo_public_key: supernode_flo_public_key,
trader_status: 0,
timestamp: +new Date()
}
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_addDB('userPublicData', public_req_object);
});
}
} catch (error) {
throw new Error('Invalid public key and flo address combination.');
}
}
});
break;
case "superNodeSignedAddUserPublicData":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
doSend(JSON.stringify(response_from_sever)); // send response to client
break;
case "refresh_deposit_status_request":
if(typeof res_obj.params[0].trader_flo_address !="string") return;
RM_RPC.filter_legit_backup_requests(res_obj.params[0].trader_flo_address,
function(is_valid_request) {
if (is_valid_request !== true) return false;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_readDBbyIndex("deposit", 'status', 1).then(function (res) {
res.map(async function (deposit_trade) {
if (localbitcoinplusplus.master_configurations.tradableAsset1
.includes(deposit_trade.product)) {
validateDepositedBTCBalance(deposit_trade, primarySupernodeOfThisUser);
}
});
});
});
});
break;
case "update_external_file_request":
RM_RPC.filter_legit_requests(res_obj.params[0].trader_flo_address, is_valid_request => {
if (is_valid_request !== true) return false;
let update_script_request = res_obj.params[0];
if (typeof update_script_request.trader_flo_address !== "string") throw new Error(
"Unknown user");
let server_pubkey = localbitcoinplusplus.wallets.my_local_flo_public_key;
if(typeof res_obj.params[0].trader_flo_address !="string") return;
localbitcoinplusplus.kademlia.determineClosestSupernode(res_obj.params[0].trader_flo_address)
.then(my_closest_su_list=>{
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[primarySupernodeOfThisUser];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
if (typeof update_script_request.file_to_update == "string") {
backup_server_db_instance.backup_readDB("external_files", update_script_request.file_to_update).then(
file_details => {
if (typeof file_details !== "undefined"
&& typeof file_details.content == "string" && file_details
.content.length > 0) {
let file_details_string = JSON.stringify(file_details);
let server_sign = RM_WALLET
.sign(file_details_string, localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY);
RM_RPC.send_rpc
.call(this, "update_external_file_server_response", {
trader_flo_address: update_script_request.trader_flo_address,
file_updated: file_details,
server_sign: server_sign,
server_pubkey: server_pubkey,
filename: update_script_request.file_to_update,
receiver_flo_address: update_script_request.trader_flo_address
}).then(response_from_sever=>doSend(response_from_sever));
}
});
} else {
backup_server_db_instance.backup_readAllDB("external_files").then(file_details => {
if (file_details.length > 0) {
let file_details_str = JSON.stringify(file_details);
let server_sign = RM_WALLET
.sign(file_details_str, localbitcoinplusplus.wallets
.MY_SUPERNODE_PRIVATE_KEY);
RM_RPC.send_rpc
.call(this, "update_external_file_server_response", {
trader_flo_address: update_script_request.trader_flo_address,
file_updated: file_details,
server_sign: server_sign,
server_pubkey: server_pubkey,
filename: "UPDATE_ALL_FILES",
receiver_flo_address: update_script_request.trader_flo_address,
}).then(response_from_sever=>doSend(response_from_sever));
}
});
}
});
});
break;
case "update_external_file_server_response":
response_from_sever = RM_RPC.backup_receive_rpc_response.call(this,
JSON.stringify(res_obj));
doSend(JSON.stringify(response_from_sever)); // send response to client
break;
case "updateUserCryptoBalanceRequest":
let updateUserCryptoBalanceResponseObject = res_obj.params[0];
let SuPubKey = readDB('userPublicData', updateUserCryptoBalanceResponseObject.trader_flo_address)
.then(user_data => {
if (typeof user_data !== "object" || user_data.supernode_flo_public_key.length <
1)
throw new Error(`No such user exists.`);
let updateUserCryptoBalanceResponseString = JSON.stringify(
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject);
let isBalanceLegit = RM_WALLET.verify(updateUserCryptoBalanceResponseString,
updateUserCryptoBalanceResponseObject.updatedBTCBalanceObjectSign,
user_data.supernode_flo_public_key
);
if (isBalanceLegit) {
updateinDB("crypto_balances", updateUserCryptoBalanceResponseObject.updatedBTCBalanceObject,
user_data.trader_flo_address);
if (localbitcoinplusplus.wallets.my_local_flo_address ==
updateUserCryptoBalanceResponseObject.trader_flo_address) {
displayBalances(updateUserCryptoBalanceResponseObject.trader_flo_address);
showMessage(`INFO: Your balance is updated.`);
}
return true;
} else {
showMessage(`WARNING: Failed to update balance in your DB. Please refresh.`);
}
});
break;
case "addNewKbucketNode":
if (!localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) return;
try {
let mss = '';
let tid = res_obj.params[0].trader_flo_address || res_obj.globalParams.senderFloId;
localbitcoinplusplus.kademlia.determineClosestSupernode(tid)
.then(async my_closest_su=>{
if (my_closest_su[0].data.id !== localbitcoinplusplus.wallets.my_local_flo_address) return;
const newKbucketObjectObj = res_obj.params[0];
const primarySupernodeOfThisUser = my_closest_su_list[0].data.id;
const getPubKeyOfSupernodeOfThisUser = RM_WALLET.getSupernodePublicKeyFromFloId(primarySupernodeOfThisUser);
const primaryKBOfTheUser = `SKBucket_${getPubKeyOfSupernodeOfThisUser}`;
if (typeof primaryKBOfTheUser !=="object") {
let mss = `ERROR: No such KBucket exists: ${primaryKBOfTheUser}`
showMessage(mss);
throw new Error(mss);
}
if (typeof newKbucketObjectObj.newKbucketNode == "object") {
newKbucketObject = newKbucketObjectObj.newKbucketNode;
newKbucketObject_id_array = Object.values(newKbucketObject.id);
newKbucketObject_idu8 = new Uint8Array(newKbucketObject_id_array);
localbitcoinplusplus.kademlia.addNewUserNodeInKbucket("FLO_TEST",
newKbucketObject_idu8, newKbucketObject.data, primaryKBOfTheUser);
localbitcoinplusplus.rpc.prototype
.send_rpc
.call(this, "requestSupernodesToRemoveAUserFloIdFromTheirKBucket", {
redundantKbucketNodeU8Id: newKbucketObject_idu8,
currentSupernodeFloId: localbitcoinplusplus.wallets.my_local_flo_address,
trader_flo_address: res_obj.globalParams.senderFloId
}).then(removeRedundantKNode=>doSend(removeRedundantKNode));
} else {
mss = `WARNING: Failed to add ${res_obj.globalParams.senderFloId} to KBucket.`;
showMessage(mss)
console.warn(mss);
}
});
} catch (error) {
console.error(error);
}
break;
case "queryKbucket":
try {
const kBucketQuery = res_obj.params[0];
const kfrom = kBucketQuery.query.from;
const kto = kBucketQuery.query.to;
const kmsg = kBucketQuery.query.msg;
buckId = localbitcoinplusplus.kademlia.floIdToKbucketId("FLO_TEST", kto);
const getItem = KBucket.get(buckId);
const getData = getItem.data;
} catch (error) {
console.error(error);
}
break;
case "link_My_Local_IP_To_My_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
const backup_server_db_instance = localbitcoinplusplus.newBackupDatabase.db[res_obj.globalParams.senderFloId];
if(typeof backup_server_db_instance !== "object") {
let backup_db_error_msg = `WARNING: Unknown DB instance. DB Backup failed.`;
showMessage(backup_db_error_msg);
throw new Error(backup_db_error_msg);
};
backup_server_db_instance.backup_updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
}).finally(()=>{
linkBackOthersLocalIPToTheirFloId();
});
}
break;
case "link_Others_Local_IP_To_Their_Flo_Id":
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const req_params = res_obj.params[0];
if(typeof req_params.requesters_pub_key !== "string") return;
let flo_addr_for_pubkey = bitjs.FLO_TEST.pubkey2address(req_params.requesters_pub_key);
if(typeof flo_addr_for_pubkey !== "string") return;
if(flo_addr_for_pubkey !== res_obj.globalParams.senderFloId) return;
updateinDB('ipTable', {
'flo_public_key': req_params.requesters_pub_key,
'temporary_ip': incoming_msg_local_ip
}).then((ipRes)=>{
reactor.dispatchEvent('fireNodeWelcomeBackEvent', ipRes);
});
}
break;
case "supernode_to_supernode_backup_request":
// RM_RPC.filter_legit_requests(function (is_valid_request) {
// if (is_valid_request === true) {
let data = res_obj.params[0];
const tableArray = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "userPublicData"
];
localbitcoinplusplus.actions.get_sharable_db_data(tableArray)
.then(function (su_db_data) {
su_db_data.trader_flo_address = data.trader_flo_address;
let msg_sha256 = Crypto.SHA256(JSON.stringify(su_db_data));
localbitcoinplusplus.encrypt
.messageBroadcasting(msg_sha256, data.trader_flo_address,
"supernode_to_supernode_backup_response");
// if (typeof su_db_data == "object") {
// su_db_data.trader_flo_address = data.trader_flo_address;
// let server_sync_response = RM_RPC
// .send_rpc
// .call(this, "supernode_to_supernode_backup_response",
// su_db_data);
// doSend(server_sync_response);
// }
})
// }
// })
break;
case "supernode_to_supernode_backup_response":
console.log(res_obj.params[0]);
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
let su_db_data = res_obj.params[0];
let db_data = localbitcoinplusplus.encrypt.decryptMessage(su_db_data.secret, su_db_data.senderPublicKeyString);
console.log(db_data);
return;
if (typeof localbitcoinplusplus.wallets.my_local_flo_address !== "string" ||
su_db_data.trader_flo_address !== localbitcoinplusplus.wallets.my_local_flo_address
) return false;
// const BACKUP_DB = new newBackupDB();
// BACKUP_DB.createNewDB();
(async function () {
for (let tableStoreName in su_db_data) {
// skip loop if the property is from prototype
if (tableStoreName == 'trader_flo_address' || !su_db_data.hasOwnProperty(
tableStoreName)) continue;
try {
let obj = su_db_data[tableStoreName];
if (["crypto_balances", "cash_balances", "userPublicData"].includes(
tableStoreName)) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await BACKUP_DB.backup_updateinDB(tableStoreName, obj[prop], obj[
prop].trader_flo_address);
}
}
} else {
let resdbdata = await BACKUP_DB.backup_removeAllinDB(tableStoreName);
if (resdbdata !== false) {
if (obj.length > 0) {
for (var prop in obj) {
if (!obj.hasOwnProperty(prop)) continue;
await BACKUP_DB.backup_addDB(resdbdata, obj[prop]);
}
}
}
}
} catch (error) {
console.log(error);
}
}
})();
}
break;
case "messageBroadcasting":
console.log(res_obj);
try {
let response = res_obj.params[0];
let msg = localbitcoinplusplus.encrypt.decryptMessage(response.data.secret, response.data.senderPublicKeyString);
console.log(msg);
} catch (error) {
console.error(error);
}
break;
case "MessageForMiddleman":
RM_RPC.filter_legit_requests(dataToBeSentToReceiver.sender_flo_address,
function (is_valid_request) {
console.log(is_valid_request);
}
);
break;
case "backup_server_sync_response":
console.log(res_obj);
break;
case "sync_data_by_vector_clock":
if (localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
try {
(async function() {
let req_dt = res_obj.params[0];
let db_instance = localbitcoinplusplus.newBackupDatabase.db[req_dt.leaving_supernode_flo_id];
let dbTable = req_dt.dbTable;
let data = req_dt.data;
let subjectUser = data.trader_flo_address;
let mss = '';
if (typeof data.id !== "string" && typeof data.id !== "number") {
mss = `WARNING: Failed to sync data by vector clock as id field could not be found.`;
showMessage(mss);
throw new Error(mss);
}
if (typeof db_instance !=="object") {
mss = `WARNING: Failed to sync data by vector clock as invalid DB instance was encountered.`;
showMessage(mss);
throw new Error(mss);
}
let myOwnDBData = await db_instance.backup_readDB(dbTable, data.id);
if (typeof myOwnDBData.vectorClock !== "number") {
mss = `WARNING: Failed to sync data by vector clock as id field could not be found.`;
showMessage(mss);
throw new Error(mss);
}
if (data.vectorClock < myOwnDBData.vectorClock) {
// You have the latest data, send it to other supernodes
let getNextClosestSuObj = await localbitcoinplusplus.kademlia
.determineClosestSupernode("", 3, supernodeKBucket, req_dt.leaving_supernode_flo_id);
let nextBackupSupernode = getNextClosestSuObj[1].data.id;
if (typeof nextBackupSupernode !== "string") {
let msg = `WARNING: Failed to determine next closest backup supernode for ${req_dt.leaving_supernode_flo_id}.`;
showMessage(msg);
throw new Error(msg);
}
getNextClosestSuObj.map((nextSu, i)=>{
if(nextSu.data.id !==localbitcoinplusplus.wallets.my_local_flo_address) {
let nextSuConn = localbitcoinplusplus.backupWS[nextSu.data.id];
if(typeof nextSuConn !== "object") {
let msg = `WARNING: Failed to open a backup WS connection with Supernode ${nextSu}.`;
showMessage(msg);
throw new Error(msg);
}
RM_RPC
.send_rpc
.call(this, "sync_data_by_vector_clock", {
trader_flo_address: data.trader_flo_address,
receiver_flo_address: nextSu.data.id,
leaving_supernode_flo_id: req_dt.leaving_supernode_flo_id,
data: myOwnDBData,
dbTable: dbTable
}).then(server_response=>
doSend(server_response, nextSu.data.id));
}
})
} else if(data.vectorClock > myOwnDBData.vectorClock) {
// You have old data, update respective DB.
db_instance.backup_updateinDB(dbTable, data).then(()=>{
showMessage(`INFO: Data updated in ${dbTable} for id ${data.id}.`);
});
}
})()
} catch (error) {
throw new Error(error);
}
}
}
break;
case "nextBackupSupernodeToSyncDataBeforeActingAsBackupSupernodeNodeRequest":
if (localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
if (typeof res_obj.params == "object" && typeof res_obj.params[0] == "object") {
const userFLoID = res_obj.params[0].trader_flo_address;
if (typeof userFLoID !== "string" || userFLoID.length<1) {
console.warn(`Invalid FLO Id`);
return;
}
(async function() {
const s_id = await localbitcoinplusplus.kademlia.determineClosestSupernode(userFLoID);
const primarySuFloId = s_id[0].data.id;
let getSupernodeClosestSuObj = await localbitcoinplusplus.kademlia
.determineClosestSupernode("", 3, supernodeKBucket, primarySuFloId);
let promises = [];
let leaving_supernode_flo_id = "";
for (let index = 0; index < getSupernodeClosestSuObj.length; index++) {
const element = getSupernodeClosestSuObj[index];
if (element.data.id==localbitcoinplusplus.wallets.my_local_flo_address) break;
promises.push(readDBbyIndex('myClosestSupernodes', 'trader_flo_address', element.data.id));
leaving_supernode_flo_id = element.data.id;
}
Promise.all(promises).then(cs=>{
let isPreviousSupernodesLive = cs.map((su_status, index)=>
(typeof su_status[index] !== "object" || su_status[index].is_live == true )
);
if (!isPreviousSupernodesLive.includes(true)) {
/*********************************************************************
*DISABLE ANY FURTHER REQUEST BY USER HERE UNTIL FULL SYNC IS COMPLETE*
**********************************************************************/
getSupernodeClosestSuObj.map((nextSu, i)=>{
if((i>0) && (nextSu.data.id !==localbitcoinplusplus.wallets.my_local_flo_address)) {
let nextSuConn = localbitcoinplusplus.newBackupDatabase.db[nextSu.data.id];
if(typeof nextSuConn !== "object") {
let msg = `WARNING: Failed to open a backup DB with Supernode ${nextSu}.`;
showMessage(msg);
throw new Error(msg);
}
const table_array = ["deposit", "withdraw_cash", "withdraw_btc",
"crypto_balances", "cash_balances", "sellOrders", "buyOrders",
];
table_array.map(async tbl=>{
let record = await nextSuConn.backup_readDBbyIndex(tbl, 'trader_flo_address', userFLoID);
record.map(rec=>{
RM_RPC
.send_rpc
.call(this, "sync_data_by_vector_clock", {
trader_flo_address: userFLoID,
receiver_flo_address: nextSu.data.id,
leaving_supernode_flo_id: leaving_supernode_flo_id,
data: rec,
dbTable: tbl
}).then(server_response=>
doSend(server_response, nextSu.data.id));
});
});
}
});
}
});
})();
}
}
break;
default:
break;
}
}
} catch (error) {
console.error(error);
return;
}
}
}
function onError(evt) {
let msg = `ERROR: Websocket Connection to ${evt.srcElement.url} returned error.`;
showMessage(msg);
return msg;
}
function doSend(message, user_flo_id="") {
let wsConn = websocket;
if (user_flo_id!=="") {
try {
wsConn = localbitcoinplusplus.backupWS[user_flo_id].ws_connection;
} catch (error) {
showMessage(`ERROR: Failed to determine WS connection with ${user_flo_id}.`);
throw new Error(error);
}
}
if(wsConn.readyState !== 1) {
let msg = "WARNING: Websocket not ready to broadcast messages.";
showMessage(msg);
console.warn(msg);
return;
}
const request_array = ['send_back_shamirs_secret_supernode_pvtkey',
'retrieve_shamirs_secret_supernode_pvtkey',
'store_shamirs_secret_pvtkey_shares'];
let finalMessage = message;
const msgObj = JSON.parse(message);
if (!request_array.includes(msgObj.method)) {
const RM_WALLET = new localbitcoinplusplus.wallets;
message = JSON.stringify(msgObj);
const message256hash = Crypto.SHA256(message);
if(typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY !== "string")
throw new Error(`Private key could not be found.`);
const nodeSignedMessage = RM_WALLET.sign(message256hash, localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY);
msgObj.nodeMessage256hash = message256hash;
msgObj.nodeSignedMessage = nodeSignedMessage;
msgObj.nodePubKey = localbitcoinplusplus.wallets.my_local_flo_public_key;
finalMessage = JSON.stringify(msgObj);
}
writeToScreen("SENT: " + finalMessage);
wsConn.send(finalMessage);
}
function validateIncomingMessage(message) {
return new Promise((resolve, reject)=>{
if(message.length <1) {
showMessage(`WARNING: The incoming websocket message on was empty.`);
reject(false)};
const request_array = ['send_back_shamirs_secret_supernode_pvtkey',
'retrieve_shamirs_secret_supernode_pvtkey',
'store_shamirs_secret_pvtkey_shares'];
try {
const msgObj = JSON.parse(message);
if (request_array.includes(msgObj.method)) return resolve(true);
const getFloId = bitjs.FLO_TEST.pubkey2address(msgObj.nodePubKey);
// Check if the public key belongs to real sender
if (getFloId !== msgObj.globalParams.senderFloId) {
showMessage(`Sender FLO address did not match signer FLO address.`);
reject(false)
}
const initialMsgObj = {
jsonrpc:msgObj.jsonrpc,
id:msgObj.id,
method:msgObj.method,
params:msgObj.params,
globalParams:msgObj.globalParams,
}
const initialMsgObjStr = JSON.stringify(initialMsgObj);
console.log(initialMsgObjStr);
const initialMsgObjStrHash = Crypto.SHA256(initialMsgObjStr);
console.log(initialMsgObjStrHash);
const RM_WALLET = new localbitcoinplusplus.wallets;
if (RM_WALLET.verify(initialMsgObjStrHash, msgObj.nodeSignedMessage, msgObj.nodePubKey)) {
resolve(true);
} else {
showMessage(`WARNING: Incoming Websocket message verification failed.`)
reject(false);
}
} catch (error) {
reject(error);
}
})
}
function writeToScreen(message) {
// var pre = document.createElement("p");
// pre.style.wordWrap = "break-word";
// pre.innerHTML = message;
//output.appendChild(pre);
console.log(message);
}
/* Websocket Code Ends Here*/
</script>
<!-- Indexed DB -->
<script>
//prefixes of implementation that we want to test
window.indexedDB = window.indexedDB || window.mozIndexedDB ||
window.webkitIndexedDB || window.msIndexedDB;
//prefixes of window.IDB objects
window.IDBTransaction = window.IDBTransaction ||
window.webkitIDBTransaction || window.msIDBTransaction;
window.IDBKeyRange = window.IDBKeyRange || window.webkitIDBKeyRange ||
window.msIDBKeyRange
if (!window.indexedDB) {
window.alert("Your browser doesn't support a stable version of IndexedDB.")
}
let localbitcoinplusplusObj = {
id: "00-01",
myLocalFLOAddress: "",
myLocalFLOPublicKey: "",
myAddressTrustLevel: 1,
lastConnectedSupernode: "",
lastConnectedTime: "",
};
const userPublicData = {
trader_flo_address: null,
trader_flo_pubKey: null,
trader_status: null,
supernode_flo_public_key: null,
timestamp: null
};
const deposit = {
id: "",
trader_flo_address: null,
depositing_amount: 0,
depositor_key_signature: null,
depositor_public_key: null,
operation_type: null,
order_validator_public_key: null,
product: null,
status: 0
}
const withdraw_cash = {
id: "",
trader_flo_address: null,
withdraw_amount: null,
currency: null,
receivinAddress: null,
status: null,
depositor_found_at: null
}
const crypto_balances = {
id: null,
trader_flo_address: null,
crypto_balance: null,
crypto_currency: null
}
const cash_balances = {
id: null,
trader_flo_address: null,
cash_balance: null,
currency: null
}
const system_btc_reserves_private_keys = {
id: '',
btc_address: null,
product: null,
balance: null,
trader_flo_address: null,
btc_private_key_shamirs_id: null,
supernode_transaction_key: null
}
const my_supernode_private_key_chunks = {
id: '',
supernode_transaction_key: null
}
const supernode_private_key_chunks = {
id: '',
privateKeyChunks: null
}
const withdraw_btc = {
id: '',
trader_flo_address: null,
utxo_addr: null,
receiverBTCAddress: null,
receiverBTCEquivalentInCash: null,
currency: null,
product: null,
change_adress: null,
timestamp: null
}
const external_files = {
filename: null,
filehash: null,
content: null
}
const kBucketStore = {
id: null,
vectorClock: 0,
data: null,
primary_supernode_flo_public_key: null,
last_updated_on: null,
}
const messages_table = {
id: null,
trader_flo_address: null,
supernode_flo_address: null,
timestamp: null,
message: null
}
const ipTable = {
flo_public_key: null,
temporary_ip: null
}
const closestSupernodesTable = {
id: null,
ip: null,
is_live: null,
port: null,
timestamp: null,
trader_flo_address: null,
vectorClock: null
}
var db;
const DBName = "localbitcoinDB";
const request = window.indexedDB.open(DBName, 1);
request.onerror = function (event) {
//https://stackoverflow.com/questions/13972385/invalidstateerror-while-opening-indexeddb-in-firefox
event.preventDefault();
var error = event.target.error;
console.log("IndexedDB database open error:", error.name, error.message);
};
request.onsuccess = function (event) {
db = request.result;
loadLocalDBData();
};
request.onupgradeneeded = function (event) {
var db = event.target.result;
if (!db.objectStoreNames.contains('localbitcoinUser')) {
var objectStore = db.createObjectStore("localbitcoinUser", {
keyPath: "id"
});
objectStore.createIndex('myLocalFLOAddress', 'myLocalFLOAddress', {
unique: false
});
objectStore.put(localbitcoinplusplusObj);
}
if (!db.objectStoreNames.contains('buyOrders')) {
var objectStore = db.createObjectStore("buyOrders", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
}
if (!db.objectStoreNames.contains('sellOrders')) {
var objectStore = db.createObjectStore("sellOrders", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
}
if (!db.objectStoreNames.contains('deposit')) {
var objectStore = db.createObjectStore("deposit", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('btc_address', 'btc_address', {
unique: false
});
}
if (!db.objectStoreNames.contains('withdraw_cash')) {
var objectStore = db.createObjectStore("withdraw_cash", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
}
if (!db.objectStoreNames.contains('crypto_balances')) {
var objectStore = db.createObjectStore("crypto_balances", {
keyPath: 'id',
autoIncrement: false
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('crypto_currency', 'crypto_currency', {
unique: false
});
}
if (!db.objectStoreNames.contains('cash_balances')) {
var objectStore = db.createObjectStore("cash_balances", {
keyPath: 'id',
autoIncrement: false
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('currency', 'currency', {
unique: false
});
}
if (!db.objectStoreNames.contains('my_supernode_private_key_chunks')) {
var objectStore = db.createObjectStore("my_supernode_private_key_chunks", {
keyPath: 'id'
});
objectStore.createIndex('supernode_transaction_key', 'supernode_transaction_key', {
unique: false
});
}
if (!db.objectStoreNames.contains('supernode_private_key_chunks')) {
var objectStore = db.createObjectStore("supernode_private_key_chunks", {
keyPath: 'id'
});
}
if (!db.objectStoreNames.contains('system_btc_reserves_private_keys')) {
var objectStore = db.createObjectStore("system_btc_reserves_private_keys", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('btc_address', 'btc_address', {
unique: false
});
objectStore.createIndex('supernode_transaction_key', 'supernode_transaction_key', {
unique: false
});
}
if (!db.objectStoreNames.contains('withdraw_btc')) {
var objectStore = db.createObjectStore("withdraw_btc", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('utxo_addr', 'utxo_addr', {
unique: false
});
objectStore.createIndex('receiverBTCAddress', 'receiverBTCAddress', {
unique: false
});
}
if (!db.objectStoreNames.contains('userPublicData')) {
var objectStore = db.createObjectStore("userPublicData", {
keyPath: 'trader_flo_address'
});
objectStore.createIndex('trader_flo_pubKey', 'trader_flo_pubKey', {
unique: true
});
objectStore.createIndex('trader_status', 'trader_status', {
unique: false
});
}
if (!db.objectStoreNames.contains('external_files')) {
var objectStore = db.createObjectStore("external_files", {
keyPath: 'filename'
});
objectStore.createIndex('filehash', 'filehash', {
unique: true
});
}
if (!db.objectStoreNames.contains('kBucketStore')) {
var objectStore = db.createObjectStore('kBucketStore', {
keyPath: "id"
});
objectStore.createIndex('primary_supernode_flo_public_key'
, 'primary_supernode_flo_public_key', {
unique: false
});
}
if (!db.objectStoreNames.contains('messages_table')) {
var objectStore = db.createObjectStore("messages_table", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
objectStore.createIndex('supernode_flo_address', 'supernode_flo_address', {
unique: false
});
}
if (!db.objectStoreNames.contains('myClosestSupernodes')) {
var objectStore = db.createObjectStore("myClosestSupernodes", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
objectStore.createIndex('ip', 'ip', {
unique: false
});
}
if (!db.objectStoreNames.contains('ipTable')) {
var objectStore = db.createObjectStore("ipTable", {
keyPath: 'flo_public_key'
});
objectStore.createIndex('temporary_ip', 'temporary_ip', {
unique: false
});
}
if (!db.objectStoreNames.contains('closestSupernodesTable')) {
var objectStore = db.createObjectStore("closestSupernodesTable", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
}
}
function readDB(tablename, id) {
return new Promise((resolve, reject) => {
var transaction = db.transaction([tablename]);
var objectStore = transaction.objectStore(tablename);
var request = objectStore.get(id);
request.onerror = function (event) {
reject("Unable to retrieve data from database!");
};
request.onsuccess = function (event) {
if (request.result) {
resolve(request.result);
} else {
resolve();
}
};
});
}
function readDBbyIndex(tablename, index, indexValue) {
return new Promise((resolve, reject) => {
var transaction = db.transaction([tablename]);
var objectStore = transaction.objectStore(tablename);
let response = [];
objectStore.openCursor().onerror = function (event) {
console.error("Error fetching data");
reject(event);
};
objectStore.openCursor().onsuccess = function (event) {
let cursor = event.target.result;
if (cursor) {
if (cursor.value[index] == indexValue) {
response.push(cursor.value);
}
cursor.continue();
} else {
resolve(response);
}
};
});
}
function readAllDB(tablename) {
return new Promise((resolve, reject) => {
let response = [];
var objectStore = db.transaction(tablename).objectStore(tablename);
objectStore.openCursor().onsuccess = function (event) {
let cursor = event.target.result;
if (cursor) {
response.push(cursor.value);
cursor.continue();
} else {
resolve(response);
}
};
});
}
async function addDB(tablename, dbObject) {
try {
if(typeof dbObject.vectorClock == "undefined") dbObject.vectorClock = 0;
let request = db.transaction([tablename], "readwrite")
let store = request.objectStore(tablename)
await store.add(dbObject);
await request.complete;
console.info("Data added in " + tablename);
return dbObject;
} catch (error) {
return new Error(error);
}
}
async function updateinDB(tablename, Obj, key) {
try {
if(typeof Obj.vectorClock == "undefined") {
Obj.vectorClock = 0;
} else if(typeof Obj.increaseVectorClock == "boolean"
&& Obj.increaseVectorClock === false) {
// leave the vector clock field unchanged
} else {
Obj.vectorClock += 1;
}
var request = db.transaction([tablename], "readwrite")
let store = request.objectStore(tablename)
await store.put(Obj);
await request.complete;
return Obj;
} catch (error) {
return new Error(error);
}
}
async function removeinDB(tablename, id) {
try {
var request = db.transaction([tablename], "readwrite")
let store = request.objectStore(tablename)
await store.delete(id);
await request.complete;
return id;
} catch (error) {
return new Error(error);
}
}
function removeByIndex(tablename, indexName, indexValue) {
return new Promise((resolve, reject) => {
var request = db.transaction([tablename], "readwrite")
.objectStore(tablename);
var index = request.index(indexName);
var request = index.openCursor(IDBKeyRange.only(indexValue));
request.onsuccess = function () {
var cursor = request.result;
if (cursor) {
cursor.delete();
cursor.continue();
} else {
resolve(true);
}
};
request.onerror = function (e) {
reject(e);
}
})
}
async function removeAllinDB(tablename) {
try {
var request = db.transaction([tablename], "readwrite")
var objectStore = request.objectStore(tablename);
var objectStoreRequest = await objectStore.clear();
await request.complete;
console.info("All the data entry has been removed from your database " + tablename);
return tablename;
} catch (error) {
return new Error(error);
}
}
</script>
<!-- Backup Indexed db Object -->
<script>
const newBackupDB = localbitcoinplusplus.newBackupDatabase = function(DBName, version=1) {
this.db = null;
this.DBName = DBName;
this.request = null;
this.error = null;
this.transaction = null;
this.version = version;
}
newBackupDB.prototype = {
createNewDB() {
this.request = window.indexedDB.open(this.DBName, this.version);
this.request.onerror = function (event) {
//https://stackoverflow.com/questions/13972385/invalidstateerror-while-opening-indexeddb-in-firefox
event.preventDefault();
this.error = event.target.error;
console.log("IndexedDB database open error:", this.error.name, this.error.message);
}.bind(this);
this.request.onsuccess = function (event) {
this.db = this.request.result;
}.bind(this);
this.request.onupgradeneeded = function (event) {
this.db = event.target.result;
if (!this.db.objectStoreNames.contains('localbitcoinUser')) {
var objectStore = this.db.createObjectStore("localbitcoinUser", {
keyPath: "id"
});
objectStore.createIndex('myLocalFLOAddress', 'myLocalFLOAddress', {
unique: false
});
objectStore.put(localbitcoinplusplusObj);
}
if (!this.db.objectStoreNames.contains('buyOrders')) {
var objectStore = this.db.createObjectStore("buyOrders", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('sellOrders')) {
var objectStore = this.db.createObjectStore("sellOrders", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('deposit')) {
var objectStore = this.db.createObjectStore("deposit", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('btc_address', 'btc_address', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('withdraw_cash')) {
var objectStore = this.db.createObjectStore("withdraw_cash", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
}
if (!this.db.objectStoreNames.contains('crypto_balances')) {
var objectStore = this.db.createObjectStore("crypto_balances", {
keyPath: 'id',
autoIncrement: false
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('crypto_currency', 'crypto_currency', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('cash_balances')) {
var objectStore = this.db.createObjectStore("cash_balances", {
keyPath: 'id',
autoIncrement: false
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('currency', 'currency', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('my_supernode_private_key_chunks')) {
var objectStore = this.db.createObjectStore("my_supernode_private_key_chunks", {
keyPath: 'id'
});
objectStore.createIndex('supernode_transaction_key', 'supernode_transaction_key', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('supernode_private_key_chunks')) {
var objectStore = this.db.createObjectStore("supernode_private_key_chunks", {
keyPath: 'id'
});
}
if (!this.db.objectStoreNames.contains('system_btc_reserves_private_keys')) {
var objectStore = this.db.createObjectStore("system_btc_reserves_private_keys", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('btc_address', 'btc_address', {
unique: false
});
objectStore.createIndex('supernode_transaction_key', 'supernode_transaction_key', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('withdraw_btc')) {
var objectStore = this.db.createObjectStore("withdraw_btc", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: false
});
objectStore.createIndex('utxo_addr', 'utxo_addr', {
unique: false
});
objectStore.createIndex('receiverBTCAddress', 'receiverBTCAddress', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('userPublicData')) {
var objectStore = this.db.createObjectStore("userPublicData", {
keyPath: 'trader_flo_address'
});
objectStore.createIndex('trader_flo_pubKey', 'trader_flo_pubKey', {
unique: true
});
objectStore.createIndex('trader_status', 'trader_status', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('external_files')) {
var objectStore = this.db.createObjectStore("external_files", {
keyPath: 'filename'
});
objectStore.createIndex('filehash', 'filehash', {
unique: true
});
}
if (!this.db.objectStoreNames.contains('kBucketStore')) {
var objectStore = this.db.createObjectStore('kBucketStore', {
keyPath: "id"
})
}
if (!this.db.objectStoreNames.contains('messages_table')) {
var objectStore = this.db.createObjectStore("messages_table", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
objectStore.createIndex('supernode_flo_address', 'supernode_flo_address', {
unique: false
});
}
if (!this.db.objectStoreNames.contains('ipTable')) {
var objectStore = this.db.createObjectStore("ipTable", {
keyPath: 'flo_public_key'
});
}
if (!this.db.objectStoreNames.contains('myClosestSupernodes')) {
var objectStore = this.db.createObjectStore("myClosestSupernodes", {
keyPath: 'id'
});
objectStore.createIndex('trader_flo_address', 'trader_flo_address', {
unique: true
});
objectStore.createIndex('ip', 'ip', {
unique: false
});
}
}.bind(this)
},
backup_readDB(tablename, id) {
return new Promise((resolve, reject) => {
this.transaction = this.db.transaction([tablename]);
var objectStore = this.transaction.objectStore(tablename);
this.request = objectStore.get(id);
let parent_request = this.request;
this.request.onerror = function (event) {
reject("Unable to retrieve data from database!");
};
this.request.onsuccess = function (event) {
if (parent_request.result) {
resolve(parent_request.result);
} else {
resolve();
}
};
});
},
backup_readDBbyIndex(tablename, index, indexValue) {
return new Promise((resolve, reject) => {
this.transaction = this.db.transaction([tablename]);
var objectStore = this.transaction.objectStore(tablename);
let response = [];
objectStore.openCursor().onerror = function (event) {
console.error("Error fetching data");
reject(event);
};
objectStore.openCursor().onsuccess = function (event) {
let cursor = event.target.result;
if (cursor) {
if (cursor.value[index] == indexValue) {
response.push(cursor.value);
}
cursor.continue();
} else {
resolve(response);
}
};
});
},
backup_readAllDB(tablename) {
return new Promise((resolve, reject) => {
let response = [];
var objectStore = this.db.transaction(tablename).objectStore(tablename);
objectStore.openCursor().onsuccess = function (event) {
let cursor = event.target.result;
if (cursor) {
response.push(cursor.value);
cursor.continue();
} else {
resolve(response);
}
};
});
},
async backup_addDB(tablename, dbObject) {
try {
this.request = this.db.transaction([tablename], "readwrite")
let store = this.request.objectStore(tablename)
await store.add(dbObject);
await this.request.complete;
console.info("Data added in " + tablename);
return dbObject;
} catch (error) {
return new Error(error);
}
},
async backup_updateinDB(tablename, Obj, key) {
try {
if(typeof Obj.vectorClock == "undefined") {
Obj.vectorClock = 0;
} else if(typeof Obj.increaseVectorClock == "boolean"
&& Obj.increaseVectorClock === false) {
// leave the vector clock field unchanged
} else {
Obj.vectorClock += 1;
}
this.request = this.db.transaction([tablename], "readwrite")
let store = this.request.objectStore(tablename)
await store.put(Obj);
await this.request.complete;
return Obj;
} catch (error) {
return new Error(error);
}
},
async backup_removeinDB(tablename, id) {
try {
this.request = this.db.transaction([tablename], "readwrite")
let store = this.request.objectStore(tablename)
await store.delete(id);
await this.request.complete;
return id;
} catch (error) {
return new Error(error);
}
},
backup_removeByIndex(tablename, indexName, indexValue) {
return new Promise((resolve, reject) => {
this.request = this.db.transaction([tablename], "readwrite")
.objectStore(tablename);
let parent_request = this.request;
var index = this.request.index(indexName);
this.request = index.openCursor(IDBKeyRange.only(indexValue));
this.request.onsuccess = function () {
var cursor = parent_request.result;
if (cursor) {
cursor.delete();
cursor.continue();
} else {
resolve(true);
}
};
request.onerror = function (e) {
reject(e);
}
})
},
async backup_removeAllinDB(tablename) {
try {
this.request = this.db.transaction([tablename], "readwrite")
var objectStore = this.request.objectStore(tablename);
var objectStoreRequest = await objectStore.clear();
await this.request.complete;
console.info("All the data entry has been removed from your database " + tablename);
return tablename;
} catch (error) {
return new Error(error);
}
}
}
</script>
<!-- Initialization of objects -->
<script>
// Fetch configs from Master Key
const doShreeGanesh = () => {
try {
var rm_configs = localbitcoinplusplus.actions.fetch_configs(async function (...fetch_configs_res) {
localbitcoinplusplus.is_ui_loaded = false;
showMessage(`Connecting to Supernode server. Please wait...`);
window.bitjs = []; // Launch bitjs
localbitcoinplusplus.master_configurations.tradableAsset1.map(asset => bitjslib(asset));
kickInit();
});
} catch (error) {
showMessage(`WARNING: System failed to collect configurations.
Please refresh the page to try again.`);
throw new Error(`Failed to fetch configurations: ${error}`);
}
}
doShreeGanesh();
</script>
<script>
const loadLocalDBData = () => {
// load local db
showMessage(`Loading your local database.`);
readDB('localbitcoinUser', "00-01").then(userInfo=>{
let my_flo_id = userInfo.myLocalFLOAddress.length > 0
? userInfo.myLocalFLOAddress : `No FLO Id found`;
showMessage(`Your FLO Id: ${my_flo_id}`);
const localbitcoinuserdiv = document.getElementById('localbitcoinuserdiv')
localbitcoinuserdiv.innerHTML = `${my_flo_id}`;
// showMessage ->updating your balances
displayBalances(my_flo_id);
});
}
const createScript = (id, content) => {
let getScriptId = document.getElementById(id);
if (getScriptId == null) {
var oScript = document.createElement("script");
oScript.id = id;
var oScriptText = document.createTextNode(content);
oScript.appendChild(oScriptText);
document.body.appendChild(oScript);
} else {
getScriptId.innerText = content;
}
}
const loadExternalFiles = async function () {
try {
const user_flo_details = await readDB("localbitcoinUser", "00-01");
if (typeof user_flo_details.myLocalFLOAddress == "undefined" || user_flo_details.myLocalFLOAddress
.trim() == '') {
showMessage(`WARNING: Failed to load external files. Please refresh the page.`);
throw new Error(
`Failed to load external files as user FLO id could not be found.`);}
const ext_scripts_hashes_object = JSON.parse(localbitcoinplusplus.master_configurations.externalFiles);
Object.keys(ext_scripts_hashes_object).map(async ext_file => {
let readExtFile = await readDB("external_files", ext_file);
if (typeof readExtFile == "object" && readExtFile.filehash ==
ext_scripts_hashes_object[ext_file]) {
createScript(ext_file, readExtFile.content);
} else {
updateFileRequest(user_flo_details.myLocalFLOAddress, ext_file);
}
});
} catch (error) {
console.error(error);
}
}
const updateFileRequest = (user_flo_address, filename) => {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC
.send_rpc
.call(this, "update_external_file_request", {
trader_flo_address: user_flo_address,
file_to_update: filename,
receiver_flo_address: localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
}).then(update_external_file=>doSend(update_external_file));
let file_to_be_updated = (filename == null ? 'each' : filename);
showMessage(`Updating ${file_to_be_updated} file. Please do not
perform any operation until next confirmation.`);
}
const privateKeyBuilder = () => {
return new Promise(async (resolve, reject) => {
let supernode_transaction_key_arr = [];
const chunks = await readAllDB("my_supernode_private_key_chunks");
if (typeof chunks == "object" && chunks.length > 0) {
const RM_RPC = new localbitcoinplusplus.rpc;
let txKey = chunks.map(async(chunk, indexx) => {
if (indexx==chunks.length-1) {
supernode_transaction_key_arr.push(chunk.supernode_transaction_key);
return supernode_transaction_key_arr;
}
let retrieve_pvtkey_req = await RM_RPC
RM_RPC
.send_rpc
.call(this, "send_back_shamirs_secret_supernode_pvtkey", {
chunk_val: chunk.id,
})
.then(retrieve_pvtkey_req=>doSend(retrieve_pvtkey_req));
});
txKey[chunks.length-1].then(txk=> {
const TRANSACTION_KEY =
localbitcoinplusplus.wallets.supernode_transaction_key =
txk[0]
});
} else {
const RM_WALLET = new localbitcoinplusplus.wallets;
await RM_WALLET.manually_assign_my_private_key();
if (typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY=='string'
&& localbitcoinplusplus.is_ui_loaded == false) {
loadExternalFiles();
dataBaseUIOperations();
}
}
resolve(true);
})
}
// localbitcoinUser Database
const dataBaseUIOperations = async function () {
localbitcoinplusplus.is_ui_loaded = true;
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
try {
readDB("localbitcoinUser", "00-01").then(async function (idbData) {
// Declare the user flo address
const MY_LOCAL_FLO_ADDRESS = localbitcoinplusplus.wallets.my_local_flo_address =
idbData.myLocalFLOAddress;
const MY_LOCAL_FLO_PUBLIC_KEY = localbitcoinplusplus.wallets.my_local_flo_public_key =
idbData.myLocalFLOPublicKey;
// Send request to others to link your flo id to your local ip
linkMyLocalIPToMyFloId();
// restore k-bucket
const dbObj = await localbitcoinplusplus.kademlia.restoreKbucket(MY_LOCAL_FLO_ADDRESS, "FLO_TEST", KBucket);
// launch supernode kbucket
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(idbData.myLocalFLOPublicKey)) {
// Build Supernodes KBuckets
launchSupernodesKBuckects = await localbitcoinplusplus.kademlia.launchSupernodesKBucket();
// Request other supernodes KBucket data
// let requestSupernodeKBData = await localbitcoinplusplus.rpc.prototype
// .send_rpc
// .call(this, "requestSupernodesKBucketData", {});
// doSend(requestSupernodeKBData);
}
// Send your id to Supernode kbucket
if (!localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key)) {
let kbuck = localbitcoinplusplus.kademlia.floIdToKbucketId("FLO_TEST", MY_LOCAL_FLO_ADDRESS);
readDB('kBucketStore', kbuck).then(async userKBData=>{
if(typeof userKBData == "undefined") {
userKBData = await localbitcoinplusplus.kademlia
.addNewUserNodeInKbucketAndDB("FLO_TEST", MY_LOCAL_FLO_ADDRESS, {id:MY_LOCAL_FLO_ADDRESS}, KB=KBucket);
};
let addNewKNode = await localbitcoinplusplus.rpc.prototype
.send_rpc
.call(this, "addNewKbucketNode", {
newKbucketNode: userKBData,
trader_flo_address: MY_LOCAL_FLO_ADDRESS
});
console.log(addNewKNode);
doSend(addNewKNode);
})
}
readDB('userPublicData', MY_LOCAL_FLO_ADDRESS).then(function (
pubic_data_response) {
if (typeof pubic_data_response !== "object") {
RM_RPC
.send_rpc
.call(this, "add_user_public_data", {
trader_flo_address: MY_LOCAL_FLO_ADDRESS,
trader_flo_pubKey: MY_LOCAL_FLO_PUBLIC_KEY,
trader_status: 0,
timestamp: +new Date(),
receiver_flo_address: localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS
}).then(add_user_public_data_req=>doSend(add_user_public_data_req))
}
});
// Show balances
displayBalances(idbData.myLocalFLOAddress);
/* Give user the facillity to trade */
buildTradeUI(idbData);
// Deposit / Withdraw asset
depositWithdrawAsset(idbData.myLocalFLOAddress);
// User's Trade Details
displayTradeOrders(idbData.myLocalFLOAddress);
// Send Tx UI
buildBroadcastTxUI();
// Upload files to DB
uploadFileToDB();
if (localbitcoinplusplus.master_configurations.supernodesPubKeys.includes(
MY_LOCAL_FLO_PUBLIC_KEY)) {
localbitcoinplusplus.master_configurations.tradableAsset1.forEach(function (
asset1) {
localbitcoinplusplus.master_configurations.tradableAsset2.forEach(
function (asset2) {
RM_TRADE.resolve_current_crypto_price_in_fiat(
asset1, asset2);
});
});
}
localbitcoinplusplus.actions.sync_with_supernode(MY_LOCAL_FLO_ADDRESS);
showMessage(`Connection successfull. Welcome to Local Bitcoin Plus Plus P2P trading platform.`);
// If connected with Backup Supernode, request it to sync data.
const closestSuList = await readAllDB('myClosestSupernodes');
if (!closestSuList[0].is_live) {
const switchMyWS = new backupSupernodesWebSocketObject();
const connectedWSServerFloId = await switchMyWS.getFloIdFromWSUrl(websocket.url);
const RM_RPC = new localbitcoinplusplus.rpc;
let server_response = await RM_RPC
.send_rpc
.call(this, "nextBackupSupernodeToSyncDataBeforeActingAsBackupSupernodeNodeRequest", {
trader_flo_address: MY_LOCAL_FLO_ADDRESS,
receiver_flo_address: connectedWSServerFloId,
});
doSend(server_response);
showMessage(`INFO: Backup Supernode is collecting information about you. This could take some time.
You will be notified soon as soon as system is ready to serve you.`);
}
});
} catch (e) {
showMessage("ERROR: Failed to initialise the localbitcoinUser database. You are unable to trade at the moment.");
throw new Error(
"ERROR: Failed to initialise the localbitcoinUser database. You are unable to trade at the moment."
);
}
}
const displayTradeOrders = (flo_id, buyOrders, sellOrders) => {
let myFloId = flo_id || localbitcoinplusplus.wallets.my_local_flo_address;
if (typeof myFloId !== "string") return;
let myBuyOrders = (typeof buyOrders == "object") ? Promise.resolve(buyOrders) : readDBbyIndex(
'buyOrders', 'trader_flo_address', myFloId);
let mySellOrders = (typeof sellOrders == "object") ? Promise.resolve(sellOrders) : readDBbyIndex(
'sellOrders', 'trader_flo_address', myFloId);
let my_trades_div = document.getElementById('my_trades_div');
const RM_TRADE = new localbitcoinplusplus.trade;
let t = `<span class='ptext'>Your Trade Orders: </span>`;
t += `<ul>`;
Promise.all([myBuyOrders, mySellOrders]).then((myOrders) => {
myOrders[0].concat(myOrders[1]).map((myOrdersData) => {
const trade_id = myOrdersData.id;
const price = myOrdersData.buy_price || myOrdersData.sell_price;
const currency = myOrdersData.currency;
const order_type = myOrdersData.order_type;
const product = myOrdersData.product;
//const status = status
t +=
`<li>Trade Id: ${trade_id}</li>
<li>Type Of Order: ${order_type}</li>
<li>Product: ${product}</li>
<li>Price: ${price}</li>
<li>Currency: ${currency}</li>
<li><button class='button bg-red fs-16 mg-5' onclick="RM_TRADE.cancelTrade('${trade_id}', '${flo_id}', '${order_type}')">Cancel Trade</button></li>
<li><hr></li>
`;
});
t += `</ul>`;
my_trades_div.innerHTML = t;
});
}
</script>
<!-- Balances Functions-->
<script>
const displayBalances = (flo_id) => {
if (typeof flo_id !== "string") return;
showMessage(`Loading your balances.`);
const balances_div = document.getElementById("balances_div");
const user_crypto_balances = readDBbyIndex("crypto_balances", "trader_flo_address", flo_id);
const user_fiat_balances = readDBbyIndex("cash_balances", "trader_flo_address", flo_id);
let t = ``;
Promise.all([user_crypto_balances, user_fiat_balances]).then((balances) => {
let all_balances = balances[0].concat(balances[1]);
if (all_balances.length == 0) {
showMessage(`You don't have any balance. You can deposit crypto or fiat
asset from DEPOSIT dection below.`);
}
all_balances.map(user_balance_data => {
let code = user_balance_data.crypto_currency || user_balance_data.currency;
let value = user_balance_data.crypto_balance || user_balance_data.cash_balance;
t += `<span>${code}:${value}</span> &nbsp;`;
});
balances_div.innerHTML = t;
});
showMessage(t);
}
</script>
<!-- Trade functions -->
<script>
const buildTradeUI = (idbData) => {
if (typeof idbData !== "object") return;
const RM_RPC = new localbitcoinplusplus.rpc;
const RM_TRADE = new localbitcoinplusplus.trade;
// RESET KEYS
const reset_flo_keys_div = document.getElementById('flo_keys_div');
const reset_flo_keys_btn = document.createElement('button');
reset_flo_keys_btn.className += ` button bg-purple mg-5 `;
const reset_flo_keys_btn_text = document.createTextNode(`Reset FLO Keys`);
reset_flo_keys_btn.appendChild(reset_flo_keys_btn_text);
reset_flo_keys_div.appendChild(reset_flo_keys_btn);
reset_flo_keys_btn.onclick = function () {
if (confirm(
`This will reset your old keys along with data associated with it. Are you sure you want to continue?`
)) {
localbitcoinplusplus.actions.reset_flo_keys().then(reset_success => {
if (reset_success) {
showMessage("INFO: FLO keys have been reset successfully.");
} else {
showMessage(`INFO: Failed to reset FLO keys.`);
}
});
}
}
//localbitcoinuserdiv
document.getElementById("localbitcoinuserdiv").innerHTML = `${idbData.myLocalFLOAddress}`;
// TRADE BOX
const tradebox = document.getElementById("tradebox");
const trade_select_div = document.createElement('div');
trade_select_div.className += ` custom-select `;
const trade_buttons_div = document.createElement('div');
trade_buttons_div.className += ` center `;
const selectListCrypto = document.createElement("select");
selectListCrypto.id = "selectListCrypto";
trade_select_div.appendChild(selectListCrypto);
const selectListFiat = document.createElement("select");
selectListFiat.id = "selectListFiat";
trade_select_div.appendChild(selectListFiat);
const selectListAmount = document.createElement('select');
selectListAmount.id = "selectListAmount";
trade_select_div.appendChild(selectListAmount);
const trade_buy_button = document.createElement('button');
trade_buy_button.className += ` button bg-transparent fs-16 mg-5`;
const trade_buy_button_text = document.createTextNode("BUY");
trade_buy_button.appendChild(trade_buy_button_text);
const trade_sell_button = document.createElement('button');
trade_sell_button.className += ` button bg-transparent fs-16 mg-5`;
const trade_sell_button_text = document.createTextNode("SELL");
trade_sell_button.appendChild(trade_sell_button_text);
trade_buttons_div.appendChild(trade_buy_button);
trade_buttons_div.appendChild(trade_sell_button);
tradebox.appendChild(trade_select_div);
tradebox.appendChild(trade_buttons_div);
localbitcoinplusplus.master_configurations.tradableAsset1.map(cryptos => {
let option = document.createElement("option");
option.value = cryptos;
option.text = cryptos;
selectListCrypto.appendChild(option);
});
localbitcoinplusplus.master_configurations.tradableAsset2.map(fiat => {
let option = document.createElement("option");
option.value = fiat;
option.text = fiat;
selectListFiat.appendChild(option);
});
localbitcoinplusplus.master_configurations.validTradingAmount.map(amount => {
let option = document.createElement("option");
option.value = amount;
option.text = amount;
selectListAmount.appendChild(option);
});
trade_buy_button.onclick = function (event) {
if (typeof idbData.myLocalFLOAddress !== "string" || idbData.myLocalFLOAddress
.trim() == "") {
let err_msg = "You must have a BTC address to receive Bitcoin. No Bitcoin address found in database.";
showMessage(err_msg);
throw new Error(err_msg);
}
RM_TRADE.place_order("buy", idbData.myLocalFLOAddress,
selectListCrypto.value, selectListFiat.value, parseFloat(selectListAmount.value))
.then(buytrade=>doSend(buytrade));
}
trade_sell_button.onclick = function (event) {
if (typeof idbData.myLocalFLOAddress == undefined || idbData.myLocalFLOAddress
.trim() == "") {
let err_msg = "You must have a FLO address to trade. No such address found in database."
showMessage(err_msg);
throw new Error(err_msg);
}
RM_TRADE.place_order("sell", idbData.myLocalFLOAddress,
selectListCrypto.value, selectListFiat.value, parseFloat(selectListAmount.value))
.then(selltrade=>doSend(selltrade));
}
}
</script>
<!-- Deposit/Withdraw asset -->
<script>
const depositWithdrawAsset = function (userFLOaddress) {
const RM_TRADE = new localbitcoinplusplus.trade;
const RM_RPC = new localbitcoinplusplus.rpc;
let asset_box = document.getElementById("asset_box");
let asset_button_box = document.getElementById("asset_button_box");
let err_msg = '';
// Create a select input for asset type
let assetTypeInput = document.createElement('select');
assetTypeInput.id = "select_assets_type";
asset_box.appendChild(assetTypeInput);
if (typeof localbitcoinplusplus.master_configurations.tradableAsset1 !== 'undefined' &&
typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined') {
let assetTypeSelectArray1 = JSON.parse(JSON.stringify(localbitcoinplusplus.master_configurations.tradableAsset1));
let assetTypeSelectArray2 = JSON.parse(JSON.stringify(localbitcoinplusplus.master_configurations.tradableAsset2));
let assetTypeSelectArray = assetTypeSelectArray1.concat(assetTypeSelectArray2)
.filter((item, pos, finalArray) => finalArray.indexOf(item) == pos);
assetTypeSelectArray.unshift("Select Asset Type");
for (var i = 0; i < assetTypeSelectArray.length; i++) {
var option = document.createElement("option");
option.value = assetTypeSelectArray[i];
option.text = assetTypeSelectArray[i];
assetTypeInput.appendChild(option);
}
}
// Create a select input for trade amount
let tradeAmountSelect = document.createElement('select');
tradeAmountSelect.id = "trade_amount_select";
asset_box.appendChild(tradeAmountSelect);
if (typeof localbitcoinplusplus.master_configurations.validTradingAmount !== 'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.length > 0) {
let tradeAmountSelectArray = JSON.parse(JSON.stringify(localbitcoinplusplus.master_configurations.validTradingAmount));
tradeAmountSelectArray.unshift("Select Asset Amount");
for (var i = 0; i < tradeAmountSelectArray.length; i++) {
var option = document.createElement("option");
option.value = tradeAmountSelectArray[i];
option.text = tradeAmountSelectArray[i];
tradeAmountSelect.appendChild(option);
}
}
let currencySelect = document.createElement('select');
currencySelect.id = `withdraw_fiat_currency`;
asset_box.appendChild(currencySelect);
if (typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset2.length > 0) {
let fiatList = localbitcoinplusplus.master_configurations.tradableAsset2
.filter(asset => !localbitcoinplusplus.master_configurations.tradableAsset1.includes(asset));
let fiatListArray = JSON.parse(JSON.stringify(fiatList));
fiatListArray.unshift("Select Fiat Currency");
for (var i = 0; i < fiatListArray.length; i++) {
var option = document.createElement("option");
option.value = fiatListArray[i];
option.text = fiatListArray[i];
currencySelect.appendChild(option);
}
}
// Create a deposit and withdraw button
let depositAssetButton = document.createElement('button');
depositAssetButton.className += ` button bg-transparent fs-16 mg-5 `;
let depositAssetButtonText = document.createTextNode('Deposit');
depositAssetButton.appendChild(depositAssetButtonText);
let withdrawAssetButton = document.createElement('button');
withdrawAssetButton.className += ` button bg-transparent fs-16 mg-5 `;
let withdrawAssetButtonText = document.createTextNode('Withdraw');
withdrawAssetButton.appendChild(withdrawAssetButtonText);
asset_button_box.appendChild(depositAssetButton);
asset_button_box.appendChild(withdrawAssetButton);
depositAssetButton.addEventListener('click', function () {
let asset_type = assetTypeInput.value;
let tradeAmount = parseFloat(tradeAmountSelect.value);
let fiatCurrency = currencySelect.value;
if (typeof userFLOaddress == undefined || userFLOaddress.trim().length < 1) {
err_msg = "Invalid or empty user FLO address.";
showMessage(err_msg);
throw new Error(err_msg);
}
if (typeof localbitcoinplusplus.master_configurations.validTradingAmount !== 'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(tradeAmount) &&
(typeof localbitcoinplusplus.master_configurations.tradableAsset1 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset1.includes(asset_type) ||
typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset2.includes(asset_type))
) {
RM_TRADE.depositAsset(asset_type, tradeAmount, fiatCurrency, userFLOaddress);
} else {
err_msg = "Error while depositing your address.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
withdrawAssetButton.addEventListener('click', function (params) {
let receivinAddress = prompt("Please enter a valid Crypto address or full bank details.");
if (receivinAddress.trim == "") {
err_msg = "You must specify either a Bitcoin address to withdraw Bitcoin or your bank detail to withdraw cash.";
showMessage(err_msg);
throw new Error(err_msg);
}
let asset_type = assetTypeInput.value;
let tradeAmount = parseFloat(tradeAmountSelect.value);
let fiatCurrency = currencySelect.value;
if (typeof userFLOaddress == undefined || userFLOaddress.trim().length < 1) {
err_msg = "Invalid or empty user FLO address.";
showMessage(err_msg);
throw new Error(err_msg);
}
if (typeof localbitcoinplusplus.master_configurations.validTradingAmount !== 'undefined' &&
localbitcoinplusplus.master_configurations.validTradingAmount.includes(tradeAmount) &&
typeof localbitcoinplusplus.master_configurations.tradableAsset1 !== 'undefined' &&
typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined' &&
localbitcoinplusplus.master_configurations.tradableAsset1
.concat(localbitcoinplusplus.master_configurations.tradableAsset2).includes(asset_type)
) {
RM_TRADE.withdrawAsset(asset_type, tradeAmount, receivinAddress, userFLOaddress,
fiatCurrency);
} else {
err_msg = "Error while depositing your address.";
showMessage(err_msg);
throw new Error(err_msg);
}
});
// NOTIFY DEPOSITED CRYPTO CONFIRMATION
const refresh_crypto_status_btn = document.createElement('button');
refresh_crypto_status_btn.className += ` button bg-transparent fs-16 mg-5 `;
const refresh_crypto_status_btn_text = document.createTextNode('Confirm Deposit');
refresh_crypto_status_btn.appendChild(refresh_crypto_status_btn_text);
asset_button_box.appendChild(refresh_crypto_status_btn);
refresh_crypto_status_btn.addEventListener('click', function () {
RM_RPC.send_rpc.call(this,
"refresh_deposit_status_request",
{
receiver_flo_address: localbitcoinplusplus.MY_SUPERNODE_FLO_ADDRESS,
trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address
}).then(refresh_deposit_status=>doSend(refresh_deposit_status));
});
}
</script>
<!-- Broadcast Tx UI -->
<script>
function buildBroadcastTxUI() {
const broadcast_tx_ui = document.getElementById('send_crypto_select_div');
const broadcast_tx_ui_form = document.getElementById('send_crypto_form_ui');
const send_crypto_type = document.createElement('select');
send_crypto_type.id = "send_crypto_type";
broadcast_tx_ui.appendChild(send_crypto_type);
if (typeof localbitcoinplusplus.master_configurations.tradableAsset1 !== 'undefined') {
let sendCryptoArray = JSON.parse(JSON.stringify(localbitcoinplusplus.master_configurations.tradableAsset1));
sendCryptoArray.unshift("Select Crypto");
for (var i = 0; i < sendCryptoArray.length; i++) {
var option = document.createElement("option");
option.value = sendCryptoArray[i];
option.text = sendCryptoArray[i];
send_crypto_type.appendChild(option);
}
}
const receiving_amount_currency_input = document.createElement('select');
receiving_amount_currency_input.id = "receiving_amount_currency_input";
broadcast_tx_ui.appendChild(receiving_amount_currency_input);
if (typeof localbitcoinplusplus.master_configurations.tradableAsset2 !== 'undefined') {
let receiving_amount_currency_inputArray = JSON.parse(JSON.stringify(localbitcoinplusplus.master_configurations
.tradableAsset2))
.filter(asset => !localbitcoinplusplus.master_configurations.tradableAsset1.includes(asset));
receiving_amount_currency_inputArray.unshift("Select Fiat");
for (var i = 0; i < receiving_amount_currency_inputArray.length; i++) {
var option = document.createElement("option");
option.value = receiving_amount_currency_inputArray[i];
option.text = receiving_amount_currency_inputArray[i];
receiving_amount_currency_input.appendChild(option);
}
}
const utxo_addr_input = document.createElement('input');
utxo_addr_input.type = "text";
utxo_addr_input.placeholder = `UTXO Address of Crypto`;
const utxo_addr_wif_input = document.createElement('input');
utxo_addr_wif_input.type = "text";
utxo_addr_wif_input.placeholder = `Private Key of Crypto Being Used`;
const receiver_address_input = document.createElement('input');
receiver_address_input.type = "text";
receiver_address_input.placeholder = `Receiver Address`;
const receiving_crypto_amount_input = document.createElement('input');
receiving_crypto_amount_input.type = "text";
receiving_crypto_amount_input.placeholder = `Amount to Send`;
const change_adress_input = document.createElement('input');
change_adress_input.type = "text";
change_adress_input.placeholder = `Change Address`;
const tx_send_button = document.createElement('button');
tx_send_button.className += ' button bg-blue fs-16 ';
const tx_send_button_text = document.createTextNode('Send Transaction');
tx_send_button.appendChild(tx_send_button_text);
broadcast_tx_ui_form.appendChild(utxo_addr_input);
broadcast_tx_ui_form.appendChild(utxo_addr_wif_input);
broadcast_tx_ui_form.appendChild(receiver_address_input);
broadcast_tx_ui_form.appendChild(receiving_crypto_amount_input);
broadcast_tx_ui_form.appendChild(change_adress_input);
broadcast_tx_ui_form.appendChild(tx_send_button);
let err_msg;
tx_send_button.onclick = function () {
if (utxo_addr_input.value.length < 1) {
err_msg = "Empty UTXO Address.";
showMessage(err_msg);
throw new Error(err_msg);
};
if (utxo_addr_wif_input.value.length < 1) {
err_msg = "Empty Private Key.";
showMessage(err_msg);
throw new Error(err_msg);
};
if (receiver_address_input.value.length < 1) {
err_msg = "Empty Receiving Address.";
showMessage(err_msg);
throw new Error(err_msg);
};
if (receiving_crypto_amount_input.value < 0) {
err_msg = "Empty Sending Amount.";
showMessage(err_msg);
throw new Error(err_msg);
};
if (change_adress_input.value.length < 1) {
err_msg = "Empty Change Address.";
showMessage(err_msg);
throw new Error(err_msg);
};
const RM_TRADE = new localbitcoinplusplus.trade;
RM_TRADE.sendTransaction(send_crypto_type.value, utxo_addr_input.value, utxo_addr_wif_input.value,
receiver_address_input.value,
receiving_crypto_amount_input.value, null, change_adress_input.value,
async function (res) {
console.log(res);
if (typeof res == "string" && res.length > 0) {
try {
let resp_obj = JSON.parse(res);
let resp_txid = resp_obj.txid.result || resp_obj.txid;
let msg = `Transaction Id for your deposited crypto asset: ${resp_txid}`;
showMessage(msg);
return true;
} catch (error) {
console.warn(error);
showMessage(error);
}
}
});
}
}
</script>
<!-- Generate new keys -->
<script>
(function () {
let new_flo_keys_ul = document.getElementById('new_flo_keys_ul');
let new_flo_keys_button = document.getElementById('new_flo_keys');
new_flo_keys_button.onclick = function () {
if (typeof localbitcoinplusplus.wallets !== "undefined") {
const RM_WALLET = new localbitcoinplusplus.wallets;
let new_flo_keys = RM_WALLET.generateFloKeys();
let new_key_li = '';
Object.keys(new_flo_keys).forEach(function (key) {
new_key_li += `<li><strong>${key}</strong>: ${new_flo_keys[key]}</li>`;
});
new_flo_keys_ul.insertAdjacentHTML('beforeend', new_key_li);
}
}
})();
</script>
<script>
//Function to check current balance of a BTC address
function validateDepositedBTCBalance(trader_deposits, backup_db="") {
if (!localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(localbitcoinplusplus.wallets.my_local_flo_public_key) &&
typeof localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY !== "string"
) return false;
if (!localbitcoinplusplus.master_configurations.tradableAsset1
.includes(trader_deposits.product)) return false;
if (typeof backup_db=="string" && backup_db.length>0) {
let _readDB = readDB;
let _readDBbyIndex = readDBbyIndex;
let _updateinDB = updateinDB;
if (typeof localbitcoinplusplus.newBackupDatabase.db[backup_db] == "object") {
const foreign_db = localbitcoinplusplus.newBackupDatabase.db[backup_db];
_readDB = foreign_db.backup_readDB.bind(foreign_db);
_readDBbyIndex = foreign_db.backup_readDBbyIndex.bind(foreign_db);
_updateinDB = foreign_db.backup_updateinDB.bind(foreign_db);
} else {
err_msg = `WARNING: Invalid Backup DB Instance Id: ${backup_db}.`;
showMessage(err_msg);
throw new Error(err_msg);
}
}
let explorer;
let decimal = 100000000;
switch (trader_deposits.product) {
case "BTC":
explorer = localbitcoinplusplus.server.btc_mainnet;
break;
case "BTC_TEST":
explorer = localbitcoinplusplus.server.btc_testnet;
break;
case "FLO":
explorer = localbitcoinplusplus.server.flo_mainnet;
decimal = 1;
break;
case "FLO_TEST":
explorer = localbitcoinplusplus.server.flo_testnet;
decimal = 1;
break;
default:
break;
}
try {
let url = `${explorer}/api/addr/${trader_deposits.btc_address}/balance`;
console.log(url);
helper_functions.ajaxGet(url).then(balance => {
if (!isNaN(balance) && parseFloat(balance) > 0) {
balance = Number(parseFloat(balance/decimal));
console.log(balance);
/************************ Case of dispute *****************/
if (0) {
//if (trader_deposits.bitcoinToBePaid - balance > localbitcoinplusplus.master_configurations.btcTradeMargin) {
console.log(trader_deposits.bitcoinToBePaid, balance, localbitcoinplusplus.master_configurations
.btcTradeMargin);
console.warn("User sent less cryptos");
//trader_deposits.status = 4; // User sent less BTC than he should #Disputed
//updateinDB("deposit", trader_deposits, trader_deposits.trader_flo_address);
} else {
//Deposit successful. Update user balance and status to 2. Its Private key can be
// now given to a random trader
trader_deposits.status = 2;
_updateinDB("deposit", trader_deposits, trader_deposits.trader_flo_address);
_readDBbyIndex('system_btc_reserves_private_keys', 'btc_address', trader_deposits.btc_address)
.then(function (reserve_res) {
if (typeof reserve_res == "object") {
reserve_res.map(reserves => {
reserves.balance = balance;
_updateinDB('system_btc_reserves_private_keys', reserves,
reserves.id);
});
}
});
let trader_depositor_cash_id =
`${trader_deposits.trader_flo_address}_${trader_deposits.product}`;
let updatedCryptobalances = {
id: trader_depositor_cash_id,
trader_flo_address: trader_deposits.trader_flo_address,
crypto_balance: balance,
crypto_currency: trader_deposits.product
}
_readDB('crypto_balances', trader_depositor_cash_id).then(function (res_btc_balances) {
if (typeof res_btc_balances == "object" && typeof res_btc_balances.result ==
"object" && typeof res_btc_balances.crypto_balance == "number") {
updatedCryptobalances.crypto_balance += parseFloat(res_btc_balances
.crypto_balance);
}
// Update crypto balance of user in crypto_balances
_updateinDB("crypto_balances", updatedCryptobalances, trader_deposits.btc_address)
.then(updatedBTCBalanceObject => {
const RM_WALLET = new localbitcoinplusplus.wallets;
const RM_RPC = new localbitcoinplusplus.rpc;
let updatedBTCBalanceObjectString = JSON.stringify(
updatedCryptobalances);
let updatedBTCBalanceObjectSign = RM_WALLET
.sign(updatedBTCBalanceObjectString,
localbitcoinplusplus.wallets.MY_SUPERNODE_PRIVATE_KEY
);
let updateUserCryptoBalanceObject = {
updatedBTCBalanceObject: updatedBTCBalanceObject,
updatedBTCBalanceObjectSign: updatedBTCBalanceObjectSign,
trader_flo_address: trader_deposits.trader_flo_address,
receiver_flo_address: trader_deposits.trader_flo_address
}
RM_RPC
.send_rpc("updateUserCryptoBalanceRequest",
updateUserCryptoBalanceObject)
.then(updateUserCryptoBalanceRequestObject=>
doSend(updateUserCryptoBalanceRequestObject));
});
});
}
}
});
} catch (error) {
console.error(error);
return false;
}
}
function giveMeYourBackup(backup_server_flo_id) {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"give_me_your_backup", {
"JOB": "BACKUP_SERVER_REQUEST",
requesters_pub_key: localbitcoinplusplus.wallets.my_local_flo_public_key,
trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address
}).then(send_backup_request=>doSend(send_backup_request));
}
function linkMyLocalIPToMyFloId() {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"link_My_Local_IP_To_My_Flo_Id", {
"JOB": "linkMyLocalIPToMyFloId",
requesters_pub_key: localbitcoinplusplus.wallets.my_local_flo_public_key,
trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address
}).then(reqst=>doSend(reqst));
}
function linkBackOthersLocalIPToTheirFloId() {
const RM_RPC = new localbitcoinplusplus.rpc;
RM_RPC.send_rpc.call(this,
"link_Others_Local_IP_To_Their_Flo_Id", {
"JOB": "linkBackOthersLocalIPToTheirFloId",
requesters_pub_key: localbitcoinplusplus.wallets.my_local_flo_public_key,
trader_flo_address: localbitcoinplusplus.wallets.my_local_flo_address
}).then(reqst=>doSend(reqst));
}
</script>
<!-- Events -->
<script>
reactor.registerEvent('new_supernode_connected');
reactor.registerEvent('primary_supernode_down');
reactor.registerEvent('backup_supernode_up');
reactor.registerEvent('backup_supernode_down');
reactor.registerEvent('fireNodeWelcomeBackEvent');
reactor.registerEvent('fireNodeGoodByeEvent');
reactor.registerEvent('primarySupernodeUpdatingLatestDataForItsUserFromOtherSupernodes');
reactor.addEventListener('fireNodeWelcomeBackEvent', function(evt) {
let getFLOId = bitjs.FLO_TEST.pubkey2address(evt.flo_public_key);
if(localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(evt.flo_public_key)) {
msg = `INFO: Supernode ${getFLOId} joined.`;
} else {
msg = `INFO: User node ${getFLOId} joined.`;
}
showMessage(msg);
});
reactor.addEventListener('new_supernode_connected', async function(evt) {
const switchMyWS = new backupSupernodesWebSocketObject();
switchMyWS.updateSupernodeAvailabilityStatus(evt.srcElement.url, true);
showMessage(`INFO: Connected successfully to Supernode: ${evt.srcElement.url}`);
writeToScreen("CONNECTED");
let my_local_data = await readDB('localbitcoinUser', '00-01');
if (typeof my_local_data == "object"
&& !localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(my_local_data.myLocalFLOAddress)) {
const conn_su_flo_id = await switchMyWS.getFloIdFromWSUrl(evt.srcElement.url);
if (typeof conn_su_flo_id == "string") {
my_local_data.lastConnectedTime = + new Date();
my_local_data.lastConnectedSupernode = conn_su_flo_id;
updateinDB('localbitcoinUser', my_local_data);
} else {
mss = `WARNING: Failed to update current supernode connected status in localbitcoinUser.`;
showMessage(mss);
throw new Error(mss);
}
}
});
reactor.addEventListener('primary_supernode_down', async function(evt) {
showMessage(`INFO: Disconnected to Supernode server: ${evt.srcElement.url}`);
const switchMyWS = new backupSupernodesWebSocketObject();
switchMyWS.updateSupernodeAvailabilityStatus(evt.srcElement.url, false);
const disconnectedWSServerFloId = await switchMyWS.getFloIdFromWSUrl(evt.srcElement.url);
showMessage(`INFO: Waiting for primary Supernode connection to come back within 30sec.`);
localbitcoinplusplus.actions.delay(30000).then(async ()=>{
const getSubjectSupernodeDetails = await readDBbyIndex('myClosestSupernodes', 'trader_flo_address', disconnectedWSServerFloId);
if (typeof getSubjectSupernodeDetails=="object" && getSubjectSupernodeDetails[0].is_live!==true) {
showMessage(`INFO: Connection to primary Supernode failed. Attempting to connect to secondary Supernode.`);
switchMyWS.switchToBackupWS(evt.srcElement.url);
}
});
});
reactor.addEventListener('fireNodeGoodByeEvent', function(evt_msg) {
let i = evt_msg.indexOf(' ')
let temp_ip = evt_msg.substr(0, i)
readDBbyIndex('ipTable', 'temporary_ip', temp_ip).then(async op =>{
if(op.length < 1 || typeof op[0].temporary_ip !== 'string') return;
let getFLOId = bitjs.FLO_TEST.pubkey2address(op[0].flo_public_key);
if(localbitcoinplusplus.master_configurations.supernodesPubKeys
.includes(op[0].flo_public_key)) {
msg = `INFO: Supernode ${getFLOId} left.`;
} else {
msg = `INFO: User node ${getFLOId} left.`;
}
showMessage(msg);
});
});
reactor.addEventListener('primarySupernodeUpdatingLatestDataForItsUserFromOtherSupernodes', async function(params) {
let msg = '';
if (typeof params.requesting_user_id !== "string") {
msg = 'ERROR: Invalid User id provided in "primarySupernodeUpdatingLatestDataForItsUserFromOtherSupernodes" request.';
showMessage(msg);
throw new Error(msg);
}
let getPrimarySuObj = await localbitcoinplusplus.kademlia.determineClosestSupernode(params.requesting_user_id, 3);
let primarySupernode = getPrimarySuObj[0].data.id;
if (typeof primarySupernode !== "string") {
let msg = `WARNING: Failed to determine primary supernode for ${params.requesting_user_id}.`;
showMessage(msg);
throw new Error(msg);
}
let getNextClosestSuObjOfPrimarySupernode = await localbitcoinplusplus.kademlia.determineClosestSupernode("", 3, supernodeKBucket, primarySupernode);
if (localbitcoinplusplus.wallets.my_local_flo_address !== primarySupernode) return;
const RM_RPC = new localbitcoinplusplus.rpc;
const table_array = ["crypto_balances", "cash_balances"];
table_array.map(async tbl=>{
let record = await readDBbyIndex(tbl, 'trader_flo_address', params.requesting_user_id);
record.map(rec=>{
getNextClosestSuObjOfPrimarySupernode.map(nextSu=>{
if (nextSu.data.id !== primarySupernode) {
let nextSuConn = localbitcoinplusplus.newBackupDatabase.db[nextSu.data.id];
if(typeof nextSuConn !== "object") {
let msg = `WARNING: Failed to open a backup DB with Supernode ${nextSu}.`;
showMessage(msg);
throw new Error(msg);
}
RM_RPC
.send_rpc
.call(this, "sync_data_by_vector_clock", {
trader_flo_address: params.requesting_user_id,
receiver_flo_address: nextSu.data.id,
leaving_supernode_flo_id: primarySupernode,
data: rec,
dbTable: tbl
}).then(server_response=>doSend(server_response, nextSu.data.id));
}
});
});
});
});
</script>
</body>
</html>
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