flowallet-testnet/floCrypto.js

(function(EXPORTS) { //floCrypto v2.3.1
    /* FLO Crypto Operators */
    'use strict';
    const floCrypto = EXPORTS;

    const p = BigInteger("FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F", 16);
    const ecparams = EllipticCurve.getSECCurveByName("secp256k1");
    const ascii_alternatives = `‘ '\n’ '\n“ "\n” "\n– --\n— ---\n≥ >=\n≤ <=\n≠ !=\n× *\n÷ /\n← <-\n→ ->\n↔ <->\n⇒ =>\n⇐ <=\n⇔ <=>`;
    const exponent1 = () => p.add(BigInteger.ONE).divide(BigInteger("4"));

    function calculateY(x) {
        let exp = 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)
    }

    function getUncompressedPublicKey(compressedPublicKey) {
        // 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 = 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
        };
    }

    function getSenderPublicKeyString() {
        let privateKey = ellipticCurveEncryption.senderRandom();
        var senderPublicKeyString = ellipticCurveEncryption.senderPublicString(privateKey);
        return {
            privateKey: privateKey,
            senderPublicKeyString: senderPublicKeyString
        }
    }

    function deriveSharedKeySender(receiverPublicKeyHex, senderPrivateKey) {
        let receiverPublicKeyString = getUncompressedPublicKey(receiverPublicKeyHex);
        var senderDerivedKey = ellipticCurveEncryption.senderSharedKeyDerivation(
            receiverPublicKeyString.x, receiverPublicKeyString.y, senderPrivateKey);
        return senderDerivedKey;
    }

    function deriveSharedKeyReceiver(senderPublicKeyString, receiverPrivateKey) {
        return ellipticCurveEncryption.receiverSharedKeyDerivation(
            senderPublicKeyString.XValuePublicString, senderPublicKeyString.YValuePublicString, receiverPrivateKey);
    }

    function getReceiverPublicKeyString(privateKey) {
        return ellipticCurveEncryption.receiverPublicString(privateKey);
    }

    function 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)
        let privateKeyDecimal = BigInteger(pk).toString()
        let privateKeyHex = Crypto.util.bytesToHex(pk)
        return {
            privateKeyDecimal: privateKeyDecimal,
            privateKeyHex: privateKeyHex
        }
    }

    //generate a random Interger within range
    floCrypto.randInt = function(min, max) {
        min = Math.ceil(min);
        max = Math.floor(max);
        return Math.floor(Math.random() * (max - min + 1)) + min;
    }

    //generate a random String within length (options : alphaNumeric chars only)
    floCrypto.randString = function(length, alphaNumeric = true) {
        var result = '';
        var characters = alphaNumeric ? 'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789' :
            'ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789_+-./*?@#&$<>=[]{}():';
        for (var i = 0; i < length; i++)
            result += characters.charAt(Math.floor(Math.random() * characters.length));
        return result;
    }

    //Encrypt Data using public-key
    floCrypto.encryptData = function(data, receiverPublicKeyHex) {
        var senderECKeyData = getSenderPublicKeyString();
        var senderDerivedKey = deriveSharedKeySender(receiverPublicKeyHex, senderECKeyData.privateKey);
        let senderKey = senderDerivedKey.XValue + senderDerivedKey.YValue;
        let secret = Crypto.AES.encrypt(data, senderKey);
        return {
            secret: secret,
            senderPublicKeyString: senderECKeyData.senderPublicKeyString
        };
    }

    //Decrypt Data using private-key
    floCrypto.decryptData = function(data, privateKeyHex) {
        var receiverECKeyData = {};
        if (typeof privateKeyHex !== "string") throw new Error("No private key found.");
        let privateKey = wifToDecimal(privateKeyHex, true);
        if (typeof privateKey.privateKeyDecimal !== "string") throw new Error("Failed to detremine your private key.");
        receiverECKeyData.privateKey = privateKey.privateKeyDecimal;
        var receiverDerivedKey = deriveSharedKeyReceiver(data.senderPublicKeyString, receiverECKeyData.privateKey);
        let receiverKey = receiverDerivedKey.XValue + receiverDerivedKey.YValue;
        let decryptMsg = Crypto.AES.decrypt(data.secret, receiverKey);
        return decryptMsg;
    }

    //Sign data using private-key
    floCrypto.signData = function(data, privateKeyHex) {
        var key = new Bitcoin.ECKey(privateKeyHex);
        var messageHash = Crypto.SHA256(data);
        var messageSign = Bitcoin.ECDSA.sign(messageHash, key.priv);
        var sighex = Crypto.util.bytesToHex(messageSign);
        return sighex;
    }

    //Verify signatue of the data using public-key
    floCrypto.verifySign = function(data, signatureHex, publicKeyHex) {
        var msgHash = Crypto.SHA256(data);
        var sigBytes = Crypto.util.hexToBytes(signatureHex);
        var publicKeyPoint = ecparams.getCurve().decodePointHex(publicKeyHex);
        var verify = Bitcoin.ECDSA.verify(msgHash, sigBytes, publicKeyPoint);
        return verify;
    }

    //Generates a new flo ID and returns private-key, public-key and floID
    const generateNewID = floCrypto.generateNewID = function() {
        var key = new Bitcoin.ECKey(false);
        key.setCompressed(true);
        return {
            floID: key.getBitcoinAddress(),
            pubKey: key.getPubKeyHex(),
            privKey: key.getBitcoinWalletImportFormat()
        }
    }

    Object.defineProperty(floCrypto, 'newID', {
        get: () => generateNewID()
    });

    //Returns public-key from private-key
    floCrypto.getPubKeyHex = function(privateKeyHex) {
        if (!privateKeyHex)
            return null;
        var key = new Bitcoin.ECKey(privateKeyHex);
        if (key.priv == null)
            return null;
        key.setCompressed(true);
        return key.getPubKeyHex();
    }

    //Returns flo-ID from public-key or private-key
    floCrypto.getFloID = function(keyHex) {
        if (!keyHex)
            return null;
        try {
            var key = new Bitcoin.ECKey(keyHex);
            if (key.priv == null)
                key.setPub(keyHex);
            return key.getBitcoinAddress();
        } catch {
            return null;
        }
    }

    //Verify the private-key for the given public-key or flo-ID
    floCrypto.verifyPrivKey = function(privateKeyHex, pubKey_floID, isfloID = true) {
        if (!privateKeyHex || !pubKey_floID)
            return false;
        try {
            var key = new Bitcoin.ECKey(privateKeyHex);
            if (key.priv == null)
                return false;
            key.setCompressed(true);
            if (isfloID && pubKey_floID == key.getBitcoinAddress())
                return true;
            else if (!isfloID && pubKey_floID == key.getPubKeyHex())
                return true;
            else
                return false;
        } catch {
            return null;
        }
    }

    //Check if the given Address is valid or not
    floCrypto.validateFloID = floCrypto.validateAddr = function(inpAddr) {
        if (!inpAddr)
            return false;
        try {
            let addr = new Bitcoin.Address(inpAddr);
            return true;
        } catch {
            return false;
        }
    }

    //Split the str using shamir's Secret and Returns the shares 
    floCrypto.createShamirsSecretShares = function(str, total_shares, threshold_limit) {
        try {
            if (str.length > 0) {
                var strHex = shamirSecretShare.str2hex(str);
                var shares = shamirSecretShare.share(strHex, total_shares, threshold_limit);
                return shares;
            }
            return false;
        } catch {
            return false
        }
    }

    //Returns the retrived secret by combining the shamirs shares
    const retrieveShamirSecret = floCrypto.retrieveShamirSecret = function(sharesArray) {
        try {
            if (sharesArray.length > 0) {
                var comb = shamirSecretShare.combine(sharesArray.slice(0, sharesArray.length));
                comb = shamirSecretShare.hex2str(comb);
                return comb;
            }
            return false;
        } catch {
            return false;
        }
    }

    //Verifies the shares and str
    floCrypto.verifyShamirsSecret = function(sharesArray, str) {
        if (!str)
            return null;
        else if (retrieveShamirSecret(sharesArray) === str)
            return true;
        else
            return false;
    }

    const validateASCII = floCrypto.validateASCII = function(string, bool = true) {
        if (typeof string !== "string")
            return null;
        if (bool) {
            let x;
            for (let i = 0; i < string.length; i++) {
                x = string.charCodeAt(i);
                if (x < 32 || x > 127)
                    return false;
            }
            return true;
        } else {
            let x, invalids = {};
            for (let i = 0; i < string.length; i++) {
                x = string.charCodeAt(i);
                if (x < 32 || x > 127)
                    if (x in invalids)
                        invalids[string[i]].push(i)
                else
                    invalids[string[i]] = [i];
            }
            if (Object.keys(invalids).length)
                return invalids;
            else
                return true;
        }
    }

    floCrypto.convertToASCII = function(string, mode = 'soft-remove') {
        let chars = validateASCII(string, false);
        if (chars === true)
            return string;
        else if (chars === null)
            return null;
        let convertor, result = string,
            refAlt = {};
        ascii_alternatives.split('\n').forEach(a => refAlt[a[0]] = a.slice(2));
        mode = mode.toLowerCase();
        if (mode === "hard-unicode")
            convertor = (c) => `\\u${('000'+c.charCodeAt().toString(16)).slice(-4)}`;
        else if (mode === "soft-unicode")
            convertor = (c) => refAlt[c] || `\\u${('000'+c.charCodeAt().toString(16)).slice(-4)}`;
        else if (mode === "hard-remove")
            convertor = c => "";
        else if (mode === "soft-remove")
            convertor = c => refAlt[c] || "";
        else
            return null;
        for (let c in chars)
            result = result.replaceAll(c, convertor(c));
        return result;
    }

    floCrypto.revertUnicode = function(string) {
        return string.replace(/\\u[\dA-F]{4}/gi,
            m => String.fromCharCode(parseInt(m.replace(/\\u/g, ''), 16)));
    }

})('object' === typeof module ? module.exports : window.floCrypto = {});