AlkantarClanX12

Your IP : 18.119.167.189


Current Path : /opt/alt/alt-nodejs11/root/lib/node_modules/npm/node_modules.bundled/sshpk/lib/formats/
Upload File :
Current File : //opt/alt/alt-nodejs11/root/lib/node_modules/npm/node_modules.bundled/sshpk/lib/formats/dnssec.js

// Copyright 2017 Joyent, Inc.

module.exports = {
	read: read,
	write: write
};

var assert = require('assert-plus');
var Buffer = require('safer-buffer').Buffer;
var Key = require('../key');
var PrivateKey = require('../private-key');
var utils = require('../utils');
var SSHBuffer = require('../ssh-buffer');
var Dhe = require('../dhe');

var supportedAlgos = {
	'rsa-sha1' : 5,
	'rsa-sha256' : 8,
	'rsa-sha512' : 10,
	'ecdsa-p256-sha256' : 13,
	'ecdsa-p384-sha384' : 14
	/*
	 * ed25519 is hypothetically supported with id 15
	 * but the common tools available don't appear to be
	 * capable of generating/using ed25519 keys
	 */
};

var supportedAlgosById = {};
Object.keys(supportedAlgos).forEach(function (k) {
	supportedAlgosById[supportedAlgos[k]] = k.toUpperCase();
});

function read(buf, options) {
	if (typeof (buf) !== 'string') {
		assert.buffer(buf, 'buf');
		buf = buf.toString('ascii');
	}
	var lines = buf.split('\n');
	if (lines[0].match(/^Private-key-format\: v1/)) {
		var algElems = lines[1].split(' ');
		var algoNum = parseInt(algElems[1], 10);
		var algoName = algElems[2];
		if (!supportedAlgosById[algoNum])
			throw (new Error('Unsupported algorithm: ' + algoName));
		return (readDNSSECPrivateKey(algoNum, lines.slice(2)));
	}

	// skip any comment-lines
	var line = 0;
	/* JSSTYLED */
	while (lines[line].match(/^\;/))
		line++;
	// we should now have *one single* line left with our KEY on it.
	if ((lines[line].match(/\. IN KEY /) ||
	    lines[line].match(/\. IN DNSKEY /)) && lines[line+1].length === 0) {
		return (readRFC3110(lines[line]));
	}
	throw (new Error('Cannot parse dnssec key'));
}

function readRFC3110(keyString) {
	var elems = keyString.split(' ');
	//unused var flags = parseInt(elems[3], 10);
	//unused var protocol = parseInt(elems[4], 10);
	var algorithm = parseInt(elems[5], 10);
	if (!supportedAlgosById[algorithm])
		throw (new Error('Unsupported algorithm: ' + algorithm));
	var base64key = elems.slice(6, elems.length).join();
	var keyBuffer = Buffer.from(base64key, 'base64');
	if (supportedAlgosById[algorithm].match(/^RSA-/)) {
		// join the rest of the body into a single base64-blob
		var publicExponentLen = keyBuffer.readUInt8(0);
		if (publicExponentLen != 3 && publicExponentLen != 1)
			throw (new Error('Cannot parse dnssec key: ' +
			    'unsupported exponent length'));

		var publicExponent = keyBuffer.slice(1, publicExponentLen+1);
		publicExponent = utils.mpNormalize(publicExponent);
		var modulus = keyBuffer.slice(1+publicExponentLen);
		modulus = utils.mpNormalize(modulus);
		// now, make the key
		var rsaKey = {
			type: 'rsa',
			parts: []
		};
		rsaKey.parts.push({ name: 'e', data: publicExponent});
		rsaKey.parts.push({ name: 'n', data: modulus});
		return (new Key(rsaKey));
	}
	if (supportedAlgosById[algorithm] === 'ECDSA-P384-SHA384' ||
	    supportedAlgosById[algorithm] === 'ECDSA-P256-SHA256') {
		var curve = 'nistp384';
		var size = 384;
		if (supportedAlgosById[algorithm].match(/^ECDSA-P256-SHA256/)) {
			curve = 'nistp256';
			size = 256;
		}

		var ecdsaKey = {
			type: 'ecdsa',
			curve: curve,
			size: size,
			parts: [
				{name: 'curve', data: Buffer.from(curve) },
				{name: 'Q', data: utils.ecNormalize(keyBuffer) }
			]
		};
		return (new Key(ecdsaKey));
	}
	throw (new Error('Unsupported algorithm: ' +
	    supportedAlgosById[algorithm]));
}

function elementToBuf(e) {
	return (Buffer.from(e.split(' ')[1], 'base64'));
}

function readDNSSECRSAPrivateKey(elements) {
	var rsaParams = {};
	elements.forEach(function (element) {
		if (element.split(' ')[0] === 'Modulus:')
			rsaParams['n'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'PublicExponent:')
			rsaParams['e'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'PrivateExponent:')
			rsaParams['d'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'Prime1:')
			rsaParams['p'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'Prime2:')
			rsaParams['q'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'Exponent1:')
			rsaParams['dmodp'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'Exponent2:')
			rsaParams['dmodq'] = elementToBuf(element);
		else if (element.split(' ')[0] === 'Coefficient:')
			rsaParams['iqmp'] = elementToBuf(element);
	});
	// now, make the key
	var key = {
		type: 'rsa',
		parts: [
			{ name: 'e', data: utils.mpNormalize(rsaParams['e'])},
			{ name: 'n', data: utils.mpNormalize(rsaParams['n'])},
			{ name: 'd', data: utils.mpNormalize(rsaParams['d'])},
			{ name: 'p', data: utils.mpNormalize(rsaParams['p'])},
			{ name: 'q', data: utils.mpNormalize(rsaParams['q'])},
			{ name: 'dmodp',
			    data: utils.mpNormalize(rsaParams['dmodp'])},
			{ name: 'dmodq',
			    data: utils.mpNormalize(rsaParams['dmodq'])},
			{ name: 'iqmp',
			    data: utils.mpNormalize(rsaParams['iqmp'])}
		]
	};
	return (new PrivateKey(key));
}

function readDNSSECPrivateKey(alg, elements) {
	if (supportedAlgosById[alg].match(/^RSA-/)) {
		return (readDNSSECRSAPrivateKey(elements));
	}
	if (supportedAlgosById[alg] === 'ECDSA-P384-SHA384' ||
	    supportedAlgosById[alg] === 'ECDSA-P256-SHA256') {
		var d = Buffer.from(elements[0].split(' ')[1], 'base64');
		var curve = 'nistp384';
		var size = 384;
		if (supportedAlgosById[alg] === 'ECDSA-P256-SHA256') {
			curve = 'nistp256';
			size = 256;
		}
		// DNSSEC generates the public-key on the fly (go calculate it)
		var publicKey = utils.publicFromPrivateECDSA(curve, d);
		var Q = publicKey.part['Q'].data;
		var ecdsaKey = {
			type: 'ecdsa',
			curve: curve,
			size: size,
			parts: [
				{name: 'curve', data: Buffer.from(curve) },
				{name: 'd', data: d },
				{name: 'Q', data: Q }
			]
		};
		return (new PrivateKey(ecdsaKey));
	}
	throw (new Error('Unsupported algorithm: ' + supportedAlgosById[alg]));
}

function dnssecTimestamp(date) {
	var year = date.getFullYear() + ''; //stringify
	var month = (date.getMonth() + 1);
	var timestampStr = year + month + date.getUTCDate();
	timestampStr += '' + date.getUTCHours() + date.getUTCMinutes();
	timestampStr += date.getUTCSeconds();
	return (timestampStr);
}

function rsaAlgFromOptions(opts) {
	if (!opts || !opts.hashAlgo || opts.hashAlgo === 'sha1')
		return ('5 (RSASHA1)');
	else if (opts.hashAlgo === 'sha256')
		return ('8 (RSASHA256)');
	else if (opts.hashAlgo === 'sha512')
		return ('10 (RSASHA512)');
	else
		throw (new Error('Unknown or unsupported hash: ' +
		    opts.hashAlgo));
}

function writeRSA(key, options) {
	// if we're missing parts, add them.
	if (!key.part.dmodp || !key.part.dmodq) {
		utils.addRSAMissing(key);
	}

	var out = '';
	out += 'Private-key-format: v1.3\n';
	out += 'Algorithm: ' + rsaAlgFromOptions(options) + '\n';
	var n = utils.mpDenormalize(key.part['n'].data);
	out += 'Modulus: ' + n.toString('base64') + '\n';
	var e = utils.mpDenormalize(key.part['e'].data);
	out += 'PublicExponent: ' + e.toString('base64') + '\n';
	var d = utils.mpDenormalize(key.part['d'].data);
	out += 'PrivateExponent: ' + d.toString('base64') + '\n';
	var p = utils.mpDenormalize(key.part['p'].data);
	out += 'Prime1: ' + p.toString('base64') + '\n';
	var q = utils.mpDenormalize(key.part['q'].data);
	out += 'Prime2: ' + q.toString('base64') + '\n';
	var dmodp = utils.mpDenormalize(key.part['dmodp'].data);
	out += 'Exponent1: ' + dmodp.toString('base64') + '\n';
	var dmodq = utils.mpDenormalize(key.part['dmodq'].data);
	out += 'Exponent2: ' + dmodq.toString('base64') + '\n';
	var iqmp = utils.mpDenormalize(key.part['iqmp'].data);
	out += 'Coefficient: ' + iqmp.toString('base64') + '\n';
	// Assume that we're valid as-of now
	var timestamp = new Date();
	out += 'Created: ' + dnssecTimestamp(timestamp) + '\n';
	out += 'Publish: ' + dnssecTimestamp(timestamp) + '\n';
	out += 'Activate: ' + dnssecTimestamp(timestamp) + '\n';
	return (Buffer.from(out, 'ascii'));
}

function writeECDSA(key, options) {
	var out = '';
	out += 'Private-key-format: v1.3\n';

	if (key.curve === 'nistp256') {
		out += 'Algorithm: 13 (ECDSAP256SHA256)\n';
	} else if (key.curve === 'nistp384') {
		out += 'Algorithm: 14 (ECDSAP384SHA384)\n';
	} else {
		throw (new Error('Unsupported curve'));
	}
	var base64Key = key.part['d'].data.toString('base64');
	out += 'PrivateKey: ' + base64Key + '\n';

	// Assume that we're valid as-of now
	var timestamp = new Date();
	out += 'Created: ' + dnssecTimestamp(timestamp) + '\n';
	out += 'Publish: ' + dnssecTimestamp(timestamp) + '\n';
	out += 'Activate: ' + dnssecTimestamp(timestamp) + '\n';

	return (Buffer.from(out, 'ascii'));
}

function write(key, options) {
	if (PrivateKey.isPrivateKey(key)) {
		if (key.type === 'rsa') {
			return (writeRSA(key, options));
		} else if (key.type === 'ecdsa') {
			return (writeECDSA(key, options));
		} else {
			throw (new Error('Unsupported algorithm: ' + key.type));
		}
	} else if (Key.isKey(key)) {
		/*
		 * RFC3110 requires a keyname, and a keytype, which we
		 * don't really have a mechanism for specifying such
		 * additional metadata.
		 */
		throw (new Error('Format "dnssec" only supports ' +
		    'writing private keys'));
	} else {
		throw (new Error('key is not a Key or PrivateKey'));
	}
}