MeshCentral/amtscanner.js
2020-04-21 01:50:27 -07:00

409 lines
23 KiB
JavaScript

/**
* @description MeshCentral Intel(R) AMT Local Scanner
* @author Ylian Saint-Hilaire & Joko Sastriawan
* @copyright Intel Corporation 2018-2020
* @license Apache-2.0
* @version v0.0.1
*/
/*jslint node: true */
/*jshint node: true */
/*jshint strict:false */
/*jshint -W097 */
/*jshint esversion: 6 */
"use strict";
// Construct a Intel AMT Scanner object
module.exports.CreateAmtScanner = function (parent) {
var obj = {};
obj.active = false;
obj.parent = parent;
obj.net = require('net');
obj.tls = require('tls');
obj.dns = require('dns');
obj.dgram = require('dgram');
obj.common = require('./common.js');
obj.servers = {};
obj.rserver = {};
obj.rpacket = null;
obj.tagToId = {}; // Tag --> { lastpong: time, id: NodeId }
obj.scanTable = {}; // NodeId --> ScanInfo : { lastping: time, lastpong: time, nodeinfo:{node} }
obj.scanTableTags = {}; // Tag --> ScanInfo
obj.pendingSends = []; // We was to stagger the sends using a 10ms timer
obj.pendingSendTimer = null;
obj.mainTimer = null;
obj.nextTag = 0;
const PeriodicScanTime = 30000; // Interval between scan sweeps
const PeriodicScanTimeout = 65000; // After this time, timeout the device.
const constants = (require('crypto').constants ? require('crypto').constants : require('constants')); // require('constants') is deprecated in Node 11.10, use require('crypto').constants instead.
// Build a RMCP packet with a given tag field
obj.buildRmcpPing = function (tag) {
var packet = Buffer.from(obj.common.hex2rstr('06000006000011BE80000000'), 'ascii');
packet[9] = tag;
return packet;
};
// Start scanning for local network Intel AMT computers
obj.start = function () {
obj.active = true;
obj.performScan();
obj.mainTimer = setInterval(obj.performScan, PeriodicScanTime);
return obj;
};
// Stop scanning for local network Intel AMT computers
obj.stop = function () {
obj.active = false;
for (var i in obj.servers) { obj.servers[i].close(); } // Stop all servers
obj.servers = {};
if (obj.mainTimer != null) { clearInterval(obj.mainTimer); obj.mainTimer = null; }
};
// Scan for Intel AMT computers using network multicast
obj.performRangeScan = function (userid, rangestr) {
if (obj.rpacket == null) { obj.rpacket = obj.buildRmcpPing(0); }
var range = obj.parseIpv4Range(rangestr);
//console.log(obj.IPv4NumToStr(range.min), obj.IPv4NumToStr(range.max));
if (range == null || (range.min > range.max)) return false;
var rangeinfo = { id: userid, range: rangestr, min: range.min, max: range.max, results: {} };
obj.rserver[userid] = rangeinfo;
rangeinfo.server = obj.dgram.createSocket("udp4");
rangeinfo.server.bind(0);
rangeinfo.server.on('error', (err) => { console.log(err); });
rangeinfo.server.on('message', (data, rinfo) => { obj.parseRmcpPacket(data, rinfo, 0, obj.reportMachineState, rangeinfo); });
rangeinfo.server.on('listening', () => {
for (var i = rangeinfo.min; i <= rangeinfo.max; i++) { rangeinfo.server.send(obj.rpacket, 623, obj.IPv4NumToStr(i)); }
});
rangeinfo.timer = setTimeout(function () { // ************************* USER OF OUTER VARS!!!!!!!!!!!!!!!
obj.parent.DispatchEvent(['*', userid], obj, { action: 'scanamtdevice', range: rangeinfo.range, results: rangeinfo.results, nolog: 1 });
rangeinfo.server.close();
delete rangeinfo.server;
}, 3000);
return true;
};
// Parse range, used to parse "ip", "ip/mask" or "ip-ip" notation.
// Return the start and end value of the scan
obj.parseIpv4Range = function (range) {
if (range == undefined || range == null) return null;
var x = range.split('-');
if (x.length == 2) { return { min: obj.parseIpv4Addr(x[0]), max: obj.parseIpv4Addr(x[1]) }; }
x = range.split('/');
if (x.length == 2) {
var ip = obj.parseIpv4Addr(x[0]), masknum = parseInt(x[1]), mask = 0;
if (masknum <= 16 || masknum > 32) return null;
masknum = 32 - masknum;
for (var i = 0; i < masknum; i++) { mask = (mask << 1); mask++; }
return { min: ip & (0xFFFFFFFF - mask), max: (ip & (0xFFFFFFFF - mask)) + mask };
}
x = obj.parseIpv4Addr(range);
if (x == null) return null;
return { min: x, max: x };
};
// Parse IP address. Takes a
obj.parseIpv4Addr = function (addr) {
var x = addr.split('.');
if (x.length == 4) { return (parseInt(x[0]) << 24) + (parseInt(x[1]) << 16) + (parseInt(x[2]) << 8) + (parseInt(x[3]) << 0); }
return null;
};
// IP address number to string
obj.IPv4NumToStr = function (num) {
return ((num >> 24) & 0xFF) + '.' + ((num >> 16) & 0xFF) + '.' + ((num >> 8) & 0xFF) + '.' + (num & 0xFF);
};
/*
// Sample we could use to optimize DNS resolving, may not be needed at all.
obj.BatchResolvePendingMax = 1;
obj.BatchResolvePendingCount = 0;
obj.BatchResolveResults = {};
obj.BatchResolve = function (hostname) {
var r = null;
hostname = hostname.toLowerCase();
if ((hostname == '127.0.0.1') || (hostname == '::1') || (hostname == 'localhost')) return null; // Don't scan localhost
if (obj.net.isIP(hostname) > 0) return hostname; // This is an IP address, already resolved.
if (obj.BatchResolveResults[hostname]) {
if ((obj.BatchResolveResults[hostname].f == 0) || (obj.BatchResolveResults[hostname].f == -1)) {
// Already resolving this one or an error occured during resolve, re-check every 30 minutes.
if (((Date.now() - obj.BatchResolveResults[hostname].t) < 1800000) || (obj.BatchResolvePendingCount >= obj.BatchResolvePendingMax)) { return null; }
} else {
// We are to try to re-resolve every 30 minutes
if (((Date.now() - obj.BatchResolveResults[hostname].t) < 1800000) || (obj.BatchResolvePendingCount >= obj.BatchResolvePendingMax)) { return obj.BatchResolveResults[hostname].a; }
r = obj.BatchResolveResults[hostname].a;
}
}
if (obj.BatchResolvePendingCount >= obj.BatchResolvePendingMax) return null; // Don't resolve more than 10 names at any given time.
console.log('Resolve: ' + hostname);
obj.BatchResolvePendingCount++;
obj.BatchResolveResults[hostname] = { f: 0, t: Date.now() }; // Mark are resolving
obj.dns.lookup(hostname, (err, address, family) => {
obj.BatchResolvePendingCount--;
if (err != null) {
console.log('Resolve error: ' + hostname);
obj.BatchResolveResults[hostname] = { f: -1 }; // Mark this as a resolve error
} else {
console.log('Resolved: %s = %j, family: IPv%s', hostname, address, family);
obj.BatchResolveResults[hostname] = { a: address, f: family, t: Date.now() };
}
});
return r;
};
*/
obj.ResolveName = function (hostname, func) {
if ((hostname == '127.0.0.1') || (hostname == '::1') || (hostname == 'localhost')) { func(hostname, null); } // Don't scan localhost
if (obj.net.isIP(hostname) > 0) { func(hostname, hostname); return; } // This is an IP address, already resolved.
obj.dns.lookup(hostname, function (err, address, family) { if (err == null) { func(hostname, address); } else { func(hostname, null); } });
};
// Look for all Intel AMT computers that may be locally reachable and poll their presence
obj.performScan = function () {
if (obj.active == false) { return false; }
obj.parent.db.getLocalAmtNodes(function (err, docs) { // TODO: handler more than 10 computer scan at the same time. DNS resolved may need to be a seperate module.
for (var i in obj.scanTable) { obj.scanTable[i].present = false; }
if (err == null && docs.length > 0) {
for (var i in docs) {
var doc = docs[i], host = doc.host.toLowerCase();
const ciraConnection = obj.parent.mpsserver ? obj.parent.mpsserver.ciraConnections[doc._id] : null;
if ((host != '127.0.0.1') && (host != '::1') && (host.toLowerCase() != 'localhost') && (ciraConnection == null)) {
var scaninfo = obj.scanTable[doc._id];
if (scaninfo == undefined) {
var tag = obj.nextTag++;
obj.scanTableTags[tag] = obj.scanTable[doc._id] = scaninfo = { nodeinfo: doc, present: true, tag: tag, state: 0 };
//console.log('Scan ' + host + ', state=' + scaninfo.state + ', delta=' + delta);
} else {
scaninfo.present = true;
var delta = Date.now() - scaninfo.lastpong;
//console.log('Rescan ' + host + ', state=' + scaninfo.state + ', delta=' + delta);
if ((scaninfo.state == 1) && (delta >= PeriodicScanTimeout)) {
// More than 2 minutes without a response, mark the node as unknown state
scaninfo.state = 0;
obj.parent.ClearConnectivityState(scaninfo.nodeinfo.meshid, scaninfo.nodeinfo._id, 4); // Clear connectivity state
} else if ((scaninfo.tcp == null) && ((scaninfo.state == 0) || isNaN(delta) || (delta > PeriodicScanTime))) {
// More than 30 seconds without a response, try TCP detection
obj.checkTcpPresence(host, (doc.intelamt.tls == 1) ? 16993 : 16992, scaninfo, function (tag, result, version) {
// TODO: It is bad that "obj" is being accessed within this function.
if (result == false) return;
tag.lastpong = Date.now();
if (tag.state == 0) {
tag.state = 1;
obj.parent.SetConnectivityState(tag.nodeinfo.meshid, tag.nodeinfo._id, tag.lastpong, 4, 7); // Report power state as "present" (7).
if (version != null) { obj.changeAmtState(tag.nodeinfo._id, version, 2, tag.nodeinfo.intelamt.tls); }
}
});
}
}
// Start scanning this node
scaninfo.lastping = Date.now();
obj.checkAmtPresence(host, scaninfo.tag);
}
}
}
for (var i in obj.scanTable) {
if (obj.scanTable[i].present == false) {
// Stop scanning this node
delete obj.scanTableTags[obj.scanTable[i].tag];
delete obj.scanTable[i];
}
}
});
return true;
};
// Check the presense of a specific Intel AMT computer using RMCP
obj.checkAmtPresence = function (host, tag) { obj.ResolveName(host, function (hostname, ip) { obj.checkAmtPresenceEx(ip, tag); }); };
// Check the presense of a specific Intel AMT computer using RMCP
obj.checkAmtPresenceEx = function (host, tag) {
if (host == null) return;
var serverid = Math.floor(tag / 255);
var servertag = (tag % 255);
var packet = obj.buildRmcpPing(servertag);
var server = obj.servers[serverid];
if (server == undefined) {
// Start new server
server = obj.dgram.createSocket('udp4');
server.on('error', (err) => { });
server.on('message', (data, rinfo) => { obj.parseRmcpPacket(data, rinfo, serverid, obj.changeConnectState, null); });
server.on('listening', () => {
obj.pendingSends.push([server, packet, host]);
if (obj.pendingSendTimer == null) { obj.pendingSendTimer = setInterval(obj.sendPendingPacket, 10); }
});
server.bind(0);
obj.servers[serverid] = server;
} else {
// Use existing server
obj.pendingSends.push([server, packet, host]);
if (obj.pendingSendTimer == null) { obj.pendingSendTimer = setInterval(obj.sendPendingPacket, 10); }
}
};
// Send a pending RMCP packet
obj.sendPendingPacket = function () {
try {
var p = obj.pendingSends.shift();
if (p != undefined) {
p[0].send(p[1], 623, p[2]);
p[0].send(p[1], 623, p[2]);
} else {
clearInterval(obj.pendingSendTimer);
obj.pendingSendTimer = null;
}
} catch (e) { }
};
// Parse RMCP packet
obj.parseRmcpPacket = function (data, rinfo, serverid, func, user) {
if (data == null || data.length < 20) return;
if (((data[12] == 0) || (data[13] != 0) || (data[14] != 1) || (data[15] != 0x57)) && (data[21] & 32)) {
var servertag = data[9];
var tag = (serverid * 255) + servertag;
var minorVersion = data[18] & 0x0F;
var majorVersion = (data[18] >> 4) & 0x0F;
var provisioningState = data[19] & 0x03; // Pre = 0, In = 1, Post = 2
var openPort = (data[16] * 256) + data[17];
var dualPorts = ((data[19] & 0x04) != 0) ? true : false;
var openPorts = [openPort];
if (dualPorts == true) { openPorts = [16992, 16993]; }
if (provisioningState <= 2) { func(tag, minorVersion, majorVersion, provisioningState, openPort, dualPorts, rinfo, user); }
}
};
// Use the RMCP packet to change the computer state
obj.changeConnectState = function (tag, minorVersion, majorVersion, provisioningState, openPort, dualPorts, rinfo, user) {
//var provisioningStates = { 0: 'Pre', 1: 'in', 2: 'Post' };
//var provisioningStateStr = provisioningStates[provisioningState];
//console.log('Intel AMT ' + majorVersion + '.' + minorVersion + ', ' + provisioningStateStr + '-Provisioning at ' + rinfo.address + ', Open Ports: [' + openPort + '], tag: ' + tag);
var scaninfo = obj.scanTableTags[tag];
if (scaninfo != undefined) {
scaninfo.lastpong = Date.now();
if (scaninfo.state == 0) {
scaninfo.state = 1;
scaninfo.nodeinfo.intelamt.tls = (((openPort == 16993) || (dualPorts == true)) ? 1 : 0);
scaninfo.nodeinfo.intelamt.ver = majorVersion + '.' + minorVersion;
scaninfo.nodeinfo.intelamt.state = provisioningState;
obj.parent.SetConnectivityState(scaninfo.nodeinfo.meshid, scaninfo.nodeinfo._id, scaninfo.lastpong, 4, 7); // Report power state as "present" (7).
obj.changeAmtState(scaninfo.nodeinfo._id, scaninfo.nodeinfo.intelamt.ver, provisioningState, scaninfo.nodeinfo.intelamt.tls);
}
}
};
// Use the RMCP packet to change the computer state
obj.reportMachineState = function (tag, minorVersion, majorVersion, provisioningState, openPort, dualPorts, rinfo, user) {
//var provisioningStates = { 0: 'Pre', 1: 'in', 2: 'Post' };
//var provisioningStateStr = provisioningStates[provisioningState];
//console.log(rinfo.address + ': Intel AMT ' + majorVersion + '.' + minorVersion + ', ' + provisioningStateStr + '-Provisioning, Open Ports: [' + openPorts.join(', ') + ']');
obj.dns.reverse(rinfo.address, function (err, hostnames) {
if ((err == null) && (hostnames != null) && (hostnames.length > 0)) {
user.results[rinfo.address] = { ver: majorVersion + '.' + minorVersion, tls: (((openPort == 16993) || (dualPorts == true)) ? 1 : 0), state: provisioningState, hostname: hostnames[0], hosttype: 'host' };
} else {
user.results[rinfo.address] = { ver: majorVersion + '.' + minorVersion, tls: (((openPort == 16993) || (dualPorts == true)) ? 1 : 0), state: provisioningState, hostname: rinfo.address, hosttype: 'addr' };
}
});
};
// Change Intel AMT information in the database and event the changes
obj.changeAmtState = function (nodeid, version, provisioningState, tls) {
//console.log('changeAmtState', nodeid, version, provisioningState, tls);
obj.parent.db.Get(nodeid, function (err, nodes) {
if (nodes.length != 1) return;
var node = nodes[0];
// Get the mesh for this device
obj.parent.db.Get(node.meshid, function (err, meshes) {
if (meshes.length != 1) return;
var mesh = meshes[0];
// Ready the node change event
var changes = [], event = { etype: 'node', action: 'changenode', nodeid: node._id };
event.msg = +": ";
// Make the change & save
var change = false;
if (node.intelamt == undefined) { node.intelamt = {}; }
if (node.intelamt.tls != tls) { node.intelamt.tls = tls; change = true; changes.push(tls == 1 ? 'TLS' : 'NoTLS'); }
if (obj.compareAmtVersionStr(node.intelamt.ver, version)) { node.intelamt.ver = version; change = true; changes.push('AMT Version ' + version); }
if (node.intelamt.state != provisioningState) { node.intelamt.state = provisioningState; change = true; changes.push('AMT State'); }
if (change == true) {
// Make the change in the database
obj.parent.db.Set(node);
// Event the node change
event.msg = 'Intel&reg; AMT changed device ' + node.name + ' from mesh ' + mesh.name + ': ' + changes.join(', ');
event.node = obj.parent.webserver.CloneSafeNode(node);
if (obj.parent.db.changeStream) { event.noact = 1; } // If DB change stream is active, don't use this event to change the node. Another event will come.
obj.parent.DispatchEvent(['*', node.meshid], obj, event);
}
});
});
};
// Return true if we should change the Intel AMT version number
obj.compareAmtVersionStr = function (oldVer, newVer) {
if (oldVer == newVer) return false; // Versions are same already, don't update.
if (newVer == undefined || newVer == null) return false; // New version is bad, don't update it.
if (oldVer == undefined || oldVer == null) return true; // Old version is no good anyway, update it.
var oldVerArr = oldVer.split('.');
var newVerArr = newVer.split('.');
if ((oldVerArr.length < 2) || (newVerArr.length < 2)) return false;
if ((oldVerArr[0] != newVerArr[0]) || (oldVerArr[1] != newVerArr[1])) return true;
if (newVerArr.length > oldVerArr.length) return true;
if ((newVerArr.length == 3) && (oldVerArr.length == 3) && (oldVerArr[2] != newVerArr[2])) return true;
return false;
};
// Check the presense of a specific Intel AMT computer using RMCP
obj.checkTcpPresence = function (host, port, scaninfo, func) { obj.ResolveName(host, function (hostname, ip) { obj.checkTcpPresenceEx(ip, port, scaninfo, func); }); };
// Check that we can connect TCP to a given port
obj.checkTcpPresenceEx = function (host, port, scaninfo, func) {
if (host == null) return;
//console.log('checkTcpPresence(' + host + ':' + port + ')');
try {
var client;
if (port == 16992) {
// Connect using TCP
client = new obj.net.Socket();
client.connect(port, host, function () { this.write('GET / HTTP/1.1\r\nhost: ' + host + '\r\n\r\n'); });
} else {
// Connect using TLS, we will switch from default TLS to TLS1-only and back if we get a connection error to support older Intel AMT.
if (scaninfo.tlsoption == null) { scaninfo.tlsoption = 0; }
const tlsOptions = { rejectUnauthorized: false, ciphers: 'RSA+AES:!aNULL:!MD5:!DSS', secureOptions: constants.SSL_OP_NO_SSLv2 | constants.SSL_OP_NO_SSLv3 | constants.SSL_OP_NO_COMPRESSION | constants.SSL_OP_CIPHER_SERVER_PREFERENCE };
if (scaninfo.tlsoption == 1) { tlsOptions.secureProtocol = 'TLSv1_method'; }
client = obj.tls.connect(port, host, tlsOptions, function () { this.write('GET / HTTP/1.1\r\nhost: ' + host + '\r\n\r\n'); });
}
client.scaninfo = scaninfo;
client.func = func;
client.port = port;
client.setTimeout(10000);
client.on('data', function (data) { var version = obj.getIntelAmtVersionFromHeaders(data.toString()); if (this.scaninfo.tcp != null) { delete this.scaninfo.tcp; try { this.destroy(); } catch (ex) { } this.func(this.scaninfo, version != null, version); } });
client.on('error', function () { if (this.scaninfo.tlsoption == 0) { this.scaninfo.tlsoption = 1; } else if (this.scaninfo.tlsoption == 1) { this.scaninfo.tlsoption = 0; } if (this.scaninfo.tcp != null) { delete this.scaninfo.tcp; try { this.destroy(); } catch (ex) { } this.func(this.scaninfo, false); } });
client.on('timeout', function () { if (this.scaninfo.tcp != null) { delete this.scaninfo.tcp; try { this.destroy(); } catch (ex) { } this.func(this.scaninfo, false); } });
client.on('close', function () { if (this.scaninfo.tcp != null) { delete this.scaninfo.tcp; try { this.destroy(); } catch (ex) { } this.func(this.scaninfo, false); } });
client.on('end', function () { if (this.scaninfo.tcp != null) { delete this.scaninfo.tcp; try { this.destroy(); } catch (ex) { } this.func(this.scaninfo, false); } });
scaninfo.tcp = client;
} catch (ex) { console.log(ex); }
};
// Return the Intel AMT version from the HTTP headers. Return null if nothing is found.
obj.getIntelAmtVersionFromHeaders = function (headers) {
if (headers == null || headers.length == 0) return null;
var lines = headers.split('\r\n');
for (var i in lines) {
// Look for the Intel AMT version
if (lines[i].substring(0, 46) == 'Server: Intel(R) Active Management Technology ') {
// We need to check that the Intel AMT version is correct, in the "a.b.c" format
var ver = lines[i].substring(46), splitver = ver.split('.');
if ((splitver.length == 3 || splitver.length == 4) && ('' + parseInt(splitver[0]) === splitver[0]) && ('' + parseInt(splitver[1]) === splitver[1]) && ('' + parseInt(splitver[2]) === splitver[2])) { return (splitver[0] + '.' + splitver[1] + '.' + splitver[2]); }
}
}
return null;
};
//console.log(obj.getIntelAmtVersionFromHeaders("HTTP/1.1 303 See Other\r\nLocation: /logon.htm\r\nContent-Length: 0\r\nServer: Intel(R) Active Management Technology 7.1.91\r\n\r\n"));
return obj;
};