MeshCentral/authenticode.js

2077 lines
118 KiB
JavaScript

/**
* @description Authenticode parsing
* @author Ylian Saint-Hilaire & Bryan Roe
* @copyright Intel Corporation 2018-2022
* @license Apache-2.0
* @version v0.0.1
*/
/*jslint node: true */
/*jshint node: true */
/*jshint strict:false */
/*jshint -W097 */
/*jshint esversion: 6 */
"use strict";
const fs = require('fs');
const crypto = require('crypto');
const forge = require('node-forge');
const pki = forge.pki;
const p7 = require('./pkcs7-modified');
// Generate a test self-signed certificate with code signing extension
function createSelfSignedCert(args) {
var keys = pki.rsa.generateKeyPair(2048);
var cert = pki.createCertificate();
cert.publicKey = keys.publicKey;
cert.serialNumber = (typeof args.serial == 'string')?args.serial:'012345'; // Serial number must always have a single leading '0', otherwise toPEM/fromPEM will not work right.
cert.validity.notBefore = new Date();
cert.validity.notAfter = new Date();
cert.validity.notAfter.setFullYear(cert.validity.notBefore.getFullYear() + 10);
var attrs = [];
if (typeof args.cn == 'string') { attrs.push({ name: 'commonName', value: args.cn }); }
if (typeof args.country == 'string') { attrs.push({ name: 'countryName', value: args.country }); }
if (typeof args.state == 'string') { attrs.push({ name: 'ST', value: args.state }); }
if (typeof args.locality == 'string') { attrs.push({ name: 'localityName', value: args.locality }); }
if (typeof args.org == 'string') { attrs.push({ name: 'organizationName', value: args.org }); }
if (typeof args.orgunit == 'string') { attrs.push({ name: 'OU', value: args.orgunit }); }
cert.setSubject(attrs);
cert.setIssuer(attrs);
cert.setExtensions([{ name: 'basicConstraints', cA: false }, { name: 'keyUsage', keyCertSign: false, digitalSignature: true, nonRepudiation: false, keyEncipherment: false, dataEncipherment: false }, { name: 'extKeyUsage', codeSigning: true }, { name: "subjectKeyIdentifier" }]);
cert.sign(keys.privateKey, forge.md.sha384.create());
return { cert: cert, key: keys.privateKey, extraCerts: [] };
}
// Create the output filename if not already specified
function createOutFile(args, filename) {
if (typeof args.out == 'string') return;
var outputFileName = filename.split('.');
outputFileName[outputFileName.length - 2] += '-out';
args.out = outputFileName.join('.');
}
// Load certificates and private key from PEM files
function loadCertificates(pemFileNames) {
var certs = [], keys = [];
if (pemFileNames == null) return;
if (typeof pemFileNames == 'string') { pemFileNames = [pemFileNames]; }
for (var i in pemFileNames) {
try {
// Read certificate
var pem = fs.readFileSync(pemFileNames[i]).toString();
var pemCerts = pem.split('-----BEGIN CERTIFICATE-----');
for (var j in pemCerts) {
var k = pemCerts[j].indexOf('-----END CERTIFICATE-----');
if (k >= 0) { certs.push(pki.certificateFromPem('-----BEGIN CERTIFICATE-----' + pemCerts[j].substring(0, k) + '-----END CERTIFICATE-----')); }
}
var PemKeys = pem.split('-----BEGIN RSA PRIVATE KEY-----');
for (var j in PemKeys) {
var k = PemKeys[j].indexOf('-----END RSA PRIVATE KEY-----');
if (k >= 0) { keys.push(pki.privateKeyFromPem('-----BEGIN RSA PRIVATE KEY-----' + PemKeys[j].substring(0, k) + '-----END RSA PRIVATE KEY-----')); }
}
PemKeys = pem.split('-----BEGIN PRIVATE KEY-----');
for (var j in PemKeys) {
var k = PemKeys[j].indexOf('-----END PRIVATE KEY-----');
if (k >= 0) { keys.push(pki.privateKeyFromPem('-----BEGIN PRIVATE KEY-----' + PemKeys[j].substring(0, k) + '-----END PRIVATE KEY-----')); }
}
} catch (ex) { }
}
if ((certs.length == 0) || (keys.length != 1)) return; // No certificates or private keys
var r = { cert: certs[0], key: keys[0], extraCerts: [] }
if (certs.length > 1) { for (var i = 1; i < certs.length; i++) { r.extraCerts.push(certs[i]); } }
return r;
}
function createAuthenticodeHandler(path) {
const obj = {};
obj.header = { path: path }
// Read a file slice
function readFileSlice(start, length) {
var buffer = Buffer.alloc(length);
var len = fs.readSync(obj.fd, buffer, 0, buffer.length, start);
if (len < buffer.length) { buffer = buffer.slice(0, len); }
return buffer;
}
// Close the file
obj.close = function () {
if (obj.fd == null) return;
fs.closeSync(obj.fd);
delete obj.fd;
}
// Private OIDS
obj.Oids = {
SPC_INDIRECT_DATA_OBJID: '1.3.6.1.4.1.311.2.1.4',
SPC_STATEMENT_TYPE_OBJID: '1.3.6.1.4.1.311.2.1.11',
SPC_SP_OPUS_INFO_OBJID: '1.3.6.1.4.1.311.2.1.12',
SPC_INDIVIDUAL_SP_KEY_PURPOSE_OBJID: '1.3.6.1.4.1.311.2.1.21',
SPC_COMMERCIAL_SP_KEY_PURPOSE_OBJID: '1.3.6.1.4.1.311.2.1.22',
SPC_MS_JAVA_SOMETHING: '1.3.6.1.4.1.311.15.1',
SPC_PE_IMAGE_DATA_OBJID: '1.3.6.1.4.1.311.2.1.15',
SPC_CAB_DATA_OBJID: '1.3.6.1.4.1.311.2.1.25',
SPC_TIME_STAMP_REQUEST_OBJID: '1.3.6.1.4.1.311.3.2.1',
SPC_SIPINFO_OBJID: '1.3.6.1.4.1.311.2.1.30',
SPC_PE_IMAGE_PAGE_HASHES_V1: '1.3.6.1.4.1.311.2.3.1',
SPC_PE_IMAGE_PAGE_HASHES_V2: '1.3.6.1.4.1.311.2.3.2',
SPC_NESTED_SIGNATURE_OBJID: '1.3.6.1.4.1.311.2.4.1',
SPC_RFC3161_OBJID: '1.3.6.1.4.1.311.3.3.1'
}
// Open the file and read header information
function openFile() {
if (obj.fd != null) return true;
// Open the file descriptor
obj.path = path;
try { obj.fd = fs.openSync(path, 'r'); } catch (ex) { return false; } // Unable to open file
obj.stats = fs.fstatSync(obj.fd);
obj.filesize = obj.stats.size;
if (obj.filesize < 64) { obj.close(); return false; } // File too short.
// Read the DOS header (64 bytes)
var buf = readFileSlice(60, 4);
obj.header.peHeaderLocation = buf.readUInt32LE(0); // The DOS header is 64 bytes long, the last 4 bytes are a pointer to the PE header.
obj.header.peOptionalHeaderLocation = obj.header.peHeaderLocation + 24; // The PE optional header is located just after the PE header which is 24 bytes long.
// Check file size and signature
if (obj.filesize < (160 + obj.header.peHeaderLocation)) { obj.close(); return false; } // Invalid SizeOfHeaders.
if (readFileSlice(obj.header.peHeaderLocation, 4).toString('hex') != '50450000') { obj.close(); return false; } // Invalid PE header, must start with "PE" (HEX: 50 45 00 00).
// Read the COFF header
// https://docs.microsoft.com/en-us/windows/win32/debug/pe-format#coff-file-header-object-and-image
var coffHeader = readFileSlice(obj.header.peHeaderLocation + 4, 20)
obj.header.coff = {};
obj.header.coff.machine = coffHeader.readUInt16LE(0);
obj.header.coff.numberOfSections = coffHeader.readUInt16LE(2);
obj.header.coff.timeDateStamp = coffHeader.readUInt32LE(4);
obj.header.coff.pointerToSymbolTable = coffHeader.readUInt32LE(8);
obj.header.coff.numberOfSymbols = coffHeader.readUInt32LE(12);
obj.header.coff.sizeOfOptionalHeader = coffHeader.readUInt16LE(16);
obj.header.coff.characteristics = coffHeader.readUInt16LE(18);
// Read the entire PE optional header
var optinalHeader = readFileSlice(obj.header.peOptionalHeaderLocation, obj.header.coff.sizeOfOptionalHeader);
// Decode the PE optional header standard fields
// https://docs.microsoft.com/en-us/windows/win32/debug/pe-format#optional-header-standard-fields-image-only
obj.header.peStandard = {};
obj.header.peStandard.magic = optinalHeader.readUInt16LE(0);
switch (obj.header.peStandard.magic) { // Check magic value
case 0x020B: obj.header.pe32plus = 1; break;
case 0x010B: obj.header.pe32plus = 0; break;
default: { obj.close(); return false; } // Invalid Magic in PE
}
obj.header.peStandard.majorLinkerVersion = optinalHeader[2];
obj.header.peStandard.minorLinkerVersion = optinalHeader[3];
obj.header.peStandard.sizeOfCode = optinalHeader.readUInt32LE(4);
obj.header.peStandard.sizeOfInitializedData = optinalHeader.readUInt32LE(8);
obj.header.peStandard.sizeOfUninitializedData = optinalHeader.readUInt32LE(12);
obj.header.peStandard.addressOfEntryPoint = optinalHeader.readUInt32LE(16);
obj.header.peStandard.baseOfCode = optinalHeader.readUInt32LE(20);
if (obj.header.pe32plus == 0) { obj.header.peStandard.baseOfData = optinalHeader.readUInt32LE(24); }
// Decode the PE optional header windows fields
// https://docs.microsoft.com/en-us/windows/win32/debug/pe-format#optional-header-windows-specific-fields-image-only
obj.header.peWindows = {}
if (obj.header.pe32plus == 0) {
// 32bit header
//obj.header.peWindows.imageBase = optinalHeader.readUInt32LE(28);
obj.header.peWindows.sectionAlignment = optinalHeader.readUInt32LE(32);
obj.header.peWindows.fileAlignment = optinalHeader.readUInt32LE(36);
obj.header.peWindows.majorOperatingSystemVersion = optinalHeader.readUInt16LE(40);
obj.header.peWindows.minorOperatingSystemVersion = optinalHeader.readUInt16LE(42);
obj.header.peWindows.majorImageVersion = optinalHeader.readUInt16LE(44);
obj.header.peWindows.minorImageVersion = optinalHeader.readUInt16LE(46);
obj.header.peWindows.majorSubsystemVersion = optinalHeader.readUInt16LE(48);
obj.header.peWindows.minorSubsystemVersion = optinalHeader.readUInt16LE(50);
obj.header.peWindows.win32VersionValue = optinalHeader.readUInt32LE(52);
obj.header.peWindows.sizeOfImage = optinalHeader.readUInt32LE(56);
obj.header.peWindows.sizeOfHeaders = optinalHeader.readUInt32LE(60);
obj.header.peWindows.checkSum = optinalHeader.readUInt32LE(64);
obj.header.peWindows.subsystem = optinalHeader.readUInt16LE(68);
obj.header.peWindows.dllCharacteristics = optinalHeader.readUInt16LE(70);
//obj.header.peWindows.sizeOfStackReserve = optinalHeader.readUInt32LE(72);
//obj.header.peWindows.sizeOfStackCommit = optinalHeader.readUInt32LE(76);
//obj.header.peWindows.sizeOfHeapReserve = optinalHeader.readUInt32LE(80);
//obj.header.peWindows.sizeOfHeapCommit = optinalHeader.readUInt32LE(84);
obj.header.peWindows.loaderFlags = optinalHeader.readUInt32LE(88);
obj.header.peWindows.numberOfRvaAndSizes = optinalHeader.readUInt32LE(92);
} else {
// 64bit header
//obj.header.peWindows.imageBase = optinalHeader.readBigUInt64LE(24); // TODO: readBigUInt64LE is not supported in older NodeJS versions
obj.header.peWindows.sectionAlignment = optinalHeader.readUInt32LE(32);
obj.header.peWindows.fileAlignment = optinalHeader.readUInt32LE(36);
obj.header.peWindows.majorOperatingSystemVersion = optinalHeader.readUInt16LE(40);
obj.header.peWindows.minorOperatingSystemVersion = optinalHeader.readUInt16LE(42);
obj.header.peWindows.majorImageVersion = optinalHeader.readUInt16LE(44);
obj.header.peWindows.minorImageVersion = optinalHeader.readUInt16LE(46);
obj.header.peWindows.majorSubsystemVersion = optinalHeader.readUInt16LE(48);
obj.header.peWindows.minorSubsystemVersion = optinalHeader.readUInt16LE(50);
obj.header.peWindows.win32VersionValue = optinalHeader.readUInt32LE(52);
obj.header.peWindows.sizeOfImage = optinalHeader.readUInt32LE(56);
obj.header.peWindows.sizeOfHeaders = optinalHeader.readUInt32LE(60);
obj.header.peWindows.checkSum = optinalHeader.readUInt32LE(64);
obj.header.peWindows.subsystem = optinalHeader.readUInt16LE(68);
obj.header.peWindows.dllCharacteristics = optinalHeader.readUInt16LE(70);
//obj.header.peWindows.sizeOfStackReserve = optinalHeader.readBigUInt64LE(72);
//obj.header.peWindows.sizeOfStackCommit = optinalHeader.readBigUInt64LE(80);
//obj.header.peWindows.sizeOfHeapReserve = optinalHeader.readBigUInt64LE(88);
//obj.header.peWindows.sizeOfHeapCommit = optinalHeader.readBigUInt64LE(96);
obj.header.peWindows.loaderFlags = optinalHeader.readUInt32LE(104);
obj.header.peWindows.numberOfRvaAndSizes = optinalHeader.readUInt32LE(108);
}
// Decode the PE optional header data directories
// https://docs.microsoft.com/en-us/windows/win32/debug/pe-format#optional-header-data-directories-image-only
obj.header.dataDirectories = {}
const pePlusOffset = (obj.header.pe32plus == 0) ? 0 : 16; // This header is the same for 32 and 64 bit, but 64bit is offset by 16 bytes.
obj.header.dataDirectories.exportTable = { addr: optinalHeader.readUInt32LE(96 + pePlusOffset), size: optinalHeader.readUInt32LE(100 + pePlusOffset) };
obj.header.dataDirectories.importTable = { addr: optinalHeader.readUInt32LE(104 + pePlusOffset), size: optinalHeader.readUInt32LE(108 + pePlusOffset) };
obj.header.dataDirectories.resourceTable = { addr: optinalHeader.readUInt32LE(112 + pePlusOffset), size: optinalHeader.readUInt32LE(116 + pePlusOffset) }; // Same as .rsrc virtual address & size
obj.header.dataDirectories.exceptionTableAddr = { addr: optinalHeader.readUInt32LE(120 + pePlusOffset), size: optinalHeader.readUInt32LE(124 + pePlusOffset) }; // Same as .pdata virtual address & size
obj.header.dataDirectories.certificateTable = { addr: optinalHeader.readUInt32LE(128 + pePlusOffset), size: optinalHeader.readUInt32LE(132 + pePlusOffset) };
obj.header.dataDirectories.baseRelocationTable = { addr: optinalHeader.readUInt32LE(136 + pePlusOffset), size: optinalHeader.readUInt32LE(140 + pePlusOffset) }; // Same as .reloc virtual address & size
obj.header.dataDirectories.debug = { addr: optinalHeader.readUInt32LE(144 + pePlusOffset), size: optinalHeader.readUInt32LE(148 + pePlusOffset) };
// obj.header.dataDirectories.architecture = optinalHeader.readBigUInt64LE(152 + pePlusOffset); // Must be zero
obj.header.dataDirectories.globalPtr = { addr: optinalHeader.readUInt32LE(160 + pePlusOffset), size: optinalHeader.readUInt32LE(164 + pePlusOffset) };
obj.header.dataDirectories.tLSTable = { addr: optinalHeader.readUInt32LE(168 + pePlusOffset), size: optinalHeader.readUInt32LE(172 + pePlusOffset) };
obj.header.dataDirectories.loadConfigTable = { addr: optinalHeader.readUInt32LE(176 + pePlusOffset), size: optinalHeader.readUInt32LE(180 + pePlusOffset) };
obj.header.dataDirectories.boundImport = { addr: optinalHeader.readUInt32LE(184 + pePlusOffset), size: optinalHeader.readUInt32LE(188 + pePlusOffset) };
obj.header.dataDirectories.iAT = { addr: optinalHeader.readUInt32LE(192 + pePlusOffset), size: optinalHeader.readUInt32LE(196 + pePlusOffset) };
obj.header.dataDirectories.delayImportDescriptor = { addr: optinalHeader.readUInt32LE(200 + pePlusOffset), size: optinalHeader.readUInt32LE(204 + pePlusOffset) };
obj.header.dataDirectories.clrRuntimeHeader = { addr: optinalHeader.readUInt32LE(208 + pePlusOffset), size: optinalHeader.readUInt32LE(212 + pePlusOffset) };
// obj.header.dataDirectories.reserved = optinalHeader.readBigUInt64LE(216 + pePlusOffset); // Must be zero
// Get the certificate table location and size
obj.header.sigpos = obj.header.dataDirectories.certificateTable.addr;
obj.header.siglen = obj.header.dataDirectories.certificateTable.size
obj.header.signed = ((obj.header.sigpos != 0) && (obj.header.siglen != 0));
// The section headers are located after the optional PE header
obj.header.SectionHeadersPtr = obj.header.peOptionalHeaderLocation + obj.header.coff.sizeOfOptionalHeader;
// Read the sections
obj.header.sections = {};
for (var i = 0; i < obj.header.coff.numberOfSections; i++) {
var section = {};
buf = readFileSlice(obj.header.SectionHeadersPtr + (i * 40), 40);
if (buf[0] != 46) { obj.close(); return false; }; // Name of the section must start with a dot. If not, something is wrong.
var sectionName = buf.slice(0, 8).toString().trim('\0');
var j = sectionName.indexOf('\0');
if (j >= 0) { sectionName = sectionName.substring(0, j); } // Trim any trailing zeroes
section.ptr = obj.header.SectionHeadersPtr + (i * 40);
section.virtualSize = buf.readUInt32LE(8);
section.virtualAddr = buf.readUInt32LE(12);
section.rawSize = buf.readUInt32LE(16);
section.rawAddr = buf.readUInt32LE(20);
section.relocAddr = buf.readUInt32LE(24);
section.lineNumbers = buf.readUInt32LE(28);
section.relocNumber = buf.readUInt16LE(32);
section.lineNumbersNumber = buf.readUInt16LE(34);
section.characteristics = buf.readUInt32LE(36);
obj.header.sections[sectionName] = section;
}
// Compute the checkSum value for this file
obj.header.peWindows.checkSumActual = runChecksum();
// If there is a .rsrc section, read the resource information and locations
if (obj.header.sections['.rsrc'] != null) {
obj.resources = readResourceTable(obj.header.sections['.rsrc'].rawAddr, 0); // Read all resources recursively
}
if (obj.header.signed) {
// Read signature block
// Check if the file size allows for the signature block
if (obj.filesize < (obj.header.sigpos + obj.header.siglen)) { obj.close(); return false; } // Executable file too short to contain the signature block.
// Remove the padding if needed
var i, pkcs7raw = readFileSlice(obj.header.sigpos + 8, obj.header.siglen - 8);
var derlen = forge.asn1.getBerValueLength(forge.util.createBuffer(pkcs7raw.slice(1, 5))) + 4;
if (derlen != pkcs7raw.length) { pkcs7raw = pkcs7raw.slice(0, derlen); }
// Decode the signature block and check that it's valid
var pkcs7der = null, valid = false;
try { pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(pkcs7raw)); } catch (ex) { }
try { valid = ((pkcs7der != null) && (forge.asn1.derToOid(pkcs7der.value[1].value[0].value[2].value[0].value) == "1.3.6.1.4.1.311.2.1.4")); } catch (ex) { }
if (pkcs7der == null) {
// Can't decode the signature
obj.header.sigpos = 0;
obj.header.siglen = 0;
obj.header.signed = false;
} else {
// To work around ForgeJS PKCS#7 limitation, this may break PKCS7 verify if ForgeJS adds support for it in the future
// Switch content type from "1.3.6.1.4.1.311.2.1.4" to "1.2.840.113549.1.7.1"
pkcs7der.value[1].value[0].value[2].value[0].value = forge.asn1.oidToDer(forge.pki.oids.data).data;
// Decode the PKCS7 message
var pkcs7 = null, pkcs7content = null;
try {
pkcs7 = p7.messageFromAsn1(pkcs7der);
pkcs7content = pkcs7.rawCapture.content.value[0];
} catch (ex) { }
if ((pkcs7 == null) || (pkcs7content == null)) {
// Can't decode the signature
obj.header.sigpos = 0;
obj.header.siglen = 0;
obj.header.signed = false;
} else {
// Verify a PKCS#7 signature
// Verify is not currently supported in node-forge, but if implemented in the future, this code could work.
//var caStore = forge.pki.createCaStore();
//for (var i in obj.certificates) { caStore.addCertificate(obj.certificates[i]); }
// Return is true if all signatures are valid and chain up to a provided CA
//if (!pkcs7.verify(caStore)) { throw ('Executable file has an invalid signature.'); }
// Get the signing attributes
obj.signingAttribs = [];
try {
for (var i in pkcs7.rawCapture.authenticatedAttributes) {
if (
(pkcs7.rawCapture.authenticatedAttributes[i].value != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[0] != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[0].value != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1] != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0] != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value != null) &&
(forge.asn1.derToOid(pkcs7.rawCapture.authenticatedAttributes[i].value[0].value) == obj.Oids.SPC_SP_OPUS_INFO_OBJID)) {
for (var j in pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value) {
if (
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value[j] != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value[j].value != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value[j].value[0] != null) &&
(pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value[j].value[0].value != null)
) {
var v = pkcs7.rawCapture.authenticatedAttributes[i].value[1].value[0].value[j].value[0].value;
if (v.startsWith('http://') || v.startsWith('https://') || ((v.length % 2) == 1)) { obj.signingAttribs.push(v); } else {
var r = ''; // This string value is in UCS2 format, convert it to a normal string.
for (var k = 0; k < v.length; k += 2) { r += String.fromCharCode((v.charCodeAt(k + 8) << 8) + v.charCodeAt(k + 1)); }
obj.signingAttribs.push(r);
}
}
}
}
}
} catch (ex) { }
// Set the certificate chain
obj.certificates = pkcs7.certificates;
// Set the signature
obj.signature = Buffer.from(pkcs7.rawCapture.signature, 'binary');
// Get the file hashing algorithm
var hashAlgoOid = forge.asn1.derToOid(pkcs7content.value[1].value[0].value[0].value);
switch (hashAlgoOid) {
case forge.pki.oids.sha256: { obj.fileHashAlgo = 'sha256'; break; }
case forge.pki.oids.sha384: { obj.fileHashAlgo = 'sha384'; break; }
case forge.pki.oids.sha512: { obj.fileHashAlgo = 'sha512'; break; }
case forge.pki.oids.sha224: { obj.fileHashAlgo = 'sha224'; break; }
case forge.pki.oids.md5: { obj.fileHashAlgo = 'md5'; break; }
}
// Get the signed file hash
obj.fileHashSigned = Buffer.from(pkcs7content.value[1].value[1].value, 'binary')
// Compute the actual file hash
if (obj.fileHashAlgo != null) { obj.fileHashActual = obj.getHash(obj.fileHashAlgo); }
}
}
}
return true;
}
// Make a timestamp signature request
obj.timeStampRequest = function (args, func) {
// Create the timestamp request in DER format
const asn1 = forge.asn1;
const pkcs7dataOid = asn1.oidToDer('1.2.840.113549.1.7.1').data;
const microsoftCodeSigningOid = asn1.oidToDer('1.3.6.1.4.1.311.3.2.1').data;
const asn1obj =
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, microsoftCodeSigningOid),
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, pkcs7dataOid),
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 0, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OCTETSTRING, false, obj.signature.toString('binary')) // Signature here
])
])
]);
// Serialize an ASN.1 object to DER format in Base64
const requestBody = Buffer.from(asn1.toDer(asn1obj).data, 'binary').toString('base64');
// Make an HTTP request
const options = { url: args.time, proxy: args.proxy };
// Make a request to the time server
httpRequest(options, requestBody, function (err, data) {
if (err != null) { func(err); return; }
// Decode the timestamp signature block
var timepkcs7der = null;
try { timepkcs7der = forge.asn1.fromDer(forge.util.createBuffer(Buffer.from(data, 'base64').toString('binary'))); } catch (ex) { func("Unable to parse time-stamp response: " + ex); return; }
// Decode the executable signature block
var pkcs7der = null;
try {
var pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(Buffer.from(obj.getRawSignatureBlock(), 'base64').toString('binary')));
// Get the ASN1 certificates used to sign the timestamp and add them to the certs in the PKCS7 of the executable
// TODO: We could look to see if the certificate is already present in the executable
const timeasn1Certs = timepkcs7der.value[1].value[0].value[3].value;
for (var i in timeasn1Certs) { pkcs7der.value[1].value[0].value[3].value.push(timeasn1Certs[i]); }
// Remove any existing time stamp signatures
var newValues = [];
for (var i in pkcs7der.value[1].value[0].value[4].value[0].value) {
const j = pkcs7der.value[1].value[0].value[4].value[0].value[i];
if ((j.tagClass != 128) || (j.type != 1)) { newValues.push(j); } // If this is not a time stamp, add it to out new list.
}
pkcs7der.value[1].value[0].value[4].value[0].value = newValues; // Set the new list
// Get the time signature and add it to the executables PKCS7
const timeasn1Signature = timepkcs7der.value[1].value[0].value[4];
const countersignatureOid = asn1.oidToDer('1.2.840.113549.1.9.6').data;
const asn1obj2 =
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 1, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, countersignatureOid),
timeasn1Signature
])
]);
pkcs7der.value[1].value[0].value[4].value[0].value.push(asn1obj2);
// Re-encode the executable signature block
const p7signature = Buffer.from(forge.asn1.toDer(pkcs7der).data, 'binary');
// Open the output file
var output = null;
try { output = fs.openSync(args.out, 'w+'); } catch (ex) { }
if (output == null) return false;
var tmp, written = 0;
var executableSize = obj.header.sigpos ? obj.header.sigpos : this.filesize;
// Compute pre-header length and copy that to the new file
var preHeaderLen = (obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
var tmp = readFileSlice(written, preHeaderLen);
fs.writeSync(output, tmp);
written += tmp.length;
// Quad Align the results, adding padding if necessary
var len = executableSize + p7signature.length;
var padding = (8 - ((len) % 8)) % 8;
// Write the signature header
var addresstable = Buffer.alloc(8);
addresstable.writeUInt32LE(executableSize);
addresstable.writeUInt32LE(8 + p7signature.length + padding, 4);
fs.writeSync(output, addresstable);
written += addresstable.length;
// Copy the rest of the file until the start of the signature block
while ((executableSize - written) > 0) {
tmp = readFileSlice(written, Math.min(executableSize - written, 65536));
fs.writeSync(output, tmp);
written += tmp.length;
}
// Write the signature block header and signature
var win = Buffer.alloc(8); // WIN CERTIFICATE Structure
win.writeUInt32LE(p7signature.length + padding + 8); // DWORD length
win.writeUInt16LE(512, 4); // WORD revision
win.writeUInt16LE(2, 6); // WORD type
fs.writeSync(output, win);
fs.writeSync(output, p7signature);
if (padding > 0) { fs.writeSync(output, Buffer.alloc(padding, 0)); }
written += (p7signature.length + padding + 8);
// Compute the checksum and write it in the PE header checksum location
var tmp = Buffer.alloc(4);
tmp.writeUInt32LE(runChecksumOnFile(output, written, ((obj.header.peOptionalHeaderLocation + 64) / 4)));
fs.writeSync(output, tmp, 0, 4, obj.header.peOptionalHeaderLocation + 64);
// Close the file
fs.closeSync(output);
// Indicate we are done
func(null);
} catch (ex) { func('' + ex); return; }
});
}
// Read a resource table.
// ptr: The pointer to the start of the resource section
// offset: The offset start of the resource table to read
function readResourceTable(ptr, offset) {
var buf = readFileSlice(ptr + offset, 16);
var r = {};
r.characteristics = buf.readUInt32LE(0);
r.timeDateStamp = buf.readUInt32LE(4);
r.majorVersion = buf.readUInt16LE(8);
r.minorVersion = buf.readUInt16LE(10);
var numberOfNamedEntries = buf.readUInt16LE(12);
var numberOfIdEntries = buf.readUInt16LE(14);
r.entries = [];
var totalResources = numberOfNamedEntries + numberOfIdEntries;
//console.log('readResourceTable', offset, 16 + (totalResources) * 8, offset + (16 + (totalResources) * 8));
for (var i = 0; i < totalResources; i++) {
buf = readFileSlice(ptr + offset + 16 + (i * 8), 8);
var resource = {};
resource.name = buf.readUInt32LE(0);
var offsetToData = buf.readUInt32LE(4);
if ((resource.name & 0x80000000) != 0) {
var oname = resource.name;
resource.name = readLenPrefixUnicodeString(ptr + (resource.name - 0x80000000));
//console.log('readResourceName', offset + (oname - 0x80000000), 2 + (resource.name.length * 2), offset + (oname - 0x80000000) + (2 + resource.name.length * 2), resource.name);
}
if ((offsetToData & 0x80000000) != 0) { resource.table = readResourceTable(ptr, offsetToData - 0x80000000); } else { resource.item = readResourceItem(ptr, offsetToData); }
r.entries.push(resource);
}
return r;
}
// Read a resource item
// ptr: The pointer to the start of the resource section
// offset: The offset start of the resource item to read
function readResourceItem(ptr, offset) {
//console.log('readResourceItem', offset, 16, offset + 16);
var buf = readFileSlice(ptr + offset, 16), r = {};
r.offsetToData = buf.readUInt32LE(0);
r.size = buf.readUInt32LE(4);
//console.log('readResourceData', r.offsetToData - obj.header.sections['.rsrc'].virtualAddr, r.size, r.offsetToData + r.size - obj.header.sections['.rsrc'].virtualAddr);
r.codePage = buf.readUInt32LE(8);
//r.reserved = buf.readUInt32LE(12);
return r;
}
// Read a unicode stting that starts with the string length as the first byte.
function readLenPrefixUnicodeString(ptr) {
var nameLen = readFileSlice(ptr, 2).readUInt16LE(0);
var buf = readFileSlice(ptr + 2, nameLen * 2), name = '';
for (var i = 0; i < nameLen; i++) { name += String.fromCharCode(buf.readUInt16LE(i * 2)); }
return name;
}
// Generate a complete resource section and pad the section
function generateResourceSection(resources) {
// Call a resursive method the compute the size needed for each element
const resSizes = { tables: 0, items: 0, names: 0, data: 0 };
getResourceSectionSize(resources, resSizes);
// Pad the resource section & allocate the buffer
const fileAlign = obj.header.peWindows.fileAlignment
var resSizeTotal = resSizes.tables + resSizes.items + resSizes.names + resSizes.data;
if ((resSizeTotal % fileAlign) != 0) { resSizeTotal += (fileAlign - (resSizeTotal % fileAlign)); }
const resSectionBuffer = Buffer.alloc(resSizeTotal);
// Write the resource section, calling a recusrize method
const resPointers = { tables: 0, items: resSizes.tables, names: resSizes.tables + resSizes.items, data: resSizes.tables + resSizes.items + resSizes.names };
createResourceSection(resources, resSectionBuffer, resPointers);
//console.log('generateResourceSection', resPointers);
// Done, return the result
return resSectionBuffer;
}
// Return the total size of a resource header, this is a recursive method
function getResourceSectionSize(resources, sizes) {
sizes.tables += (16 + (resources.entries.length * 8));
for (var i in resources.entries) {
if (typeof resources.entries[i].name == 'string') {
var dataSize = (2 + (resources.entries[i].name.length * 2));
if ((dataSize % 8) != 0) { dataSize += (8 - (dataSize % 8)); }
sizes.names += dataSize;
}
if (resources.entries[i].table) { getResourceSectionSize(resources.entries[i].table, sizes); }
else if (resources.entries[i].item) {
sizes.items += 16;
if (resources.entries[i].item.buffer) {
sizes.data += resources.entries[i].item.buffer.length;
} else {
var dataSize = resources.entries[i].item.size;
if ((dataSize % 8) != 0) { dataSize += (8 - (dataSize % 8)); }
sizes.data += dataSize;
}
}
}
}
// Write the resource section in the buffer, this is a recursive method
function createResourceSection(resources, buf, resPointers) {
var numberOfNamedEntries = 0, numberOfIdEntries = 0, ptr = resPointers.tables;
//console.log('createResourceSection', resPointers, ptr);
// Figure out how many items we have to save
for (var i in resources.entries) {
if (typeof resources.entries[i].name == 'string') { numberOfNamedEntries++; } else { numberOfIdEntries++; }
}
// Move the table pointer forward
resPointers.tables += (16 + (8 * numberOfNamedEntries) + (8 * numberOfIdEntries));
// Write the table header
buf.writeUInt32LE(resources.characteristics, ptr);
buf.writeUInt32LE(resources.timeDateStamp, ptr + 4);
buf.writeUInt16LE(resources.majorVersion, ptr + 8);
buf.writeUInt16LE(resources.minorVersion, ptr + 10);
buf.writeUInt16LE(numberOfNamedEntries, ptr + 12);
buf.writeUInt16LE(numberOfIdEntries, ptr + 14);
// For each table entry, write the entry for it
for (var i in resources.entries) {
// Write the name
var name = resources.entries[i].name;
if (typeof resources.entries[i].name == 'string') {
// Set the pointer to the name
name = resPointers.names + 0x80000000;
// Write the name length, followed by the name string in unicode
buf.writeUInt16LE(resources.entries[i].name.length, resPointers.names);
for (var j = 0; j < resources.entries[i].name.length; j++) {
buf.writeUInt16LE(resources.entries[i].name.charCodeAt(j), 2 + resPointers.names + (j * 2));
}
// Move the names pointer forward, 8 byte align
var dataSize = (2 + (resources.entries[i].name.length * 2));
if ((dataSize % 8) != 0) { dataSize += (8 - (dataSize % 8)); }
resPointers.names += dataSize;
}
buf.writeUInt32LE(name, ptr + 16 + (i * 8));
// Write the data
var data;
if (resources.entries[i].table) {
// This is a pointer to a table entry
data = resPointers.tables + 0x80000000;
createResourceSection(resources.entries[i].table, buf, resPointers);
} else if (resources.entries[i].item) {
// This is a pointer to a data entry
data = resPointers.items;
// Write the data
var entrySize = 0;
if (resources.entries[i].item.buffer) {
// Write the data from given buffer
resources.entries[i].item.buffer.copy(buf, resPointers.data, 0, resources.entries[i].item.buffer.length);
entrySize = resources.entries[i].item.buffer.length;
} else {
// Write the data from original file
const actualPtr = (resources.entries[i].item.offsetToData - obj.header.sections['.rsrc'].virtualAddr) + obj.header.sections['.rsrc'].rawAddr;
const tmp = readFileSlice(actualPtr, resources.entries[i].item.size);
tmp.copy(buf, resPointers.data, 0, tmp.length);
entrySize = resources.entries[i].item.size;;
}
// Write the item entry
buf.writeUInt32LE(resPointers.data + obj.header.sections['.rsrc'].virtualAddr, resPointers.items); // Write the pointer relative to the virtual address
buf.writeUInt32LE(entrySize, resPointers.items + 4);
buf.writeUInt32LE(resources.entries[i].item.codePage, resPointers.items + 8);
buf.writeUInt32LE(resources.entries[i].item.reserved, resPointers.items + 12);
// Move items pointers forward
resPointers.items += 16;
var dataSize = entrySize;
if ((dataSize % 8) != 0) { dataSize += (8 - (dataSize % 8)); }
resPointers.data += dataSize;
}
buf.writeUInt32LE(data, ptr + 20 + (i * 8));
}
}
// Convert a unicode buffer to a string
function unicodeToString(buf) {
var r = '', c;
for (var i = 0; i < (buf.length / 2) ; i++) {
c = buf.readUInt16LE(i * 2);
if (c != 0) { r += String.fromCharCode(c); } else { return r; }
}
return r;
}
// Convert a string to a unicode buffer
// Input is a string, a buffer to write to and the offset in the buffer (0 is default).
function stringToUnicode(str, buf, offset) {
if (offset == null) { offset = 0; }
for (var i = 0; i < str.length; i++) { buf.writeInt16LE(str.charCodeAt(i), offset + (i * 2)); }
}
var resourceDefaultNames = {
'bitmaps': 2,
'icon': 3,
'dialogs': 5,
'iconGroups': 14,
'versionInfo': 16,
'configurationFiles': 24
}
// Return the raw signature block buffer with padding removed
obj.getRawSignatureBlock = function () {
if ((obj.header.sigpos == 0) || (obj.header.siglen == 0)) return null;
var pkcs7raw = readFileSlice(obj.header.sigpos + 8, obj.header.siglen - 8);
var derlen = forge.asn1.getBerValueLength(forge.util.createBuffer(pkcs7raw.slice(1, 5))) + 4;
if (derlen != pkcs7raw.length) { pkcs7raw = pkcs7raw.slice(0, derlen); }
return pkcs7raw;
}
// Get icon information from resource
obj.getIconInfo = function () {
const r = {}, ptr = obj.header.sections['.rsrc'].rawAddr;
// Find and parse each icon
const icons = {}
for (var i = 0; i < obj.resources.entries.length; i++) {
if (obj.resources.entries[i].name == resourceDefaultNames.icon) {
for (var j = 0; j < obj.resources.entries[i].table.entries.length; j++) {
const iconName = obj.resources.entries[i].table.entries[j].name;
const offsetToData = obj.resources.entries[i].table.entries[j].table.entries[0].item.offsetToData;
const size = obj.resources.entries[i].table.entries[j].table.entries[0].item.size;
const actualPtr = (offsetToData - obj.header.sections['.rsrc'].virtualAddr) + ptr;
icons[iconName] = readFileSlice(actualPtr, size);
}
}
}
// Find and parse each icon group
for (var i = 0; i < obj.resources.entries.length; i++) {
if (obj.resources.entries[i].name == resourceDefaultNames.iconGroups) {
for (var j = 0; j < obj.resources.entries[i].table.entries.length; j++) {
const groupName = obj.resources.entries[i].table.entries[j].name;
const offsetToData = obj.resources.entries[i].table.entries[j].table.entries[0].item.offsetToData;
const size = obj.resources.entries[i].table.entries[j].table.entries[0].item.size;
const actualPtr = (offsetToData - obj.header.sections['.rsrc'].virtualAddr) + ptr;
const group = {};
const groupData = readFileSlice(actualPtr, size);
// Parse NEWHEADER structure: https://docs.microsoft.com/en-us/windows/win32/menurc/newheader
group.resType = groupData.readUInt16LE(2);
group.resCount = groupData.readUInt16LE(4);
// Parse many RESDIR structure: https://docs.microsoft.com/en-us/windows/win32/menurc/resdir
group.icons = {};
for (var p = 6; p < size; p += 14) {
var icon = {}
icon.width = groupData[p];
icon.height = groupData[p + 1];
icon.colorCount = groupData[p + 2];
icon.planes = groupData.readUInt16LE(p + 4);
icon.bitCount = groupData.readUInt16LE(p + 6);
icon.bytesInRes = groupData.readUInt32LE(p + 8);
icon.iconCursorId = groupData.readUInt16LE(p + 12);
icon.icon = icons[icon.iconCursorId];
group.icons[icon.iconCursorId] = icon;
}
// Add an icon group
r[groupName] = group;
}
}
}
return r;
}
// Decode the version information from the resource
obj.getVersionInfo = function () {
//console.log('READ', getVersionInfoData().toString('hex'));
var r = {}, info = readVersionInfo(getVersionInfoData(), 0);
if ((info == null) || (info.stringFiles == null)) return null;
var StringFileInfo = null;
for (var i in info.stringFiles) { if (info.stringFiles[i].szKey == 'StringFileInfo') { StringFileInfo = info.stringFiles[i]; } }
if ((StringFileInfo == null) || (StringFileInfo.stringTable == null) || (StringFileInfo.stringTable.strings == null)) return null;
const strings = StringFileInfo.stringTable.strings;
for (var i in strings) { r[strings[i].key] = strings[i].value; }
r['~FileVersion'] = (info.fixedFileInfo.dwFileVersionMS >> 16) + '.' + (info.fixedFileInfo.dwFileVersionMS & 0xFFFF) + '.' + (info.fixedFileInfo.dwFileVersionLS >> 16) + '.' + (info.fixedFileInfo.dwFileVersionLS & 0xFFFF);
r['~ProductVersion'] = (info.fixedFileInfo.dwProductVersionMS >> 16) + '.' + (info.fixedFileInfo.dwProductVersionMS & 0xFFFF) + '.' + (info.fixedFileInfo.dwProductVersionLS >> 16) + '.' + (info.fixedFileInfo.dwProductVersionLS & 0xFFFF);
return r;
}
// Encode the version information to the resource
obj.setVersionInfo = function (versions) {
// Convert the version information into a string array
const stringArray = [];
for (var i in versions) { if (!i.startsWith('~')) { stringArray.push({ key: i, value: versions[i] }); } }
// Get the existing version data and switch the strings to the new strings
var r = {}, info = readVersionInfo(getVersionInfoData(), 0);
if ((info == null) || (info.stringFiles == null)) return;
var StringFileInfo = null;
for (var i in info.stringFiles) { if (info.stringFiles[i].szKey == 'StringFileInfo') { StringFileInfo = info.stringFiles[i]; } }
if ((StringFileInfo == null) || (StringFileInfo.stringTable == null) || (StringFileInfo.stringTable.strings == null)) return;
StringFileInfo.stringTable.strings = stringArray;
// Set the file version
if (versions['~FileVersion'] != null) {
const FileVersionSplit = versions['~FileVersion'].split('.');
info.fixedFileInfo.dwFileVersionMS = (parseInt(FileVersionSplit[0]) << 16) + parseInt(FileVersionSplit[1]);
info.fixedFileInfo.dwFileVersionLS = (parseInt(FileVersionSplit[2]) << 16) + parseInt(FileVersionSplit[3]);
}
// Set the product version
if (versions['~ProductVersion'] != null) {
const ProductVersionSplit = versions['~ProductVersion'].split('.');
info.fixedFileInfo.dwProductVersionMS = (parseInt(ProductVersionSplit[0]) << 16) + parseInt(ProductVersionSplit[1]);
info.fixedFileInfo.dwProductVersionLS = (parseInt(ProductVersionSplit[2]) << 16) + parseInt(ProductVersionSplit[3]);
}
// Re-encode the version information into a buffer
var verInfoResBufArray = [];
writeVersionInfo(verInfoResBufArray, info);
var verInfoRes = Buffer.concat(verInfoResBufArray);
// Display all buffers
//console.log('--WRITE BUF ARRAY START--');
//for (var i in verInfoResBufArray) { console.log(verInfoResBufArray[i].toString('hex')); }
//console.log('--WRITE BUF ARRAY END--');
//console.log('OUT', Buffer.concat(verInfoResBufArray).toString('hex'));
// Set the new buffer as part of the resources
for (var i = 0; i < obj.resources.entries.length; i++) {
if (obj.resources.entries[i].name == resourceDefaultNames.versionInfo) {
const verInfo = obj.resources.entries[i].table.entries[0].table.entries[0].item;
delete verInfo.size;
delete verInfo.offsetToData;
verInfo.buffer = verInfoRes;
obj.resources.entries[i].table.entries[0].table.entries[0].item = verInfo;
}
}
}
// Return the version info data block
function getVersionInfoData() {
if (obj.resources == null) return null;
const ptr = obj.header.sections['.rsrc'].rawAddr;
for (var i = 0; i < obj.resources.entries.length; i++) {
if (obj.resources.entries[i].name == resourceDefaultNames.versionInfo) {
const verInfo = obj.resources.entries[i].table.entries[0].table.entries[0].item;
if (verInfo.buffer != null) {
return verInfo.buffer;
} else {
const actualPtr = (verInfo.offsetToData - obj.header.sections['.rsrc'].virtualAddr) + ptr;
return readFileSlice(actualPtr, verInfo.size);
}
}
}
return null;
}
// Create a VS_VERSIONINFO structure as a array of buffer that is ready to be placed in the resource section
// VS_VERSIONINFO structure: https://docs.microsoft.com/en-us/windows/win32/menurc/vs-versioninfo
function writeVersionInfo(bufArray, info) {
const buf = Buffer.alloc(40);
buf.writeUInt16LE(0, 4); // wType
stringToUnicode('VS_VERSION_INFO', buf, 6);
bufArray.push(buf);
var wLength = 40;
var wValueLength = 0;
if (info.fixedFileInfo != null) {
const buf2 = Buffer.alloc(52);
wLength += 52;
wValueLength += 52;
buf2.writeUInt32LE(info.fixedFileInfo.dwSignature, 0); // dwSignature
buf2.writeUInt32LE(info.fixedFileInfo.dwStrucVersion, 4); // dwStrucVersion
buf2.writeUInt32LE(info.fixedFileInfo.dwFileVersionMS, 8); // dwFileVersionMS
buf2.writeUInt32LE(info.fixedFileInfo.dwFileVersionLS, 12); // dwFileVersionLS
buf2.writeUInt32LE(info.fixedFileInfo.dwProductVersionMS, 16); // dwProductVersionMS
buf2.writeUInt32LE(info.fixedFileInfo.dwProductVersionLS, 20); // dwProductVersionLS
buf2.writeUInt32LE(info.fixedFileInfo.dwFileFlagsMask, 24); // dwFileFlagsMask
buf2.writeUInt32LE(info.fixedFileInfo.dwFileFlags, 28); // dwFileFlags
buf2.writeUInt32LE(info.fixedFileInfo.dwFileOS, 32); // dwFileOS
buf2.writeUInt32LE(info.fixedFileInfo.dwFileType, 36); // dwFileType
buf2.writeUInt32LE(info.fixedFileInfo.dwFileSubtype, 40); // dwFileSubtype
buf2.writeUInt32LE(info.fixedFileInfo.dwFileDateMS, 44); // dwFileDateMS
buf2.writeUInt32LE(info.fixedFileInfo.dwFileDateLS, 48); // dwFileDateLS
bufArray.push(buf2);
}
if (info.stringFiles != null) { wLength += writeStringFileInfo(bufArray, info.stringFiles); }
buf.writeUInt16LE(Buffer.concat(bufArray).length, 0); // wLength
buf.writeUInt16LE(wValueLength, 2); // wValueLength
return wLength;
}
// StringFileInfo structure: https://docs.microsoft.com/en-us/windows/win32/menurc/stringfileinfo
function writeStringFileInfo(bufArray, stringFiles) {
var totalLen = 0;
for (var i in stringFiles) {
var l = 6 + (stringFiles[i].szKey.length * 2);
if (stringFiles[i].szKey == 'VarFileInfo') { l += 4; } // TODO: This is a hack, not sure what the correct code should be
const buf2 = Buffer.alloc(padPointer(l));
buf2.writeUInt16LE(1, 4); // wType
stringToUnicode(stringFiles[i].szKey, buf2, 6);
bufArray.push(buf2);
var wLength = 0, wValueLength = 0;
if (stringFiles[i].szKey == 'StringFileInfo') { wLength += writeStringTableStruct(bufArray, stringFiles[i].stringTable); }
if (stringFiles[i].szKey == 'VarFileInfo') { wLength += writeVarFileInfoStruct(bufArray, stringFiles[i].varFileInfo); }
buf2.writeUInt16LE(l + wLength, 0); // wLength
buf2.writeUInt16LE(wValueLength, 2); // wValueLength
totalLen += buf2.length + wLength;
}
return totalLen;
}
// VarFileInfo structure: https://docs.microsoft.com/en-us/windows/win32/menurc/var-str
function writeVarFileInfoStruct(bufArray, varFileInfo) {
var l = 8 + (varFileInfo.szKey.length * 2);
const buf = Buffer.alloc(padPointer(l));
buf.writeUInt16LE(0, 4); // wType
stringToUnicode(varFileInfo.szKey, buf, 6);
bufArray.push(buf);
var wLength = 0;
var wValueLength = 0;
if (varFileInfo.value) {
bufArray.push(varFileInfo.value);
wLength += varFileInfo.value.length;
wValueLength += varFileInfo.value.length;
}
buf.writeUInt16LE(buf.length + wLength, 0); // wLength
buf.writeUInt16LE(wValueLength, 2); // wValueLength
return buf.length + wLength;
}
// StringTable structure: https://docs.microsoft.com/en-us/windows/win32/menurc/stringtable
function writeStringTableStruct(bufArray, stringTable) {
//console.log('writeStringTableStruct', stringTable);
var l = 6 + (stringTable.szKey.length * 2);
const buf = Buffer.alloc(padPointer(l));
buf.writeUInt16LE(1, 4); // wType
stringToUnicode(stringTable.szKey, buf, 6);
bufArray.push(buf);
var wLength = 0;
var wValueLength = 0;
if (stringTable.strings) { wLength += writeStringStructs(bufArray, stringTable.strings); }
buf.writeUInt16LE(l + wLength, 0); // wLength
buf.writeUInt16LE(wValueLength, 2); // wValueLength
return buf.length + wLength;
}
// String structure: https://docs.microsoft.com/en-us/windows/win32/menurc/string-str
function writeStringStructs(bufArray, stringTable) {
//console.log('writeStringStructs', stringTable);
var totalLen = 0, bufadd = 0;
for (var i in stringTable) {
//console.log('writeStringStructs', stringTable[i]);
const buf = Buffer.alloc(padPointer(6 + ((stringTable[i].key.length + 1) * 2)));
var buf2, wLength = buf.length;
var wValueLength = 0;
stringToUnicode(stringTable[i].key, buf, 6);
bufArray.push(buf);
bufadd += buf.length;
if (typeof stringTable[i].value == 'string') {
// wType (string)
buf.writeUInt16LE(1, 4);
var l = (stringTable[i].value.length + 1) * 2;
buf2 = Buffer.alloc(padPointer(l));
stringToUnicode(stringTable[i].value, buf2, 0);
bufArray.push(buf2);
bufadd += buf2.length;
wValueLength = stringTable[i].value.length + 1;
wLength += l;
}
if (typeof stringTable[i].value == 'object') {
// wType (binary)
buf.writeUInt16LE(2, 4); // TODO: PADDING
bufArray.push(stringTable[i].value);
bufadd += stringTable[i].value.length;
wValueLength = stringTable[i].value.length;
wLength += wValueLength;
}
buf.writeUInt16LE(wLength, 0); // wLength
buf.writeUInt16LE(wValueLength, 2); // wValueLength
//console.log('WStringStruct', buf.toString('hex'), buf2.toString('hex'));
totalLen += wLength;
}
//return totalLen;
return bufadd;
}
// VS_VERSIONINFO structure: https://docs.microsoft.com/en-us/windows/win32/menurc/vs-versioninfo
function readVersionInfo(buf, ptr) {
const r = {};
if (buf.length < 2) return null;
const wLength = buf.readUInt16LE(ptr);
if (buf.length < wLength) return null;
const wValueLength = buf.readUInt16LE(ptr + 2);
const wType = buf.readUInt16LE(ptr + 4);
r.szKey = unicodeToString(buf.slice(ptr + 6, ptr + 36));
if (r.szKey != 'VS_VERSION_INFO') return null;
//console.log('getVersionInfo', wLength, wValueLength, wType, r.szKey.toString());
if (wValueLength == 52) { r.fixedFileInfo = readFixedFileInfoStruct(buf, ptr + 40); }
r.stringFiles = readStringFilesStruct(buf, ptr + 40 + wValueLength, wLength - 40 - wValueLength);
return r;
}
// VS_FIXEDFILEINFO structure: https://docs.microsoft.com/en-us/windows/win32/api/verrsrc/ns-verrsrc-vs_fixedfileinfo
function readFixedFileInfoStruct(buf, ptr) {
if (buf.length - ptr < 50) return null;
var r = {};
r.dwSignature = buf.readUInt32LE(ptr);
if (r.dwSignature != 0xFEEF04BD) return null;
r.dwStrucVersion = buf.readUInt32LE(ptr + 4);
r.dwFileVersionMS = buf.readUInt32LE(ptr + 8);
r.dwFileVersionLS = buf.readUInt32LE(ptr + 12);
r.dwProductVersionMS = buf.readUInt32LE(ptr + 16);
r.dwProductVersionLS = buf.readUInt32LE(ptr + 20);
r.dwFileFlagsMask = buf.readUInt32LE(ptr + 24);
r.dwFileFlags = buf.readUInt32LE(ptr + 28);
r.dwFileOS = buf.readUInt32LE(ptr + 32);
r.dwFileType = buf.readUInt32LE(ptr + 36);
r.dwFileSubtype = buf.readUInt32LE(ptr + 40);
r.dwFileDateMS = buf.readUInt32LE(ptr + 44);
r.dwFileDateLS = buf.readUInt32LE(ptr + 48);
return r;
}
// StringFileInfo structure: https://docs.microsoft.com/en-us/windows/win32/menurc/stringfileinfo
function readStringFilesStruct(buf, ptr, len) {
var t = [], startPtr = ptr;
while (ptr < (startPtr + len)) {
const r = {};
const wLength = buf.readUInt16LE(ptr);
if (wLength == 0) return t;
const wValueLength = buf.readUInt16LE(ptr + 2);
const wType = buf.readUInt16LE(ptr + 4); // 1 = Text, 2 = Binary
r.szKey = unicodeToString(buf.slice(ptr + 6, ptr + 6 + (wLength - 6))); // String value
//console.log('readStringFileStruct', wLength, wValueLength, wType, r.szKey);
if (r.szKey == 'StringFileInfo') { r.stringTable = readStringTableStruct(buf, ptr + 36); }
if (r.szKey == 'VarFileInfo') { r.varFileInfo = readVarFileInfoStruct(buf, ptr + 32); }
t.push(r);
ptr += wLength;
ptr = padPointer(ptr);
}
return t;
}
// VarFileInfo structure: https://docs.microsoft.com/en-us/windows/win32/menurc/var-str
function readVarFileInfoStruct(buf, ptr) {
const r = {};
const wLength = buf.readUInt16LE(ptr);
const wValueLength = buf.readUInt16LE(ptr + 2);
const wType = buf.readUInt16LE(ptr + 4); // 1 = Text, 2 = Binary
r.szKey = unicodeToString(buf.slice(ptr + 6, ptr + wLength)); // "VarFileInfo"
r.value = buf.slice(ptr + wLength - wValueLength, ptr + wLength)
//console.log('readVarFileInfoStruct', wLength, wValueLength, wType, r.szKey, r.value.toString('hex'));
return r;
}
// StringTable structure: https://docs.microsoft.com/en-us/windows/win32/menurc/stringtable
function readStringTableStruct(buf, ptr) {
const r = {};
const wLength = buf.readUInt16LE(ptr);
const wValueLength = buf.readUInt16LE(ptr + 2);
const wType = buf.readUInt16LE(ptr + 4); // 1 = Text, 2 = Binary
//console.log('RStringTableStruct', buf.slice(ptr, ptr + wLength).toString('hex'));
r.szKey = unicodeToString(buf.slice(ptr + 6, ptr + 6 + 16)); // An 8-digit hexadecimal number stored as a Unicode string.
//console.log('readStringTableStruct', wLength, wValueLength, wType, r.szKey);
r.strings = readStringStructs(buf, ptr + 24 + wValueLength, wLength - 22);
return r;
}
// String structure: https://docs.microsoft.com/en-us/windows/win32/menurc/string-str
function readStringStructs(buf, ptr, len) {
var t = [], startPtr = ptr;
while ((ptr + 6) < (startPtr + len)) {
const r = {};
const wLength = buf.readUInt16LE(ptr);
if (wLength == 0) return t;
//console.log('RStringStruct', buf.slice(ptr, ptr + wLength).toString('hex'));
const wValueLength = buf.readUInt16LE(ptr + 2);
const wType = buf.readUInt16LE(ptr + 4); // 1 = Text, 2 = Binary
//console.log('R', buf.slice(ptr, ptr + wLength).toString('hex'));
r.key = unicodeToString(buf.slice(ptr + 6, ptr + (wLength - (wValueLength * 2)) - 2)); // Key
if (wType == 1) { r.value = unicodeToString(buf.slice(ptr + wLength - (wValueLength * 2), ptr + wLength - 2)); } // String value
if (wType == 2) { r.value = buf.slice(ptr + wLength - (wValueLength * 2), ptr + wLength); } // Binary value
//console.log('readStringStruct', wLength, wValueLength, wType, r.key, r.value);
t.push(r);
ptr += wLength;
ptr = padPointer(ptr);
}
return t;
}
// Return the next 4 byte aligned number
function padPointer(ptr) { return ptr + (((ptr % 4) == 0) ? 0 : (4 - (ptr % 4))); }
//function padPointer(ptr) { return ptr + (ptr % 4); }
// Hash the file using the selected hashing system
// This hash skips the executables CRC and code signing data and signing block
obj.getHash = function(algo) {
const hash = crypto.createHash(algo);
runHash(hash, 0, obj.header.peHeaderLocation + 88);
runHash(hash, obj.header.peHeaderLocation + 88 + 4, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
runHash(hash, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16) + 8, obj.header.sigpos > 0 ? obj.header.sigpos : obj.filesize);
return hash.digest();
}
// Hash of an open file using the selected hashing system
// This hash skips the executables CRC and code signing data and signing block
obj.getHashOfFile = function(fd, algo, filesize) {
const hash = crypto.createHash(algo);
runHashOnFile(fd, hash, 0, obj.header.peHeaderLocation + 88);
runHashOnFile(fd, hash, obj.header.peHeaderLocation + 88 + 4, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
runHashOnFile(fd, hash, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16) + 8, obj.header.sigpos > 0 ? obj.header.sigpos : filesize);
return hash.digest();
}
// Hash the file using the selected hashing system skipping resource section
// This hash skips the executables CRC, sections table, resource section, code signing data and signing block
obj.getHashNoResources = function (algo) {
if (obj.header.sections['.rsrc'] == null) { return obj.getHash(algo); } // No resources in this executable, return a normal hash
// Get the sections table start and size
const sectionHeaderPtr = obj.header.SectionHeadersPtr;
const sectionHeaderSize = obj.header.coff.numberOfSections * 40;
// Get the resource section start and size
const resPtr = obj.header.sections['.rsrc'].rawAddr;
const resSize = obj.header.sections['.rsrc'].rawSize;
// Get the end-of-file location
const eof = obj.header.sigpos > 0 ? obj.header.sigpos : obj.filesize;
// Hash the remaining data
const hash = crypto.createHash(algo);
runHash(hash, 0, obj.header.peHeaderLocation + 88);
runHash(hash, obj.header.peHeaderLocation + 88 + 4, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
runHash(hash, obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16) + 8, sectionHeaderPtr);
runHash(hash, sectionHeaderPtr + sectionHeaderSize, resPtr);
runHash(hash, resPtr + resSize, eof);
return hash.digest();
}
// Hash the file from start to end loading 64k chunks
function runHash(hash, start, end) {
var ptr = start;
while (ptr < end) { const buf = readFileSlice(ptr, Math.min(65536, end - ptr)); hash.update(buf); ptr += buf.length; }
}
// Hash the open file loading 64k chunks
// TODO: Do chunks on this!!!
function runHashOnFile(fd, hash, start, end) {
const buf = Buffer.alloc(end - start);
const len = fs.readSync(fd, buf, 0, buf.length, start);
if (len != buf.length) { console.log('BAD runHashOnFile'); }
hash.update(buf);
}
// Checksum the file loading 64k chunks
function runChecksum() {
var ptr = 0, c = createChecksum(((obj.header.peOptionalHeaderLocation + 64) / 4));
while (ptr < obj.filesize) { const buf = readFileSlice(ptr, Math.min(65536, obj.filesize - ptr)); c.update(buf); ptr += buf.length; }
return c.digest();
}
// Checksum the open file loading 64k chunks
function runChecksumOnFile(fd, filesize, checksumLocation) {
var ptr = 0, c = createChecksum(checksumLocation), buf = Buffer.alloc(65536);
while (ptr < filesize) { var len = fs.readSync(fd, buf, 0, Math.min(65536, filesize - ptr), ptr); c.update(buf, len); ptr += len; }
return c.digest();
}
// Steaming checksum methods
// TODO: Works only with files padded to 4 byte.
function createChecksum(checksumLocation) {
const obj = { checksum: 0, length: 0 };
obj.update = function (data, len) {
if (!len) { len = data.length; }
for (var i = 0; i < (len / 4) ; i++) {
if (((obj.length / 4) + i) == checksumLocation) continue; // Skip PE checksum location
const dword = data.readUInt32LE(i * 4);
var checksumlo = (obj.checksum > 4294967296) ? (obj.checksum - 4294967296) : obj.checksum;
var checksumhi = (obj.checksum > 4294967296) ? 1 : 0;
obj.checksum = checksumlo + dword + checksumhi;
if (obj.checksum > 4294967296) {
checksumlo = (obj.checksum > 4294967296) ? (obj.checksum - 4294967296) : obj.checksum;
checksumhi = (obj.checksum > 4294967296) ? 1 : 0;
obj.checksum = checksumlo + checksumhi;
}
}
obj.length += len;
}
obj.digest = function () {
obj.checksum = (obj.checksum & 0xffff) + (obj.checksum >>> 16);
obj.checksum = (obj.checksum) + (obj.checksum >>> 16);
obj.checksum = obj.checksum & 0xffff;
obj.checksum += obj.length;
return obj.checksum;
}
return obj;
}
// Compute the PE checksum of an entire file
function getChecksum(data, checksumLocation) {
var checksum = 0;
for (var i = 0; i < (data.length / 4) ; i++) {
if (i == (checksumLocation / 4)) continue; // Skip PE checksum location
var dword = data.readUInt32LE(i * 4);
var checksumlo = (checksum > 4294967296) ? (checksum - 4294967296) : checksum;
var checksumhi = (checksum > 4294967296) ? 1 : 0;
checksum = checksumlo + dword + checksumhi;
if (checksum > 4294967296) {
checksumlo = (checksum > 4294967296) ? (checksum - 4294967296) : checksum;
checksumhi = (checksum > 4294967296) ? 1 : 0;
checksum = checksumlo + checksumhi;
}
}
checksum = (checksum & 0xffff) + (checksum >>> 16);
checksum = (checksum) + (checksum >>> 16);
checksum = checksum & 0xffff;
checksum += data.length;
return checksum;
}
// Sign the file using the certificate and key. If none is specified, generate a dummy one
obj.sign = function (cert, args, func) {
if (cert == null) { cert = createSelfSignedCert({ cn: 'Test' }); }
// Set the hash algorithm hash OID
var hashOid = null, fileHash = null;
if (args.hash == null) { args.hash = 'sha384'; }
if (args.hash == 'sha256') { hashOid = forge.pki.oids.sha256; fileHash = obj.getHash('sha256'); }
if (args.hash == 'sha384') { hashOid = forge.pki.oids.sha384; fileHash = obj.getHash('sha384'); }
if (args.hash == 'sha512') { hashOid = forge.pki.oids.sha512; fileHash = obj.getHash('sha512'); }
if (args.hash == 'sha224') { hashOid = forge.pki.oids.sha224; fileHash = obj.getHash('sha224'); }
if (args.hash == 'md5') { hashOid = forge.pki.oids.md5; fileHash = obj.getHash('md5'); }
if (hashOid == null) { func('Invalid signing hash: ' + args.hash); return; };
// Create the signature block
var xp7 = forge.pkcs7.createSignedData();
var content = { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 6, 'constructed': false, 'composed': false, 'value': forge.asn1.oidToDer('1.3.6.1.4.1.311.2.1.15').data }, { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 3, 'constructed': false, 'composed': false, 'value': '\u0000', 'bitStringContents': '\u0000', 'original': { 'tagClass': 0, 'type': 3, 'constructed': false, 'composed': false, 'value': '\u0000' } }, { 'tagClass': 128, 'type': 0, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 2, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': '' }] }] }] }] }, { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 6, 'constructed': false, 'composed': false, 'value': forge.asn1.oidToDer(hashOid).data }, { 'tagClass': 0, 'type': 5, 'constructed': false, 'composed': false, 'value': '' }] }, { 'tagClass': 0, 'type': 4, 'constructed': false, 'composed': false, 'value': fileHash.toString('binary') }] }] };
xp7.contentInfo = forge.asn1.create(forge.asn1.Class.UNIVERSAL, forge.asn1.Type.SEQUENCE, true, [forge.asn1.create(forge.asn1.Class.UNIVERSAL, forge.asn1.Type.OID, false, forge.asn1.oidToDer('1.3.6.1.4.1.311.2.1.4').getBytes())]);
xp7.contentInfo.value.push(forge.asn1.create(forge.asn1.Class.CONTEXT_SPECIFIC, 0, true, [content]));
xp7.content = {}; // We set .contentInfo and have .content empty to bypass node-forge limitation on the type of content it can sign.
xp7.addCertificate(cert.cert);
if (cert.extraCerts) { for (var i = 0; i < cert.extraCerts.length; i++) { xp7.addCertificate(cert.extraCerts[0]); } } // Add any extra certificates that form the cert chain
// Build authenticated attributes
var authenticatedAttributes = [
{ type: forge.pki.oids.contentType, value: forge.pki.oids.data },
{ type: forge.pki.oids.messageDigest } // This value will populated at signing time by node-forge
]
if ((typeof args.desc == 'string') || (typeof args.url == 'string')) {
var codeSigningAttributes = { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [] };
if (args.desc != null) { // Encode description as big-endian unicode.
var desc = "", ucs = Buffer.from(args.desc, 'ucs2').toString()
for (var k = 0; k < ucs.length; k += 2) { desc += String.fromCharCode(ucs.charCodeAt(k + 1), ucs.charCodeAt(k)); }
codeSigningAttributes.value.push({ 'tagClass': 128, 'type': 0, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': desc }] });
}
if (args.url != null) { codeSigningAttributes.value.push({ 'tagClass': 128, 'type': 1, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': args.url }] }); }
authenticatedAttributes.push({ type: obj.Oids.SPC_SP_OPUS_INFO_OBJID, value: codeSigningAttributes });
}
// Add the signer and sign
xp7.addSigner({
key: cert.key,
certificate: cert.cert,
digestAlgorithm: forge.pki.oids.sha384,
authenticatedAttributes: authenticatedAttributes
});
xp7.sign();
var p7signature = Buffer.from(forge.pkcs7.messageToPem(xp7).split('-----BEGIN PKCS7-----')[1].split('-----END PKCS7-----')[0], 'base64');
if (args.time == null) {
// Sign the executable without timestamp
signEx(args, p7signature, obj.filesize, func);
} else {
// Decode the signature block
var pkcs7der = null;
try { pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(p7signature)); } catch (ex) { func('' + ex); return; }
// To work around ForgeJS PKCS#7 limitation, this may break PKCS7 verify if ForgeJS adds support for it in the future
// Switch content type from "1.3.6.1.4.1.311.2.1.4" to "1.2.840.113549.1.7.1"
pkcs7der.value[1].value[0].value[2].value[0].value = forge.asn1.oidToDer(forge.pki.oids.data).data;
// Decode the PKCS7 message
var pkcs7 = p7.messageFromAsn1(pkcs7der);
// Create the timestamp request in DER format
const asn1 = forge.asn1;
const pkcs7dataOid = asn1.oidToDer('1.2.840.113549.1.7.1').data;
const microsoftCodeSigningOid = asn1.oidToDer('1.3.6.1.4.1.311.3.2.1').data;
const asn1obj =
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, microsoftCodeSigningOid),
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, pkcs7dataOid),
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 0, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OCTETSTRING, false, pkcs7.rawCapture.signature.toString('binary')) // Signature here
])
])
]);
// Re-decode the PKCS7 from the executable, this time, no workaround needed
try { pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(p7signature)); } catch (ex) { func('' + ex); return; }
// Serialize an ASN.1 object to DER format in Base64
const requestBody = Buffer.from(asn1.toDer(asn1obj).data, 'binary').toString('base64');
// Make an HTTP request
const options = { url: args.time, proxy: args.proxy };
// Make a request to the time server
httpRequest(options, requestBody, function (err, data) {
if (err != null) { func(err); return; }
// Decode the timestamp signature block
var timepkcs7der = null;
try { timepkcs7der = forge.asn1.fromDer(forge.util.createBuffer(Buffer.from(data, 'base64').toString('binary'))); } catch (ex) { func("Unable to parse time-stamp response: " + ex); return; }
try {
// Get the ASN1 certificates used to sign the timestamp and add them to the certs in the PKCS7 of the executable
// TODO: We could look to see if the certificate is already present in the executable
const timeasn1Certs = timepkcs7der.value[1].value[0].value[3].value;
for (var i in timeasn1Certs) { pkcs7der.value[1].value[0].value[3].value.push(timeasn1Certs[i]); }
// Get the time signature and add it to the executables PKCS7
const timeasn1Signature = timepkcs7der.value[1].value[0].value[4];
const countersignatureOid = asn1.oidToDer('1.2.840.113549.1.9.6').data;
const asn1obj2 =
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 1, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, countersignatureOid),
timeasn1Signature
])
]);
pkcs7der.value[1].value[0].value[4].value[0].value.push(asn1obj2);
// Re-encode the executable signature block
const p7signature = Buffer.from(forge.asn1.toDer(pkcs7der).data, 'binary');
// Write the file with the signature block
signEx(args, p7signature, obj.filesize, func);
} catch (ex) { func('' + ex); }
});
}
}
// Make a HTTP request, use a proxy if needed
function httpRequest(options, requestBody, func) {
// Decode the URL
const timeServerUrl = new URL(options.url);
options.protocol = timeServerUrl.protocol;
options.hostname = timeServerUrl.hostname;
options.path = timeServerUrl.pathname;
options.port = ((timeServerUrl.port == '') ? 80 : parseInt(timeServerUrl.port));
if (options.proxy == null) {
// No proxy needed
// Setup the options
delete options.url;
options.method = 'POST';
options.headers = {
'accept': 'application/octet-stream',
'cache-control': 'no-cache',
'user-agent': 'Transport',
'content-type': 'application/octet-stream',
'content-length': Buffer.byteLength(requestBody)
};
// Set up the request
var responseAccumulator = '';
var req = require('http').request(options, function (res) {
res.setEncoding('utf8');
res.on('data', function (chunk) { responseAccumulator += chunk; });
res.on('end', function () { func(null, responseAccumulator); });
});
// Post the data
req.on('error', function (err) { func('' + err); });
req.write(requestBody);
req.end();
} else {
// We are using a proxy
// This is a fairly basic proxy implementation, should work most of the time.
// Setup the options and decode the proxy URL
var proxyOptions = { method: 'CONNECT' };
if (options.proxy) {
const proxyUrl = new URL(options.proxy);
proxyOptions.protocol = proxyUrl.protocol;
proxyOptions.hostname = proxyUrl.hostname;
proxyOptions.path = options.hostname + ':' + options.port;
proxyOptions.port = ((proxyUrl.port == '') ? 80 : parseInt(proxyUrl.port));
}
// Set up the proxy request
var responseAccumulator = '';
var req = require('http').request(proxyOptions);
req.on('error', function (err) { func('' + err); });
req.on('connect', function (res, socket, head) {
// Make a request over the HTTP tunnel
socket.write('POST ' + options.path + ' HTTP/1.1\r\n' +
'host: ' + options.hostname + ':' + options.port + '\r\n' +
'accept: application/octet-stream\r\n' +
'cache-control: no-cache\r\n' +
'user-agent: Transport\r\n' +
'content-type: application/octet-stream\r\n' +
'content-length: ' + Buffer.byteLength(requestBody) + '\r\n' +
'\r\n' + requestBody);
socket.on('data', function (chunk) {
responseAccumulator += chunk.toString();
var responseData = parseHttpResponse(responseAccumulator);
if (responseData != null) { try { socket.end(); } catch (ex) { console.log('ex', ex); } socket.xdone = true; func(null, responseData); }
});
socket.on('end', function () {
if (socket.xdone == true) return;
var responseData = parseHttpResponse(responseAccumulator);
if (responseData != null) { func(null, responseData); } else { func("Unable to parse response."); }
});
});
req.end();
}
}
// Parse the HTTP response and return data if available
function parseHttpResponse(data) {
var dataSplit = data.split('\r\n\r\n');
if (dataSplit.length < 2) return null;
// Parse the HTTP header
var headerSplit = dataSplit[0].split('\r\n'), headers = {};
for (var i in headerSplit) {
if (i != 0) {
var x = headerSplit[i].indexOf(':');
headers[headerSplit[i].substring(0, x).toLowerCase()] = headerSplit[i].substring(x + 2);
}
}
// If there is a content-length in the header, keep accumulating data until we have the right length
if (headers['content-length'] != null) {
const contentLength = parseInt(headers['content-length']);
if (dataSplit[1].length < contentLength) return null; // Wait for more data
return dataSplit[1];
}
return dataSplit[1];
}
// Complete the signature of an executable
function signEx(args, p7signature, filesize, func) {
// Open the output file
var output = null;
try { output = fs.openSync(args.out, 'w+'); } catch (ex) { }
if (output == null) { func('Unable to open output file: ' + args.out); return; }
var tmp, written = 0, executableSize = obj.header.sigpos ? obj.header.sigpos : filesize;
// Compute pre-header length and copy that to the new file
var preHeaderLen = (obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
var tmp = readFileSlice(written, preHeaderLen);
fs.writeSync(output, tmp);
written += tmp.length;
// Quad Align the results, adding padding if necessary
var len = executableSize + p7signature.length;
var padding = (8 - ((len) % 8)) % 8;
// Write the signature header
var addresstable = Buffer.alloc(8);
addresstable.writeUInt32LE(executableSize);
addresstable.writeUInt32LE(8 + p7signature.length + padding, 4);
fs.writeSync(output, addresstable);
written += addresstable.length;
// Copy the rest of the file until the start of the signature block
while ((executableSize - written) > 0) {
tmp = readFileSlice(written, Math.min(executableSize - written, 65536));
fs.writeSync(output, tmp);
written += tmp.length;
}
// Write the signature block header and signature
var win = Buffer.alloc(8); // WIN CERTIFICATE Structure
win.writeUInt32LE(p7signature.length + padding + 8); // DWORD length
win.writeUInt16LE(512, 4); // WORD revision
win.writeUInt16LE(2, 6); // WORD type
fs.writeSync(output, win);
fs.writeSync(output, p7signature);
if (padding > 0) { fs.writeSync(output, Buffer.alloc(padding, 0)); }
written += (p7signature.length + padding + 8);
// Compute the checksum and write it in the PE header checksum location
var tmp = Buffer.alloc(4);
tmp.writeUInt32LE(runChecksumOnFile(output, written, ((obj.header.peOptionalHeaderLocation + 64) / 4)));
fs.writeSync(output, tmp, 0, 4, obj.header.peOptionalHeaderLocation + 64);
// Close the file
fs.closeSync(output);
func(null);
}
// Save an executable without the signature
obj.unsign = function (args) {
// Open the file
var output = fs.openSync(args.out, 'w+');
var written = 0, totalWrite = obj.header.sigpos;
// Compute pre-header length and copy that to the new file
var preHeaderLen = (obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
var tmp = readFileSlice(written, preHeaderLen);
fs.writeSync(output, tmp);
written += tmp.length;
// Write the new signature header
fs.writeSync(output, Buffer.alloc(8));
written += 8;
// Copy the rest of the file until the start of the signature block
while ((totalWrite - written) > 0) {
tmp = readFileSlice(written, Math.min(totalWrite - written, 65536));
fs.writeSync(output, tmp);
written += tmp.length;
}
// Compute the checksum and write it in the PE checksum header at position
var tmp = Buffer.alloc(4);
tmp.writeUInt32LE(runChecksumOnFile(output, written));
fs.writeSync(output, tmp, 0, 4, obj.header.peOptionalHeaderLocation + 64);
fs.closeSync(output);
}
// Save the executable
obj.writeExecutable = function (args, cert, func) {
// Open the file
var output = fs.openSync(args.out, 'w+');
var tmp, written = 0;
// Compute the size of the complete executable header up to after the sections header
var fullHeaderLen = obj.header.SectionHeadersPtr + (obj.header.coff.numberOfSections * 40);
var fullHeader = readFileSlice(written, fullHeaderLen);
// Calculate the location and original and new size of the resource segment
var fileAlign = obj.header.peWindows.fileAlignment
var resPtr = obj.header.sections['.rsrc'].rawAddr;
var oldResSize = obj.header.sections['.rsrc'].rawSize;
var newResSize = obj.header.sections['.rsrc'].rawSize; // Testing 102400
var resDeltaSize = newResSize - oldResSize;
// Change PE optional header sizeOfInitializedData standard field
fullHeader.writeUInt32LE(obj.header.peStandard.sizeOfInitializedData + resDeltaSize, obj.header.peOptionalHeaderLocation + 8);
fullHeader.writeUInt32LE(obj.header.peWindows.sizeOfImage, obj.header.peOptionalHeaderLocation + 56); // TODO: resDeltaSize
// Update the checksum to zero
fullHeader.writeUInt32LE(0, obj.header.peOptionalHeaderLocation + 64);
// Make change to the data directories header to fix resource segment size and add/remove signature
const pePlusOffset = (obj.header.pe32plus == 0) ? 0 : 16; // This header is the same for 32 and 64 bit, but 64bit is offset by 16 bytes.
if (obj.header.dataDirectories.exportTable.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.exportTable.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 96 + pePlusOffset); }
if (obj.header.dataDirectories.importTable.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.importTable.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 104 + pePlusOffset); }
//fullHeader.writeUInt32LE(obj.header.dataDirectories.resourceTable.size + resDeltaSize, obj.header.peOptionalHeaderLocation + 116 + pePlusOffset); // Change the resource segment size
if (obj.header.dataDirectories.exceptionTableAddr.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.exceptionTableAddr.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 120 + pePlusOffset); }
fullHeader.writeUInt32LE(0, obj.header.peOptionalHeaderLocation + 128 + pePlusOffset); // certificate table addr (TODO)
fullHeader.writeUInt32LE(0, obj.header.peOptionalHeaderLocation + 132 + pePlusOffset); // certificate table size (TODO)
if (obj.header.dataDirectories.baseRelocationTable.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.baseRelocationTable.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 136 + pePlusOffset); }
if (obj.header.dataDirectories.debug.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.debug.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 144 + pePlusOffset); }
if (obj.header.dataDirectories.globalPtr.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.globalPtr.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 160 + pePlusOffset); }
if (obj.header.dataDirectories.tLSTable.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.tLSTable.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 168 + pePlusOffset); }
if (obj.header.dataDirectories.loadConfigTable.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.loadConfigTable.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 176 + pePlusOffset); }
if (obj.header.dataDirectories.boundImport.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.boundImport.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 184 + pePlusOffset); }
if (obj.header.dataDirectories.iAT.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.iAT.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 192 + pePlusOffset); }
if (obj.header.dataDirectories.delayImportDescriptor.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.delayImportDescriptor.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 200 + pePlusOffset); }
if (obj.header.dataDirectories.clrRuntimeHeader.addr > resPtr) { fullHeader.writeUInt32LE(obj.header.dataDirectories.clrRuntimeHeader.addr + resDeltaSize, obj.header.peOptionalHeaderLocation + 208 + pePlusOffset); }
// Make changes to the segments table
for (var i in obj.header.sections) {
const section = obj.header.sections[i];
if (i == '.rsrc') {
// Change the size of the resource section
fullHeader.writeUInt32LE(section.rawSize + resDeltaSize, section.ptr + 8); // virtualSize (TODO)
fullHeader.writeUInt32LE(section.rawSize + resDeltaSize, section.ptr + 16); // rawSize
} else {
// Change the location of any other section if located after the resource section
if (section.virtualAddr > resPtr) { fullHeader.writeUInt32LE(section.virtualAddr + resDeltaSize, section.ptr + 12); }
if (section.rawAddr > resPtr) { fullHeader.writeUInt32LE(section.rawAddr + resDeltaSize, section.ptr + 20); }
}
}
// Write the entire header to the destination file
//console.log('Write header', fullHeader.length, written);
fs.writeSync(output, fullHeader);
written += fullHeader.length;
// Write the entire executable until the start to the resource segment
var totalWrite = resPtr;
//console.log('Write until res', totalWrite, written);
while ((totalWrite - written) > 0) {
tmp = readFileSlice(written, Math.min(totalWrite - written, 65536));
fs.writeSync(output, tmp);
written += tmp.length;
}
// Write the new resource section
var rsrcSection = generateResourceSection(obj.resources);
fs.writeSync(output, rsrcSection);
written += rsrcSection.length;
//console.log('Write res', rsrcSection.length, written);
// Write until the signature block
if (obj.header.sigpos > 0) {
// Since the original file was signed, write from the end of the resources to the start of the signature block.
totalWrite = obj.header.sigpos + resDeltaSize;
} else {
// The original file was not signed, write from the end of the resources to the end of the file.
totalWrite = obj.filesize + resDeltaSize;
}
//console.log('Write until signature', totalWrite, written);
while ((totalWrite - written) > 0) {
tmp = readFileSlice(written - resDeltaSize, Math.min(totalWrite - written, 65536));
fs.writeSync(output, tmp);
written += tmp.length;
}
//console.log('Write to signature', written);
// Write the signature if needed
if (cert != null) {
//if (cert == null) { cert = createSelfSignedCert({ cn: 'Test' }); }
// Set the hash algorithm hash OID
var hashOid = null, fileHash = null;
if (args.hash == null) { args.hash = 'sha384'; }
if (args.hash == 'sha256') { hashOid = forge.pki.oids.sha256; fileHash = obj.getHashOfFile(output, 'sha256', written); }
if (args.hash == 'sha384') { hashOid = forge.pki.oids.sha384; fileHash = obj.getHashOfFile(output, 'sha384', written); }
if (args.hash == 'sha512') { hashOid = forge.pki.oids.sha512; fileHash = obj.getHashOfFile(output, 'sha512', written); }
if (args.hash == 'sha224') { hashOid = forge.pki.oids.sha224; fileHash = obj.getHashOfFile(output, 'sha224', written); }
if (args.hash == 'md5') { hashOid = forge.pki.oids.md5; fileHash = obj.getHashOfFile(output, 'md5', written); }
if (hashOid == null) { func('Bad hash method OID'); return; }
// Create the signature block
var xp7 = forge.pkcs7.createSignedData();
var content = { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 6, 'constructed': false, 'composed': false, 'value': forge.asn1.oidToDer('1.3.6.1.4.1.311.2.1.15').data }, { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 3, 'constructed': false, 'composed': false, 'value': '\u0000', 'bitStringContents': '\u0000', 'original': { 'tagClass': 0, 'type': 3, 'constructed': false, 'composed': false, 'value': '\u0000' } }, { 'tagClass': 128, 'type': 0, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 2, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': '' }] }] }] }] }, { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 0, 'type': 6, 'constructed': false, 'composed': false, 'value': forge.asn1.oidToDer(hashOid).data }, { 'tagClass': 0, 'type': 5, 'constructed': false, 'composed': false, 'value': '' }] }, { 'tagClass': 0, 'type': 4, 'constructed': false, 'composed': false, 'value': fileHash.toString('binary') }] }] };
xp7.contentInfo = forge.asn1.create(forge.asn1.Class.UNIVERSAL, forge.asn1.Type.SEQUENCE, true, [forge.asn1.create(forge.asn1.Class.UNIVERSAL, forge.asn1.Type.OID, false, forge.asn1.oidToDer('1.3.6.1.4.1.311.2.1.4').getBytes())]);
xp7.contentInfo.value.push(forge.asn1.create(forge.asn1.Class.CONTEXT_SPECIFIC, 0, true, [content]));
xp7.content = {}; // We set .contentInfo and have .content empty to bypass node-forge limitation on the type of content it can sign.
xp7.addCertificate(cert.cert);
if (cert.extraCerts) { for (var i = 0; i < cert.extraCerts.length; i++) { xp7.addCertificate(cert.extraCerts[0]); } } // Add any extra certificates that form the cert chain
// Build authenticated attributes
var authenticatedAttributes = [
{ type: forge.pki.oids.contentType, value: forge.pki.oids.data },
{ type: forge.pki.oids.messageDigest } // This value will populated at signing time by node-forge
]
if ((typeof args.desc == 'string') || (typeof args.url == 'string')) {
var codeSigningAttributes = { 'tagClass': 0, 'type': 16, 'constructed': true, 'composed': true, 'value': [] };
if (args.desc != null) { // Encode description as big-endian unicode.
var desc = "", ucs = Buffer.from(args.desc, 'ucs2').toString()
for (var k = 0; k < ucs.length; k += 2) { desc += String.fromCharCode(ucs.charCodeAt(k + 1), ucs.charCodeAt(k)); }
codeSigningAttributes.value.push({ 'tagClass': 128, 'type': 0, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': desc }] });
}
if (args.url != null) { codeSigningAttributes.value.push({ 'tagClass': 128, 'type': 1, 'constructed': true, 'composed': true, 'value': [{ 'tagClass': 128, 'type': 0, 'constructed': false, 'composed': false, 'value': args.url }] }); }
authenticatedAttributes.push({ type: obj.Oids.SPC_SP_OPUS_INFO_OBJID, value: codeSigningAttributes });
}
// Add the signer and sign
xp7.addSigner({
key: cert.key,
certificate: cert.cert,
digestAlgorithm: forge.pki.oids.sha384,
authenticatedAttributes: authenticatedAttributes
});
xp7.sign();
var p7signature = Buffer.from(forge.pkcs7.messageToPem(xp7).split('-----BEGIN PKCS7-----')[1].split('-----END PKCS7-----')[0], 'base64');
//console.log('Signature', Buffer.from(p7signature, 'binary').toString('base64'));
if (args.time == null) {
// Write the signature block to the output executable without time stamp
writeExecutableEx(output, p7signature, written, func);
} else {
// Decode the signature block
var pkcs7der = null;
try { pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(p7signature)); } catch (ex) { func('' + ex); return; }
// To work around ForgeJS PKCS#7 limitation, this may break PKCS7 verify if ForgeJS adds support for it in the future
// Switch content type from "1.3.6.1.4.1.311.2.1.4" to "1.2.840.113549.1.7.1"
pkcs7der.value[1].value[0].value[2].value[0].value = forge.asn1.oidToDer(forge.pki.oids.data).data;
// Decode the PKCS7 message
var pkcs7 = p7.messageFromAsn1(pkcs7der);
// Create the timestamp request in DER format
const asn1 = forge.asn1;
const pkcs7dataOid = asn1.oidToDer('1.2.840.113549.1.7.1').data;
const microsoftCodeSigningOid = asn1.oidToDer('1.3.6.1.4.1.311.3.2.1').data;
const asn1obj =
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, microsoftCodeSigningOid),
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, pkcs7dataOid),
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 0, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OCTETSTRING, false, pkcs7.rawCapture.signature.toString('binary')) // Signature here
])
])
]);
// Re-decode the PKCS7 from the executable, this time, no workaround needed
try { pkcs7der = forge.asn1.fromDer(forge.util.createBuffer(p7signature)); } catch (ex) { func('' + ex); return; }
// Serialize an ASN.1 object to DER format in Base64
const requestBody = Buffer.from(asn1.toDer(asn1obj).data, 'binary').toString('base64');
// Make an HTTP request
const options = { url: args.time, proxy: args.proxy };
// Make a request to the time server
httpRequest(options, requestBody, function (err, data) {
if (err != null) { func(err); return; }
// Decode the timestamp signature block
var timepkcs7der = null;
try { timepkcs7der = forge.asn1.fromDer(forge.util.createBuffer(Buffer.from(data, 'base64').toString('binary'))); } catch (ex) { func("Unable to parse time-stamp response: " + ex); return; }
// Get the ASN1 certificates used to sign the timestamp and add them to the certs in the PKCS7 of the executable
// TODO: We could look to see if the certificate is already present in the executable
try {
var timeasn1Certs = timepkcs7der.value[1].value[0].value[3].value;
for (var i in timeasn1Certs) { pkcs7der.value[1].value[0].value[3].value.push(timeasn1Certs[i]); }
// Get the time signature and add it to the executables PKCS7
const timeasn1Signature = timepkcs7der.value[1].value[0].value[4];
const countersignatureOid = asn1.oidToDer('1.2.840.113549.1.9.6').data;
const asn1obj2 =
asn1.create(asn1.Class.CONTEXT_SPECIFIC, 1, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.SEQUENCE, true, [
asn1.create(asn1.Class.UNIVERSAL, asn1.Type.OID, false, countersignatureOid),
timeasn1Signature
])
]);
pkcs7der.value[1].value[0].value[4].value[0].value.push(asn1obj2);
// Re-encode the executable signature block
const p7signature = Buffer.from(forge.asn1.toDer(pkcs7der).data, 'binary');
// Write the file with the signature block
writeExecutableEx(output, p7signature, written, func);
} catch (ex) { func('' + ex); return; } // Something failed
});
}
return;
}
// Close the file
fs.closeSync(output);
// Indicate success
func(null);
}
function writeExecutableEx(output, p7signature, written, func) {
// Quad Align the results, adding padding if necessary
var len = written + p7signature.length;
var padding = (8 - ((len) % 8)) % 8;
// Write the signature block header and signature
var win = Buffer.alloc(8); // WIN CERTIFICATE Structure
win.writeUInt32LE(p7signature.length + padding + 8); // DWORD length
win.writeUInt16LE(512, 4); // WORD revision
win.writeUInt16LE(2, 6); // WORD type
fs.writeSync(output, win);
fs.writeSync(output, p7signature);
if (padding > 0) { fs.writeSync(output, Buffer.alloc(padding, 0)); }
// Write the signature header
var addresstable = Buffer.alloc(8);
addresstable.writeUInt32LE(written);
addresstable.writeUInt32LE(8 + p7signature.length + padding, 4);
var signatureHeaderLocation = (obj.header.peHeaderLocation + 152 + (obj.header.pe32plus * 16));
fs.writeSync(output, addresstable, 0, 8, signatureHeaderLocation);
written += (p7signature.length + padding + 8); // Add the signature block to written counter
// Compute the checksum and write it in the PE header checksum location
var tmp = Buffer.alloc(4);
tmp.writeUInt32LE(runChecksumOnFile(output, written, ((obj.header.peOptionalHeaderLocation + 64) / 4)));
fs.writeSync(output, tmp, 0, 4, obj.header.peOptionalHeaderLocation + 64);
// Close the file
fs.closeSync(output);
// Indicate success
func(null);
}
// Return null if we could not open the file
return (openFile() ? obj : null);
}
function start() {
// Parse the arguments
const args = require('minimist')(process.argv.slice(2));
// Show tool help
if (process.argv.length < 3) {
console.log("MeshCentral Authenticode Tool.");
console.log("Usage:");
console.log(" node authenticode.js [command] [options]");
console.log("Commands:");
console.log(" info: Show information about an executable.");
console.log(" --exe [file] Required executable to view information.");
console.log(" --json Show information in JSON format.");
console.log(" sign: Sign an executable.");
console.log(" --exe [file] Required executable to sign.");
console.log(" --out [file] Resulting signed executable.");
console.log(" --pem [pemfile] Certificate & private key to sign the executable with.");
console.log(" --desc [description] Description string to embbed into signature.");
console.log(" --url [url] URL to embbed into signature.");
console.log(" --hash [method] Default is SHA384, possible value: MD5, SHA224, SHA256, SHA384 or SHA512.");
console.log(" --time [url] The time signing server URL.");
console.log(" --proxy [url] The HTTP proxy to use to contact the time signing server, must start with http://");
console.log(" unsign: Remove the signature from the executable.");
console.log(" --exe [file] Required executable to un-sign.");
console.log(" --out [file] Resulting executable with signature removed.");
console.log(" createcert: Create a code signging self-signed certificate and key.");
console.log(" --out [pemfile] Required certificate file to create.");
console.log(" --cn [value] Required certificate common name.");
console.log(" --country [value] Certificate country name.");
console.log(" --state [value] Certificate state name.");
console.log(" --locality [value] Certificate locality name.");
console.log(" --org [value] Certificate organization name.");
console.log(" --ou [value] Certificate organization unit name.");
console.log(" --serial [value] Certificate serial number.");
console.log(" timestamp: Add a signed timestamp to an already signed executable.");
console.log(" --exe [file] Required executable to sign.");
console.log(" --out [file] Resulting signed executable.");
console.log(" --time [url] The time signing server URL.");
console.log(" --proxy [url] The HTTP proxy to use to contact the time signing server, must start with http://");
console.log("");
console.log("Note that certificate PEM files must first have the signing certificate,");
console.log("followed by all certificates that form the trust chain.");
console.log("");
console.log("When doing sign/unsign, you can also change resource properties of the generated file.");
console.log("");
console.log(" --fileversionnumber n.n.n.n");
console.log(" --productversionnumber n.n.n.n");
console.log(" --filedescription [value]");
console.log(" --fileversion [value]");
console.log(" --internalname [value]");
console.log(" --legalcopyright [value]");
console.log(" --originalfilename [value]");
console.log(" --productname [value]");
console.log(" --productversion [value]");
return;
}
// Check that a valid command is passed in
if (['info', 'sign', 'unsign', 'createcert', 'icons', 'saveicon', 'header', 'timestamp', 'signblock'].indexOf(process.argv[2].toLowerCase()) == -1) {
console.log("Invalid command: " + process.argv[2]);
console.log("Valid commands are: info, sign, unsign, createcert, timestamp");
return;
}
var exe = null;
if (args.exe) {
// Check the file exists and open the file
var stats = null;
try { stats = require('fs').statSync(args.exe); } catch (ex) { }
if (stats == null) { console.log("Unable to executable open file: " + args.exe); return; }
exe = createAuthenticodeHandler(args.exe);
if (exe == null) { console.log("Unable to parse executable file: " + args.exe); return; }
}
// Parse the string resources and make any required changes
var resChanges = false, versionStrings = null;
if (exe != null) {
versionStrings = exe.getVersionInfo();
var versionProperties = ['FileDescription', 'FileVersion', 'InternalName', 'LegalCopyright', 'OriginalFilename', 'ProductName', 'ProductVersion'];
for (var i in versionProperties) {
const prop = versionProperties[i], propl = prop.toLowerCase();
if (args[propl] && (args[propl] != versionStrings[prop])) { versionStrings[prop] = args[propl]; resChanges = true; }
}
if (args['fileversionnumber'] != null) {
const fileVerSplit = args['fileversionnumber'].split('.');
if (fileVerSplit.length != 4) { console.log("--fileversionnumber must be of format n.n.n.n, for example: 1.2.3.4"); return; }
for (var i in fileVerSplit) { var n = parseInt(fileVerSplit[i]); if ((n < 0) || (n > 65535)) { console.log("--fileversionnumber numbers must be between 0 and 65535."); return; } }
if (args['fileversionnumber'] != versionStrings['~FileVersion']) { versionStrings['~FileVersion'] = args['fileversionnumber']; resChanges = true; }
}
if (args['productversionnumber'] != null) {
const productVerSplit = args['productversionnumber'].split('.');
if (productVerSplit.length != 4) { console.log("--productversionnumber must be of format n.n.n.n, for example: 1.2.3.4"); return; }
for (var i in productVerSplit) { var n = parseInt(productVerSplit[i]); if ((n < 0) || (n > 65535)) { console.log("--productversionnumber numbers must be between 0 and 65535."); return; } }
if (args['productversionnumber'] != versionStrings['~ProductVersion']) { versionStrings['~ProductVersion'] = args['productversionnumber']; resChanges = true; }
}
if (resChanges == true) { exe.setVersionInfo(versionStrings); }
}
// Execute the command
var command = process.argv[2].toLowerCase();
if (command == 'info') { // Get signature information about an executable
if (exe == null) { console.log("Missing --exe [filename]"); return; }
if (args.json) {
var r = {}, stringInfo = exe.getVersionInfo();
if (stringInfo != null) {
r.versionInfo = {};
r.stringInfo = {};
for (var i in stringInfo) { if (i.startsWith('~')) { r.versionInfo[i.substring(1)] = stringInfo[i]; } else { r.stringInfo[i] = stringInfo[i]; } }
}
if (exe.fileHashAlgo != null) {
r.signture = {};
if (exe.fileHashAlgo != null) { r.signture.hashMethod = exe.fileHashAlgo; }
if (exe.fileHashSigned != null) { r.signture.hashSigned = exe.fileHashSigned.toString('hex'); }
if (exe.fileHashActual != null) { r.signture.hashActual = exe.fileHashActual.toString('hex'); }
if (exe.signingAttribs && exe.signingAttribs.length > 0) { r.signture.attributes = exe.signingAttribs; }
}
console.log(JSON.stringify(r, null, 2));
} else {
var versionInfo = exe.getVersionInfo();
if (versionInfo != null) {
console.log("Version Information:");
for (var i in versionInfo) { if (i.startsWith('~') == true) { console.log(' ' + i.substring(1) + ': ' + versionInfo[i] + ''); } }
console.log("String Information:");
for (var i in versionInfo) { if (i.startsWith('~') == false) { if (versionInfo[i] == null) { console.log(' ' + i + ': (Empty)'); } else { console.log(' ' + i + ': \"' + versionInfo[i] + '\"'); } } }
}
console.log("Checksum Information:");
console.log(" Header CheckSum: 0x" + exe.header.peWindows.checkSum.toString(16));
console.log(" Actual CheckSum: 0x" + exe.header.peWindows.checkSumActual.toString(16));
console.log("Signature Information:");
if (exe.fileHashAlgo != null) {
console.log(" Hash Method:", exe.fileHashAlgo);
if (exe.fileHashSigned != null) { console.log(" Signed Hash:", exe.fileHashSigned.toString('hex')); }
if (exe.fileHashActual != null) { console.log(" Actual Hash:", exe.fileHashActual.toString('hex')); }
} else {
console.log(" This file is not signed.");
}
if (exe.signingAttribs && exe.signingAttribs.length > 0) { console.log("Signature Attributes:"); for (var i in exe.signingAttribs) { console.log(' ' + exe.signingAttribs[i]); } }
}
}
if (command == 'header') { // Display the full executable header in JSON format
if (exe == null) { console.log("Missing --exe [filename]"); return; }
console.log(exe.header);
}
if (command == 'sign') { // Sign an executable
if (typeof args.exe != 'string') { console.log("Missing --exe [filename]"); return; }
if (typeof args.hash == 'string') { args.hash = args.hash.toLowerCase(); if (['md5', 'sha224', 'sha256', 'sha384', 'sha512'].indexOf(args.hash) == -1) { console.log("Invalid hash method, must be SHA256 or SHA384"); return; } }
if (args.hash == null) { args.hash = 'sha384'; }
createOutFile(args, args.exe);
var cert = loadCertificates(args.pem);
if (cert == null) { console.log("Unable to load certificate and/or private key, generating test certificate."); cert = createSelfSignedCert({ cn: 'Test' }); }
if (resChanges == false) {
console.log("Signing to " + args.out);
exe.sign(cert, args, function (err) { // Simple signing, copy most of the original file.
if (err == null) { console.log("Done."); } else { console.log(err); }
if (exe != null) { exe.close(); }
});
return;
} else {
console.log("Changing resources and signing to " + args.out);
exe.writeExecutable(args, cert, function (err) { // Signing with resources decoded and re-encoded.
if (err == null) { console.log("Done."); } else { console.log(err); }
if (exe != null) { exe.close(); }
});
return;
}
}
if (command == 'unsign') { // Unsign an executable
if (typeof args.exe != 'string') { console.log("Missing --exe [filename]"); return; }
createOutFile(args, args.exe);
if (resChanges == false) {
if (exe.header.signed) {
console.log("Unsigning to " + args.out);
exe.unsign(args); // Simple unsign, copy most of the original file.
console.log("Done.");
} else {
console.log("Executable is not signed.");
}
} else {
console.log("Changing resources and unsigning to " + args.out);
exe.writeExecutable(args, null, function (err) { // Unsigning with resources decoded and re-encoded.
if (err == null) { console.log("Done."); } else { console.log(err); }
if (exe != null) { exe.close(); }
});
}
}
if (command == 'createcert') { // Create a code signing certificate and private key
if (typeof args.out != 'string') { console.log("Missing --out [filename]"); return; }
if (typeof args.cn != 'string') { console.log("Missing --cn [name]"); return; }
if (typeof args.serial == 'string') { if (args.serial != parseInt(args.serial)) { console.log("Invalid serial number."); return; } else { args.serial = parseInt(args.serial); } }
if (typeof args.serial == 'number') { args.serial = '0' + args.serial; } // Serial number must be a integer string with a single leading '0'
const cert = createSelfSignedCert(args);
console.log("Writing to " + args.out);
fs.writeFileSync(args.out, pki.certificateToPem(cert.cert) + '\r\n' + pki.privateKeyToPem(cert.key));
console.log("Done.");
}
if (command == 'icons') { // Show icons in the executable
if (exe == null) { console.log("Missing --exe [filename]"); return; }
if (args.json) {
var r = {}, iconInfo = exe.getIconInfo();
if (iconInfo != null) { r.iconInfo = iconInfo; }
console.log(JSON.stringify(r, null, 2));
} else {
var iconInfo = exe.getIconInfo();
if (iconInfo != null) {
console.log("Icon Information:");
for (var i in iconInfo) { console.log(' Group ' + i + ':'); for (var j in iconInfo[i].icons) { console.log(' Icon ' + j + ': ' + ((iconInfo[i].icons[j].width == 0) ? 256 : iconInfo[i].icons[j].width) + 'x' + ((iconInfo[i].icons[j].height == 0) ? 256 : iconInfo[i].icons[j].height) + ', size: ' + iconInfo[i].icons[j].icon.length); } }
}
}
}
if (command == 'saveicon') { // Save an icon to file
if (exe == null) { console.log("Missing --exe [filename]"); return; }
if (typeof args.out != 'string') { console.log("Missing --out [filename]"); return; }
if (typeof args.icon != 'number') { console.log("Missing or incorrect --icon [number]"); return; }
const iconInfo = exe.getIconInfo();
var icon = null;
for (var i in iconInfo) { if (iconInfo[i].icons[args.icon]) { icon = iconInfo[i].icons[args.icon]; } }
if (icon == null) { console.log("Unknown icon: " + args.icon); return; }
// .ico header: https://en.wikipedia.org/wiki/ICO_(file_format)
var buf = Buffer.alloc(22);
buf.writeUInt16LE(1, 2); // 1 = Icon, 2 = Cursor
buf.writeUInt16LE(1, 4); // Icon Count, always 1 in our case
buf[6] = icon.width; // Width (0 = 256)
buf[7] = icon.height; // Height (0 = 256)
buf[8] = icon.colorCount; // Colors
buf.writeUInt16LE(icon.planes, 10); // Color planes
buf.writeUInt16LE(icon.bitCount, 12); // Bits per pixel
buf.writeUInt32LE(icon.icon.length, 14); // Size
buf.writeUInt32LE(22, 18); // Offset, always 22 in our case
console.log("Writing to " + args.out);
fs.writeFileSync(args.out, Buffer.concat([buf, icon.icon]));
console.log("Done.");
}
if (command == 'signblock') { // Display the raw signature block of the executable in hex
if (exe == null) { console.log("Missing --exe [filename]"); return; }
var buf = exe.getRawSignatureBlock();
if (buf == null) { console.log("Executable is not signed."); return } else { console.log(buf.toString('hex')); return }
}
if (command == 'timestamp') {
if (exe == null) { console.log("Missing --exe [filename]"); return; }
if (exe.signature == null) { console.log("Executable is not signed."); return; }
if (typeof args.time != 'string') { console.log("Missing --time [url]"); return; }
createOutFile(args, args.exe);
console.log("Requesting time signature...");
exe.timeStampRequest(args, function (err) {
if (err == null) { console.log("Done."); } else { console.log(err); }
if (exe != null) { exe.close(); }
})
return;
}
// Close the file
if (exe != null) { exe.close(); }
}
// If this is the main module, run the command line version
if (require.main === module) { start(); }
// Exports
module.exports.createAuthenticodeHandler = createAuthenticodeHandler;
module.exports.loadCertificates = loadCertificates;