Load Library/Module from Memory

Question

I realized a little C# porting of this application that allows to load libraries from memory/stream instead of using LoadLibrary API function that works through filesystem. After messing around a little bit with pointers and mimatching results... finally I have something working as intended. The only problem I have is that the call to DLLMain always fails (I tried it with Kernel32.dll and User32.dll). I can't understand why and I don't know how to debug the issue.

Here is the main function of my project (a simple 32bit console application) which reads a library, allocates it into memory and loads it manually:

public static UInt32 Load(String libraryName)
{
    if (libraries.ContainsKey(libraryName))
        return libraries[libraryName];

    String libraryPath = Path.Combine(Environment.SystemDirectory, libraryName);
    Byte[] libraryBytes = File.ReadAllBytes(libraryPath);

    fixed (Byte* libraryPointer = libraryBytes)
    {
        HeaderDOS* headerDOS = (HeaderDOS*)libraryPointer;

        if ((UInt16)((headerDOS->Magic << 8) | (headerDOS->Magic >> 8)) != IMAGE_DOS_SIGNATURE)
            return 0;

        HeadersNT* headerNT = (HeadersNT*)(libraryPointer + headerDOS->LFANEW);

        UInt32 addressLibrary = VirtualAlloc(headerNT->OptionalHeader.ImageBase, headerNT->OptionalHeader.SizeOfImage, AllocationType.RESERVE, MemoryProtection.READWRITE);

        if (addressLibrary == 0)
            addressLibrary = VirtualAlloc(0, headerNT->OptionalHeader.SizeOfImage, AllocationType.RESERVE, MemoryProtection.READWRITE);

        if (addressLibrary == 0)
            return 0;

        Library* library = (Library*)Marshal.AllocHGlobal(sizeof(Library));
        library->Address = (Byte*)addressLibrary;
        library->ModulesCount = 0;
        library->Modules = null;
        library->Initialized = false;

        VirtualAlloc(addressLibrary, headerNT->OptionalHeader.SizeOfImage, AllocationType.COMMIT, MemoryProtection.READWRITE);

        UInt32 addressHeaders = VirtualAlloc(addressLibrary, headerNT->OptionalHeader.SizeOfHeaders, AllocationType.COMMIT, MemoryProtection.READWRITE);

        MemoryCopy((Byte*)headerDOS, (Byte*)addressHeaders, (headerDOS->LFANEW + headerNT->OptionalHeader.SizeOfHeaders));

        library->Headers = (HeadersNT*)((Byte*)addressHeaders + headerDOS->LFANEW);
        library->Headers->OptionalHeader.ImageBase = addressLibrary;

        CopySections(library, headerNT, libraryPointer);

        UInt32 locationDelta = addressLibrary - headerNT->OptionalHeader.ImageBase;

        if (locationDelta != 0)
            PerformBaseRelocation(library, locationDelta);

        UInt32 libraryHandle = (UInt32)library;

        if (!BuildImportTable(library))
        {
            Free(libraryName);
            return 0;
        }

        FinalizeSections(library);

        if (library->Headers->OptionalHeader.AddressOfEntryPoint == 0)
        {
            Free(libraryName);
            return 0;
        }

        UInt32 libraryEntryPoint = addressLibrary + library->Headers->OptionalHeader.AddressOfEntryPoint;

        if (libraryEntryPoint == 0)
        {
            Free(libraryName);
            return 0;
        }

        LibraryMain main = (LibraryMain)Marshal.GetDelegateForFunctionPointer(new IntPtr(libraryEntryPoint), typeof(LibraryMain));
        UInt32 result = main(addressLibrary, DLL_PROCESS_ATTACH, 0);

        if (result == 0)
        {
            Free(libraryName);
            return 0;
        }

        library->Initialized = true;

        libraries[libraryName] = libraryHandle;

        return libraryHandle;
    }
}

And here is an example on how to use it:

private const Byte VK_Z_BREAK = 0x5A;

[UnmanagedFunctionPointer(CallingConvention.Cdecl)]
private delegate void KeyboardEventDelegate(Byte key, Byte scan, KeyboardFlags flags, Int32 extra);

[Flags]
private enum KeyboardFlags : uint
{
    EXTENDEDKEY = 0x0001,
    KEYUP = 0x0002,
}

public static void Main()
{
    UInt32 libraryHandle = LibraryLoader.Load("User32.dll");

    if (libraryHandle != 0)
    {
        UInt32 functionHandle = LibraryLoader.GetFunctionAddress("User32.dll", "keybd_event");

        if (functionHandle != 0)
        {
            KeyboardEventDelegate s_KeyboardEvent = (KeyboardEventDelegate)Marshal.GetDelegateForFunctionPointer(new IntPtr(functionHandle), typeof(KeyboardEventDelegate));

            while (true)
            {
                s_KeyboardEvent(VK_Z_BREAK, VK_Z_SCANCODE, 0, 0);
                s_KeyboardEvent(VK_Z_BREAK, VK_Z_SCANCODE, KeyboardFlags.KEYUP, 0);
            }
        }
    }

    Console.ReadLine();
}

If you want to give it a fast try, you can download the project from this link.

[EDIT] After a few tries, using Marshal.GetLastWin32Error() just after calling DllMain, I discovered that an error code 14 is being produced, which corresponds to ERROR_OUTOFMEMORY. If I go on after the DllMain call failure, and I get the address of a library function, trying to call it using a delegate produces a PInvokeStackImbalance exception. Any clues about this? ^_^

Answer 1

This code is only a first-order approximation of what the Windows loader does to load a DLL. It can only work for the simplest of DLLs, the translation from C to C# code is also highly likely to cause trouble like the stack imbalance problem you are dealing with. The chief problems I see:

• It doesn't do anything to ensure that the DLL wasn't already loaded before. This is pretty much guaranteed to be a source of trouble when you try to load kernel32.dll and user32.dll, those DLLs are already loaded before managed code starts executing. They will not take kindly to getting loaded again.

• It doesn't do anything obvious to ensure that dependent DLLs get loaded as well and that their DllMain() entrypoints are called in the correct order and strictly serialized.

• It doesn't do anything to properly deal with the managed code loader stub, MSCoree.dll, which makes it very unlikely you can ever properly load any DLLs that contain mixed mode code.

• It doesn't do anything to ensure that the Windows loader is aware of these modules, which makes it very likely that any subsequent request for the DLL will fail. Such failure is quite undiagnosable.

The likelihood that you'll be able to address these problems correctly is quite low.