Example #1
0
bool MoveToTrash::exec() const
{
    HRESULT result = CoInitializeEx(nullptr, COINIT_APARTMENTTHREADED | COINIT_DISABLE_OLE1DDE);

    if (!SUCCEEDED(result))
        return false;

    IFileOperation *fo = nullptr;
    result = CoCreateInstance(CLSID_FileOperation, nullptr, CLSCTX_ALL, IID_PPV_ARGS(&fo));

    if (!SUCCEEDED(result)) {
        CoUninitialize();
        return false;
    }

    ulong flags = FOF_ALLOWUNDO | FOF_NOCONFIRMATION | FOF_NOERRORUI | FOF_SILENT;

//    if (QSysInfo::windowsVersion() >= QSysInfo::WV_WINDOWS8)
//        flags |= FOFX_RECYCLEONDELETE;

    result = fo->SetOperationFlags(flags);

    if (SUCCEEDED(result)) {
        IShellItem *iShellItem = nullptr;
        result = SHCreateItemFromParsingName(path.toStdWString().c_str(), nullptr, IID_PPV_ARGS(&iShellItem));

        if (SUCCEEDED(result)) {
            result = fo->DeleteItem(iShellItem, nullptr);
            iShellItem->Release();
        }

        if (SUCCEEDED(result))
            result = fo->PerformOperations();
    }

    fo->Release();
    CoUninitialize();

    return SUCCEEDED(result);
}
Example #2
0
bool OsShell::deleteItems(const std::vector<std::wstring>& items, bool moveToTrash, void * parentWindow)
{
	ComInitializer comInitializer;

	assert_r(parentWindow);
	std::vector<ITEMIDLIST*> idLists;
	for (auto& path: items)
	{
		__unaligned ITEMIDLIST* idl = ILCreateFromPathW(path.c_str());
		if (!idl)
		{
			for (auto& pid : idLists)
				ILFree(pid);

			qInfo() << "ILCreateFromPathW" << "failed for path" << QString::fromWCharArray(path.c_str());
			return false;
		}
		idLists.push_back(idl);
		assert_r(idLists.back());
	}

	IShellItemArray * iArray = 0;
	HRESULT result = SHCreateShellItemArrayFromIDLists((UINT)idLists.size(), (LPCITEMIDLIST*)idLists.data(), &iArray);

	// Freeing memory
	for (auto& pid: idLists)
		ILFree(pid);
	idLists.clear();

	if (!SUCCEEDED(result) || !iArray)
	{
		qInfo() << "SHCreateShellItemArrayFromIDLists failed";
		return false;
	}

	IFileOperation * iOperation = 0;
	result = CoCreateInstance(CLSID_FileOperation, 0, CLSCTX_ALL, IID_IFileOperation, (void**)&iOperation);
	if (!SUCCEEDED(result) || !iOperation)
	{
		qInfo() << "CoCreateInstance(CLSID_FileOperation, 0, CLSCTX_ALL, IID_IFileOperation, (void**)&iOperation) failed";
		return false;
	}

	result = iOperation->DeleteItems(iArray);
	if (!SUCCEEDED(result))
	{
		qInfo() << "DeleteItems failed";
	}
	else
	{
		if (moveToTrash)
		{
			result = iOperation->SetOperationFlags(FOF_ALLOWUNDO);
		}
		else
			result = iOperation->SetOperationFlags(FOF_WANTNUKEWARNING);

		if (!SUCCEEDED(result))
			qInfo() << "SetOperationFlags failed";

		result = iOperation->SetOwnerWindow((HWND) parentWindow);
		if (!SUCCEEDED(result))
			qInfo() << "SetOwnerWindow failed";

		result = iOperation->PerformOperations();
		if (!SUCCEEDED(result) && result != COPYENGINE_E_USER_CANCELLED)
		{
			qInfo() << "PerformOperations failed";
			if (result == COPYENGINE_E_REQUIRES_ELEVATION)
				qInfo() << "Elevation required";
		}
		else
			result = S_OK;
	}

	iOperation->Release();
	iArray->Release();
	return SUCCEEDED(result);
}
static DWORD WINAPI RemoteCodeFunc(LPVOID lpThreadParameter)
{
	// This is the injected code of "part 1."

	// As this code is copied into another process it cannot refer to any static data (i.e. no string, GUID, etc. constants)
	// and it can only directly call functions that are within Kernel32.dll (which is all we need as it lets us call
	// LoadLibrary and GetProcAddress). The data we need (strings, GUIDs, etc.) is copied into the remote process and passed to
	// us in our InjectArgs structure.

	// The compiler settings are important. You have to ensure that RemoteCodeFunc doesn't do any stack checking (since it
	// involves a call into the CRT which may not exist (in the same place) in the target process) and isn't made inline
	// or anything like that. (Compiler optimizations are best turned off.) You need RemoteCodeFunc to be compiled into a
	// contiguous chunk of assembler that calls/reads/writes nothing except its own stack variables and what is passed to it via pArgs.

	// It's also important that all asm jump instructions in this code use relative addressing, not absolute. Jumps to absolute
	// addresses will not be valid after the code is copied to a different address in the target process. Visual Studio seems
	// to use absolute addresses sometimes and relative ones at other times and I'm not sure what triggers one or the other. For example,
	// I had a problem with it turning a lot of the if-statements in this code into absolute jumps when compiled for 32-bit and that
	// seemed to go away when I set the Release build to generate a PDF file, but then they came back again.
	// I never had this problem in February, and 64-bit builds always seem fine, but now in June I'm getting the problem with 32-bit
	// builds on my main machine. However, if I switch to the older compiler install and older Windows SDK that I have on another machine
	// it always builds a working 32-bit (and 64-bit) version, just like it used to. So I guess something in the compiler/SDK has triggered
	// this change but I don't know what. It could just be that things have moved around in memory due to a structure size change and that's
	// triggering the different modes... I don't know!
	//
	// So if the 32-bit version crashes the process you inject into, you probably need to work out how to convince the compiler
	// to generate the code it used to in February. :) Or you could write some code to fix up the jump instructions after copying them,
	// or hand-code the 32-bit asm (seems you can ignore 64-bit as it always works so far), or find a style of if-statement (or equivalent)
	// that always generates relative jumps, or whatever...
	//
	// Take a look at the asm_code_issue.png image that comes with the source to see what the absolute and relative jumps look like.
	//
	// PS: I've never written Intel assembler, and it's many years since I've hand-written any type of assembler, so I may have the wrong end
	// of the stick about some of this! Either way, 32-bit version works when built on my older compiler/SDK install and usually doesn't on
	// the newer install.

	InjectArgs * pArgs = reinterpret_cast< InjectArgs * >(lpThreadParameter);
	
	// Use an elevated FileOperation object to copy a file to a protected folder.
	// If we're in a process that can do silent COM elevation then we can do this without any prompts.

	HMODULE hModuleOle32    = pArgs->fpLoadLibrary(pArgs->szOle32);
	HMODULE hModuleShell32  = pArgs->fpLoadLibrary(pArgs->szShell32);

	if (hModuleOle32
	&&	hModuleShell32)
	{
		// Load the non-Kernel32.dll functions that we need.

		W7EUtils::GetProcAddr< HRESULT (STDAPICALLTYPE *)(LPVOID pvReserved) >
			tfpCoInitialize( pArgs->fpGetProcAddress, hModuleOle32, pArgs->szCoInitialize );

		W7EUtils::GetProcAddr< void (STDAPICALLTYPE *)(void) >
			tfpCoUninitialize( pArgs->fpGetProcAddress, hModuleOle32, pArgs->szCoUninitialize );

		W7EUtils::GetProcAddr< HRESULT (STDAPICALLTYPE *)(LPCWSTR pszName, BIND_OPTS *pBindOptions, REFIID riid, void **ppv) >
			tfpCoGetObject( pArgs->fpGetProcAddress, hModuleOle32, pArgs->szCoGetObject );

		W7EUtils::GetProcAddr< HRESULT (STDAPICALLTYPE *)(REFCLSID rclsid, LPUNKNOWN pUnkOuter, DWORD dwClsContext, REFIID riid, void ** ppv) >
			tfpCoCreateInstance( pArgs->fpGetProcAddress, hModuleOle32, pArgs->szCoCreateInstance );

		W7EUtils::GetProcAddr< HRESULT (STDAPICALLTYPE *)(PCWSTR pszPath, IBindCtx *pbc, REFIID riid, void **ppv) >
			tfpSHCreateItemFromParsingName( pArgs->fpGetProcAddress, hModuleShell32, pArgs->szSHCreateItemFPN );

		W7EUtils::GetProcAddr< BOOL (STDAPICALLTYPE *)(LPSHELLEXECUTEINFOW lpExecInfo) >
			tfpShellExecuteEx( pArgs->fpGetProcAddress, hModuleShell32, pArgs->szShellExecuteExW );

		if (0 != tfpCoInitialize.f
		&&	0 != tfpCoUninitialize.f
		&&	0 != tfpCoGetObject.f
		&&	0 != tfpCoCreateInstance.f
		&&	0 != tfpSHCreateItemFromParsingName.f
		&&	0 != tfpShellExecuteEx.f)
		{
			if (S_OK == tfpCoInitialize.f(NULL))
			{
				BIND_OPTS3 bo;
				for(int i = 0; i < sizeof(bo); ++i) { reinterpret_cast< BYTE * >(&bo)[i] = 0; } // This loop is easier than pushing ZeroMemory or memset through pArgs.
				bo.cbStruct = sizeof(bo);
				bo.dwClassContext = CLSCTX_LOCAL_SERVER;

				// For testing other COM objects/methods, start here.
				{
					IFileOperation *pFileOp = 0;
					IShellItem *pSHISource = 0;
					IShellItem *pSHIDestination = 0;
					IShellItem *pSHIDelete = 0;

					// This is a completely standard call to IFileOperation, if you ignore all the pArgs/func-pointer indirection.
					if (
						(pArgs->szEIFOMoniker  && S_OK == tfpCoGetObject.f( pArgs->szEIFOMoniker, &bo, *pArgs->pIID_EIFO, reinterpret_cast< void ** >(&pFileOp)))
					||	(pArgs->pIID_EIFOClass && S_OK == tfpCoCreateInstance.f( *pArgs->pIID_EIFOClass, NULL, CLSCTX_LOCAL_SERVER|CLSCTX_INPROC_SERVER|CLSCTX_INPROC_HANDLER, *pArgs->pIID_EIFO, reinterpret_cast< void ** >(&pFileOp)))
						)
					if (0    != pFileOp)
					if (S_OK == pFileOp->SetOperationFlags(FOF_NOCONFIRMATION|FOF_SILENT|FOFX_SHOWELEVATIONPROMPT|FOFX_NOCOPYHOOKS|FOFX_REQUIREELEVATION))
					if (S_OK == tfpSHCreateItemFromParsingName.f( pArgs->szSourceDll, NULL, *pArgs->pIID_ShellItem2, reinterpret_cast< void ** >(&pSHISource)))
					if (0    != pSHISource)
					if (S_OK == tfpSHCreateItemFromParsingName.f( pArgs->szElevDir, NULL, *pArgs->pIID_ShellItem2, reinterpret_cast< void ** >(&pSHIDestination)))
					if (0    != pSHIDestination)
					if (S_OK == pFileOp->CopyItem(pSHISource, pSHIDestination, pArgs->szElevDll, NULL))
					if (S_OK == pFileOp->PerformOperations())
					{
						// Use ShellExecuteEx to launch the "part 2" target process. Again, a completely standard API call.
						// (Note: Don't use CreateProcess as it seems not to do the auto-elevation stuff.)
						SHELLEXECUTEINFO shinfo;
						for(int i = 0; i < sizeof(shinfo); ++i) { reinterpret_cast< BYTE * >(&shinfo)[i] = 0; } // This loop is easier than pushing ZeroMemory or memset through pArgs.
						shinfo.cbSize = sizeof(shinfo);
						shinfo.fMask = SEE_MASK_NOCLOSEPROCESS;
						shinfo.lpFile = pArgs->szElevExeFull;
						shinfo.lpParameters = pArgs->szElevArgs;
						shinfo.lpDirectory = pArgs->szElevDir;
						shinfo.nShow = SW_SHOW;

						if (tfpShellExecuteEx.f(&shinfo) && shinfo.hProcess != NULL)
						{
							// Wait for the "part 2" target process to finish.
							pArgs->fpWaitForSingleObject(shinfo.hProcess, INFINITE);

							pArgs->fpCloseHandle(shinfo.hProcess);
						}

						// Another standard call to IFileOperation, this time to delete our dummy DLL. We clean up our mess.
						if (S_OK == tfpSHCreateItemFromParsingName.f( pArgs->szElevDllFull, NULL, *pArgs->pIID_ShellItem2, reinterpret_cast< void ** >(&pSHIDelete)))
						if (0    != pSHIDelete)
						if (S_OK == pFileOp->DeleteItem(pSHIDelete, NULL))
						{
							pFileOp->PerformOperations();
						}
					}

					if (pSHIDelete)      { pSHIDelete->Release();      }
					if (pSHIDestination) { pSHIDestination->Release(); }
					if (pSHISource)      { pSHISource->Release();      }
					if (pFileOp)         { pFileOp->Release();         }
				}

				tfpCoUninitialize.f();
			}
		}
	}

	if (hModuleShell32)  { pArgs->fpFreeLibrary(hModuleShell32);  }
	if (hModuleOle32)    { pArgs->fpFreeLibrary(hModuleOle32);    }

	return 0;
}