Process Herpaderping is a method of obscuring the intentions of a process by modifying the content on disk after the image has been mapped. This results in curious behavior by security products and the OS itself.
Generally, a security product takes action on process creation by registering a callback in the Windows Kernel (PsSetCreateProcessNotifyRoutineEx). At this point, a security product may inspect the file that was used to map the executable and determine if this process should be allowed to execute. This kernel callback is invoked when the initial thread is inserted, not when the process object is created.
Because of this, an actor can create and map a process, modify the content of the file, then create the initial thread. A product that does inspection at the creation callback would see the modified content. Additionally, some products use an on-write scanning approach which consists of monitoring for file writes. A familiar optimization here is recording the file has been written to and defer the actual inspection until IRP_MJ_CLEANUP occurs (e.g. the file handle is closed). Thus, an actor using a
write -> map -> modify -> execute -> close workflow will subvert on-write scanning that solely relies on inspection at IRP_MJ_CLEANUP.
To abuse this convention, we first write a binary to a target file on disk. Then, we map an image of the target file and provide it to the OS to use for process creation. The OS kindly maps the original binary for us. Using the existing file handle, and before creating the initial thread, we modify the target file content to obscure or fake the file backing the image. Some time later, we create the initial thread to begin execution of the original binary. Finally, we will close the target file handle. Let’s walk through this step-by-step:
- Write target binary to disk, keeping the handle open. This is what will execute in memory.
- Map the file as an image section (NtCreateSection, SEC_IMAGE).
- Create the process object using the section handle (
- Using the same target file handle, obscure the file on disk.
- Create the initial thread in the process (
- At this point the process creation callback in the kernel will fire. The contents on disk do not match what was mapped. Inspection of the file at this point will result in incorrect attribution.
- Close the handle. IRP_MJ_CLEANUP will occur here.
- Since we’ve hidden the contents of what is executing, inspection at this point will result in incorrect attribution.
hide empty description
[*] --> CreateFile
CreateFile --> FileHandle
FileHandle --> Write
FileHandle --> NtCreateSection
Write -[hidden]-> NtCreateSection
NtCreateSection --> SectionHandle
SectionHandle --> NtCreateProcessEx
FileHandle --> Modify
NtCreateProcessEx -[hidden]-> Modify
NtCreateProcessEx --> NtCreateThreadEx
Modify -[hidden]-> NtCreateThreadEx
NtCreateThreadEx --> [*]
FileHandle --> CloseFile
NtCreateThreadEx -[hidden]-> CloseFile
NtCreateThreadEx --> PspCallProcessNotifyRoutines
PspCallProcessNotifyRoutines -[hidden]-> [*]
CloseFile --> IRP_MJ_CLEANUP
IRP_MJ_CLEANUP -[hidden]-> [*]
PspCallProcessNotifyRoutines --> Inspect
PspCallProcessNotifyRoutines -[hidden]-> CloseFile
IRP_MJ_CLEANUP --> Inspect
Inspect -[hidden]-> [*]
CreateFile : Create target file, keep handle open.
Write : Write source payload into target file.
Modify : Obscure the file on disk.
NtCreateSection : Create section using file handle.
NtCreateProcessEx : Image section for process is mapped and cached in file object.
NtCreateThreadEx : The cached section is used.
NtCreateThreadEx : Process notify routines fire in kernel.
Inspect : The contents on disk do not match what was executed.
Inspect : Inspection of the file at this point will result in incorrect attribution.
You’ll see in the demo below,
CMD.exe is used as the execution target. The first run overwrites the bytes on disk with a pattern. The second run overwrites
ProcessHacker.exe. The Herpaderping tool fixes up the binary to look as close to
ProcessHacker.exe as possible, even retaining the original signature. Note the multiple executions of the same binary and how the process looks to the user compared to what is in the file on disk.
We’ve observed the behavior and some of this may be surprising. Let’s try to explain this behavior.
Background and Motivation
When designing products for securing Windows platforms, many engineers in this field (myself included) have fallen on preconceived notions with respect to how the OS will handle data. In this scenario, some might expect the file on disk to remain “locked” when the process is created. You can’t delete the file. You can’t write to it. But you can rename it. Seen here, under the right conditions, you can in fact write to it. Remain vigilant on your assumptions, always question them, and do your research.
The motivation for this research came about when discovering how to do analysis when a file is written. With prior background researching process Hollowing and Doppelganging, I had theorized this might be possible. The goal is to provide better security. You cannot create a better lock without first understanding how to break the old one.
Herpaderping is similar to Hollowing and Doppelganging however there are some key differences:
Process Hollowing involves modifying the mapped section before execution begins, which abstractly this looks like:
map -> modify section -> execute. This workflow results in the intended execution flow of the Hollowed process diverging into unintended code. Doppelganging might be considered a form of Hollowing. However, Hollowing, in my opinion, is closer to injection in that Hollowing usually involves an explicit write to the already mapped code. This differs from Herpaderping where there are no modified sections.
Process Doppelganging is closer to Herpaderping. Doppelganging abuses transacted file operations and generally involves these steps:
transact -> write -> map -> rollback -> execute. In this workflow, the OS will create the image section and account for transactions, so the cached image section ends up being what you wrote to the transaction. The OS has patched this technique. Well, they patched the crash it caused. Maybe they consider this a “legal” use of a transaction. Thankfully, Windows Defender does catch the Doppelganging technique. Doppelganging differs from Herpaderping in that Herpaderping does not rely on transacted file operations. And Defender doesn’t catch Herpaderping.
For reference, the generalized techniques:
We can see the differences laid out here. While Herpaderping is arguably noisier than Doppelganging, in that the malicious bits do hit the disk, we’ve seen that security products are still incapable of detecting Herpaderping.
There is not a clear fix here. It seems reasonable that preventing an image section from being mapped/cached when there is write access to the file should close the hole. However, that may or may not be a practical solution.
Another option might be to flush the changes to the file through to the cached image section if it hasn’t yet been mapped into a process. However, since the map into the new process occurs at
NtCreateProcess that is probably not a viable solution.
From a detection standpoint, there is not a great way to identify the actual bits that got mapped, inspection at IRP_MJ_CLEANUP or a callback registered at PsSetCreateProcessNotifyRoutineEx results in incorrect attribution since the bits on disk have been changed, you would have to rebuild the file from the section that got created. It’s worth pointing out here there is a new callback in Windows 10 you may register for PsSetCreateProcessNotifyRoutineEx2 however this suffers from the same problem as the previous callback, it’s called out when the initial thread is executed, not when the process object is created. Microsoft did add PsSetCreateThreadNotifyRoutineEx which is called out when the initial thread is inserted if registered with PsCreateThreadNotifyNonSystem, opposed to when it is about to begin execution (as the old callback did). Extending PSCREATEPROCESSNOTIFYTYPE to be called out when the process object is created won’t help either, we’ve seen in the Diving Deeper section that the image section object is cached on the NtCreateSection call not
We can’t easily identify what got executed. We’re left with trying to detect the exploitive behavior by the actor, I’ll leave discovery of the behavior indicators as an exercise for the reader.
Known Affected Platforms
Below is a list of products and Windows OSes that have been tested as of (8/31/2020). Tests were carried out with a known malicious binary.
|Windows 7 Enterprise x86||6.1.7601||Yes|
|Windows 10 Pro x64||10.0.18363.900||Yes|
|Windows 10 Pro Insider Preview x64||10.0.20170.1000||Yes|
|Windows 10 Pro Insider Preview x64||10.0.20201.1000||Yes|
|Windows Defender AntiMalware Client||4.18.2006.10||Yes|
|Windows Defender Engine||1.1.17200.2||Yes|
|Windows Defender Antivirus||1.319.1127.0||Yes|
|Windows Defender Antispyware||1.319.1127.0||Yes|
|Windows Defender AntiMalware Client||4.18.2007.6||Yes|
|Windows Defender Engine||1.1.17300.2||Yes|
|Windows Defender Antivirus||1.319.1676.0||Yes|
|Windows Defender Antispyware||1.319.1676.0||Yes|
|Windows Defender AntiMalware Client||4.18.2007.8||Yes|
|Windows Defender Engine||1.1.17400.5||Yes|
|Windows Defender Antivirus||1.323.267.0||Yes|
|Windows Defender Antispyware||1.323.267.0||Yes|
This vulnerability was disclosed to the Microsoft Security Response Center (MSRC) on 7/17/2020 and a case was opened by MSRC on 7/22/2020. MSRC concluded their investigation on 8/25/2020 and determined the findings are valid but do not meet their bar for immediate servicing. At this time their case is closed, without resolution, and is marked for future review, with no timeline.
We disagree on the severity of this bug; this was communicated to MSRC on 8/27/2020.
- There are similar vulnerabilities in this class (Hollowing and Doppelganging).
- The vulnerability is shown to defeat security features inherent to the OS (Windows Defender).
- The vulnerability allows an actor to gain execution of arbitrary code.
- The user is not notified of the execution of unintended code.
- The process information presented to the user does not accurately reflect what is executing.
- Facilities to accurately identify the process are not intuitive or incorrect, even from the kernel.
This repo contains a tool for exercising the Herpaderping method of process obfuscation. Usage is as follows:
Process Herpaderping Tool - Copyright (c) Johnny Shaw
ProcessHerpaderping.exe SourceFile TargetFile [ReplacedWith] [Options...]
SourceFile Source file to execute.
TargetFile Target file to execute the source from.
ReplacedWith File to replace the target with. Optional,
default overwrites the binary with a pattern.
-h,--help Prints tool usage.
-d,--do-not-wait Does not wait for spawned process to exit,
-l,--logging-mask number Specifies the logging mask, defaults to full
-q,--quiet Runs quietly, overrides logging mask, no title.
-r,--random-obfuscation Uses random bytes rather than a pattern for
-e,--exclusive Target file is created with exclusive access and
the handle is held open as long as possible.
Without this option the handle has full share
access and is closed as soon as possible.
-u,--do-not-flush-file Does not flush file after overwrite.
-c,--close-file-early Closes file before thread creation (before the
process notify callback fires in the kernel).
Not valid with "--exclusive" option.
-k,--kill Terminates the spawned process regardless of
success or failure, this is useful in some
automation environments. Forces "--do-not-wait
Cloning and Building
The repo uses submodules, after cloning be sure to init and update the submodules. Projects files are targeted to Visual Studio 2019.
git clone https://github.com/jxy-s/herpaderping.git
git submodule update --init --recursive
The following are used without modification. Credits to their authors.
- Windows Implementation Libraries (WIL)
A header-only C++ library created to make life easier for developers on Windows through readable type-safe C++ interfaces for common Windows coding patterns.
- Process Hacker Native API Headers
Collection of Native API header files. Gathered from Microsoft header files and symbol files, as well as a lot of reverse engineering and guessing.