Windows Local Privilege Escalation
Last updated
Last updated
Learn & practice AWS Hacking:HackTricks Training AWS Red Team Expert (ARTE) Learn & practice GCP Hacking: HackTricks Training GCP Red Team Expert (GRTE)
If you don't know what are Windows Access Tokens, read the following page before continuing:
Access TokensCheck the following page for more info about ACLs - DACLs/SACLs/ACEs:
ACLs - DACLs/SACLs/ACEsIf you don't know what are integrity levels in Windows you should read the following page before continuing:
Integrity LevelsThere are different things in Windows that could prevent you from enumerating the system, run executables or even detect your activities. You should read the following page and enumerate all these defenses mechanisms before starting the privilege escalation enumeration:
Windows Security ControlsCheck if the Windows version has any known vulnerability (check also the patches applied).
This site is handy for searching out detailed information about Microsoft security vulnerabilities. This database has more than 4,700 security vulnerabilities, showing the massive attack surface that a Windows environment presents.
On the system
post/windows/gather/enum_patches
post/multi/recon/local_exploit_suggester
winpeas (Winpeas has watson embedded)
Locally with system information
Github repos of exploits:
Any credential/Juicy info saved in the env variables?
You can learn how to turn this on in https://sid-500.com/2017/11/07/powershell-enabling-transcription-logging-by-using-group-policy/
Details of PowerShell pipeline executions are recorded, encompassing executed commands, command invocations, and parts of scripts. However, complete execution details and output results might not be captured.
To enable this, follow the instructions in the "Transcript files" section of the documentation, opting for "Module Logging" instead of "Powershell Transcription".
To view the last 15 events from PowersShell logs you can execute:
A complete activity and full content record of the script's execution is captured, ensuring that every block of code is documented as it runs. This process preserves a comprehensive audit trail of each activity, valuable for forensics and analyzing malicious behavior. By documenting all activity at the time of execution, detailed insights into the process are provided.
Logging events for the Script Block can be located within the Windows Event Viewer at the path: Application and Services Logs > Microsoft > Windows > PowerShell > Operational. To view the last 20 events you can use:
You can compromise the system if the updates are not requested using httpS but http.
You start by checking if the network uses a non-SSL WSUS update by running the following:
If you get a reply such as:
And if HKLM\Software\Policies\Microsoft\Windows\WindowsUpdate\AU /v UseWUServer
is equals to 1
.
Then, it is exploitable. If the last registry is equals to 0, then, the WSUS entry will be ignored.
In orther to exploit this vulnerabilities you can use tools like: Wsuxploit, pyWSUS - These are MiTM weaponized exploits scripts to inject 'fake' updates into non-SSL WSUS traffic.
Read the research here:
WSUS CVE-2020-1013
Read the complete report here. Basically, this is the flaw that this bug exploits:
If we have the power to modify our local user proxy, and Windows Updates uses the proxy configured in Internet Explorer’s settings, we therefore have the power to run PyWSUS locally to intercept our own traffic and run code as an elevated user on our asset.
Furthermore, since the WSUS service uses the current user’s settings, it will also use its certificate store. If we generate a self-signed certificate for the WSUS hostname and add this certificate into the current user’s certificate store, we will be able to intercept both HTTP and HTTPS WSUS traffic. WSUS uses no HSTS-like mechanisms to implement a trust-on-first-use type validation on the certificate. If the certificate presented is trusted by the user and has the correct hostname, it will be accepted by the service.
You can exploit this vulnerability using the tool WSUSpicious (once it's liberated).
A local privilege escalation vulnerability exists in Windows domain environments under specific conditions. These conditions include environments where LDAP signing is not enforced, users possess self-rights allowing them to configure Resource-Based Constrained Delegation (RBCD), and the capability for users to create computers within the domain. It is important to note that these requirements are met using default settings.
Find the exploit in https://github.com/Dec0ne/KrbRelayUp
For more information about the flow of the attack check https://research.nccgroup.com/2019/08/20/kerberos-resource-based-constrained-delegation-when-an-image-change-leads-to-a-privilege-escalation/
If these 2 registers are enabled (value is 0x1), then users of any privilege can install (execute) *.msi
files as NT AUTHORITY\SYSTEM.
If you have a meterpreter session you can automate this technique using the module exploit/windows/local/always_install_elevated
Use the Write-UserAddMSI
command from power-up to create inside the current directory a Windows MSI binary to escalate privileges. This script writes out a precompiled MSI installer that prompts for a user/group addition (so you will need GIU access):
Just execute the created binary to escalate privileges.
Read this tutorial to learn how to create a MSI wrapper using this tools. Note that you can wrap a ".bat" file if you just want to execute command lines
MSI WrapperGenerate with Cobalt Strike or Metasploit a new Windows EXE TCP payload in C:\privesc\beacon.exe
Open Visual Studio, select Create a new project and type "installer" into the search box. Select the Setup Wizard project and click Next.
Give the project a name, like AlwaysPrivesc, use C:\privesc
for the location, select place solution and project in the same directory, and click Create.
Keep clicking Next until you get to step 3 of 4 (choose files to include). Click Add and select the Beacon payload you just generated. Then click Finish.
Highlight the AlwaysPrivesc project in the Solution Explorer and in the Properties, change TargetPlatform from x86 to x64.
There are other properties you can change, such as the Author and Manufacturer which can make the installed app look more legitimate.
Right-click the project and select View > Custom Actions.
Right-click Install and select Add Custom Action.
Double-click on Application Folder, select your beacon.exe file and click OK. This will ensure that the beacon payload is executed as soon as the installer is run.
Under the Custom Action Properties, change Run64Bit to True.
Finally, build it.
If the warning File 'beacon-tcp.exe' targeting 'x64' is not compatible with the project's target platform 'x86'
is shown, make sure you set the platform to x64.
To execute the installation of the malicious .msi
file in background:
To exploit this vulnerability you can use: exploit/windows/local/always_install_elevated
These settings decide what is being logged, so you should pay attention
Windows Event Forwarding, is interesting to know where are the logs sent
LAPS is designed for the management of local Administrator passwords, ensuring that each password is unique, randomised, and regularly updated on computers joined to a domain. These passwords are securely stored within Active Directory and can only be accessed by users who have been granted sufficient permissions through ACLs, allowing them to view local admin passwords if authorized.
LAPSIf active, plain-text passwords are stored in LSASS (Local Security Authority Subsystem Service). More info about WDigest in this page.
Starting with Windows 8.1, Microsoft introduced enhanced protection for the Local Security Authority (LSA) to block attempts by untrusted processes to read its memory or inject code, further securing the system. More info about LSA Protection here.
Credential Guard wasn introduced in Windows 10. Its purpose is to safeguard the credentials stored on a device against threats like pass-the-hash attacks.| More info about Credentials Guard here.
Domain credentials are authenticated by the Local Security Authority (LSA) and utilized by operating system components. When a user's logon data is authenticated by a registered security package, domain credentials for the user are typically established. More info about Cached Credentials here.
You should check if any of the groups where you belong have interesting permissions
If you belongs to some privileged group you may be able to escalate privileges. Learn about privileged groups and how to abuse them to escalate privileges here:
Privileged GroupsLearn more about what is a token in this page: Windows Tokens. Check the following page to learn about interesting tokens and how to abuse them:
Abusing TokensFirst of all, listing the processes check for passwords inside the command line of the process. Check if you can overwrite some binary running or if you have write permissions of the binary folder to exploit possible DLL Hijacking attacks:
Always check for possible electron/cef/chromium debuggers running, you could abuse it to escalate privileges.
Checking permissions of the processes binaries
Checking permissions of the folders of the processes binaries (DLL Hijacking)
You can create a memory dump of a running process using procdump from sysinternals. Services like FTP have the credentials in clear text in memory, try to dump the memory and read the credentials.
Applications running as SYSTEM may allow an user to spawn a CMD, or browse directories.
Example: "Windows Help and Support" (Windows + F1), search for "command prompt", click on "Click to open Command Prompt"
Get a list of services:
You can use sc to get information of a service
It is recommended to have the binary accesschk from Sysinternals to check the required privilege level for each service.
It is recommended to check if "Authenticated Users" can modify any service:
You can download accesschk.exe for XP for here
If you are having this error (for example with SSDPSRV):
System error 1058 has occurred. The service cannot be started, either because it is disabled or because it has no enabled devices associated with it.
You can enable it using
Take into account that the service upnphost depends on SSDPSRV to work (for XP SP1)
Another workaround of this problem is running:
In the scenario where the "Authenticated users" group possesses SERVICE_ALL_ACCESS on a service, modification of the service's executable binary is possible. To modify and execute sc:
Privileges can be escalated through various permissions:
SERVICE_CHANGE_CONFIG: Allows reconfiguration of the service binary.
WRITE_DAC: Enables permission reconfiguration, leading to the ability to change service configurations.
WRITE_OWNER: Permits ownership acquisition and permission reconfiguration.
GENERIC_WRITE: Inherits the ability to change service configurations.
GENERIC_ALL: Also inherits the ability to change service configurations.
For the detection and exploitation of this vulnerability, the exploit/windows/local/service_permissions can be utilized.
Check if you can modify the binary that is executed by a service or if you have write permissions on the folder where the binary is located (DLL Hijacking). You can get every binary that is executed by a service using wmic (not in system32) and check your permissions using icacls:
You can also use sc and icacls:
You should check if you can modify any service registry. You can check your permissions over a service registry doing:
It should be checked whether Authenticated Users or NT AUTHORITY\INTERACTIVE possess FullControl
permissions. If so, the binary executed by the service can be altered.
To change the Path of the binary executed:
If you have this permission over a registry this means to you can create sub registries from this one. In case of Windows services this is enough to execute arbitrary code:
AppendData/AddSubdirectory permission over service registryIf the path to an executable is not inside quotes, Windows will try to execute every ending before a space.
For example, for the path C:\Program Files\Some Folder\Service.exe Windows will try to execute:
List all unquoted service paths, excluding those belonging to built-in Windows services:
You can detect and exploit this vulnerability with metasploit: exploit/windows/local/trusted\_service\_path
You can manually create a service binary with metasploit:
Windows allows users to specify actions to be taken if a service fails. This feature can be configured to point to a binary. If this binary is replaceable, privilege escalation might be possible. More details can be found in the official documentation.
Check permissions of the binaries (maybe you can overwrite one and escalate privileges) and of the folders (DLL Hijacking).
Check if you can modify some config file to read some special file or if you can modify some binary that is going to be executed by an Administrator account (schedtasks).
A way to find weak folder/files permissions in the system is doing:
Check if you can overwrite some registry or binary that is going to be executed by a different user. Read the following page to learn more about interesting autoruns locations to escalate privileges:
Privilege Escalation with AutorunsLook for possible third party weird/vulnerable drivers
If you have write permissions inside a folder present on PATH you could be able to hijack a DLL loaded by a process and escalate privileges.
Check permissions of all folders inside PATH:
For more information about how to abuse this check:
Writable Sys Path +Dll Hijacking PrivescCheck for other known computers hardcoded on the hosts file
Check for restricted services from the outside
Check this page for Firewall related commands (list rules, create rules, turn off, turn off...)
More commands for network enumeration here
Binary bash.exe
can also be found in C:\Windows\WinSxS\amd64_microsoft-windows-lxssbash_[...]\bash.exe
If you get root user you can listen on any port (the first time you use nc.exe
to listen on a port it will ask via GUI if nc
should be allowed by the firewall).
To easily start bash as root, you can try --default-user root
You can explore the WSL
filesystem in the folder C:\Users\%USERNAME%\AppData\Local\Packages\CanonicalGroupLimited.UbuntuonWindows_79rhkp1fndgsc\LocalState\rootfs\
From https://www.neowin.net/news/windows-7-exploring-credential-manager-and-windows-vault The Windows Vault stores user credentials for servers, websites and other programs that Windows can log in the users automatically. At first instance, this might look like now users can store their Facebook credentials, Twitter credentials, Gmail credentials etc., so that they automatically log in via browsers. But it is not so.
Windows Vault stores credentials that Windows can log in the users automatically, which means that any Windows application that needs credentials to access a resource (server or a website) can make use of this Credential Manager & Windows Vault and use the credentials supplied instead of users entering the username and password all the time.
Unless the applications interact with Credential Manager, I don't think it is possible for them to use the credentials for a given resource. So, if your application wants to make use of the vault, it should somehow communicate with the credential manager and request the credentials for that resource from the default storage vault.
Use the cmdkey
to list the stored credentials on the machine.
Then you can use runas
with the /savecred
options in order to use the saved credentials. The following example is calling a remote binary via an SMB share.
Using runas
with a provided set of credential.
Note that mimikatz, lazagne, credentialfileview, VaultPasswordView, or from Empire Powershells module.
The Data Protection API (DPAPI) provides a method for symmetric encryption of data, predominantly used within the Windows operating system for the symmetric encryption of asymmetric private keys. This encryption leverages a user or system secret to significantly contribute to entropy.
DPAPI enables the encryption of keys through a symmetric key that is derived from the user's login secrets. In scenarios involving system encryption, it utilizes the system's domain authentication secrets.
Encrypted user RSA keys, by using DPAPI, are stored in the %APPDATA%\Microsoft\Protect\{SID}
directory, where {SID}
represents the user's Security Identifier. The DPAPI key, co-located with the master key that safeguards the user's private keys in the same file, typically consists of 64 bytes of random data. (It's important to note that access to this directory is restricted, preventing listing its contents via the dir
command in CMD, though it can be listed through PowerShell).
You can use mimikatz module dpapi::masterkey
with the appropriate arguments (/pvk
or /rpc
) to decrypt it.
The credentials files protected by the master password are usually located in:
You can use mimikatz module dpapi::cred
with the appropiate /masterkey
to decrypt.
You can extract many DPAPI masterkeys from memory with the sekurlsa::dpapi
module (if you are root).
PowerShell credentials are often used for scripting and automation tasks as a way to store encrypted credentials conveniently. The credentials are protected using DPAPI, which typically means they can only be decrypted by the same user on the same computer they were created on.
To decrypt a PS credentials from the file containing it you can do:
You can find them on HKEY_USERS\<SID>\Software\Microsoft\Terminal Server Client\Servers\
and in HKCU\Software\Microsoft\Terminal Server Client\Servers\
Use the Mimikatz dpapi::rdg
module with appropriate /masterkey
to decrypt any .rdg files
You can extract many DPAPI masterkeys from memory with the Mimikatz sekurlsa::dpapi
module
People often use the StickyNotes app on Windows workstations to save passwords and other information, not realizing it is a database file. This file is located at C:\Users\<user>\AppData\Local\Packages\Microsoft.MicrosoftStickyNotes_8wekyb3d8bbwe\LocalState\plum.sqlite
and is always worth searching for and examining.
Note that to recover passwords from AppCmd.exe you need to be Administrator and run under a High Integrity level.
AppCmd.exe is located in the %systemroot%\system32\inetsrv\
directory.
If this file exists then it is possible that some credentials have been configured and can be recovered.
This code was extracted from PowerUP:
Check if C:\Windows\CCM\SCClient.exe
exists .
Installers are run with SYSTEM privileges, many are vulnerable to DLL Sideloading (Info from https://github.com/enjoiz/Privesc).
SSH private keys can be stored inside the registry key HKCU\Software\OpenSSH\Agent\Keys
so you should check if there is anything interesting in there:
If you find any entry inside that path it will probably be a saved SSH key. It is stored encrypted but can be easily decrypted using https://github.com/ropnop/windows_sshagent_extract. More information about this technique here: https://blog.ropnop.com/extracting-ssh-private-keys-from-windows-10-ssh-agent/
If ssh-agent
service is not running and you want it to automatically start on boot run:
It looks like this technique isn't valid anymore. I tried to create some ssh keys, add them with ssh-add
and login via ssh to a machine. The registry HKCU\Software\OpenSSH\Agent\Keys doesn't exist and procmon didn't identify the use of dpapi.dll
during the asymmetric key authentication.
You can also search for these files using metasploit: post/windows/gather/enum_unattend
Example content:
Search for a file called SiteList.xml
A feature was previously available that allowed the deployment of custom local administrator accounts on a group of machines via Group Policy Preferences (GPP). However, this method had significant security flaws. Firstly, the Group Policy Objects (GPOs), stored as XML files in SYSVOL, could be accessed by any domain user. Secondly, the passwords within these GPPs, encrypted with AES256 using a publicly documented default key, could be decrypted by any authenticated user. This posed a serious risk, as it could allow users to gain elevated privileges.
To mitigate this risk, a function was developed to scan for locally cached GPP files containing a "cpassword" field that is not empty. Upon finding such a file, the function decrypts the password and returns a custom PowerShell object. This object includes details about the GPP and the file's location, aiding in the identification and remediation of this security vulnerability.
Search in C:\ProgramData\Microsoft\Group Policy\history
or in C:\Documents and Settings\All Users\Application Data\Microsoft\Group Policy\history (previous to W Vista) for these files:
Groups.xml
Services.xml
Scheduledtasks.xml
DataSources.xml
Printers.xml
Drives.xml
To decrypt the cPassword:
Using crackmapexec to get the passwords:
Example of web.config with credentials:
You can always ask the user to enter his credentials of even the credentials of a different user if you think he can know them (notice that asking the client directly for the credentials is really risky):
Known files that some time ago contained passwords in clear-text or Base64
Search all of the proposed files:
You should also check the Bin to look for credentials inside it
To recover passwords saved by several programs you can use: http://www.nirsoft.net/password_recovery_tools.html
Other possible registry keys with credentials
Extract openssh keys from registry.
You should check for dbs where passwords from Chrome or Firefox are stored. Also check for the history, bookmarks and favourites of the browsers so maybe some passwords are stored there.
Tools to extract passwords from browsers:
Mimikatz: dpapi::chrome
Component Object Model (COM) is a technology built within the Windows operating system that allows intercommunication between software components of different languages. Each COM component is identified via a class ID (CLSID) and each component exposes functionality via one or more interfaces, identified via interface IDs (IIDs).
COM classes and interfaces are defined in the registry under HKEY_CLASSES_ROOT\CLSID and HKEY_CLASSES_ROOT\Interface respectively. This registry is created by merging the HKEY_LOCAL_MACHINE\Software\Classes + HKEY_CURRENT_USER\Software\Classes = HKEY_CLASSES_ROOT.
Inside the CLSIDs of this registry you can find the child registry InProcServer32 which contains a default value pointing to a DLL and a value called ThreadingModel that can be Apartment (Single-Threaded), Free (Multi-Threaded), Both (Single or Multi) or Neutral (Thread Neutral).
Basically, if you can overwrite any of the DLLs that are going to be executed, you could escalate privileges if that DLL is going to be executed by a different user.
To learn how attackers use COM Hijacking as a persistence mechanism check:
COM HijackingSearch for file contents
Search for a file with a certain filename
Search the registry for key names and passwords
MSF-Credentials Plugin is a msf plugin I have created this plugin to automatically execute every metasploit POST module that searches for credentials inside the victim. Winpeas automatically search for all the files containing passwords mentioned in this page. Lazagne is another great tool to extract password from a system.
The tool SessionGopher search for sessions, usernames and passwords of several tools that save this data in clear text (PuTTY, WinSCP, FileZilla, SuperPuTTY, and RDP)
Imagine that a process running as SYSTEM open a new process (OpenProcess()
) with full access. The same process also create a new process (CreateProcess()
) with low privileges but inheriting all the open handles of the main process.
Then, if you have full access to the low privileged process, you can grab the open handle to the privileged process created with OpenProcess()
and inject a shellcode.
Read this example for more information about how to detect and exploit this vulnerability.
Read this other post for a more complete explanation on how to test and abuse more open handlers of processes and threads inherited with different levels of permissions (not only full access).
Shared memory segments, referred to as pipes, enable process communication and data transfer.
Windows provides a feature called Named Pipes, allowing unrelated processes to share data, even over different networks. This resembles a client/server architecture, with roles defined as named pipe server and named pipe client.
When data is sent through a pipe by a client, the server that set up the pipe has the ability to take on the identity of the client, assuming it has the necessary SeImpersonate rights. Identifying a privileged process that communicates via a pipe you can mimic provides an opportunity to gain higher privileges by adopting the identity of that process once it interacts with the pipe you established. For instructions on executing such an attack, helpful guides can be found here and here.
Also the following tool allows to intercept a named pipe communication with a tool like burp: https://github.com/gabriel-sztejnworcel/pipe-intercept and this tool allows to list and see all the pipes to find privescs https://github.com/cyberark/PipeViewer
When getting a shell as a user, there may be scheduled tasks or other processes being executed which pass credentials on the command line. The script below captures process command lines every two seconds and compares the current state with the previous state, outputting any differences.
If you have access to the graphical interface (via console or RDP) and UAC is enabled, in some versions of Microsoft Windows it's possible to run a terminal or any other process such as "NT\AUTHORITY SYSTEM" from an unprivileged user.
This makes it possible to escalate privileges and bypass UAC at the same time with the same vulnerability. Additionally, there is no need to install anything and the binary used during the process, is signed and issued by Microsoft.
Some of the affected systems are the following:
To exploit this vulnerability, it's necessary to perform the following steps:
You have all the necessary files and information in the following GitHub repository:
https://github.com/jas502n/CVE-2019-1388
Read this to learn about Integrity Levels:
Integrity LevelsThen read this to learn about UAC and UAC bypasses:
UAC - User Account ControlIf you are already running on a High Integrity process, the pass to SYSTEM can be easy just creating and executing a new service:
From a High Integrity process you could try to enable the AlwaysInstallElevated registry entries and install a reverse shell using a .msi wrapper. More information about the registry keys involved and how to install a .msi package here.
You can find the code here.
If you have those token privileges (probably you will find this in an already High Integrity process), you will be able to open almost any process (not protected processes) with the SeDebug privilege, copy the token of the process, and create an arbitrary process with that token. Using this technique is usually selected any process running as SYSTEM with all the token privileges (yes, you can find SYSTEM processes without all the token privileges). You can find an example of code executing the proposed technique here.
This technique is used by meterpreter to escalate in getsystem
. The technique consists on creating a pipe and then create/abuse a service to write on that pipe. Then, the server that created the pipe using the SeImpersonate
privilege will be able to impersonate the token of the pipe client (the service) obtaining SYSTEM privileges.
If you want to learn more about name pipes you should read this.
If you want to read an example of how to go from high integrity to System using name pipes you should read this.
If you manages to hijack a dll being loaded by a process running as SYSTEM you will be able to execute arbitrary code with those permissions. Therefore Dll Hijacking is also useful to this kind of privilege escalation, and, moreover, if far more easy to achieve from a high integrity process as it will have write permissions on the folders used to load dlls. You can learn more about Dll hijacking here.
Read: https://github.com/itm4n/FullPowers
Best tool to look for Windows local privilege escalation vectors: WinPEAS
PS
PrivescCheck
PowerSploit-Privesc(PowerUP) -- Check for misconfigurations and sensitive files (check here). Detected.
JAWS -- Check for some possible misconfigurations and gather info (check here).
privesc -- Check for misconfigurations
SessionGopher -- It extracts PuTTY, WinSCP, SuperPuTTY, FileZilla, and RDP saved session information. Use -Thorough in local.
Invoke-WCMDump -- Extracts crendentials from Credential Manager. Detected.
DomainPasswordSpray -- Spray gathered passwords across domain
Inveigh -- Inveigh is a PowerShell ADIDNS/LLMNR/mDNS/NBNS spoofer and man-in-the-middle tool.
WindowsEnum -- Basic privesc Windows enumeration
Sherlock ~~~~ -- Search for known privesc vulnerabilities (DEPRECATED for Watson)
WINspect -- Local checks (Need Admin rights)
Exe
Watson -- Search for known privesc vulnerabilities (needs to be compiled using VisualStudio) (precompiled)
SeatBelt -- Enumerates the host searching for misconfigurations (more a gather info tool than privesc) (needs to be compiled) (precompiled)
LaZagne -- Extracts credentials from lots of softwares (precompiled exe in github)
SharpUP -- Port of PowerUp to C#
Beroot ~~~~ -- Check for misconfiguration (executable precompiled in github). Not recommended. It does not work well in Win10.
Windows-Privesc-Check -- Check for possible misconfigurations (exe from python). Not recommended. It does not work well in Win10.
Bat
winPEASbat -- Tool created based in this post (it does not need accesschk to work properly but it can use it).
Local
Windows-Exploit-Suggester -- Reads the output of systeminfo and recommends working exploits (local python) Windows Exploit Suggester Next Generation -- Reads the output of systeminfo andrecommends working exploits (local python)
Meterpreter
multi/recon/local_exploit_suggestor
You have to compile the project using the correct version of .NET (see this). To see the installed version of .NET on the victim host you can do:
Learn & practice AWS Hacking:HackTricks Training AWS Red Team Expert (ARTE) Learn & practice GCP Hacking: HackTricks Training GCP Red Team Expert (GRTE)