Hunting Down MS Exchange Attacks. Part 1. ProxyLogon (CVE-2021–26855, 26858, 27065, 26857)
Microsoft Exchange is one of the most common mail servers used by hundreds of thousands of companies around the world. Its popularity and accessibility from the Internet make it an attractive target for attackers.
Since the end of 2020, we have recorded a sharp increase in the number of incidents related to the compromise of MS Exchange server and its various components, in particular OWA (Outlook Web Access). Given the MS Exchange’s 24-year history, the complexity of its architecture, its location on the perimeter, and the increased interest in it among security researchers, we can assume that the number of vulnerabilities found in the popular mail server will only increase over time. This is evidenced by the recent discovery by DEVCORE researchers of a chain of critical vulnerabilities known collectively as ProxyLogon.
All this led us to write a series of articles that will focus on MS Exchange security: server attacks and detection techniques.
In the first article in the series, we will take a brief look at the MS Exchange server architecture and move on to the most relevant topic for everyone, i.e. detecting the exploitation of ProxyLogon. We will show how to use standard operating system events and Exchange logs to detect ProxyLogon, both in real time, using proactive threat hunting approaches, and attacks that have already happened in the past.
MS Exchange Architecture and Primary Attack Vectors
The main components of the MS Exchange server and the links between them are shown in the diagram below.
Depending on the version, MS Exchange may have the following roles:
- Mailbox server.
- A Client Access server, which is a frontend service that proxies client requests to the backend servers.
- Transport, which is responsible for managing mail traffic.
- Unified Messaging, which allows voice messaging and other telephony features (the role is not available on version 2019 servers).
- Management role, which is concerned with administration and flexible configuration of MS Exchange components.
Table 1. Basic protocols used by MS Exchange
The main components of Exchange and their brief descriptions are given below:
- Outlook Web Access (OWA) — a web interface for mailbox access and management (read/send/delete mail, edit calendar, etc.).
- Exchange Control Panel (ECP) — a web interface to administer Exchange components: manage mailboxes, create various policies to manage mail traffic, connect new mail servers, etc.
- Autodiscover — a service that allows customers to retrieve information about the location of various Exchange server components such as the URL for the EWS service. A user needs to be authenticated before the information can be retrieved.
- Exchange Web Services (EWS) — an API to provide various applications with access to mailbox components.
- Exchange ActiveSync (EAS) — a service that allows mobile device users to access and manage their email, calendar, contacts, tasks, etc. without an internet connection.
- RPC — a client access service that uses the RPC protocol, which runs on top of HTTP.
- Offline Address Book (OAB) — an offline address book service on the Exchange server that allows Outlook users to cache the contents of the Global Address List (GAL) and access it even when not connected to Exchange.
All of the components described above function as applications on the Microsoft IIS web server.
Attackers typically target MS Exchange servers for the following purposes:
- to gain access to confidential information in corporate emails
- to launch a malicious mailing from the victim company’s addresses to infiltrate the infrastructure of another organisation
- to compromise user accounts with the the use of Exchange components (successful bruteforce attack or detection of credentials in email correspondence) to infiltrate the company’s network via one of the corporate services
- to gain foothold into the company network (e.g. by using a web shell on the OWA service)
- to escalate privileges in the domain by using the Exchange server
- to disable the Exchange server in order to disrupt internal business processes (e.g. by fully encrypting server data)
Logs and Useful Events
The source events listed in Table 2 will be useful for detecting various attacks against the MS Exchange server.
Table 2. Event source profile
On 2 March 2021, Microsoft released security updates for a number of critical MS Exchange server vulnerabilities. The updates included a chain of critical vulnerabilities CVE-2021–26857, CVE-2021–26855, CVE-2021–26858, CVE-2021–27065, commonly referred to as ProxyLogon. After security updates were released and the first articles about these vulnerabilities were published, cyberattacks that exploited these vulnerabilities started being detected all over the world. Most of the attacks were aimed at uploading the initial web shell to the server to develop the attack in the future. While US companies took the brunt of the attack, we also recorded a number of similar attacks targeting our customers in Russia and Asia.
Let us take a closer look at the ProxyLogon vulnerability chain. CVE-2021–26857 is not actually part of this chain, as it leads to code execution on the server and does not require other vulnerabilities to be exploited beforehand. Vulnerability CVE-2021–26857 is related to insecure data deserialisation in the Unified Messaging service. Exploiting this vulnerability requires that the Unified Messaging role be installed and configured on the Exchange server. As this role is rarely used, no exploitation of this vulnerability has been reported so far. Instead, attackers exploit the CVE-2021–26855, CVE-2021–26858 and CVE-2021–27065 vulnerability chain, which also allows remote arbitrary code execution on the mail server but is easier to exploit.
ProxyLogon is the name of CVE-2021–26855 (SSRF) vulnerability that allows an external attacker to bypass the MS Exchange authentication mechanism and impersonate any user. By forging a server-side request, an attacker can send an arbitrary HTTP request that will be redirected to another internal service on behalf of the mail server computer account. To exploit the vulnerability, the attacker must generate a special POST request for a static file in a directory which is readable without authentication, such as
/ecp/x.js, where the presence of the file in the directory is not required. The body of the POST request will also be redirected to the service specified in the cookie named
An attacker using ProxyLogon can impersonate, for example, an administrator and authenticate into the Exchange Control Panel (ECP) and then overwrite any file on the system using the CVE-2021–26858 or CVE-2021–27065 vulnerabilities.
The greatest effect of overwriting files is achieved by creating a web shell in publicly accessible directories. To create a web shell, an attacker exploits a vulnerability in the built-in virtual directory mechanism. When creating a new virtual directory (for example, for an OAB service) an attacker can specify an address that includes a simple web shell as its external address. The attacker must then reset the virtual directory and specify the path to a file on the server where the current virtual directory settings should be saved as a backup. After resetting, the file to which the virtual directory backup will be saved will contain the web shell specified in the previous step.
Once the chain of vulnerabilities have been exploited, an attacker is able to execute commands through a web shell on the Exchange server with the privileges of the account that is used to run the application pool on the IIS server (
NT AUTHORITY\SYSTEM by default). In order to exploit the vulnerability chain successfully, an attacker must have network access on port 443 to MS Exchange with
Client Access role installed and know the email account name of a user with administrative privileges.
Detection of CVE-2021–26855 Vulnerability
The CVE-2021–26855 vulnerability allows an external attacker to send an arbitrary HTTP request that will be redirected to the specified internal service from the mail server computer account. In this way, the vulnerability allows the attacker to bypass the authentication mechanism of the Exchange server and perform the request with the highest privileges.
Since the attacker can specify the service to which an arbitrary HTTP request is to be redirected, this SSRF vulnerability can be exploited in different ways. Let us look at two ways to exploit this vulnerability: reading emails via EWS and downloading web shells via ECP (CVE-2021–26858 and CVE-2021–27065).
CVE-2021–26855 makes it easy to download any user’s email, just by knowing their email address. The exploitation requires at least two MS Exchange servers in the attacked infrastructure. For example, the request is sent to
exchange.lab.local and from there it is redirected via SSRF to
exchange02.lab.local. The screenshot below shows an example of this request to the EWS API using a SOAP request to get the last 10 emails from the
firstname.lastname@example.org mailbox. The response from the server contains email IDs and other information about the emails (e.g. header or date received).
The attacker can retrieve the original email message by inserting its identifier into another SOAP request.
The response from the server will contain a base64 representation of the original email message.
In this way, all emails from any given email account can be downloaded from the server without authentication. Email is often used to transmit sensitive information such as payment orders, configuration files, credentials or instructions for connecting to VPN servers, etc. Attackers can use the information obtained from compromised email correspondence for phishing mailings and other cybercrimes. This attack vector is no less dangerous than downloading a web shell to a server.
Such requests are logged by EWS. Accordingly, a rule to detect the described attack might look like this:
event_log_source:'EWS' AND AuthenticatedUser end with:'$' AND SoapAction IS NOT NULL AND UserAgent contains:'ExchangeWebServicesProxy/CrossSite/' AND NOT (SoapAction = 'GetUserOofSettings')
The second way to exploit the SSRF vulnerability is by authenticating into the ECP and then exploiting the CVE-2021–26858/CVE-2021–27065 vulnerabilities to upload the web shell to the server. In order to make requests to the ECP, a full session must be established in the ECP. For the attacker to impersonate an administrator when setting up a session, they need to know the SID of the mail server administrator’s account.
First of all, from the response to the NTLM request to
/rpc/rpcproxy.dll, an attacker can find out the FQDN of the mail server, which will be needed in the following stages: it will be specified in the NTLM response to be decoded.
The next step is to obtain the
LegacyDN and the email account ID by making an HTTP request to Autodiscover. The FQDN of the mail server obtained in the previous step is specified in a cookie named
The attacker can then retrieve the SID of the targeted user by sending an HTTP request to MAPI. The attacker sends a request to delegate access to the email account. This request is also forwarded to MAPI on behalf of the computer account user and causes an access error. The error contains the SID of the targeted user.
Finally, having obtained the user’s SID, the attacker can authenticate themselves on the server by posing as the administrator by sending a specially crafted POST request to
The request includes a header named
msExchLogonMailBox with the SID of the user to be authenticated. The body of the POST request also contains the SID of that user. In response, the server returns two cookies named
msExchEcpCanary that the attacker can use for any future ECP requests. Obtaining these cookies is the end result of the attacker exploiting the ProxyLogon vulnerability (CVE-2021-26855) if they plan to exploit CVE-2021-26858 and CVE-2021-27065 to upload a web shell to the server.
Such requests are logged in the IIS log. Accordingly, a rule to detect this activity can be as follows:
event_log_source:'IIS' AND cs-method:'POST' AND cs-uri-stem:'/ecp/proxyLogon.ecp' AND cs-username end with:'$'
Detection of CVE-2021–26858, CVE-2021–27065 Vulnerabilities
Successful exploitation of CVE-2021–27065 allows a malicious file to be uploaded to an Exchange server using the ECP interface, which can then be used as a web shell. Exploitation of this vulnerability requires pre-authentication, which can be performed using CVE-2021–26855. Let us take a closer look at the exploitation of CVE-2021–27065.
We start by logging into the ECP interface and going to
Servers → Virtual directories. Editing the virtual directories allows the Exchange application to migrate by changing the current application directory to IIS.
By navigating to the OAB (Default Web Site) edit box in the
External URL, an attacker can insert a web shell code, e.g.
After setting the new virtual directory configuration parameters, the following event may be seen in the MSExchange Management log:
The following rule can be implemented to detect such activity:
event_log_source:('PowershellAudit' OR 'MSExchangeCMDExec') AND event_id:('1' OR ’800’ OR '4104') AND (Message contains ‘Set-’ AND Message contains ‘VirtualDirectory AND Message contains ‘-ExternalUrl’ AND Message contains ‘script’)
The next step resets the virtual directory settings. In the interface that appears, we see that before resetting we are prompted to save the current virtual directory settings to a selected file:
After resetting the virtual directory in the MSExchange Management log we can see two events with
EventID 1 where first the
Remove-OabVirtualDirectory command is used, which is followed by the
New-OabVirtualDirectory command in the next event. These events can be used as additional indicators in case the rule described above is triggered.
Let us save the configuration as
test.aspx file in
C:\Program Files\Microsoft\Exchange Server\V15\FrontEnd\HttpProxy\ecp\auth. In the IIS ECP events, we can see an event telling us that the settings for the application virtual directory have been reset. Example of the event:
2021-03-10 08:16:52 10.3.132.20 POST /ecp/DDI/DDIService.svc/SetObject ActivityCorrelationID=d874fdcd-bd9d-9545-af02-677d356f1aa9&schema=ResetOABVirtualDirectory
444 LAB\dadmin 192.168.1.20 Mozilla/5.0+(Windows+NT+10.0;+Win64;+x64)+AppleWebKit/537.36+(KHTML,+like+Gecko)+Chrome/89.0.4389.82+Safari/537.36
https://exchange/ecp/VDirMgmt/ResetVirtualDirectory.aspx?pwmcid=6&ReturnObjectType=1&id=7a466ca6-419b-4445-9cc8-ae66a6bff719&schema=ResetOABVirtualDirectory 200 0 0 7
The following rule detects attempts to reset virtual directories based on IIS log events:
event_log_source:’IIS’ AND http_method:’POST’ AND http_code:'200' AND url_path:'/ecp/DDI/DDIService.svc/SetObject' AND (Message contains 'schema=Reset' AND Message contains 'VirtualDirectory')
When exploiting this vulnerability with CVE-2021–26858, an SSRF attack is used to manipulate virtual directories. For this reason, the
Username field will contain the computer account, in our case
lab.local\EXCHANGE$, as the request is initiated by the Exchange server itself. Given this fact, another rule can be implemented:
event_log_source:’IIS’ AND http_method:’POST’ AND http_code:'200' AND url_path:'/ecp/DDI/DDIService.svc/SetObject' AND (Message contains 'schema=Reset' AND Message contains 'VirtualDirectory') AND Username contains '$'
The contents of the
test.aspx configuration file can be seen in the screenshot below, where the
ExternalUrl parameter contains the specified
Let us try to execute the command using the downloaded web shell. With Burp Suite we specify the command of interest in the POST parameter
a. The result of the command is added to the response from the server, followed by the contents of the configuration file.
If we look at the start events of the processes, we can see the execution of our command in the IIS work process, which runs the
cmd.exe command line interpreter with the corresponding arguments.
By supplementing the detection logic with the PowerShell interpreter, we get the following rule:
event_log_source:'Security' AND event_id:'4688' AND proc_parent_file_path end with:'\w3wp.exe' AND proc_file_path end with:('\cmd.exe' OR '\powershell.exe')
Detection of this activity will be described in more detail in one of our upcoming articles.
In practice, this CVE was used as a payload after authentication was bypassed using the CVE-2021–26855 vulnerability.
The CVE-2021–26858 vulnerability also allows writing an arbitrary file to an Exchange server, but requires pre-authentication for successful exploitation. This vulnerability can also be used in conjunction with SSRF (CVE-2021–26858).
There are no publicly available PoCs or other sources detailing its exploitation. Nevertheless, Microsoft has reported how this activity can be detected. To do so, we implement the following rule using events from the OAB Generator service:
event_log_source:'OABGenerator' AND Message contains 'Download failed and temporary file'
Files must only be uploaded to the
%PROGRAMFILES%\Microsoft\Exchange Server\V15\ClientAccess\OAB\Temp directory, writing the file to any other directory is considered illegitimate.
Detection of CVE-2021–26857 Vulnerability
CVE-2021–26857 is an insecure deserialisation vulnerability in a Unified Messaging service.
Unified Messaging allows voice messaging and other features, including Outlook Voice Access and Call Answering Rules. The service must be preconfigured for it to work properly, and is rarely used. For this reason, attackers more often exploit CVE-2021–27065 in real-world attacks.
The problem is contained in the
Base64Deserialize method of the
CommonUtil class, and the class itself in the
Microsoft.Exchange.UM.UMCommon namespace of the
This method is called upon in the main library of the Unified Messaging service —
Microsoft.Exchange.UM.UMCore.dll, more specifically within the method
FromHeaderFile, classed as
PipelineContext with namespaces
Microsoft.Exchange.UM.UMCore. This way, the attacker can generate their serialised object, for example using the ysoserial.net utility, and remotely execute their code on the Exchange server in the
The new version of the
Microsoft.Exchange.UM.UMCore.dll library (after installing the update) has many additional checks on the incoming object types before the deserialisation process. As you can see in the screenshot below, the library is loaded into the
UMWorkerProcess.exe process. Consequently, if the vulnerability is exploited, this process will initiate abnormal activity.
A rule to detect suspicious child processes being started by UMWorkerProcess.exe (
cmd/powershell start, by Security and Sysmon log events):
event_log_source:'Security' AND event_id:'4688' AND proc_parent_file_path end with:'\UMWorkerProcess.exe' AND proc_file_path end with:('\cmd.exe' OR '\powershell.exe')
A malicious file may be created as a payload on the file system, such as a reverse shell in the autostart directory or a web shell in one of the IIS directories. The following rule can be implemented to detect this activity:
event_log_source:’Sysmon’ AND event_id:'11' AND proc_file_path end with:'\UMWorkerProcess.exe' AND file_name end with:(*.asp OR *.aspx) AND file_path contains:("\ClientAccess\Owa\" OR "\HttpProxy\Owa\" OR "\inetpub\wwwroot\" OR "\www\")
According to Microsoft, at the time of writing about 92% of MS Exchange servers have already been patched and are no longer vulnerable to ProxyLogon. Those who haven’t yet installed the patches should do so as a matter of urgency.
Even if the servers are already patched it is worth checking them for signs of ProxyLogon exploitation and repair the consequences if needed. This is quite easy to do with the standard operating system and Exchange server log events at hand.
Discovering new vulnerabilities in the Exchange server and new attacks are just a matter of time, so it is important to not only protect your mail servers properly, but also to collect and monitor important security events in advance.
We hope you have enjoyed our first article in this series. In the next article, we will explore how to detect the exploitation of other notorious MS Exchange vulnerabilities.