PowerPoint, ArcaneDoor, the Z80 and Kaiser Permanente - April 21-27, 2024 - This Week in Security
Notable security news from the week of April 21st with a small side of nostalgia for the Z80 CPU; we'll dive into the exploitation of an old PowerPoint CVE from 2017, ArcaneDoor and the targeting of Cisco perimiter devices and an enormous breach of Kaiser Permanente user information!Deploy WAF on any Edge with F5 Distributed Cloud (SaaS Console, Automation)
F5 XC WAAP/WAF presents a clear advantage over classical WAAP/WAFs in that it can be deployed on a variety of environments without loss of functionality. In this first article of a series, we present an overview of the main deployment options for XC WAAP while follow-on articles will dive deeper into the details of the deployment procedures.Can iRule be used to perform exception of IPI category based on Geolocation
Hi Everyone, Can we configure iRule to perform exception on certain IPI category like "Spam Sources" based on Geolocation. For instance, I want to bypass the mitigation enforced on "Spam Sources" IP intelligence category for "Nepal" -Geolocation specific because of the large false positives on this category. I found the iRules to enforce the mitigation based on the defined IPI category: when HTTP_REQUEST { set ip_reputation_categories [IP::reputation [IP::client_addr]] set is_reject 0 if {($ip_reputation_categories contains "Windows Exploits")} { set is_reject 1 } if {($ip_reputation_categories contains "Web Attacks")} { set is_reject 1 } if {($is_reject)} { log local0. "Attempted access from malicious IP address [IP::client_addr] ($ip_reputation_categories), request was rejected" HTTP::respond 200 content "<HTML><HEAD><TITLE>Rejected Request</TITLE> </HEAD><BODY>The request was rejected. <BR> Attempted access from malicious IP address</BODY></HTML>" } } https://techdocs.f5.com/en-us/bigip-15-0-0/big-ip-local-traffic-manager-implementations/enabling-ip-address-intelligence.html
help irules for compatibilty
Please , someone can help me wiyh the irule below: when HTTP_REQUEST { log local0. "HTTP Method = [HTTP::method]" log local0. "HTTP URI = [HTTP::uri]" log local0. "HTTP Path = [HTTP::path]" log local0. "HTTP Query = [HTTP::query]" log local0. "HTTP Version = [HTTP::version]" log local0. "HTTP Host Header = [HTTP::host]" log local0. "HTTP User Agent Header = [HTTP::header value "user-agent"]" if { [HTTP::host] eq "pp.appro-cb.pmu.fr" }{ pool POOL__PREPR SSL::disable serverside HTTP::header insert X-Forwarded-For [IP::remote_addr] } elseif { [HTTP::host] contains "lab.tech.zu" }{ pool POOL_GITLAB } elseif { [HTTP::host] contains "nessus.tech.ai" }{ pool POOL_NEXUS } elseif { [HTTP::host] contains "rai5.pp.ei" }{ pool POOL_STP_RE5_appv1 } elseif { [HTTP::host] contains "apicccc-tech.ai" }{ pool POOL_APICMD_TST } elseif { [HTTP::host] contains "myhome-pp.pcc.ai"}{ pool POOL_MYBET_PP HTTP::header insert Access-Control-Allow-Origin "[HTTP::header Origin]" \ HTTP::header insert Access-Control-Allow-Methods "GET, POST, PUT, DELETE, OPTIONS" \ HTTP::header inster Access-Control-Expose-Header "Pmu-Session-Id" \ HTTP::header insert Access-Control-Allow-Headers "Pmu-Session-Id,OTT,DNT,X-Mx-ReqToken,Keep-Alive,User-Agent,X-Requested-With,If-Modified-Since,Cache-Control,Content-Type,correlationId,emetteur,idDevice" \ HTTP::header insert Access-Control-Allow-Credentials "true" return } }
Wildcard SSL Certificate Deployment on F5 LTM
We utilize F5 load balancer to generate CSR and implement Entrust SSL certificates across all subdomains within our infra. We're exploring the possibility of deploying a wildcard SSL certificate for a domain and its associated subdomains. ltm version is 14.1.5 If feasible, we seek guidance on the process of importing and deploying it within F5.SSL Profiles Part 8: Client Authentication
This is the eighth article in a series of Tech Tips that highlight SSL Profiles on the BIG-IP LTM. SSL Overview and Handshake SSL Certificates Certificate Chain Implementation Cipher Suites SSL Options SSL Renegotiation Server Name Indication Client Authentication Server Authentication All the "Little" Options This article will discuss the concept of Client Authentication, how it works, and how the BIG-IP system allows you to configure it for your environment. Client Authentication In a TLS handshake, the client and the server exchange several messages that ultimately result in an encrypted channel for secure communication. During this handshake, the client authenticates the server's identity by verifying the server certificate (for more on the TLS handshake, see SSL Overview and Handshake - Article 1in this series). Although the client always authenticates the server's identity, the server is not required to authenticate the client's identity. However, there are some situations that call for the server to authenticate the client. Client authentication is a feature that lets you authenticate users that are accessing a server. In client authentication, a certificate is passed from the client to the server and is verified by the server. Client authentication allow you to rest assured that the person represented by the certificate is the person you expect. Many companies want to ensure that only authorized users can gain access to the services and content they provide. As more personal and access-controlled information moves online, client authentication becomes more of a reality and a necessity. How Does Client Authentication Work? Before we jump into client authentication, let's make sure we understand server authentication. During the TLS handshake, the client authenticates the identity of the server by verifying the server's certificate and using the server's public key to encrypt data that will be used to compute the shared symmetric key. The server can only generate the symmetric key used in the TLS session if it can decrypt that data with its private key. The following diagram shows an abbreviated version of the TLS handshake that highlights some of these concepts. Ultimately, the client and server need to use a symmetric key to encrypt all communication during their TLS session. In order to calculate that key, the server shares its certificate with the client (the certificate includes the server's public key), and the client sends a random string of data to the server (encrypted with the server's public key). Now that the client and server each have the random string of data, they can each calculate (independently) the symmetric key that will be used to encrypt all remaining communication for the duration of that specific TLS session. In fact, the client and server both send a "Finished' message at the end of the handshake...and that message is encrypted with the symmetric key that they have both calculated on their own. So, if all that stuff works and they can both read each other's "Finished" message, then the server has been authenticated by the client and they proceed along with smiles on their collective faces (encrypted smiles, of course). You'll notice in the diagram above that the server sent its certificate to the client, but the client never sent its certificate to the server. When client authentication is used, the server still sends its certificate to the client, but it also sends a "Certificate Request" message to the client. This lets the client know that it needs to get its certificate ready because the next message from the client to the server (during the handshake) will need to include the client certificate. The following diagram shows the added steps needed during the TLS handshake for client authentication. So, you can see that when client authentication is enabled, the public and private keys are still used to encrypt and decrypt critical information that leads to the shared symmetric key. In addition to the public and private keys being used for authentication, the client and server both send certificates and each verifies the certificate of the other. This certificate verification is also part of the authentication process for both the client and the server. The certificate verification process includes four important checks. If any of these checks do not return a valid response, the certificate verification fails (which makes the TLS handshake fail) and the session will terminate. These checks are as follows: Check digital signature Check certificate chain Check expiration date and validity period Check certificate revocation status Here's how the client and server accomplish each of the checks for client authentication: Digital Signature: The client sends a "Certificate Verify" message that contains a digitally signed copy of the previous handshake message. This message is signed using the client certificate's private key. The server can validate the message digest of the digital signature by using the client's public key (which is found in the client certificate). Once the digital signature is validated, the server knows that public key belonging to the client matches the private key used to create the signature. Certificate Chain: The server maintains a list of trusted CAs, and this list determines which certificates the server will accept. The server will use the public key from the CA certificate (which it has in its list of trusted CAs) to validate the CA's digital signature on the certificate being presented. If the message digest has changed or if the public key doesn't correspond to the CA's private key used to sign the certificate, the verification fails and the handshake terminates. Expiration Date and Validity Period: The server compares the current date to the validity period listed in the certificate. If the expiration date has not passed and the current date is within the period, everything is good. If it's not, then the verification fails and the handshake terminates. Certificate Revocation Status: The server compares the client certificate to the list of revoked certificates on the system. If the client certificate is on the list, the verification fails and the handshake terminates. As you can see, a bunch of stuff has to happen in just the right way for the Client-Authenticated TLS handshake to finalize correctly. But, all this is in place for your own protection. After all, you want to make sure that no one else can steal your identity and impersonate you on a critically important website! BIG-IP Configuration Now that we've established the foundation for client authentication in a TLS handshake, let's figure out how the BIG-IP is set up to handle this feature. The following screenshot shows the user interface for configuring Client Authentication. To get here, navigate to Local Traffic > Profiles > SSL > Client. The Client Certificate drop down menu has three settings: Ignore (default), Require, and Request. The "Ignore" setting specifies that the system will ignore any certificate presented and will not authenticate the client before establishing the SSL session. This effectively turns off client authentication. The "Require" setting enforces client authentication. When this setting is enabled, the BIG-IP will request a client certificate and attempt to verify it. An SSL session is established only if a valid client certificate from a trusted CA is presented. Finally, the "Request" setting enables optional client authentication. When this setting is enabled, the BIG-IP will request a client certificate and attempt to verify it. However, an SSL session will be established regardless of whether or not a valid client certificate from a trusted CA is presented. The Request option is often used in conjunction with iRules in order to provide selective access depending on the certificate that is presented. For example: let's say you would like to allow clients who present a certificate from a trusted CA to gain access to the application while clients who do not provide the required certificate be redirected to a page detailing the access requirements. If you are not using iRules to enforce a different outcome based on the certificate details, there is no significant benefit to using the "Request" setting versus the default "Ignore" setting. In both cases, an SSL session will be established regardless of the certificate presented. Frequency specifies the frequency of client authentication for an SSL session. This menu offers two options: Once (default) and Always. The "Once" setting specifies that the system will authenticate the client only once for an SSL session. The "Always"setting specifies that the system will authenticate the client once when the SSL session is established as well as each time that session is reused. The Retain Certificate box is checked by default. When checked, the client certificate is retained for the SSL session. Certificate Chain Traversal Depth specifies the maximum number of certificates that can be traversed in a client certificate chain. The default for this setting is 9. Remember that "Certificate Chain" part of the verification checks? This setting is where you configure the depth that you allow the server to dig for a trusted CA. For more on certificate chains, see article 2 of this SSL series. Trusted Certificate Authorities setting is used to specify the BIG-IP's Trusted Certificate Authorities store. These are the CAs that the BIG-IP trusts when it verifies a client certificate that is presented during client authentication. The default value for the Trusted Certificate Authorities setting is None, indicating that no CAs are trusted. Don't forget...if the BIG-IP Client Certificate menu is set to Require but the Trusted Certificate Authorities is set to None, clients will not be able to establish SSL sessions with the virtual server. The drop down list in this setting includes the name of all the SSL certificates installed in the BIG-IP's /config/ssl/ssl.crt directory. A newly-installed BIG-IP system will include the following certificates: default certificate and ca-bundle certificate. The default certificate is a self-signed server certificate used when testing SSL profiles. This certificate is not appropriate for use as a Trusted Certificate Authorities certificate bundle. The ca-bundle certificate is a bundle of CA certificates from most of the well-known PKIs around the world. This certificate may be appropriate for use as a Trusted Certificate Authorities certificate bundle. However, if this bundle is specified as the Trusted Certificate Authorities certificate store, any valid client certificate that is signed by one of the popular Root CAs included in the default ca-bundle.crt will be authenticated. This provides some level of identification, but it provides very little access control since almost any valid client certificate could be authenticated. If you want to trust only certificates signed by a specific CA or set of CAs, you should create and install a bundle containing the certificates of the CAs whose certificates you trust. The bundle must also include the entire chain of CA certificates necessary to establish a chain of trust. Once you create this new certificate bundle, you can select it in the Trusted Certificate Authorities drop down menu. The Advertised Certificate Authorities setting is used to specify the CAs that the BIG-IP advertises as trusted when soliciting a client certificate for client authentication. The default value for the Advertised Certificate Authorities setting is None, indicating that no CAs are advertised. When set to None, no list of trusted CAs is sent to a client with the certificate request. If the Client Certificate menu is set to Require or Request, you can configure the Advertised Certificate Authorities setting to send clients a list of CAs that the server is likely to trust. Like the Trusted Certificate Authorities list, the Advertised Certificate Authorities drop down list includes the name of all the SSL certificates installed in the BIG-IP /config/ssl/ssl.crt directory. A newly-installed BIG-IP system includes the following certificates: default certificate and ca-bundle certificate. The default certificate is a self-signed server certificate used for testing SSL profiles. This certificate is not appropriate for use as an Advertised Certificate Authorities certificate bundle. The ca-bundle certificate is a bundle of CA certificates from most of the well-known PKIs around the world. This certificate may be appropriate for use as an Advertised Certificate Authorities certificate bundle. If you want to advertise only a specific CA or set of CAs, you should create and install a bundle containing the certificates of the CA to advertise. Once you create this new certificate bundle, you can select it in the Advertised Certificate Authorities setting drop down menu. You are allowed to configure the Advertised Certificate Authorities setting to send a different list of CAs than that specified for the Trusted Certificate Authorities. This allows greater control over the configuration information shared with unknown clients. You might not want to reveal the entire list of trusted CAs to a client that does not automatically present a valid client certificate from a trusted CA. Finally, you should avoid specifying a bundle that contains a large number of certificates when you configure the Advertised Certificate Authorities setting. This will cut down on the number of certificates exchanged during a client SSL handshake. The maximum size allowed by the BIG-IP for native SSL handshake messages is 14,304 bytes. Most handshakes don't result in large message lengths, but if the SSL handshake is negotiating a native cipher and the total length of all messages in the handshake exceeds the 14,304 byte threshold, the handshake will fail. The Certificate Revocation List (CRL) setting allows you to specify a CRL that the BIG-IP will use to check revocation status of a certificate prior to authenticating a client. If you want to use a CRL, you must upload it to the /config/ssl/ssl.crl directory on the BIG-IP. The name of the CRL file may then be entered in the CRL setting dialog box. Note that this box will offer no drop down menu options until you upload a CRL file to the BIG-IP. Since CRLs can quickly become outdated, you should use either OCSP or CRLDP profiles for more robust and current verification functionality. Conclusion Well, that wraps up our discussion on Client Authentication. I hope the information helped, and I hope you can use this to configure your BIG-IP to meet the needs of your specific network environment. Be sure to come back for our next article in the SSL series. As always, if you have any other questions, feel free to post a question here or Contact Us directly. See you next time!
http protocol compliance
Hello All, We experienced a issue with specific end user only, when user is accessing a application he is getting error message , on basis of support ID we came to know it is "http protocol compliance failed" violation on ASM. We are not able to find the exact feature in http protocol compliance field which is blocking user to access the site. As workaround we have unchecked the block option of "http protocol compliance failed" in policy building > learning policies and things started working. Can anyone please share what to look for actually in the violation details to implement the recommended solution as what we did is workaround only and may not be recommended fix. Rgds ***
Open Redirection Mitigation
hello, ASM has a feature to mitigate the open redirection attacks when the redirect happens at the header level (i.e: with Location in response). When the redirection is within the payload response, the ASM does not block it. do you guys know about any ASM configuration that may address this issue and mitigate this kind of attack ? thanks. o.
Using okta as SSO to login F5 GUI
Hi All, Greetings..!! Currently we are using local user accounts in f5 to login. We have different users with different roles on f5. In our organization we are using okta for other apps authentication. Is it possible to have Okta for logging in f5 with SSO. If yes, please share the article or guide with the required configurations. Thanks in Advance, K Kuzhali
