OPENSSL update fixes Certificate Verification issue
OpenSSL 1.0.2.d and 1.0.1p were release fixing an issue with the Certification verification process. The security advisory for the issue can be found here: https://www.openssl.org/news/secadv_20150709.txt
OpenSSL Security Advisory [9 Jul 2015] ======================================= Alternative chains certificate forgery (CVE-2015-1793) ====================================================== Severity: High During certificate verification, OpenSSL (starting from version 1.0.1n and 1.0.2b) will attempt to find an alternative certificate chain if the first attempt to build such a chain fails. An error in the implementation of this logic can mean that an attacker could cause certain checks on untrusted certificates to be bypassed, such as the CA flag, enabling them to use a valid leaf certificate to act as a CA and "issue" an invalid certificate. This issue will impact any application that verifies certificates including SSL/TLS/DTLS clients and SSL/TLS/DTLS servers using client authentication. This issue affects OpenSSL versions 1.0.2c, 1.0.2b, 1.0.1n and 1.0.1o. OpenSSL 1.0.2b/1.0.2c users should upgrade to 1.0.2d OpenSSL 1.0.1n/1.0.1o users should upgrade to 1.0.1p This issue was reported to OpenSSL on 24th June 2015 by Adam Langley/David Benjamin (Google/BoringSSL). The fix was developed by the BoringSSL project. Note ==== As per our previous announcements and our Release Strategy (https://www.openssl.org/about/releasestrat.html), support for OpenSSL versions 1.0.0 and 0.9.8 will cease on 31st December 2015. No security updates for these releases will be provided after that date. Users of these releases are advised to upgrade. References ========== URL for this Security Advisory: https://www.openssl.org/news/secadv_20150709.txt Note: the online version of the advisory may be updated with additional details over time. For details of OpenSSL severity classifications please see: https://www.openssl.org/about/secpolicy.html
Cisco PSIRT reporting Customers affected by ASA VPN DoS attacks
Patch your firewalls!
2015-July-08 UPDATE: Cisco PSIRT is aware of disruption to some Cisco customers with Cisco ASA devices affected by CVE-2014-3383, the Cisco ASA VPN Denial of Service Vulnerability that was disclosed in this Security Advisory. Traffic causing the disruption was isolated to a specific source IPv4 address. Cisco has engaged the provider and owner of that device and determined that the traffic was sent with no malicious intent. Cisco strongly recommends that customers upgrade to a fixed Cisco ASA software release to remediate this issue.
Cisco has released free software updates that address these vulnerabilities. Workarounds that mitigate some of these vulnerabilities are available.
This advisory is available at the following link:
http://tools.cisco.com/security/center/content/CiscoSecurityAdvisory/cisco-sa-20141008-asa
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Detecting Random - Finding Algorithmically chosen DNS names (DGA)
Most normal user traffic communicates via a hostname and not an IP address. So looking at traffic communicating directly by IP with no associated DNS request is a good thing do to. Some attackers use DNS names for their communications. There is also malware such as Skybot and the Styx exploit kit that use algorithmically chosen host name rather than IP addresses for their command and control channels. This malware uses what has been called DGA or Domain Generation Algorithms to create random looking host names for it's TLS command and control channel or to digitally sign it's SSL certificates. These do not look like normal host names. A human being can easily pick them out of our logs and traffic, but it turns out to be a somewhat challenging thing to do in an automated process. "Natural Language Processing" or measuring the randomness don't seem to work very well. Here is a video that illustrates the problem and one possible approach to solving it.
One way you might try to solve this is with a tool called ent. "ent" a great Linux tool for detecting entropy in files. Consider this:
[~]$ head -c 10000000 /dev/urandom | ent
Entropy = 7.999982 bits per byte. <-- 8 = random
[~]$ python -c "print 'A'*1000000" | ent
Entropy = 0.000021 bits per byte. <-- 0 = not random
So 8 is highly random and 0 is not random at all. Now lets look at some host names.
[~]$ echo "google" | ent
Entropy = 2.235926 bits per byte.
[~]$ echo "clearing-house" | ent
Entropy = 3.773557 bits per byte. <- Valid hosts are in the 2 to 4 range
Google scores 2.23 and clearing-house scores 3.7. So it appears as though legitimate host names will be in the 2 to 4 range. Now lets try some host names that we know are associated with malware that uses random host names.
[~]$ echo "e6nbbzucq2zrhzqzf" | ent
Entropy = 3.503258 bits per byte.
[~]$ echo "sdfe3454hhdf" | ent
Entropy = 3.085055 bits per byte. <- Malicious host from Skybot and Styx malware are in the same range as valid hosts
That's no good. Known malicious host names are also in the 2 to 4 range. They score just about the same as normal host names. We need a different approach to this problem.
Normal readable English has some pairs of characters that appear more frequently than others. "TH", "QU" and "ER" appear very frequently but other pairs like "WZ" appear very rarely. Specifically, there is approximately a 40% chance that a T will be followed by an H. There is approximately a 97% change that a Q will be followed by the letter U. There is approximately a 19% chance that E is followed by R. With regard to unlikely pairs, there is approximately a 0.004% chance that W will be followed by a Z. So here is the idea, lets analyze a bunch of text and figure out what normal looks like. Then measure the host names against the tables. I'm making this script and a Windows executable version of this tool available to you to try it out. Let me know how it works. Here is a look at how to use the tool.
Step 1) You need a frequency table. I shared two of them in my github if you want to use them you can download them and skip to step 2.
1a) Create the table: I'm creating a table called custom.freq. Create a table with the --create option
C:\freq>freq.exe --create custom.freq
1b) You can optionally turn ON case sensitivity if you want the frequency table to count uppercase letters and lowercase letters separately. Without this option the tool will convert everything to lowercase before counting character pairs. Toggle case sensitivity with -t or --toggle_case_sensitivity
C:\freq>freq.exe -t custom.freq
1c) Next fill the frequency table with normal text. You might load it with known legitimate host names like the Alexa top 1 million most commonly accessed websites. (http://s3.amazonaws.com/alexa-static/top-1m.csv.zip) I will just load it up with famous works of literature. The --normalfile argument is used to load the table with a text file containing normal text.
C:\freq>for %i in (txtdocs\*.*) do freq.exe --normalfile %i custom.freq
C:\freq>freq.exe --normalfile txtdocs\center_earth custom.freq
C:\freq>freq.exe --normalfile txtdocs\defoe-robinson-103.txt custom.freq
C:\freq>freq.exe --normalfile txtdocs\dracula.txt custom.freq
C:\freq>freq.exe --normalfile txtdocs\freck10.txt custom.freq
C:\freq>freq.exe --normalfile txtdocs\invisman.txt custom.freq
Step 2) Measure badness!
Once the frequency table is filled with data you can start to measure strings to see how probable they are according to our frequency tables. The --measure option is used for this purpose.
C:\freq>freq.exe --measure "google" custom.freq
6.59612840648
C:\freq>freq.exe --measure "clearing-house" custom.freq
12.1836883765
So normal host names have a probability above 5 (at least these two and most others do). We will consider anything above 5 to be good for our tests. Now lets feed it the host name we know are associated with malware.
C:\freq>freq.exe --measure "asdfl213u1" custom.freq
3.15113061843
C:\freq>freq.exe --measure "po24sf92cxlk" custom.freq
2.44994506765
Our malicious hosts are less than 5. 5 seems to be a pretty good benchmark. In my testing it seems to work pretty well for picking out these abnormal host names. But it isn't perfect. Nothing is. One problem is that very small host names and acronyms that are not in the source files you use to build your frequency tables will be below 5. For example, "fbi" and "cia" both come up below 5 when I just use classic literature to build my frequency tables. But I am not limited to classic literature. That leads us to step 3.
Step 3) Tune for your organization.
The real power of frequency tables is when you tune it to match normal traffic for your network. The program has two options for this purpose; --normal and --odd. --normal can be given a normal string and it will update the frequency table with that string. Both --normal and --odd can be used with the --weight option to control how much influence the given string has on the probabilities in the frequency table. It's effectiveness is demonstrated by the accompanying youtube video. Note that marking "random" host names as --odd is not a good strategy. It simply injects noise into the frequency table. Like everything else in security identifying all the bad in the world is a losing proposition. Instead focus on learning normal and identifying anomalies. So passing --normal "cia" --weight 10000 adds 10000 counts of the pair "ci" and the pair "ia" to the frequency table and increases the probability of "cia" to some number above 5..
C:\freq>freq.exe --normal "cia" --weight 10000 custom.freq
The source code and a Windows Executable version of this program can be downloaded from here: https://github.com/MarkBaggett/MarkBaggett/tree/master/freq
Tomorrow I in my diary I will show you some other cool things you can do with this approach and how you can incorporate this into your own tools.
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