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Windows Forensics and Incident Recovery
The intended audience, according to the author, is "anyone with an interest in Windows security, which includes Windows system and security administrators, consultants, incident response team members, students and even home users." The author assumes the reader is familiar with basic networking (including TCP/IP) and has some Windows administration skills. Some programming ability, though not actually required, will help out greatly with reading and understanding the many examples provided, and will let you make your own modifications (this is encouraged by the author throughout the book).
The chapter on data hiding was a real eye-opener -- it's amazing the things Microsoft has implemented as part of the operating system (and included applications) that can be used to hide things. Discovering the hidden information is talked about, as well how it is hidden. Sample topics include file attributes, alternate data streams, OLE and stenography. This is an excellent chapter with many examples; I found myself stopping after each subject to try out each of the discussed techniques.
The next chapter delves into incident preparation. Carvey addresses some of the things that administrators can do to harden their systems. He goes over the application of security policies in general, as well as intelligent assignment of file permissions. He then covers Windows File Protection and how it is implemented, and includes a perl script to implement your own file watcher. He touches briefly on patch management and anti-virus programs, then moves into monitoring. He provides quite a few scripts, and discusses other means by which you can monitor your system.
The next chapter describes tools that can be used in incident response. This chapter has quite a lot of information and took me the longest to get through, because of all the tools mentioned that I had to download and check while I was reading the book. Carvey uses a mixture of his own perl scripts and programs that can be downloaded from places like Sysinternals, Foundstone, DiamondCS and others. All of the tools used are open source (or are at least freely available). That equips the reader with a low-cost toolkit, especially important to the home user or small business owner who cannot afford to buy the commercial equivalent. Carvey does acknowledge, though, that there are quite a few commercial tools with great functionality out there.
The first part of the incident-response tools chapter deals with the collection of volatile information (processes, services, etc.); this is a vital part of live analysis. The second part deals with the collection of non-volatile information (the content of the Windows registry, file MAC times and hashes, etc.) and tools for analyzing files. Carvey also shows how some of the tools complement each other, and that there is not one almighty tool that will find all the data you need. (This is also proven by example in a later chapter when he talks about rootkits.)
The next chapter deals with developing a security methodology, and it's handled differently than in most books: the author presents the material as a series of dreams that a Windows system administrator has, showing how an individual can come up with and fine tune a methodology as incidents happen. Carvey has used this approach before in a series of articles entitled "No Stone Unturned" for SecurityFocus.com, and the creative approach appeals to me. As he moves from dream to dream, you can relate to the admin's circumstances (and mistakes), and how be and becomes better at responding to different incidents.
The next chapter talks about what to usefully look for with the tools the book has introduced. It discusses infection vectors, types of malware and rootkits, and demonstrates tools and techniques for detecting them. This is where the author makes a clear point of why you would need to run several different tools, even if some overlap. His example uses an installed rootkit; running a particular program from a previous chapter, he shows that it fails to find that anything untoward is running -- it takes another program from the same chapter to actually reveal the rootkit's presence. By cross referencing the output for both programs, you can see why you should run more then one type of analysis tool for certain areas to make sure you are not missing anything.
Finally, the author dedicates an entire chapter to his own Forensic Server Project, a two-pronged approach to live forensic analysis which uses two machines simultaneously. The first piece, the Forensic Server Module, is the listener software; this runs on a clean PC where the data will be sent from the compromised system. The other piece, called the First Responder Utility, runs several of the programs and scripts from the incident tools chapter on the compromised system . After installing everything needed for both parts of this system, I followed the author's instructions on how to run it. What a slick tool! I ran it from a couple of PCs on my home network and was able to get a lot of the information that was described in the book as well as hash values for each log file that was produced, and a general log of everything the First Responder Unit did. The whole principle of this is that when you have an incident there will be very little interaction with the compromised system, since everything is scripted to begin with.
The framework that this software constitutes is very flexible. I was able to add two new features to the Forensic Server Module and the First Responder Utility with very little code. The first addition I made was to mark all the logs as read-only on the file system after they were written from the Forensic Server module. The next addition I made was to add a perl script to scan the c:\ drive of the PC that the First Responder Utility was running on. After I made both additions, I tested everything out, and it worked great. I had my extra log files and they were all read-only. My hat goes off to the author for coming up with and including this in the book, a really nice piece of software.
You can purchase Windows Forensics and Incident Recovery from bn.com. Slashdot welcomes readers' book reviews. To see your own review here, carefully read the book review guidelines, then visit the submission page.
From article:
" Sample topics include file attributes, alternate data streams, OLE and stenography"
Should that be Steganography?
Does the book offer any comprehensive ideas beyond tools you can download and hwo to use them? I'm really more interested in knowing where an attacker's footprints are likely to be evident, not in using some sort of footprint detector. Tools are nice, but one should have basics to fall back on when tools are unavailable or untrusted. That said, the best Windows security tool is Nero. It's great for burning Debian .isos. . .:)
You are not the customer.
Cool, I love arcane knowledge *hugs his falconry for dummies book*
"It's too bad she won't live, but then again who does?" - Gaff
We had an SGI IRIX system rooted a while ago. One of those obscure machines that sat in a corner running for years, rarely updated or touched. When it was discovered that the machine was taken over the person that admin'd the machine left it exactly as is but firewalled and VLAN'd the machine from touching anything outside of a test VLAN he set up.
In February he gave us (network guys visiting his branch) a look at the machine and what he found. The machine, the root kit and the IRC bot were all left intact and running. It was pretty neat, he wrote up a lengthy port-mortem of the event.
Trolling is a art,
If you're going to repost other people's posts, at least preserve the formatting, you lazy turd.
1) This is no "one" tool accepted in court, many tools are accepted and it is almost always the competency of the examiner and only rarely is the tool that is ever called into question. Companies like Guidance Software (makers of Encase) would like you to think that way...
2) Most dedicated computer forensic tools, especially those for examining hard drive images, can work with any filesystem from FAT12 to xfs on a RAID 5 set. Again, the burden falls on the examiner to know the proper tools/methods for examining these file structures.
3) SATA drives can be copied with any dedicated hardware copier (such as Logicube's MD5 or Solitaire), but dd combined with an SATA interface will work just fine. Any memory image (RAM, IDE, SCSI, SATA, etc.) can be imaged with just dd, even over a network.
4) "Average nerds and hackers are so far ahread of the forensics guys"...what nonsense. Computer forensic analysts are without a doubt some of the most talented people in IT period. Computer forensics is multi-discipline and analysts typically have backgrounds in engineering, programming, criminology, and languages. And why are you assuming that most computer forensics experts are in law enforcement? The best analysts are in the private sector, military, and government intelligence.
"Forensics" on a live system is a misnomer. For incident response, collecting live data on open ports, running processes, logged on users, and mounted devices is useful and sometimes necessary. Investigators should be sure to check -- gingerly -- whether any encrypted volumes are mounted.
Generally, however, if there's any chance that the investigation could wind up in court, it's best to pull the plug (literally) and conduct a static analysis of the hard drive. You lose access to running processes and some live registry keys, but otherwise just about everything exists on the hard drive and is accessible through standard forensic tools.
As a forensic programmer/consultant, one of the biggest problems I run into is when J. Random Sysadmin is tasked with conducting an initial investigation and ends up rampaging through the hard drive like a bull in a china shop. If you ever find yourself in this situation, stop and get the facts. There's no better way for a sysadmin to wind up in the doghouse than to ruin a legal investigation.
Jon
(Disclaimer: I work at Guidance Software, makers of EnCase, which is the all-in-one tool that can do all of the things mentioned in the review. But not for free...)
Crackers and hackers always find ways to exploit the code to access or share protected content. There is not a DRM system that has not been cracked within months of widespread release.
A stealth virus is one that, while active, hides the modifications it has made to files or boot records. It usually achieves this by monitoring the system functions used to read files or sectors from storage media and forging the results of calls to such functions. This means that programs that try to read infected files or sectors see the original, uninfected form instead of the actual, infected form. Thus the virus's modifications may go undetected by antivirus programs.
OS based DRM systems can still successfully lock a user, and any program, even if is running under localsystem/root privilege, out of areas of diskspace and memory. Microsoft's Mediaplayer , Active-X ( used with some DRM protection ), Real's realplayer, and even Microsoft's and Sun's Java JVMs, have in the past had remotely exploitable vulnerabilities. Such enviable offers the malware creator the ability to hide the virus from any antivirus tool or live forensic analysis.
The DRM encryption offers the ability for the malware to store content, and without the keys to decode the content, it is hidden from any forensic analysis.