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ANTI-VIRUS INFORMATION Here's something to keep your computer healthy! Following is a 35 page guide to computer viruses with definitions, suggestions for prevention and more. It was included in HealthFreebies to help answer some basic questions you may have about this popular topic and also to give an example of the type of information that is readily available on the Internet and similar electronic networks such as Compuserve, Genie, your local BBS, etc. This and other documents on many other subjects are available free by using a simple email command. Summary: This posting contains a list of Frequently Asked Questions, and their answers, about computer viruses. It should be read by anyone who wishes to post to VIRUS-L/comp.virus. Archive-name: computer-virus-faq Frequently Asked Questions on VIRUS-L/comp.virus ==================== = Preface Section: = ==================== This document is intended to answer the most Frequently Asked Questions (FAQs) about computer viruses. As you can see, there are many of them! If you are desperately seeking help after recently discovering what appears to be a virus on your computer, consider skimming through sections A and B to learn the essential jargon, then concentrate on section C. If you may have found a new virus, or are not quite sure if some file or boot sector is infected, it is important to understand the protocol for raising such questions, e.g. to avoid asking questions that can be answered in this document, and to avoid sending "live" viruses except to someone who is responsible (and even then in a safe form!). Above all, remember the time to really worry about viruses is BEFORE your computer gets one! The FAQ is a dynamic document, which changes as people's questions change. Contributions are gratefully accepted -- please e-mail them to me at krvw@cert.org. The most recent copy of this FAQ will always be available on the VIRUS-L/comp.virus archives, including the anonymous FTP on cert.org (192.88.209.5) in the file: pub/virus-l/FAQ.virus-l Ken van Wyk, moderator VIRUS-L/comp.virus Primary contributors (in alphabetical order): Mark Aitchison <phys169@csc.canterbury.ac.nz> Vaughan Bell <vaughan@computing-department.poly-south-west.ac.uk> Matt Bishop <matt.bishop@dartmouth.edu> Vesselin Bontchev <bontchev@fbihh.informatik.uni-hamburg.de> Olivier M.J. Crepin-Leblond <umeeb37@vaxa.cc.ic.ac.uk> David Chess <chess@watson.ibm.com> John-David Childs <con_jdc@lewis.umt.edu> Nick FitzGerald <cctr132@csc.canterbury.ac.nz> Claude Bersano-Hayes <hayes@urvax.urich.edu> John Kida <jhk@washington.ssds.COM> Donald G. Peters <Peters@Dockmaster.NCSC.Mil> A. Padgett Peterson <padgett%tccslr.dnet@mmc.com> Y. Radai <radai@hujivms.huji.ac.il> Rob Slade <rslade@sfu.ca> Gene Spafford <spaf@cs.purdue.edu> Otto Stolz <rzotto@nyx.uni-konstanz.de> ==================== Questions answered in this document Section A: Sources of Information and Anti-viral Software (Where can I find HELP..!) A1) What is VIRUS-L/comp.virus? A2) What is the difference between VIRUS-L and comp.virus? A3) How do I get onto VIRUS-L/comp.virus? A4) What are the guidelines for VIRUS-L? A5) How can I get back-issues of VIRUS-L? A6) What is VALERT-L? A7) What are the known viruses, their names, major symptoms and possible cures? A8) Where can I get free or shareware anti-virus programs? A9) Where can I get more information on viruses, etc.? Section B: Definitions (What is ...?) B1) What are computer viruses (and why should I worry about them)? B2) What is a Trojan Horse? B3) What are the main types of PC viruses? B4) What is a stealth virus? B5) What is a polymorphic virus? B6) What are fast and slow infectors? B7) What is a sparse infector? B8) What is a companion virus? B9) What is an armored virus? B10) Miscellaneous Jargon and Abbreviations Section C: Virus Detection (Is my computer infected? What do I do?) C1) What are the symptoms and indications of a virus infection? C2) What steps should be taken in diagnosing and identifying viruses? C3) What is the best way to remove a virus? C4) What does the <insert name here> virus do? C5) What are "false positives" and "false negatives"? C6) Could an anti-viral program itself be infected? C7) Where can I get a virus scanner for my Unix system? C8) Why does an antiviral scanner report an infection only sometimes? C9) Is my disk infected with the Stoned virus? C10) I think I have detected a new virus; what do I do? C11) CHKDSK reports 639K (or less) total memory on my system; am I infected? C12) I have an infinite loop of sub-directories on my hard drive; am I infected? Section D: Protection Plans (What should I do to prepare against viruses?) D1) What is the best protection policy for my computer? D2) Is it possible to protect a computer system with only software? D3) Is it possible to write-protect the hard disk with only software? D4) What can be done with hardware protection? D5) Will setting DOS file attributes to READ ONLY protect them from viruses? D6) Will password/access control systems protect my files from viruses? D7) Will the protection systems in DR DOS work against viruses? D8) Will a write-protect tab on a floppy disk stop viruses? D9) Do local area networks (LANs) help to stop viruses or do they facilitate their spread? D10) What is the proper way to make backups? Section E: Facts and Fibs about computer viruses (Can a virus...?) E1) Can boot sector viruses infect non-bootable floppy disks? E2) Can a virus hide in a PC's CMOS memory? E3) Can a virus hide in Extended or in Expanded RAM? E4) Can a virus hide in Upper Memory or in High Memory? E5) Can a virus infect data files? E6) Can viruses spread from one type of computer to another? E7) Can DOS viruses run on non-DOS machines (e.g. Mac, Amiga)? E8) Can mainframe computers be susceptible to computer viruses? E9) Some people say that disinfecting files is a bad idea. Is that true? E10) Can I avoid viruses by avoiding shareware/free software/games? E11) Can I contract a virus on my PC by performing a "DIR" of an infected floppy disk? E12) Is there any risk in copying data files from an infected floppy disk to a clean PC's hard disk? E13) Can a DOS virus survive and spread on an OS/2 system using the HPFS file system? E14) Under OS/2 2.0, could a virus infected DOS session infect another DOS session? E15) Can normal DOS viruses work under MS Windows? Section F: Miscellaneous Questions (I was just wondering...) F1) How many viruses are there? F2) How do viruses spread so quickly? F3) What is the plural of "virus"? "Viruses" or "viri" or "virii" or... F4) When reporting a virus infection (and looking for assistance), what information should be included? F5) How often should we upgrade our anti-virus tools to minimize software and labor costs and maximize our protection? Section G: Specific Virus and Anti-viral software Questions... G1) I was infected by the Jerusalem virus and disinfected the infected files with my favorite anti-virus program. However, Wordperfect and some other programs still refuse to work. Why? G2) I was told that the Stoned virus displays the text "Your PC is now Stoned" at boot time. I have been infected by this virus several times, but have never seen the message. Why? G3) I was infected by both Stoned and Michelangelo. Why has my computer became unbootable? And why, each time I run my favorite scanner, does it find one of the viruses and say that it is removed, but when I run it again, it says that the virus is still there? ================================================================ = Section A. Sources of Information and Anti-viral Software. = ================================================================ A1) What is VIRUS-L/comp.virus? It is a discussion forum with a focus on computer virus issues. More specifically, VIRUS-L is an electronic mailing list and comp.virus is a USENET newsgroup. Both groups are moderated; all submissions are sent to the moderator for possible inclusion in the group. For more information, including a copy of the posting guidelines, see the file virus-l.README, available by anonymous FTP on cert.org in the pub/virus-l directory. (FTP is the Internet File Transfer Protocol, and is described in more detail in the monthly VIRUS-L/comp.virus archive postings - see below.) Note that there have been, from time to time, other USENET cross-postings of VIRUS-L, including the bit.listserv.virus-l. These groups are generally set up by individual site maintainers and are not as globally accessible as VIRUS-L and comp.virus. A2) What is the difference between VIRUS-L and comp.virus? As mentioned above, VIRUS-L is a mailing list and comp.virus is a newsgroup. In addition, VIRUS-L is distributed in digest format (with multiple e-mail postings in one large digest) and comp.virus is distributed as individual news postings. However, the content of the two groups is identical. A3) How do I get onto VIRUS-L/comp.virus? Send e-mail to LISTSERV@LEHIGH.EDU stating: "SUB VIRUS-L your-name". To "subscribe" to comp.virus, simply use your favorite USENET news reader to read the group (assuming that your site receives USENET news). A4) What are the guidelines for VIRUS-L? The list of posting guidelines is available by anonymous FTP on cert.org. See the file pub/virus-l/virus-l.README for the most recent copy. In general, however, the moderator requires that discussions are polite and non-commercial. (Objective postings of product availability, product reviews, etc., are fine, but commercial advertisements are not.) Also, requests for viruses (binary or disassembly) are not allowed. Technical discussions are strongly encouraged, however, within reason. A5) How can I get back-issues of VIRUS-L? VIRUS-L/comp.virus includes a series of archive sites that carry all the back issues of VIRUS-L, as well as public anti-virus software (for various computers) and documents. The back-issues date back to the group's inception, 21 April 1988. The list of archive sites is updated monthly and distributed to the group; it includes a complete listing of the sites, what they carry, access instructions, as well as information on how to access FTP sites by e-mail. The anonymous FTP archive at cert.org carries all of the VIRUS-L back issues. See the file pub/virus-l/README for more information on the cert.org archive site. A6) What is VALERT-L? VALERT-L is a sister group to VIRUS-L, but is intended for virus alerts and warnings only -- NO DISCUSSIONS. There is no direct USENET counterpart to VALERT-L; it is a mailing list only. All VALERT-L postings are re-distributed to VIRUS-L/comp.virus later. This group is also moderated, but on a much higher priority than VIRUS-L. The group is monitored during business hours (East Coast, U.S.A., GMT-5/GMT-4); high priority off-hour postings can be made by submitting to the group and then telephoning the CERT/CC hotline at +1 412 268 7090 -- instruct the person answering the hotline to call or page Ken van Wyk. Subscriptions to VALERT-L are handled identically to VIRUS-L -- contact the LISTSERV. A7) What are the known viruses, their names, major symptoms and possible cures? First of all, the reader must be aware that there is no universally accepted naming convention for viruses, nor is there any standard means of testing. As a consequence nearly ALL viral information is highly subjective and subject to interpretation and dispute. There are several major sources of information on specific viruses. Probably the biggest one is Patricia Hoffman's hypertext VSUM. It describes only DOS viruses, but almost all of them which are known at any given time. Unfortunately, it is regarded by many in the field as being inaccurate, so we do not advise people to rely solely on it. It can be downloaded from most major archive sites except SIMTEL20. The second one is the Computer Virus Catalog, published by the Virus Test Center in Hamburg. It contains a highly technical description of computer viruses for several platforms: DOS, Mac, Amiga, Atari ST, Unix. Unfortunately, the DOS section is quite incomplete. The CVC is available for anonymous FTP from ftp.informatik.uni-hamburg.de (IP=134.100.4.42), directory pub/virus/texts/catalog. (A copy of the CVC is also available by anonymous FTP on cert.org in the pub/virus-l/docs/vtc directory.) A third source of information is the monthly Virus Bulletin, published in the UK. Among other things, it gives detailed technical information on viruses (see also A9 below). Unfortunately, it is very expensive (the subscription price is $395 per year). US subscriptions can be obtained by calling 203-431-8720 or writing to 590 Danbury Road, Ridgefield, CT 06877; for European subscriptions, the number is +44-235-555139 and the address is: The Quadrant, Abingdon, OX14 3YS, England. A fourth good source of information on DOS viruses is the "Computer Viruses" report of the National/International Computer Security Association. This is updated regularly, and is fairly complete. Copies cost approximately $75, and can be ordered by calling +1- 202-244-7875. ICSA/NCSA also publishes the monthly "Virus News and Reviews" and other publications. Another source of information is the documentation of Dr. Solomon's Anti-Virus ToolKit. It is more complete than the CVC list, just as accurate (if not more), but lists only DOS viruses. However, it is not available electronically; you must buy his anti-virus package and the virus information is part of the documentation. Yet another source of information is "Virus News International", published by S & S International. And, while not entirely virus- related, "Computers & Security" provides information on many aspects of computer security, including viruses. The best source of information available on Apple Macintosh viruses is the on-line documentation provided with the freeware Disinfectant program by John Norstad. This is available at most Mac archive sites. A8) Where can I get free or shareware anti-virus programs? The VIRUS-L/comp.virus archive sites carry publicly distributable anti-virus software products. See a recent listing of the archive sites (or ask the moderator for a recent listing) for more information on these sites. Many freeware/shareware anti-virus programs for DOS are available via anonymous FTP on WSMR-SIMTEL20.ARMY.MIL (192.88.110.20), in the directory PD1:<MSDOS.TROJAN-PRO>. Note that the SIMTEL20 archives are also "mirrored" at many other anonymous FTP sites, including oak.oakland.edu (141.210.10.117, pub/msdos/trojan-pro), wuarchive.wustl.edu (128.252.135.4, /mirrors/msdos/trojan-pro), and nic.funet.fi (128.214.6.100, /pub/msdos/utilities/trojan-pro). They can also be obtained via e-mail in uuencoded form from various TRICKLE sites, especially in Europe. Likewise, Macintosh anti-virus programs can be found on SIMTEL20 in the PD3:<MACINTOSH.VIRUS> directory. A list of many anti-viral programs, incl. commercial products and one person's rating of them, can be obtained by anonymous ftp from cert.org (192.88.209.5) in pub/virus-l/docs/reviews as file slade.quickref.rvw. A9) Where can I get more information on viruses, etc.? There are four excellent books on computer viruses available that should cover most of the introductory and technical questions you might have: * "Computers Under Attack: Intruders, Worms and Viruses," edited by Peter J. Denning, ACM Press/Addison-Wesley, 1990. This is a book of collected readings that discuss computer viruses, computer worms, break-ins, legal and social aspects, and many other items related to computer security and malicious software. A very solid, readable collection that doesn't require a highly-technical background. Price: $20.50. * "Rogue Programs: Viruses, Worms and Trojan Horses," edited by Lance J. Hoffman, Van Nostrand Reinhold, 1990. This is a book of collected readings describing in detail how viruses work, where they come from, what they do, etc. It also has material on worms, trojan horse programs, and other malicious software programs. This book focuses more on mechanism and relatively less on social aspects than does the Denning book; however, there is an excellent piece by Anne Branscomb that covers the legal aspects. Price: $32.95. * "A Pathology of Computer Viruses," by David Ferbrache, Springer-Verlag, 1992. This is a recent, in-depth book on the history, operation, and effects of computer viruses. It is one of the most complete books on the subject, with an extensive history section, a section on Macintosh viruses, network worms, and Unix viruses (if they were to exist). * "A Short Course on Computer Viruses", by Dr. Fred B. Cohen, ASP Press, 1990. This book is by a well-known pioneer in virus research, who has also written dozens of technical papers on the subject. The book can be obtained by writing to ASP Press, P.O. Box 81270, Pittsburgh, PA 15217. Price: $24.00. A somewhat dated, but still useful, high-level description of viruses, suitable for a complete novice without extensive computer background is in "Computer Viruses: Dealing with Electronic Vandalism and Programmed Threats," by Eugene H. Spafford, Kathleen A. Heaphy, and David J. Ferbrache, ADAPSO (Arlington VA), 1989. ADAPSO is a computer industry service organization and not a publisher, so the book cannot be found in bookstores; copies can be obtained directly from ADAPSO @ +1 703-522-5055). There is a discount for ADAPSO members, educators, and law enforcement personnel. Many people have indicated they find this a very understandable reference; portions of it have been reprinted many other places, including Denning & Hoffman's books (above). It is also worth consulting various publications such as _Computers & Security_ (which, while not restricted to viruses, contains many of Cohen's papers) and the _Virus Bulletin_ (published in the UK; its technical articles are considered good, although there has been much criticism in VIRUS-L of some of its product evaluations). ====================================================== = Section B. Definitions and General Information = ====================================================== B1) What are computer viruses (and why should I worry about them)? According to Fred Cohen's well-known definition, a COMPUTER VIRUS is a computer program that can infect other computer programs by modifying them in such a way as to include a (possibly evolved) copy of itself. Note that a program does not have to perform outright damage (such as deleting or corrupting files) in order to to be called a "virus". However, Cohen uses the terms within his definition (e.g. "program" and "modify") a bit differently from the way most anti-virus researchers use them, and classifies as viruses some things which most of us would not consider viruses. Many people use the term loosely to cover any sort of program that tries to hide its (malicious) function and tries to spread onto as many computers as possible. (See the definition of "Trojan".) Be aware that what constitutes a "program" for a virus to infect may include a lot more than is at first obvious - don't assume too much about what a virus can or can't do! These software "pranks" are very serious; they are spreading faster than they are being stopped, and even the least harmful of viruses could be fatal. For example, a virus that stops your computer and displays a message, in the context of a hospital life-support computer, could be fatal. Even those who created the viruses could not stop them if they wanted to; it requires a concerted effort from computer users to be "virus-aware", rather than the ignorance and ambivalence that have allowed them to grow to such a problem. B2) What is a Trojan Horse? A TROJAN HORSE is a program that does something undocumented which the programmer intended, but that the user would not approve of if he knew about it. According to some people, a virus is a particular case of a Trojan Horse, namely one which is able to spread to other programs (i.e., it turns them into Trojans too). According to others, a virus that does not do any deliberate damage (other than merely replicating) is not a Trojan. Finally, despite the definitions, many people use the term "Trojan" to refer only to a *non-replicating* malicious program, so that the set of Trojans and the set of viruses are disjoint. B3) What are the main types of PC viruses? Generally, there are two main classes of viruses. The first class consists of the FILE INFECTORS which attach themselves to ordinary program files. These usually infect arbitrary .COM and/or .EXE programs, though some can infect any program for which execution is requested, such as .SYS, .OVL, .PRG, & .MNU files. File infectors can be either DIRECT ACTION or RESIDENT. A direct- action virus selects one or more other programs to infect each time the program which contains it is executed. A resident virus hides itself somewhere in memory the first time an infected program is executed, and thereafter infects other programs when *they* are executed (as in the case of the Jerusalem) or when certain other conditions are fulfilled. The Vienna is an example of a direct-action virus. Most other viruses are resident. The second category is SYSTEM or BOOT-RECORD INFECTORS: those viruses which infect executable code found in certain system areas on a disk which are not ordinary files. On DOS systems, there are ordinary boot-sector viruses, which infect only the DOS boot sector, and MBR viruses which infect the Master Boot Record on fixed disks and the DOS boot sector on diskettes. Examples include Brain, Stoned, Empire, Azusa, and Michelangelo. Such viruses are always resident viruses. Finally, a few viruses are able to infect both (the Tequila virus is one example). These are often called "MULTI-PARTITE" viruses, though there has been criticism of this name; another name is "BOOT-AND-FILE" virus. FILE SYSTEM or CLUSTER viruses (e.g. Dir-II) are those which modify directory table entries so that the virus is loaded and executed before the desired program is. Note that the program itself is not physically altered, only the directory entry is. Some consider these infectors to be a third category of viruses, while others consider them to be a sub-category of the file infectors. B4) What is a stealth virus? A STEALTH virus is one which hides the modifications it has made in the file or boot record, usually by monitoring the system functions used by programs to read files or physical blocks from storage media, and forging the results of such system functions so that programs which try to read these areas see the original uninfected form of the file instead of the actual infected form. Thus the viral modifications go undetected by anti-viral programs. However, in order to do this, the virus must be resident in memory when the anti-viral program is executed. Example: The very first DOS virus, Brain, a boot-sector infector, monitors physical disk I/O and re-directs any attempt to read a Brain-infected boot sector to the disk area where the original boot sector is stored. The next viruses to use this technique were the file infectors Number of the Beast and Frodo (= 4096 = 4K). Countermeasures: A "clean" system is needed so that no virus is present to distort the results. Thus the system should be built from a trusted, clean master copy before any virus-checking is attempted; this is "The Golden Rule of the Trade." With DOS, (1) boot from original DOS diskettes (i.e. DOS Startup/Program diskettes from a major vendor that have been write-protected since their creation); (2) use only tools from original diskettes until virus-checking has completed. B5) What is a polymorphic virus? A POLYMORPHIC virus is one which produces varied (yet fully operational) copies of itself, in the hope that virus scanners (see D1) will not be able to detect all instances of the virus. One method to evade signature-driven virus scanners is self-encryption with a variable key; however these viruses (e.g. Cascade) are not termed "polymorphic," as their decryption code is always the same and thus can be used as a virus signature even by the simplest, signature- driven virus scanners (unless another virus or program uses the identical decryption routine). One method to make a polymorphic virus is to choose among a variety of different encryption schemes requiring different decryption routines: only one of these routines would be plainly visible in any instance of the virus (e.g. the Whale virus). A signature-driven virus scanner would have to exploit several signatures (one for each possible encryption method) to reliably identify a virus of this kind. A more sophisticated polymorphic virus (e.g. V2P6) will vary the sequence of instructions in its copies by interspersing it with "noise" instructions (e.g. a No Operation instruction, or an instruction to load a currently unused register with an arbitrary value), by interchanging mutually independent instructions, or even by using various instruction sequences with identical net effects (e.g. Subtract A from A, and Move 0 to A). A simple-minded, signature-based virus scanner would not be able to reliably identify this sort of virus; rather, a sophisticated "scanning engine" has to be constructed after thorough research into the particular virus. The most sophisticated form of polymorphism discovered so far is the MtE "Mutation Engine" written by the Bulgarian virus writer who calls himself the "Dark Avenger". It comes in the form of an object module. Any virus can be made polymorphic by adding certain calls to the assembler source code and linking to the mutation-engine and random-number-generator modules. The advent of polymorphic viruses has rendered virus-scanning an ever more difficult and expensive endeavor; adding more and more search strings to simple scanners will not adequately deal with these viruses. B6) What are fast and slow infectors? A typical file infector (such as the Jerusalem) copies itself to memory when a program infected by it is executed, and then infects other programs when they are executed. A FAST infector is a virus which, when it is active in memory, infects not only programs which are executed, but even those which are merely opened. The result is that if such a virus is in memory, running a scanner or integrity checker can result in all (or at least many) programs becoming infected all at once. Examples are the Dark Avenger and the Frodo viruses. The term "SLOW infector" is sometimes used for a virus which, if it is active in memory, infects only files as they are modified (or created). The purpose is to fool people who use integrity checkers into thinking that the modification reported by the integrity checker is due solely to legitimate reasons. An example is the Darth Vader virus. B7) What is a sparse infector? The term "SPARSE infector" is sometimes given to a virus which infects only occasionally, e.g. every 10th executed file, or only files whose lengths fall within a narrow range, etc. By infecting less often, such viruses try to minimize the probability of being discovered by the user. B8) What is a companion virus? A COMPANION virus is one which, instead of modifying an existing file, creates a new program which (unknown to the user) gets executed by the command-line interpreter instead of the intended program. (On exit, the new program executes the original program so that things will appear normal.) The only way this has been done so far is by creating an infected .COM file with the same name as an existing .EXE file. Note that those integrity checkers which look only for *modifications* in *existing* files will fail to detect such viruses. (Note that not all researchers consider this type of malicious code to be a virus, since it does not modify existing files.) B9) What is an armored virus? An ARMORED virus is one which uses special tricks to make the tracing, disassembling and understanding of their code more difficult. A good example is the Whale virus. B10) Miscellaneous Jargon and Abbreviations BSI = Boot Sector Infector: a virus which takes control when the computer attempts to boot (as opposed to a file infector). CMOS = Complementary Metal Oxide Semiconductor: A memory area that is used in AT and higher class PCs for storage of system information. CMOS is battery backed RAM (see below), originally used to maintain date and time information while the PC was turned off. CMOS memory is not in the normal CPU address space and cannot be executed. While a virus may place data in the CMOS or may corrupt it, a virus cannot hide there. DOS = Disk Operating System. We use the term "DOS" to mean any of the MS-DOS, PC-DOS, or DR DOS systems for PCs and compatibles, even though there are operating systems called "DOS" on other (unrelated) machines. MBR = Master Boot Record: the first Absolute sector (track 0, head 0, sector 1) on a PC hard disk, that usually contains the partition table (but on some PCs may simply contain a boot sector). This is not the same as the first DOS sector (Logical sector 0). RAM = Random Access Memory: the place programs are loaded into in order to execute; the significance for viruses is that, to be active, they must grab some of this for themselves. However, some virus scanners may declare that a virus is active simply when it is found in RAM, even though it might be simply left over in a buffer area of RAM rather than truly being active. TOM = Top Of Memory: the end of conventional memory, an architectural design limit at the 640K mark on most PCs. Some early PCs may not be fully populated, but the amount of memory is always a multiple of 64K. A boot-record virus on a PC typically resides just below this mark and changes the value which will be reported for the TOM to the location of the beginning of the virus so that it won't get overwritten. Checking this value for changes can help detect a virus, but there are also legitimate reasons why it may change (see C11). A very few PCs with unusual memory managers/settings may report in excess of 640K. TSR = Terminate but Stay Resident: these are PC programs that stay in memory while you continue to use the computer for other purposes; they include pop-up utilities, network software, and the great majority of viruses. These can often be seen using utilities such as MEM, MAPMEM, PMAP, F-MMAP and INFOPLUS. ================================= = Section C. Virus Detection = ================================= C1) What are the symptoms and indications of a virus infection? Viruses try to spread as much as possible before they deliver their "payload", but there can be symptoms of virus infection before this, and it is important to use this opportunity to spot and eradicate the virus before any destruction. There are various kinds of symptoms which some virus authors have written into their programs, such as messages, music and graphical displays. However, the main indications are changes in file sizes and contents, changing of interrupt vectors or the reassignment of other system resources. The unaccounted use of RAM or a reduction in the amount known to be in the machine are important indicators. The examination of the code is valuable to the trained eye, but even the novice can often spot the gross differences between a valid boot sector and an infected one. However, these symptoms, along with longer disk activity and strange behavior from the hardware, can also be caused by genuine software, by harmless "prank" programs, or by hardware faults. The only foolproof way to determine that a virus is present is for an expert to analyze the assembly code contained in all programs and system areas, but this is usually impracticable. Virus scanners go some way towards that by looking in that code for known viruses; some will even try to use heuristic means to spot viral code, but this is not always reliable. It is wise to arm yourself with the latest anti-viral software, but also to pay close attention to your system; look particularly for any change in the memory map or configuration as soon as you start the computer. For users of DOS 5.0, the MEM program with the /C switch is very handy for this. If you have DRDOS, use MEM with the /A switch; if you have an earlier version, use CHKDSK or the commonly-available PMAP or MAPMEM utilities. You don't have to know what all the numbers mean, only that they change. Mac users have "info" options that give some indication of memory use, but may need ResEdit for more detail. C2) What steps should be taken in diagnosing and identifying viruses? Most of the time, a virus scanner program will take care of that for you. (Remember, though, that scanning programs must be kept up to date. Also remember that different scanner authors may call the same virus by different names. If you want to identify a virus in order to ask for help, it is best to run at least two scanners on it and, when asking, say which scanners, and what versions, gave the names.) To help identify problems early, run it on new programs and diskettes; when an integrity checker reports a mismatch, when a generic monitoring program sounds an alarm; or when you receive an updated version of a scanner (or a different scanner than the one you have been using). However, because of the time required, it is not generally advisable to insert into your AUTOEXEC.BAT file a command to run a scanner on an entire hard disk on every boot. If you run into an alarm that the scanner doesn't identify, or doesn't properly clean up for you, first verify that the version that you are using is the most recent, and then get in touch with one of the reputable antivirus researchers, who may ask you to send a copy of the infected file to him. See also question C10. C3) What is the best way to remove a virus? In order that downtime be short and losses low, do the minimum that you must to restore the system to a normal state, starting with booting the system from a clean diskette. It is very unlikely that you need to low-level reformat the hard disk! If backups of the infected files are available and appropriate care was taken when making the backups (see D10), this is the safest solution, even though it requires a lot of work if many files are involved. More commonly, a disinfecting program is used. If the virus is a boot sector infector, you can continue using the computer with relative safety if you boot it from a clean system diskette, but it is wise to go through all your diskettes removing infection, since sooner or later you may be careless and leave a diskette in the machine when it reboots. Boot sector infections on PCs can be cured by a two-step approach of replacing the MBR (on the hard disk), either by using a backup or by the FDISK/MBR command (from DOS 5 and up), then using the SYS command to replace the DOS boot sector. C4) What does the <insert name here> virus do? If an anti-virus program has detected a virus on your computer, don't rush to post a question to this list asking what it does. First, it might be a false positive alert (especially if the virus is found only in one file), and second, some viruses are extremely common, so the question "What does the Stoned virus do?" or "What does the Jerusalem virus do?" is asked here repeatedly. While this list is monitored by several anti-virus experts, they get tired of perpetually answering the same questions over and over again. In any case, if you really need to know what a particular virus does (as opposed to knowing enough to get rid of it), you will need a longer treatise than could be given to you here. For example, the Stoned virus replaces the disk's boot record with its own, relocating the original to a sector on the disk that may (or may not) occur in an unused portion of the root directory of a DOS diskette; when active, it sits in an area a few kilobytes below the top of memory. All this description could apply to a number of common viruses; but the important points of where the original boot sector goes - and what effect that has on networking software, non-DOS partitions, and so on are all major questions in themselves. Therefore, it is better if you first try to answer your question yourself. There are several sources of information about the known computer viruses, so please consult one of them before requesting information publicly. Chances are that your virus is rather well known and that it is already described in detail in at least one of these sources. (See the answer to question A7, for instance.) C5) What are "false positives" and "false negatives"? A FALSE POSITIVE (or Type-I) error is one in which the anti-viral software claims that a given file is infected by a virus when in reality the file is clean. A FALSE NEGATIVE (or Type-II) error is one in which the software fails to indicate that an infected file is infected. Clearly false negatives are more serious than false positives, although both are undesirable. It has been proven by Dr. Fred Cohen that every virus detector must have either false positives or false negatives or both. This is expressed by saying that detection of viruses is UNDECIDABLE. However his theorem does not preclude a program which has no false negatives and *very few* false positives (e.g. if the only false positives are those due to the file containing viral code which is never actually executed, so that technically we do not have a virus). In the case of virus scanners, false positives are rare, but they can arise if the scan string chosen for a given virus is also present in some benign programs because the string was not well chosen. False negatives are more common with virus scanners because scanners will miss a completely new or a heavily modified virus. One other serious problem could occur: A positive that is misdiagnosed (e.g., a scanner that detects the Empire virus in a boot record but reports it as the Stoned). In the case of a boot sector infector, use of a Stoned specific "cure" to recover from the Empire could result in an unreadable disk or loss of extended partitions. Similarly, sometimes "generic" recovery can result in unusable files, unless a check is made (e.g. by comparing checksums) that the recovered file is identical to the original file. Some more recent products store information about the original programs to allow verification of recovery processes. C6) Could an anti-viral program itself be infected? Yes, so it is important to obtain this software from good sources, and to trust results only after running scanners from a "clean" system. But there are situations where a scanner appears to be infected when it isn't. Most antiviral programs try very hard to identify only viral infections, but sometimes they give false alarms. If two different antiviral programs are both of the "scanner" type, they will contain "signature strings" to identify viral infections. If the strings are not "encrypted", then they will be identified as a virus by another scanner type program. Also, if the scanner does not remove the strings from memory after they are run, then another scanner may detect the virus string "in memory". Some "change detection" type antiviral programs add a bit of code or data to a program when "protecting" it. This might be detected by another "change detector" as a change to a program, and therefore suspicious. It is good practice to use more than one antiviral program. Do be aware, however, that antiviral programs, by their nature, may confuse each other. C7) Where can I get a virus scanner for my Unix system? Basically, you shouldn't bother scanning for Unix viruses at this point in time. Although it is possible to write Unix-based viruses, we have yet to see any instance of a non-experimental virus in that environment. Someone with sufficient knowledge and access to write an effective virus would be more likely to conduct other activities than virus-writing. Furthermore, the typical form of software sharing in an Unix environment would not support virus spread. This answer is not meant to imply that viruses are impossible, or that there aren't security problems in a typical Unix environment -- there are. However, true viruses are highly unlikely and would corrupt file and/or memory integrity. For more information on Unix security, see the book "Practical Unix Security" by Garfinkel and Spafford, O'Reilly & Associates, 1991 (it can be ordered via e-mail from nuts@ora.com). However, there are special cases for which scanning Unix systems for non-Unix viruses does make sense. For example, a Unix system which is acting as a file server (e.g., PC-NFS) for PC systems is quite capable of containing PC file infecting viruses that are a danger to PC clients. Note that, in this example, the UNIX system would be scanned for PC viruses, not UNIX viruses. Another example is in the case of a 386/486 PC system running Unix, since this system is still vulnerable to infection by MBR infectors such as Stoned and Michelangelo, which are operating system independent. (Note that an infection on such a Unix PC system would probably result in disabling the Unix disk partition(s) from booting.) In addition, a file integrity checker (to detect unauthorized changes in executable files) on Unix systems is a very good idea. (One free program which can do this test, as well as other tests, is the COPS package, available by anonymous FTP on cert.org.) Unauthorized file changes on Unix systems are very common, although they usually are not due to virus activity. C8) Why does my anti-viral scanner report an infection only sometimes? There are circumstances where part of a virus exists in RAM without being active: If your scanner reports a virus in memory only occasionally, it could be due to the operating system buffering disk reads, keeping disk contents that include a virus in memory (harmlessly), in which case it should also find it on disk. Or after running another scanner, there may be scan strings left (again harmlessly) in memory. This is sometimes called a "ghost positive" alert. C9) Is my disk infected with the Stoned virus? Of course the answer to this, and many similar questions, is to obtain a good virus detector. There are many to choose from, including ones that will scan diskettes automatically as you use them. Remember to check all diskettes, even non-system ("data") diskettes. It is possible, if you have an urgent need to check a system when you don't have any anti-viral tools, to boot from a clean system diskette, and use the CHKDSK method (mentioned in C1) to see if it is in memory, then look at the boot sector with a disk editor. Usually the first few bytes will indicate the characteristic far jump of the Stoned virus; however, you could be looking at a perfectly good disk that has been "innoculated" against the virus, or at a diskette that seems safe but contains a totally different type of virus. C10) I think I have detected a new virus; what do I do? Whenever there is doubt over a virus, you should obtain the latest versions of several (not just one) major virus scanners. Some scanning programs now use "heuristic" methods (F-PROT, CHECKOUT and SCANBOOT are examples), and "activity monitoring" programs can report a disk or file as being possibly infected when it is in fact perfectly safe (odd, perhaps, but not infected). If no string-matching scan finds a virus, but a heuristic program does (or there are other reasons to suspect the file, e.g., change in size of files) then it is possible that you have found a new virus, although the chances are probably greater that it is an odd-but-okay disk or file. Start by looking in recent VIRUS-L postings about "known" false positives, then contact the author of the anti-virus software that reports it as virus-like; the documentation for the software may have a section explaining what to do if you think you have found a new virus. Consider using the BootID or Checkout programs to calculate the "hashcode" of a diskette in the case of boot sector infectors, rather than send a complete diskette or "live" virus until requested. C11) CHKDSK reports 639K (or less) total memory on my system; am I infected? If CHKDSK displays 639K for the total memory instead of 640K (655,360 bytes) - so that you are missing only 1K - then it is probably due to reasons other than a virus since there are very few viruses which take only 1K from total memory. Legitimate reasons for a deficiency of 1K include: 1) A PS/2 computer. IBM PS/2 computers reserve 1K of conventional RAM for an Extended BIOS Data Area, i.e. for additional data storage required by its BIOS. 2) A computer with American Megatrends Inc. (AMI) BIOS, which is set up (with the built-in CMOS setup program) in such a way that the BIOS uses the upper 1K of memory for its internal variables. (It can be instructed to use lower memory instead.) 3) A SCSI controller. 4) The DiskSecure program. 5) Mouse buffers for older Compaqs. If, on the other hand, you are missing 2K or more from the 640K, 512K, or whatever the conventional memory normally is for your PC, the chances are greater that you have a boot-record virus (e.g. Stoned, Michelangelo), although even in this case there may be legitimate reasons for the missing memory: 1) Many access control programs for preventing booting from a floppy. 2) H/P Vectra computers. 3) Some special BIOSes which use memory (e.g.) for a built-in calendar and/or calculator. However, these are only rough guides. In order to be more certain whether the missing memory is due to a virus, you should: (1) run several virus detectors; (2) look for a change in total memory every now and then; (3) compare the total memory size with that obtained when cold booting from a "clean" system diskette. The latter should show the normal amount of total memory for your configuration. Note: in all cases, CHKDSK should be run without software such as MS-Windows or DesqView loaded, since GUIs seem to be able to open DOS boxes only on whole K boundaries (some seem to be even coarser); thus CHKDSK run from a DOS box may report unrepresentative values. Note also that some machines have only 512K or 256K instead of 640K of conventional memory. C12) I have an infinite loop of sub-directories on my hard drive; am I infected? Probably not. This happens now and then, when something sets the "cluster number" field of some subdirectory the same cluster as an upper-level (usually the root) directory. The /F parameter of CHKDSK, and any of various popular utility programs, should be able to fix this, usually by removing the offending directory. *Don't* erase any of the "replicated" files in the odd directory, since that will erase the "copy" in the root as well (it's really not a copy at all; just a second pointer to the same file). =================================== = Section D. Protection plans = =================================== D1) What is the best protection policy for my computer? There is no "best" anti-virus policy. In particular, there is no program that can magically protect you against all viruses. But you can design an anti-virus protection strategy based on multiple layers of defense. There are three main kinds of anti-viral software, plus several other means of protection (such as hardware write-protect methods). 1) GENERIC MONITORING programs. These try to prevent viral activity before it happens, such as attempts to write to another executable, reformat the disk, etc. Examples: SECURE and FluShot+ (PC), and GateKeeper (Macintosh). 2) SCANNERS. Most look for known virus strings (byte sequences which occur in known viruses, but hopefully not in legitimate software) or patterns, but a few use heuristic techniques to recognize viral code. A scanner may be designed to examine specified disks or files on demand, or it may be resident, examining each program which is about to be executed. Most scanners also include virus removers. Examples: FindViru in Dr Solomon's Anti-Virus Toolkit, FRISK's F-Prot, McAfee's VIRUSCAN (all PC), Disinfectant (Macintosh). Resident scanners: McAfee's V-Shield, and VIRSTOP. Heuristic scanners: the Analyse module in FRISK's F-PROT package, and SCANBOOT. 3) INTEGRITY CHECKERS or MODIFICATION DETECTORS. These compute a small "checksum" or "hash value" (usually CRC or cryptographic) for files when they are presumably uninfected, and later compare newly calculated values with the original ones to see if the files have been modified. This catches unknown viruses as well as known ones and thus provides *generic* detection. On the other hand, modifications can also be due to reasons other than viruses. Usually, it is up to the user to decide which modifications are intentional and which might be due to viruses, although a few products give the user help in making this decision. As in the case of scanners, integrity checkers may be called to checksum entire disks or specified files on demand, or they may be resident, checking each program which is about to be executed (the latter is sometimes called an INTEGRITY SHELL). A third implementation is as a SELF-TEST, i.e. the checksumming code is attached to each executable file so that it checks itself just before execution. Examples: Fred Cohen's ASP Integrity Toolkit (commercial), and Integrity Master and VDS (shareware), all for the PC. 3a) A few modification detectors come with GENERIC DISINFECTION. I.e., sufficient information is saved for each file that it can be restored to its original state in the case of the great majority of viral infections, even if the virus is unknown. Examples: V-Analyst 3 (BRM Technologies, Israel), marketed in the US as Untouchable (by Fifth Generation), and the VGUARD module of V-care. Of course, only a few examples of each type have been given. All of them can find their place in the protection against computer viruses, but you should appreciate the limitations of each method, along with system-supplied security measures that may or may not be helpful in defeating viruses. Ideally, you would arrange a combination of methods that cover the loopholes between them. A typical PC installation might include a protection system on the hard disk's MBR to protect against viruses at load time (ideally this would be hardware or in BIOS, but software methods such as DiskSecure and PanSoft's Immunise are pretty good). This would be followed by resident virus detectors loaded as part of the machine's startup (CONFIG.SYS or AUTOEXEC.BAT), such as FluShot+ and/or VirStop together with ScanBoot. A scanner such as F-Prot or McAfee's SCAN could be put into AUTOEXEC.BAT to look for viruses as you start up, but this may be a problem if you have a large disk to check (or don't reboot often enough). Most importantly, new files should be scanned as they arrive on the system. If your system has DR DOS installed, you should use the PASSWORD command to write-protect all system executables and utilities. If you have Stacker or SuperStore, you can get some improved security from these compressed drives, but also a risk that those viruses stupid enough to directly write to the disk could do much more damage than normal; using a software write-protect system (such as provided with Disk Manager or Norton Utilities) may help, but the best solution (if possible) is to put all executables on a disk of their own, protected by a hardware read-only system that sounds an alarm if a write is attempted. If you do use a resident BSI detector or a scan-while-you-copy detector, it is important to trace back any infected diskette to its source; the reason why viruses survive so well is that usually you cannot do this, because the infection is found long after the infecting diskette has been forgotten with most people's lax scanning policies. Organizations should devise and implement a careful policy, that may include a system of vetting new software brought into the building and free virus detectors for home machines of employees/students/etc who take work home with them. Other anti-viral techniques include: (a) Creation of a special MBR to make the hard disk inaccessible when booting from a diskette (the latter is useful since booting from a diskette will normally bypass the protection in the CONFIG.SYS and AUTOEXEC.BAT files of the hard disk). Example: GUARD. (b) Use of Artificial Intelligence to learn about new viruses and extract scan patterns for them. Examples: V-Care (CSA Interprint, Israel; distributed in the U.S. by Sela Consultants Corp.), Victor Charlie (Bangkok Security Associates, Thailand; distributed in the US by Computer Security Associates). (c) Encryption of files (with decryption before execution). D2) Is it possible to protect a computer system with only software? Not perfectly; however, software defenses can significantly reduce your risk of being affected by viruses WHEN APPLIED APPROPRIATELY. All virus defense systems are tools - each with their own capabilities and limitations. Learn how your system works and be sure to work within its limitations. From a software standpoint, a very high level of protection/detection can be achieved with only software, using a layered approach. 1) ROM BIOS - password (access control) and selection of boot disk. (Some may consider this hardware.) 2) Boot sectors - integrity management and change detection. 3) OS programs - integrity management of existing programs, scanning of unknown programs. Requirement of authentication values for any new or transmitted software. 4) Locks that prevent writing to a fixed or floppy disk. As each layer is added, invasion without detection becomes more difficult. However complete protection against any possible attack cannot be provided without dedicating the computer to pre-existing or unique tasks. The international standardization of the world on the IBM PC architecture is both its greatest asset and its greatest vulnerability. D3) Is it possible to write-protect the hard disk with only software? The answer is no. There are several programs which claim to do that, but *all* of them can be bypassed using only the currently known techniques that are used by some viruses. Therefore you should never rely on such programs *alone*, although they can be useful in combination with other anti-viral measures. D4) What can be done with hardware protection? Hardware protection can accomplish various things, including: write protection for hard disk drives, memory protection, monitoring and trapping unauthorized system calls, etc. Again, no tool is foolproof. The popular idea of write-protection (see D3) may stop viruses spreading to the disk that is protected, but doesn't, in itself, prevent a virus from running. Also, some of the existing hardware protections can be easily bypassed, fooled, or disconnected, if the virus writer knows them well and designs a virus which is aware of the particular defense. D5) Will setting DOS file attributes to READ ONLY protect them from viruses? No. While the Read Only attribute will protect your files from a few viruses, most simply override it, and infect normally. So, while setting executable files to Read Only is not a bad idea, it is certainly not a thorough protection against viruses! D6) Will password/access control systems protect my files from viruses? All password and other access control systems are designed to protect the user's data from other users and/or their programs. Remember, however, that when you execute an infected program the virus in it will gain your current rights/privileges. Therefore, if the access control system provides *you* the right to modify some files, it will provide it to the virus too. Note that this does not depend on the operating system used - DOS, Unix, or whatever. Therefore, an access control system will protect your files from viruses no better than it protects them from you. Under DOS, there is no memory protection, so a virus could disable the access control system in memory, or even patch the operating system itself. On the more advanced operating systems (Unix) this is not possible, so at least the protection cannot be disabled by a virus. However it will still spread, due to the reasons noted above. In general, the access control systems (if implemented correctly) are able only to slow down the virus spread, not to eliminate viruses entirely. Of course, it's better to have access control than not to have it at all. Just be sure not to develop a false sense of security and to rely *entirely* on the access control system to protect you. D7) Will the protection systems in DR DOS work against viruses? Partially. Neither the password file/directory protection available from DR DOS version 5 onwards, nor the secure disk partitions introduced in DR DOS 6 are intended to combat viruses, but they do to some extent. If you have DR DOS, it is very wise to password-protect your files (to stop accidental damage too), but don't depend on it as the only means of defense. The use of the password command (e.g. PASSWORD/W:MINE *.EXE *.COM) will stop more viruses than the plain DOS attribute facility, but that isn't saying much! The combination of the password system plus a disk compression system may be more secure (because to bypass the password system they must access the disk directly, but under SuperStore or Stacker the physical disk is meaningless to the virus). There may be some viruses which, rather than invisibly infecting files on compressed disks in fact very visibly corrupt the disk. The "secure disk partitions" system introduced with DR DOS 6 may be of some help against a few viruses that look for DOS partitions on a disk. The main use is in stopping people fiddling with (and infecting) your hard disk while you are away. Furthermore, DR DOS is not very compatible with MS/PC-DOS, especially down to the low-level tricks that some viruses are using. For instance, some internal memory structures are "read-only" in the sense that they are constantly updated (for DOS compatibility) but not really used by DR DOS, so that even if a sophisticated virus modifies them, this does not have any effect. In general, using a less compatible system diminishes the number of viruses that can infect it. For instance, the introduction of hard disks made the Brain virus almost disappear; the introduction of 80286 and DOS 4.x+ made the Yale and Ping Pong viruses extinct, and so on. D8) Will a write-protect tab on a floppy disk stop viruses? In general, yes. The write-protection on IBM PC (and compatible) and Macintosh floppy disk drives is implemented in hardware, not software, so viruses cannot infect a diskette when the write-protection mechanism is functioning properly. But remember: (a) A computer may have a faulty write-protect system (this happens!) - you can test it by trying to copy a file to the diskette when it is presumably write-protected. (b) Someone may have removed the tab for a while, allowing a virus on. (c) The files may have been infected before the disk was protected. Even some diskettes "straight from the factory" have been known to be infected in the production processes. So it is worthwhile scanning even write-protected disks for viruses. D9) Do local area networks (LANs) help to stop viruses or do they facilitate their spread? Both. A set of computers connected in a well managed LAN, with carefully established security settings, with minimal privileges for each user, and without a transitive path of information flow between the users (i.e., the objects writable by any of the users are not readable by any of the others) is more virus-resistant than the same set of computers if they are not interconnected. The reason is that when all computers have (read-only) access to a common pool of executable programs, there is usually less need for diskette swapping and software exchange between them, and therefore less ways through which a virus could spread. However, if the LAN is not well managed, with lax security, it could help a virus to spread like wildfire. It might even be impossible to remove the infection without shutting down the entire LAN. A network that supports login scripting is inherently more resistant to viruses than one that does not, if this is used to validate the client before allowing access to the network. D10) What is the proper way to make backups? Data and text files, and programs in source form, should be backed up each time they are modified. However, the only backups you should keep of COM, EXE and other *executable* files are the *original* versions, since if you back up an executable file on your hard disk over and over, it may have become infected meanwhile, so that you may no longer have an uninfected backup of that file. Therefore: 1. If you've downloaded shareware, copy it (preferably as a ZIP or other original archive file) onto your backup medium and do not re-back it up later. 2. If you have purchased commercial software, it's best to create a ZIP (or other) archive from the original diskettes (assuming they're not copy protected) and transfer the archive onto that medium. Again, do not re-back up. 3. If you write your own programs, back up only the latest version of the *source* programs. Depend on recompilation to reproduce the executables. 4. If an executable has been replaced by a new version, then of course you will want to keep a backup of the new version. However, if it has been modified as a result of your having changed configuration information, it seems safer *not* to back up the modified file; you can always re-configure the backup copy later if you have to. 5. Theoretically, source programs could be infected, but until such a virus is discovered, it seems preferable to treat such files as non-executables and back them up whenever you modify them. The same advice is probably appropriate for batch files as well, despite the fact that a few batch file infectors have been discovered. ======================================================= = Section E. Facts and Fibs about computer viruses = ======================================================= E1) Can boot sector viruses infect non-bootable floppy disks? Any diskette that has been properly formatted contains an executable program in the boot sector. If the diskette is not "bootable," all that boot sector does is print a message like "Non-system disk or disk error; replace and strike any key when ready", but it's still executable and still vulnerable to infection. If you accidentally turn your machine on with a "non-bootable" diskette in the drive, and see that message, it means that any boot virus that may have been on that diskette *has* run, and has had the chance to infect your hard drive, or whatever. So when thinking about viruses, the word "bootable" (or "non-bootable") is really misleading. All formatted diskettes are capable of carrying a virus. E2) Can a virus hide in a PC's CMOS memory? No. The CMOS RAM in which system information is stored and backed up by batteries is ported, not addressable. That is, in order to get anything out, you use I/O instructions. So anything stored there is not directly sitting in memory. Nothing in a normal machine loads the data from there and executes it, so a virus that "hid" in the CMOS RAM would still have to infect an executable object of some kind in order to load and execute whatever it had written to CMOS. A malicious virus can of course *alter* values in the CMOS as part of its payload, but it can't spread through, or hide itself in, the CMOS. A virus could also use the CMOS RAM to hide a small part of its body (e.g., the payload, counters, etc.). However, any executable code stored there must be first extracted to ordinary memory in order to be executed. E3) Can a virus hide in Extended or in Expanded RAM? Theoretically yes, although no such viruses are known yet. However, even if they are created, they will have to have a small part resident in conventional RAM; they cannot reside *entirely* in Extended or in Expanded RAM. E4) Can a virus hide in Upper Memory or in High Memory? Yes, it is possible to construct a virus which will locate itself in Upper Memory (640K to 1024K) or in High Memory (1024K to 1088K), and a few currently known viruses (e.g. EDV) do hide in Upper Memory. It might be thought that there is no point in scanning in these areas for any viruses other than those which are specifically known to inhabit them. However, there are cases when even ordinary viruses can be found in Upper Memory. Suppose that a conventional memory-resident virus infects a TSR program and this program is loaded high by the user (for instance, from AUTOEXEC.BAT). Then the virus code will also reside in Upper Memory. Therefore, an effective scanner must be able to scan this part of memory for viruses too. E5) Can a virus infect data files? Some viruses (e.g., Frodo, Cinderella) modify non-executable files. However, in order to spread, the virus must be executed. Therefore the "infected" non-executable files cannot be sources of further infection. However, note that it is not always possible to make a sharp distinction between executable and non-executable files. One man's code is another man's data and vice versa. Some files that are not directly executable contain code or data which can under some conditions be executed or interpreted. Some examples from the IBM PC world are .OBJ files, libraries, device drivers, source files for any compiler or interpreter, macro files for some packages like MS Word and Lotus 1-2-3, and many others. Currently there are viruses that infect boot sectors, master boot records, COM files, EXE files, BAT files, and device drivers, although any of the objects mentioned above can theoretically be used as an infection carrier. PostScript files can also be used to carry a virus, although no currently known virus does that. E6) Can viruses spread from one type of computer to another? The simple answer is that no currently known viruses can do this. Although the disk formats may be the same (e.g. Atari ST and DOS), the different machines interpret the code differently. For example, the Stoned virus cannot infect an Atari ST as the ST cannot execute the virus code in the bootsector. The Stoned virus contains instructions for the 80x86 family of CPU's that the 680x0-family CPU (Atari ST) can't understand or execute. The more general answer is that such viruses are possible, but unlikely. Such a virus would be quite a bit larger than current viruses and might well be easier to find. Additionally, the low incidence of cross-machine sharing of software means that any such virus would be unlikely to spread -- it would be a poor environment for virus growth. E7) Can DOS viruses run on non-DOS machines (e.g. Mac, Amiga)? In general, no. However, on machines running DOS emulators (either hardware or software based), DOS viruses - just like any DOS program - may function. These viruses would be subject to the file access controls of the host operating system. An example is when running a DOS emulator such as VP/ix under a 386 UNIX environment, DOS programs are not permitted access to files which the host UNIX system does not allow them to. Thus, it is important to administer these systems carefully. E8) Can mainframe computers be susceptible to computer viruses? Yes. Numerous experiments have shown that computer viruses spread very quickly and effectively on mainframe systems. However, to our knowledge, no non-research computer virus has been seen on mainframe systems. (The Internet worm of November 1988 was not a computer virus by most definitions, although it had some virus-like characteristics.) Computer viruses are actually a special case of something else called "malicious logic", and other forms of malicious logic -- notably Trojan horses -- are far quicker, more effective, and harder to detect than computer viruses. Nevertheless, on personal computers many more viruses are written than Trojans. There are two reasons for this: (1) Since a virus propagates, the number of users to which damage can be caused is much greater than in the case of a Trojan; (2) It's almost impossible to trace the source of a virus since viruses are not attached to any particular program. For further information on malicious programs on multi-user systems, see Matt Bishop's paper, "An Overview of Malicious Logic in a Research Environment", available by anonymous FTP on Dartmouth.edu (129.170.16.4) as "pub/security/mallogic.ps". E9) Some people say that disinfecting files is a bad idea. Is that true? Disinfecting a file is completely "safe" only if the disinfecting process restores the non-infected state of the object completely. That is, not only the virus must be removed from the file, but the original length of the file must be restored exactly, as well as its time and date of last modification, all fields in the header, etc. Sometimes it is necessary to be sure that the file is placed on the same clusters of the disk that it occupied prior to infection. If this is not done, then a program which uses some kind of self-checking or copy protection may stop functioning properly, if at all. None of the currently available disinfecting programs do all this. For instance, because of the bugs that exist in many viruses, some of the information of the original file is destroyed and cannot be recovered. Other times, it is even impossible to detect that this information has been destroyed and to warn the user. Furthermore, some viruses corrupt information very slightly and in a random way (Nomenklatura, Phoenix), so that it is not even possible to tell which files have been corrupted. Therefore, it is usually better to replace the infected objects with clean backups, provided you are certain that your backups are uninfected (see D10). You should try to disinfect files only if they contain some valuable data that cannot be restored from backups or compiled from their original source. E10) Can I avoid viruses by avoiding shareware/free software/games? No. There are many documented instances in which even commercial "shrink wrap" software was inadvertently distributed containing viruses. Avoiding shareware, freeware, games, etc. only isolates you from a vast collection of software (some of it very good, some of it very bad, most of it somewhere in between...). The important thing is not to avoid a certain type of software, but to be cautious of ANY AND ALL newly acquired software. Simply scanning all new software media for known viruses would be rather effective at preventing virus infections, especially when combined with some other prevention/detection strategy such as integrity management of programs. E11) Can I contract a virus on my PC by performing a "DIR" of an infected floppy disk? If you assume that the PC you are using is virus free before you perform the DIR command, then the answer is no. However, when you perform a DIR, the contents of the boot sector of the diskette are loaded into a buffer for use when determining disk layout etc., and certain anti-virus products will scan these buffers. If a boot sector virus has infected your diskette, the virus code will be contained in the buffer, which may cause some anti-virus packages to give the message "xyz virus found in memory, shut down computer immediately". In fact, the virus is not a threat at this point since control of the CPU is never passed to the virus code residing in the buffer. But, even though the virus is really not a threat at this point, this message should not be ignored. If you get a message like this, and then reboot from a clean DOS diskette and scan your hard-drive and find no virus, then you know that the false positive was caused by the fact that the infected boot-sector was loaded into a buffer, and the diskette should be appropriately disinfected before use. The use of DIR will not infect a clean system, even if the diskette it is being performed on does contain a virus. E12) Is there any risk in copying data files from an infected floppy disk to a clean PC's hard disk? Assuming that you did not boot or run any executable programs from the infected disk, the answer is generally no. There are two caveats: 1) you should be somewhat concerned about checking the integrity of these data files as they may have been destroyed or altered by the virus, and 2) if any of the "data" files are interpretable as executable by some other program (such as a Lotus macro) then these files should be treated as potentially malicious until the symptoms of the infection are known. The copying process itself is safe (given the above scenario). However, you should be concerned with what type of files are being copied to avoid introducing other problems. E13) Can a DOS virus survive and spread on an OS/2 system using the HPFS file system? Yes, both file-infecting and boot sector viruses can infect HPFS partitions. File-infecting viruses function normally and can activate and do their dirty deeds, and boot sector viruses can prevent OS/2 from booting if the primary bootable partition is infected. Viruses that try to directly address disk sectors cannot function because OS/2 prevents this activity. E14) Under OS/2 2.0, could a virus infected DOS session infect another DOS session? Each DOS program is run in a separate Virtual DOS Machine (their memory spaces are kept separated by OS/2). However, any DOS program has almost complete access to the files and disks, so infection can occur if the virus infects files; any other DOS session that executes a program infected by a virus that makes itself memory resident would itself become infected. However, bear in mind that all DOS sessions share the same copy of the command interpreter. Hence if it becomes infected, the virus will be active in *all* DOS sessions. E15) Can normal DOS viruses work under MS Windows? Most of them cannot. A system that runs exclusively MS Windows is, in general, more virus-resistant than a plain DOS system. The reason is that most resident viruses are not compatible with the memory management in Windows. Furthermore, most of the existing viruses will damage the Windows applications if they try to infect them as normal EXE files. The damaged applications will stop working and this will alert the user that something is wrong. However, virus-resistant is by no means virus-proof. For instance, most of the well-behaved resident viruses that infect only COM files (Cascade is an excellent example), will work perfectly in a DOS window. All non-resident COM infectors will be able to run and infect too. And currently there exists at least one Windows-specific virus which is able to properly infect Windows applications (it is compatible with the NewEXE file format). Any low level trapping of Interrupt 13, as by resident boot sector and MBR viruses, can also affect Windows operation, particularly if protected disk access (32BitDiskAccess=ON in SYSTEM.INI) is used. ========================================= = Section F. Miscellaneous Questions = ========================================= F1) How many viruses are there? It is not possible to give an exact number because new viruses are being created literally every day. Furthermore, different anti-virus researchers use different criteria to decide whether two viruses are different or one and the same. Some count viruses as different if they differ by at least one bit in their non-variable code. Others group the viruses in families and do not count the closely related variants in one family as different viruses. Taking a rough average, as of October 1992 there were about 1,800 IBM PC viruses, about 150 Amiga viruses, about 30 Macintosh viruses, about a dozen Acorn Archimedes viruses, several Atari ST viruses, and a few Apple II viruses. However, very few of the existing viruses are widespread. For instance, only about three dozen of the known IBM PC viruses are causing most of the reported infections. F2) How do viruses spread so quickly? This is a very complex issue. Most viruses don't spread very quickly. Those that do spread widely are able to do so for a variety of reasons. A large target population (i.e., millions of compatible computers) helps... A large virus population helps... Vendors whose quality assurance mechanisms rely on, for example, outdated scanners help... Users who gratuitously insert new software into their systems without making any attempt to test for viruses help... All of these things are factors. F3) What is the plural of "virus"? "Viruses" or "viri" or "virii" or... The correct English plural of "virus" is "viruses." The Latin word is a mass noun (like "air"), and there is no correct Latin plural. Please use "viruses," and if people use other forms, please don't use VIRUS-L/comp.virus to correct them. F4) When reporting a virus infection (and looking for assistance), what information should be included? People frequently post messages to VIRUS-L/comp.virus requesting assistance on a suspected virus problem. Quite often, the information supplied is not sufficient for the various experts on the list to be able to help out. Also note that any such assistance from members of the list is provided on a volunteer basis; be grateful for any help received. Try to provide the following information in your requests for assistance: - The name of the virus (if known); - The name of the program that detected it; - The version of the program that detected it; - Any other anti-virus software that you are running and whether it has been able to detect the virus or not, and if yes, by what name did it call it; - Your software and hardware configuration (computer type, kinds of disk(ette) drives, amount of memory and configuration (extended/expanded/conventional), TSR programs and device drivers used, OS version, etc.) It is helpful if you can use more than one scanning program to identify a virus, and to say which scanner gave which identification. However, some scanning programs leave "signatures" in memory which will confuse others, so it is best to do a "cold reboot" between runs of successive scanners, particularly if you are getting confusing results. F5) How often should we upgrade our anti-virus tools to minimize software and labor costs and maximize our protection? This is a difficult question to answer. Antiviral software is a kind of insurance, and these type of calculations are difficult. There are two things to watch out for here: the general "style" of the software, and the signatures which scanners use to identify viruses. Scanners should be updated more frequently than other software, and it is probably a good idea to update your set of signatures at least once every two months. Some antiviral software looks for changes to programs or specific types of viral "activity," and these programs generally claim to be good for "all current and future viral programs." However, even these programs cannot guarantee to protect against all future viruses, and should probably be upgraded once per year. Of course, not every anti-virus product is effective against all viruses, even if upgraded regularly. Thus, do *not* depend on the fact that you have upgraded your product recently as a guarantee that your system is free of viruses! ===================================================================== = Section G. Specific Virus and Anti-viral software Questions... = ===================================================================== G1) I was infected by the Jerusalem virus and disinfected the infected files with my favorite anti-virus program. However, Wordperfect and some other programs still refuse to work. Why? The Jerusalem virus and WordPerfect 4.2 program combination is an example of a virus and program that cannot be completely disinfected by an anti-virus tool. In some cases such as this one, the virus will destroy code by overwriting it instead of appending itself to the file. The only solution is to re-install the programs from clean (non-infected) backups or distribution media. (See question D10.) G2) I was told that the Stoned virus displays the text "Your PC is now Stoned" at boot time. I have been infected by this virus several times, but have never seen the message. Why? The "original" Stoned message was ".Your PC is now Stoned!", where the "." represents the "bell" character (ASCII 7 or "PC speaker beep"). The message is displayed with a probability of 1 in 8 only when a PC is booted from an infected diskette. When booting from an infected hard disk, Stoned never displays this message. Recently, versions of Stoned with no message whatsoever or only the leading bell character have become very common. These versions of Stoned are likely to go unnoticed by all but the most observant, even when regularly booting from infected diskettes. Contrary to some reports, the Stoned virus -does NOT- display the message "LEGALISE MARIJUANA", although such a string is quite clearly visible in the boot sectors of diskettes infected with the "original" version of Stoned in "standard" PC's. G3) I was infected by both Stoned and Michelangelo. Why has my computer became unbootable? And why, each time I run my favorite scanner, does it find one of the viruses and say that it is removed, but when I run it again, it says that the virus is still there? These two viruses store the original Master Boot Record at one and the same place on the hard disk. They do not recognize each other, and therefore a computer can become infected with both of them at the same time. The first of these viruses that infects the computer will overwrite the Master Boot Record with its body and store the original MBR at a certain place on the disk. So far, this is normal for a boot-record virus. But if now the other virus infects the computer too, it will replace the MBR (which now contains the virus that has come first) with its own body, and store what it believes is the original MBR (but in fact is the body of the first virus) AT THE SAME PLACE on the hard disk, thus OVERWRITING the original MBR. When this happens, the contents of the original MBR are lost. Therefore the disk becomes non-bootable. When a virus removal program inspects such a hard disk, it will see the SECOND virus in the MBR and will try to remove it by overwriting it with the contents of the sector where this virus normally stores the original MBR. However, now this sector contains the body of the FIRST virus. Therefore, the virus removal program will install the first virus in trying to remove the second. In all probability it will not wipe out the sector where the (infected) MBR has been stored. When the program is run again, it will find the FIRST virus in the MBR. By trying to remove it, the program will get the contents of the sector where this virus normally stores the original MBR, and will move it over the current (infected) MBR. Unfortunately, this sector still contains the body of the FIRST virus. Therefore, the body of this virus will be re-installed over the MBR ad infinitum. There is no easy solution to this problem, since the contents of the original MBR is lost. The only solution for the anti-virus program is to detect that there is a problem, and to overwrite the contents of the MBR with a valid MBR program, which the anti-virus program will have to carry with itself. If your favorite anti-virus program is not that smart, consider replacing it with a better one, or just boot from a write-protected uninfected DOS 5.0 diskette, and execute the program FDISK with the option /MBR. This will re-create the executable code in the MBR without modifying the partition table data. In general, infection by multiple viruses of the same file or area is possible and vital areas of the original may be lost. This can make it difficult or impossible for virus disinfection tools to be effective, and replacement of the lost file/area will be necessary. ==================== [End of VIRUS-L/comp.virus FAQ]