Antivirus software

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Antivirus software consists of computer programs that attempt to identify, thwart and eliminate computer viruses and other malicious software (malware).

Antivirus software typically uses two different techniques to accomplish this:

• Examining (scanning) files to look for known viruses matching definitions in a virus dictionary
• Identifying suspicious behavior from any computer program which might indicate infection. Such analysis may include data captures, port monitoring and other methods.

Most commercial antivirus software uses both of these approaches, with an emphasis on the virus dictionary approach.

Historically, the term antivirus has also been used for benign computer viruses that spread and combated malicious viruses. This was common on the Amiga computer platform.^{[citation needed]}

Contents 1 Approaches 1.1 Dictionary 1.2 Suspicious behavior 1.3 Other approaches 2 Issues of concern 3 History 4 See also 5 Notes 6 External links

[edit] Approaches

[edit] Dictionary

In the virus dictionary approach, when the antivirus software looks at a file, it refers to a dictionary of known viruses that the authors of the antivirus software have identified. If a piece of code in the file matches any virus identified in the dictionary, then the antivirus software can take one of the following actions:

1. attempt to repair the file by removing the virus itself from the file
2. quarantine the file (such that the file remains inaccessible to other programs and its virus can no longer spread)
3. delete the infected file

To achieve consistent success in the medium and long term, the virus dictionary approach requires periodic (generally online) downloads of updated virus dictionary entries. As civically minded and technically inclined users identify new viruses "in the wild", they can send their infected files to the authors of antivirus software, who then include information about the new viruses in their dictionaries.

Dictionary-based antivirus software typically examines files when the computer's operating system creates, opens, closes or e-mails them. In this way it can detect a known virus immediately upon receipt. Note too that a System Administrator can typically schedule the antivirus software to examine (scan) all files on the computer's hard disk on a regular basis.

Although the dictionary approach can effectively contain virus outbreaks in the right circumstances, virus authors have tried to stay a step ahead of such software by writing "oligomorphic", "polymorphic" and more recently "metamorphic" viruses, which encrypt parts of themselves or otherwise modify themselves as a method of disguise, so as to not match the virus's signature in the dictionary.

[edit] Suspicious behavior

The suspicious behavior approach, by contrast, doesn't attempt to identify known viruses, but instead monitors the behavior of all programs. If one program tries to write data to an executable program, for example, the antivirus software can flag this suspicious behavior, alert a user and ask what to do.

Unlike the dictionary approach, the suspicious behavior approach therefore provides protection against brand-new viruses that do not yet exist in any virus dictionaries. However, it can also sound a large number of false positives, and users probably become desensitized to all the warnings. If the user clicks "Accept" on every such warning, then the antivirus software obviously gives no benefit to that user. This problem has worsened since 1997, since many more nonmalicious program designs came to modify other .exe files without regard to this false positive issue. Thus, most modern antivirus software uses this technique less and less.

[edit] Other approaches

Some antivirus-software uses of other types of heuristic analysis. For example, it could try to emulate the beginning of the code of each new executable that the system invokes before transferring control to that executable. If the program seems to use self-modifying code or otherwise appears as a virus (if it immediately tries to find other executables, for example), one could assume that a virus has infected the executable. However, this method could result in a lot of false positives.

Yet another detection method involves using a sandbox. A sandbox emulates the operating system and runs the executable in this simulation. After the program has terminated, software analyzes the sandbox for any changes which might indicate a virus. Because of performance issues, this type of detection normally only takes place during on-demand scans. Also this method may fail as virus can be nondeterministic and result in different actions or no actions at all done when run - so it will be impossible to detect it from one run. ^[1]

Some virus scanners can also warn a user if a file is likely to contain a virus based on the file type.

An emerging technique to deal with malware in general is whitelisting. Rather than looking for only known bad software, this technique prevents execution of all computer code except that which has been previously identified as trustworthy by the system administrator. By following this default deny approach, the limitations inherent in keeping virus signatures up to date are avoided. Additionally, computer applications that are unwanted by the system administrator are prevented from executing since they are not on the whitelist. Since modern enterprise organizations have large quantities of trusted applications, the limitations of adopting this technique rest with the system administrators' ability to properly inventory and maintain the whitelist of trusted applications. As such, viable implementations of this technique include tools for automating the inventory and whitelist maintenance processes.

[edit] Issues of concern

• The spread of viruses using e-mail as their infection vector could be inhibited far more inexpensively and effectively, without the need to install additional antivirus software; if bugs in e-mail clients, which allow the unauthorized execution of code, were fixed.^{[citation needed]}
• User education can effectively supplement antivirus software. Simply training users in safe computing practices (such as not downloading and executing unknown programs from the Internet) would slow the spread of viruses and obviate the need of much antivirus software.^{[citation needed]}
• The ongoing writing and spreading of viruses and of panic about them gives the vendors of commercial antivirus software a financial interest in the ongoing existence of viruses. Some theorize that antivirus companies have financial ties to virus writers, to generate their own market, though there is currently no evidence for this.^[2]
• Some antivirus software can considerably reduce performance. Users may disable the antivirus protection to overcome the performance loss, thus increasing the risk of infection. For maximum protection the antivirus software needs to be enabled all the time — often at the cost of slower performance (see also software bloat).
• It is sometimes necessary to temporarily disable virus protection when installing major updates such as Windows Service Packs or updating graphics card drivers. Having antivirus protection running at the same time as installing a major update may prevent the update installing properly or at all.
• When purchasing antivirus software, the agreement may include a clause that your subscription will be automatically renewed, and your credit card automatically billed at the renewal time without your approval. For example, McAfee requires one to unsubscribe at least 60 days before the expiration of the present subscription, yet it does not provide phone access nor a way to unsubscribe directly through their website. In that case, the subscriber's recourse is to contest the charges with the credit card issuer.^{[citation needed]}
• Antivirus software is one of most common source of computer problems. There is a strong trend that antivirus software often delivers more pain than value to end users.

[edit] History

• See Also Timeline of notable computer viruses and worms

There are competing claims for the innovator of the first antivirus product. Perhaps the first publicly known neutralization of a wild PC virus was performed by European Bernt Fix (also Bernd) in early 1987. Fix neutralized an infection of the Vienna virus.^[3] Following Vienna a number of highly successful viruses appeared including Ping Pong, Lehigh, and Suriv-3 aka Jerusalem.

In January 1988, researchers in the Hebrew University developed "unvirus" and "immune", which tell users whether their disks have been infected and applies an antidote to those that have. ^[4]

From 1988 onwards many companies formed with a focus on the new field of antivirus technology. One of the first breakthroughs in antivirus technology occurred in March 1988 with the release of the Den Zuk viruses created by Denny Yanuar Ramdhani of Indonesia. Den Zuk neutralized the Brain virus. April 1988 saw the Virus-L forum on Usenet created, and mid 1988 saw the development by Peter Tippett of a heuristic scanner capable of detecting viruses and Trojans which was given a small public release.^[5][6] Fall 1988 also saw antivirus software Dr. Solomon's Anti-Virus Toolkit released by Briton Alan Solomon. By December 1990 the market had matured to the point of nineteen separate antivirus products being on sale including Norton AntiVirus and ViruScan from McAfee.

Tippett made a number of contributions to the budding field of virus detection. He was an emergency room doctor who also ran a computer software company. He had read an article about the Lehigh virus were the first viruses to be developed, but it was Lehigh that Tippett read about and he questioned whether they would have similar characteristics to viruses that attack humans. From an epidemiological viewpoint, he was able to determine how these viruses were affecting systems within the computer (the boot-sector was affected by the Brain virus, the .com files were affected by the Lehigh virus, and both .com and .exe files were affected by the Jerusalem virus). Tippett’s company Certus International Corp. then began to create anti-virus software programs. The company was sold in 1992 to Symantec Corp, and Tippett went to work for them, incorporating the software he had developed into Symantec’s product, Norton AntiVirus.

[edit] See also

• Computer insecurity
• List of antivirus software
• List of computer viruses
• List of trojan horses
• List of computer virus hoaxes
• List of Linux computer viruses
• Timeline of notable computer viruses and worms
• Virus hoax
• Virus statistics

[edit] Notes

1. ^ Raynal, Frederic (2006-05-16). Malicious cryptography, part two.
2. ^ Why there is no global antivirus software conspiracy, by Jonathan Yarden
3. ^ Kaspersky Lab Virus list
4. ^ Hebrew University computers sabotaged by electronic "virus"
5. ^ IBM anti-virus research timeline
6. ^ It has been claimed that Israeli Yuval Rechavi also created an antivirus product around this time,[1] with this product being marketed as "V-Analyst" from 1989 onwards. However V-Analyst did not begin to be marketed until 1990, placing it after the release of IBM's first antivirus product in 1989 which they had begun developing in 1988.IBM anti-virus research timeline

[edit] External links

• Carnegie Mellon's CERT coordination center
• EICAR — European Institute for Computer Anti-Virus Research
• The History of Computer Viruses — A Timeline
• Computer Viruses at the Open Directory Project (suggest site)