Assignment
Computer Security:
Principles and Practice
Fourth Edition
By: William Stallings and Lawrie Brown
Lecture slides prepared for “Computer Security: Principles and Practice”, 4/e, by William Stallings and Lawrie Brown, Chapter 6 “Malicious Software”.
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Chapter 6
Malicious Software
This chapter examines the wide spectrum of malware threats and countermeasures.
We begin with a survey of various types of malware, and offer a broad
classification based first on the means malware uses to spread or propagate, and
then on the variety of actions or payloads used once the malware has reached a
target. Propagation mechanisms include those used by viruses, worms, and Trojans.
Payloads include system corruption, bots, phishing, spyware, and rootkits. The
discussion concludes with a review of countermeasure approaches.
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Malware
NIST 800-83 defines malware as:
“a program that is inserted into a system, usually covertly, with the intent of compromising the confidentiality, integrity, or availability of the victim’s data, applications, or operating system or otherwise annoying or disrupting the victim.”
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Malicious software, or malware, arguably constitutes one of the most significant categories
of threats to computer systems. NIST SP 800-83 (Guide to Malware Incident Prevention and
Handling for Desktops and Laptops, July 2013) defines malware as “a program that
is inserted into a system, usually covertly, with the intent of compromising the confidentiality,
integrity, or availability of the victim’s data, applications, or operating
system or otherwise annoying or disrupting the victim.” Hence, we are concerned
with the threat malware poses to application programs, to utility programs, such as
editors and compilers, and to kernel-level programs. We are also concerned with
its use on compromised or malicious Web sites and servers, or in especially crafted
spam e-mails or other messages, which aim to trick users into revealing sensitive
personal information.
Malware Terminology
Table 6.1
(Table can be found on page 185 in the textbook.)
The terminology in this area presents problems because of a lack of universal agreement
on all of the terms and because some of the categories overlap. Table 6.1 is a
useful guide to some of the terms in use.
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Classification of Malware
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A number of authors attempt to classify malware, as shown in the survey and proposal
of [HANS04]. Although a range of aspects can be used, one useful approach
classifies malware into two broad categories, based first on how it spreads or propagates
to reach the desired targets; and then on the actions or payloads it performs
once a target is reached.
Earlier approaches to malware classification distinguished between those that
need a host program, being parasitic code such as viruses, and those that are independent,
self-contained programs run on the system such as worms, trojans, and
bots. Another distinction used was between malware that does not replicate, such as
trojans and spam e-mail, and malware that does, including viruses and worms.
Classified into two broad categories:
Based first on how it spreads or propagates to reach the desired targets
Then on the actions or payloads it performs once a target is reached
Also classified by:
Those that need a host program (parasitic code such as viruses)
Those that are independent, self-contained programs (worms, trojans, and bots)
Malware that does not replicate (trojans and spam e-mail)
Malware that does replicate (viruses and worms)
Types of Malicious Software (Malware)
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Propagation mechanisms include infection of existing executable or interpreted
content by viruses that is subsequently spread to other systems; exploit of software
vulnerabilities either locally or over a network by worms or drive-by-downloads to
allow the malware to replicate; and social engineering attacks that convince users to
bypass security mechanisms to install Trojans, or to respond to phishing attacks.
Payload actions performed by malware once it reaches a target system can
include corruption of system or data files; theft of service in order to make the
system a zombie agent of attack as part of a botnet; theft of information from the
system, especially of logins, passwords, or other personal details by keylogging or
spyware programs; and stealthing where the malware hides its presence on the
system from attempts to detect and block it.
While early malware tended to use a single means of propagation to deliver
a single payload, as it evolved, we see a growth of blended malware that incorporates
a range of both propagation mechanisms and payloads that increase its ability
to spread, hide, and perform a range of actions on targets. A blended attack uses
multiple methods of infection or propagation, to maximize the speed of contagion
and the severity of the attack. Some malware even support an update mechanism
that allows it to change the range of propagation and payload mechanisms utilized
once it is deployed.
In the following sections, we survey these various categories of malware, and
then follow with a discussion of appropriate countermeasures.
Propagation mechanisms include:
Infection of existing content by viruses that is subsequently spread to other systems
Exploit of software vulnerabilities by worms or drive-by-downloads to allow the malware to replicate
Social engineering attacks that convince users to bypass security mechanisms to install Trojans or to respond to phishing attacks
Payload actions performed by malware once it reaches a target system can include:
Corruption of system or data files
Theft of service/make the system a zombie agent of attack as part of a botnet
Theft of information from the system/keylogging
Stealthing/hiding its presence on the system
Attack Kits
Initially the development and deployment of malware required considerable technical skill by software authors
The development of virus-creation toolkits in the early 1990s and then more general attack kits in the 2000s greatly assisted in the development and deployment of malware
Toolkits are often known as “crimeware”
Include a variety of propagation mechanisms and payload modules that even novices can deploy
Variants that can be generated by attackers using these toolkits creates a significant problem for those defending systems against them
Examples are:
Zeus
Angler
Initially, the development and deployment of malware required considerable technical
skill by software authors. This changed with the development of virus-
creation toolkits in the early 1990s, and then later of more general attack kits in the 2000s,
that greatly assisted in the development and deployment of malware [FOSS10].
These toolkits, often known as crimeware, now include a variety of propagation
mechanisms and payload modules that even novices can combine, select, and
deploy. They can also easily be customized with the latest discovered vulnerabilities
in order to exploit the window of opportunity between the publication
of a weakness and the widespread deployment of patches to close it. These kits
greatly enlarged the population of attackers able to deploy malware. Although the
malware created with such toolkits tends to be less sophisticated than that designed
from scratch, the sheer number of new variants that can be generated by attackers
using these toolkits creates a significant problem for those defending systems
against them.
The Zeus crimeware toolkit is a prominent example of such an attack kit, which was
used to generate a wide range of very effective, stealthed malware that facilitates a range
of criminal activities, in particular capturing and exploiting banking credentials [BINS10].
The Angler exploit kit, first seen in 2013, was the most active kit seen in 2015, often
distributed via malvertising that exploited Flash vulnerabilities. It is sophisticated and
technically advanced, in both attacks executed and counter-measures deployed to resist
detection. There are a number of other attack kits in active use, though the specific kits
change from year to year as attackers continue to evolve and improve them [SYMA16].
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Attack Sources
Another significant malware development is the change from attackers being individuals often motivated to demonstrate their technical competence to their peers to more organized and dangerous attack sources such as:
This has significantly changed the resources available and motivation behind the rise of malware and has led to development of a large underground economy involving the sale of attack kits, access to compromised hosts, and to stolen information
Another significant malware development over the last couple of decades is the
change from attackers being individuals, often motivated to demonstrate their
technical competence to their peers, to more organized and dangerous attack
sources. These include politically motivated attackers, criminals, and organized
crime; organizations that sell their services to companies and nations, and national
government agencies, as we discuss in Section 8.1. This has significantly changed the
resources available and motivation behind the rise of malware, and indeed has led
to development of a large underground economy involving the sale of attack kits,
access to compromised hosts, and to stolen information.
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Politically motivated attackers
Criminals
Organized crime
Organizations that sell their services to companies and nations
National government agencies
Advanced Persistent Threats (APTs)
Well-resourced, persistent application of a wide variety of intrusion technologies and malware to selected targets (usually business or political)
Typically attributed to state-sponsored organizations and criminal enterprises
Differ from other types of attack by their careful target selection and stealthy intrusion efforts over extended periods
High profile attacks include Aurora, RSA, APT1, and Stuxnet
Advanced Persistent Threats (APTs) have risen to prominence in recent years.
These are not a new type of malware, but rather the well-resourced, persistent
application of a wide variety of intrusion technologies and malware to selected targets,
usually business or political. APTs are typically attributed to state-sponsored
organizations, with some attacks likely from criminal enterprises as well. We discuss
these categories of intruders further in Section 8.1.
APTs differ from other types of attack by their careful target selection, and
persistent, often stealthy, intrusion efforts over extended periods. A number of
high profile attacks, including Aurora, RSA, APT1, and Stuxnet, are often cited as
examples.
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APT Characteristics
They are named as a result of these characteristics:
• Advanced: Use by the attackers of a wide variety of intrusion technologies
and malware, including the development of custom malware if required. The
individual components may not necessarily be technically advanced, but are
carefully selected to suit the chosen target.
• Persistent: Determined application of the attacks over an extended period
against the chosen target in order to maximize the chance of success. A variety
of attacks may be progressively, and often stealthily, applied until the target is
compromised.
• Threats: Threats to the selected targets as a result of the organized, capable,
and well-funded attackers intent to compromise the specifically chosen targets.
The active involvement of people in the process greatly raises the threat
level from that due to automated attacks tools, and also the likelihood of
successful attack.
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Advanced
Used by the attackers of a wide variety of intrusion technologies and malware including the development of custom malware if required
The individual components may not necessarily be technically advanced but are carefully selected to suit the chosen target
Persistent
Determined application of the attacks over an extended period against the chosen target in order to maximize the chance of success
A variety of attacks may be progressively applied until the target is compromised
Threats
Threats to the selected targets as a result of the organized, capable, and well-funded attackers intent to compromise the specifically chosen targets
The active involvement of people in the process greatly raises the threat level from that due to automated attacks tools, and also the likelihood of successful attacks
APT Attacks
Aim:
Varies from theft of intellectual property or security and infrastructure related data to the physical disruption of infrastructure
Techniques used:
Social engineering
Spear-phishing email
Drive-by-downloads from selected compromised websites likely to be visited by personnel in the target organization
Intent:
To infect the target with sophisticated malware with multiple propagation mechanisms and payloads
Once they have gained initial access to systems in the target organization a further range of attack tools are used to maintain and extend their access
The aim of these attacks varies from theft of intellectual property or security
and infrastructure related data to the physical disruption of infrastructure. Techniques
used include social engineering, spear-phishing emails, and drive-by-downloads
from selected compromised websites likely to be visited by personnel in the target
organization. The intent is to infect the target with sophisticated malware with multiple
propagation mechanisms and payloads. Once they have gained initial access to
systems in the target organization, a further range of attack tools are used to maintain
and extend their access.
As a result, these attacks are much harder to defend against due to this specific
targeting and persistence. It requires a combination of technical countermeasures,
such as we discuss later in this chapter, as well as awareness training to assist
personnel to resist such attacks, as we discuss in Chapter 17. Even with current best practice
countermeasures, the use of zero-day exploits and new attack approaches
means that some of these attacks are likely to succeed [SYMA16, MAND13]. Thus
multiple layers of defense are needed, with mechanisms to detect, respond and
mitigate such attacks. These may include monitoring for malware command and
control traffic, and detection of exfiltration traffic.
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Viruses
Piece of software that infects programs
Modifies them to include a copy of the virus
Replicates and goes on to infect other content
Easily spread through network environments
When attached to an executable program a virus can do anything that the program is permitted to do
Executes secretly when the host program is run
Specific to operating system and hardware
Takes advantage of their details and weaknesses
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The first category of malware propagation concerns parasitic software fragments that
attach themselves to some existing executable content. The fragment may be machine
code that infects some existing application, utility, or system program, or even the
code used to boot a computer system. Computer virus infections formed the majority
of malware seen in the early personal computer era. The term “computer virus”
is still often used to refer to malware in general, rather than just computer viruses
specifically. More recently, the virus software fragment has been some form of scripting
code, typically used to support active content within data files such as Microsoft
Word documents, Excel spreadsheets, or Adobe PDF documents.
A computer virus is a piece of software that can “infect” other programs, or indeed any
type of executable content, by modifying them. The modification includes injecting
the original code with a routine to make copies of the virus code, which can then go
on to infect other content. Computer viruses first appeared in the early 1980s, and the
term itself is attributed to Fred Cohen. Cohen is the author of a groundbreaking book
on the subject [COHE94]. The Brain virus, first seen in 1986, was one of the first to
target MSDOS systems, and resulted in a significant number of infections for this time.
Biological viruses are tiny scraps of genetic code—DNA or RNA—that
can take over the machinery of a living cell and trick it into making thousands of
flawless replicas of the original virus. Like its biological counterpart, a computer
virus carries in its instructional code the recipe for making perfect copies of itself.
The typical virus becomes embedded in a program, or carrier of executable content,
on a computer. Then, whenever the infected computer comes into contact with an
uninfected piece of code, a fresh copy of the virus passes into the new location.
Thus, the infection can spread from computer to computer, aided by unsuspecting
users, who exchange these programs or carrier files on disk or USB stick; or who
send them to one another over a network. In a network environment, the ability to
access documents, applications, and system services on other computers provides a
perfect culture for the spread of such viral code.
A virus that attaches to an executable program can do anything that the
program is permitted to do. It executes secretly when the host program is run. Once
the virus code is executing, it can perform any function, such as erasing files and
programs, that is allowed by the privileges of the current user. One reason viruses
dominated the malware scene in earlier years was the lack of user authentication
and access controls on personal computer systems at that time. This enabled a virus
to infect any executable content on the system. The significant quantity of programs
shared on floppy disk also enabled its easy, if somewhat slow, spread. The inclusion
of tighter access controls on modern operating systems significantly hinders the
ease of infection of such traditional, machine executable code, viruses. This resulted
in the development of macro viruses that exploit the active content supported
by some documents types, such as Microsoft Word or Excel files, or Adobe PDF
documents. Such documents are easily modified and shared by users as part of their
normal system use, and are not protected by the same access controls as programs.
Currently, a viral mode of infection is typically one of several propagation mechanisms
used by contemporary malware, which may also include worm and Trojan
capabilities.
Virus Components
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[AYCO06] states that a computer virus has three parts. More generally, many
contemporary types of malware also include one or more variants of each of these
components:
• Infection mechanism : The means by which a virus spreads or propagates,
enabling it to replicate. The mechanism is also referred to as the infection
vector.
• Trigger: The event or condition that determines when the payload is activated
or delivered, sometimes known as a logic bomb.
• Payload: What the virus does, besides spreading. The payload may involve
damage or may involve benign but noticeable activity.
Infection mechanism
Means by which a virus spreads or propagates
Also referred to as the infection vector
Trigger
Event or condition that determines when the payload is activated or delivered
Sometimes known as a logic bomb
Payload
What the virus does (besides spreading)
May involve damage or benign but noticeable activity
Virus Phases
During its lifetime, a typical virus goes through the following four phases:
• Dormant phase: The virus is idle. The virus will eventually be activated by
some event, such as a date, the presence of another program or file, or the
capacity of the disk exceeding some limit. Not all viruses have this stage.
• Propagation phase: The virus places a copy of itself into other programs or
into certain system areas on the disk. The copy may not be identical to the
propagating version; viruses often morph to evade detection. Each infected
program will now contain a clone of the virus, which will itself enter a propagation
phase.
• Triggering phase: The virus is activated to perform the function for which it
was intended. As with the dormant phase, the triggering phase can be caused
by a variety of system events, including a count of the number of times that
this copy of the virus has made copies of itself.
• Execution phase: The function is performed. The function may be harmless,
such as a message on the screen, or damaging, such as the destruction of
programs and data files.
Most viruses that infect executable program files carry out their work in a
manner that is specific to a particular operating system and, in some cases, specific
to a particular hardware platform. Thus, they are designed to take advantage of the
details and weaknesses of particular systems. Macro viruses though, target specific
document types, which are often supported on a variety of systems.
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Dormant phase
Triggering phase
Propagation phase
Execution phase
Virus is idle
Will eventually be activated by some event
Not all viruses have this stage
Virus is activated to perform the function for which it was intended
Can be caused by a variety of system events
Virus places a copy of itself into other programs or into certain system areas on the disk
May not be identical to the propagating version
Each infected program will now contain a clone of the virus which will itself enter a propagation phase
Function is performed
May be harmless or damaging
Macro and Scripting Viruses
NISTIR 7298 defines a macro virus as:
“a virus that attaches itself to documents and uses the macro programming capabilities of the document’s application to execute and propagate”
Macro viruses infect scripting code used to support active content in a variety of user document types
Are threatening for a number of reasons:
Is platform independent
Infect documents, not executable portions of code
Are easily spread
Because they infect user documents rather than system programs, traditional file system access controls are of limited use in preventing their spread, since users are expected to modify them
Are much easier to write or to modify than traditional executable viruses
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In the mid-1990s, macro or scripting code viruses became by far the most prevalent
type of virus. NISTIR 7298 (Glossary of Key Information Security Terms, May 2013)
defines a macro virus as a virus that attaches itself to documents and uses the macro
programming capabilities of the document’s application to execute and propagate.
Macro viruses infect scripting code used to support active content in a variety of user
document types. Macro viruses are particularly threatening for a number of reasons:
1. A macro virus is platform independent. Many macro viruses infect active
content in commonly used applications, such as macros in Microsoft Word
documents or other Microsoft Office documents, or scripting code in Adobe
PDF documents. Any hardware platform and operating system that supports
these applications can be infected.
2. Macro viruses infect documents, not executable portions of code. Most of the
information introduced onto a computer system is in the form of documents
rather than programs.
3. Macro viruses are easily spread, as the documents they exploit are shared in
normal use. A very common method is by electronic mail, particularly since these
documents can sometimes be opened automatically without prompting the user.
4. Because macro viruses infect user documents rather than system programs,
traditional file system access controls are of limited use in preventing their
spread, since users are expected to modify them.
5. Macro viruses are much easier to write or to modify than traditional executable
viruses.
Macro viruses take advantage of support for active content using a scripting or
macro language, embedded in a word processing document or other type of file.
Typically, users employ macros to automate repetitive tasks and thereby save keystrokes.
They are also used to support dynamic content, form validation, and other
useful tasks associated with these documents.
Microsoft Word and Excel documents are common targets due to their widespread
use. Successive releases of MS Office products provide increased protection
against macro viruses. For example, Microsoft offers an optional Macro Virus Protection
tool that detects suspicious Word files and alerts the customer to the potential
risk of opening a file with macros. Office 2000 improved macro security by allowing
macros to be digitally signed by their author, and for authors to be listed as trusted.
Users were then warned if a document being opened contained unsigned, or signed
but untrusted, macros, and were advised to disable macros in this case. Various antivirus
product vendors have also developed tools to detect and remove macro viruses.
As in other types of malware, the arms race continues in the field of macro viruses,
but they no longer are the predominant malware threat.
Another possible host for macro virus–style malware is in Adobe’s PDF documents.
These can support a range of embedded components, including Javascript
and other types of scripting code. Although recent PDF viewers include measures to
warn users when such code is run, the message the user is shown can be manipulated
to trick them into permitting its execution. If this occurs, the code could potentially
act as a virus to infect other PDF documents the user can access on their system.
Alternatively, it can install a Trojan, or act as a worm, as we discuss later [STEV11].
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Although macro languages may have a similar syntax,
the details depend on the application interpreting the macro, and so will always target
documents for a specific application. For example, a Microsoft Word macro, including
a macro virus, will be different to an Excel macro. Macros can either be saved with
a document, or be saved in a global template or worksheet. Some macros are run
automatically when certain actions occur. In Microsoft Word, for example, macros
can run when Word starts, a document is opened, a new document is created, or when
a document is closed. Macros can perform a wide range of operations, not just only
on the document content, but can read and write files, and call other applications.
As an example of the operation of a macro virus, pseudo-code for the Melissa
macro virus is shown in Figure 6.1. This was a component of the Melissa e-mail worm
that we will describe further in the next section. This code would be introduced onto a
system by opening an infected Word document, most likely sent by e-mail. This macro
code is contained in the Document_Open macro, which is automatically run when
the document is opened. It first disables the Macro menu and some related security
features, making it harder for the user stop or remove its operation. Next it checks to
see if it is being run from an infected document, and if so copies itself into the global
template file. This file is opened with every subsequent document, and the macro virus
run, infecting that document. It then checks to see if it has been run on this system
before, by looking to see if a specific key “Melissa” has been added to the registry. If
that key is absent, and Outlook is the e-mail client, the macro virus then sends a copy
of the current, infected document to each of the first 50 addresses in the current user’s
Address Book. It then creates the “Melissa” registry entry, so this is only done once on
any system. Finally it checks the current time and date for a specific trigger condition,
which if met results in a Simpson quote being inserted into the current document.
Once the macro virus code has finished, the document continues opening and the user
can then edit as normal. This code illustrates how a macro virus can manipulate both
the document contents, and access other applications on the system. It also shows two
infection mechanisms, the first infecting every subsequent document opened on the
system, the second sending infected documents to other users via e-mail.
More sophisticated macro virus code can use stealth techniques such as encryption
or polymorphism, changing its appearance each time, to avoid scanning detection.
Virus Classifications
Classification by target
Classification by concealment strategy
Boot sector infector
Infects a master boot record or boot record and spreads when a system is booted from the disk containing the virus
File infector
Infects files that the operating system or shell considers to be executable
Macro virus
Infects files with macro or scripting code that is interpreted by an application
Multipartite virus
Infects files in multiple ways
Encrypted virus
A portion of the virus creates a random encryption key and encrypts the remainder of the virus
Stealth virus
A form of virus explicitly designed to hide itself from detection by anti-virus software
Polymorphic virus
A virus that mutates with every infection
Metamorphic virus
A virus that mutates and rewrites itself completely at each iteration and may change behavior as well as appearance
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There has been a continuous arms race between virus writers and writers of
anti- virus software since viruses first appeared. As effective countermeasures are
developed for existing types of viruses, newer types are developed. There is no
simple or universally agreed upon classification scheme for viruses. In this section,
we follow [AYCO06] and classify viruses along two orthogonal axes: the type of
target the virus tries to infect and the method the virus uses to conceal itself from
detection by users and anti-virus software.
A virus classification by target includes the following categories:
• Boot sector infector: Infects a master boot record or boot record and spreads
when a system is booted from the disk containing the virus.
• File infector: Infects files that the operating system or shell consider to be
executable.
• Macro virus: Infects files with macro or scripting code that is interpreted by an
application.
• Multipartite virus: Infects files in multiple ways. Typically, the multipartite
virus is capable of infecting multiple types of files, so that virus eradication
must deal with all of the possible sites of infection.
A virus classification by concealment strategy includes the following categories:
• Encrypted virus: A form of virus that uses encryption to obscure it’s content.
A portion of the virus creates a random encryption key and encrypts
the remainder of the virus. The key is stored with the virus. When an infected
program is invoked, the virus uses the stored random key to decrypt the virus.
When the virus replicates, a different random key is selected. Because the bulk
of the virus is encrypted with a different key for each instance, there is no constant
bit pattern to observe.
• Stealth virus : A form of virus explicitly designed to hide itself from detection
by anti-virus software. Thus, the entire virus, not just a payload is hidden. It
may use code mutation, compression, or rootkit techniques to achieve this.
• Polymorphic virus: A form of virus that creates copies during replication that
are functionally equivalent but have distinctly different bit patterns, in order
to defeat programs that scan for viruses. In this case, the “signature” of the
virus will vary with each copy. To achieve this variation, the virus may randomly
insert superfluous instructions or interchange the order of independent
instructions. A more effective approach is to use encryption. The strategy of
the encryption virus is followed. The portion of the virus that is responsible
for generating keys and performing encryption/decryption is referred to as the
mutation engine . The mutation engine itself is altered with each use.
• Metamorphic virus: As with a polymorphic virus, a metamorphic virus mutates
with every infection. The difference is that a metamorphic virus rewrites
itself completely at each iteration, using multiple transformation techniques, increasing
the difficulty of detection. Metamorphic viruses may change their behavior
as well as their appearance.
Worms
Program that actively seeks out more machines to infect and each infected machine serves as an automated launching pad for attacks on other machines
Exploits software vulnerabilities in client or server programs
Can use network connections to spread from system to system
Spreads through shared media (USB drives, CD, DVD data disks)
E-mail worms spread in macro or script code included in attachments and instant messenger file transfers
Upon activation the worm may replicate and propagate again
Usually carries some form of payload
First known implementation was done in Xerox Palo Alto Labs in the early 1980s
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The next category of malware propagation concerns the exploit of software
vulnerabilities, such as those we discuss in Chapters 10 and 11 , which are commonly
exploited by computer worms. A worm is a program that actively seeks out
more machines to infect, and then each infected machine serves as an automated
launching pad for attacks on other machines. Worm programs exploit software
vulnerabilities in client or server programs to gain access to each new system. They
can use network connections to spread from system to system. They can also spread
through shared media, such as USB drives or CD and DVD data disks. E-mail
worms spread in macro or script code included in documents attached to e-mail or
to instant messenger file transfers. Upon activation, the worm may replicate and
propagate again. In addition to propagation, the worm usually carries some form of
payload, such as those we discuss later.
The concept of a computer worm was introduced in John Brunner’s 1975 SF
novel The Shockwave Rider . The first known worm implementation was done in
Xerox Palo Alto Labs in the early 1980s. It was nonmalicious, searching for idle
systems to use to run a computationally intensive task.
Worm Replication
To replicate itself, a worm uses some means to access remote systems. These
include the following, most of which are still seen in active use:
• Electronic mail or instant messenger facility: A worm e-mails a copy of itself to
other systems, or sends itself as an attachment via an of instant message service,
so that its code is run when the e-mail or attachment is received or viewed.
• File sharing: A worm either creates a copy of itself or infects other suitable
files as a virus on removable media such as a USB drive; it then executes when
the drive is connected to another system using the autorun mechanism by
exploiting some software vulnerability, or when a user opens the infected file
on the target system.
• Remote execution capability: A worm executes a copy of itself on another
system, either by using an explicit remote execution facility or by exploiting a
program flaw in a network service to subvert its operations (as we discuss in
Chapters 10 and 11 ).
• Remote file access or transfer capability: A worm uses a remote file access or
transfer service to another system to copy itself from one system to the other,
where users on that system may then execute it.
• Remote login capability: A worm logs onto a remote system as a user and
then uses commands to copy itself from one system to the other, where it then
executes.
The new copy of the worm program is then run on the remote system where, in
addition to any payload functions that it performs on that system, it continues to
propagate.
A worm typically uses the same phases as a computer virus: dormant, propagation,
triggering, and execution. The propagation phase generally performs the
following functions:
• Search for appropriate access mechanisms to other systems to infect by examining
host tables, address books, buddy lists, trusted peers, and other similar
repositories of remote system access details; by scanning possible target host
addresses; or by searching for suitable removable media devices to use.
• Use the access mechanisms found to transfer a copy of itself to the remote
system, and cause the copy to be run.
The worm may also attempt to determine whether a system has previously
been infected before copying itself to the system. In a multiprogramming system,
it can also disguise its presence by naming itself as a system process or using some
other name that may not be noticed by a system operator. More recent worms can
even inject their code into existing processes on the system, and run using additional
threads in that process, to further disguise their presence.
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Electronic mail or instant messenger facility
Worm e-mails a copy of itself to other systems
Sends itself as an attachment via an instant message service
File sharing
Creates a copy of itself or infects a file as a virus on removable media
Remote execution capability
Worm executes a copy of itself on another system
Remote file access or transfer capability
Worm uses a remote file access or transfer service to copy itself from one system to the other
Remote login capability
Worm logs onto a remote system as a user and then uses commands to copy itself from one system to the other
Target Discovery
Scanning (or fingerprinting)
First function in the propagation phase for a network worm
Searches for other systems to infect
Random
Each compromised host probes random addresses in the IP address space using a different seed
This produces a high volume of Internet traffic which may cause generalized disruption even before the actual attack is launched
Hit-list
The attacker first compiles a long list of potential vulnerable machines
Once the list is compiled the attacker begins infecting machines on the list
Each infected machine is provided with a portion of the list to scan
This results in a very short scanning period which may make it difficult to detect that infection is taking place
Topological
This method uses information contained on an infected victim machine to find more hosts to scan
Local subnet
If a host can be infected behind a firewall that host then looks for targets in its own local network
The host uses the subnet address structure to find other hosts that would otherwise be protected by the firewall
The first function in the propagation phase for a network worm is for it to search
for other systems to infect, a process known as scanning or fingerprinting. For
such worms, which exploit software vulnerabilities in remotely accessible network
services, it must identify potential systems running the vulnerable service, and then
infect them. Then, typically, the worm code now installed on the infected machines
repeats the same scanning process, until a large distributed network of infected
machines is created.
[MIRK04] lists the following types of network address scanning strategies that
such a worm can use:
• Random: Each compromised host probes random addresses in the IP address
space, using a different seed. This technique produces a high volume of Internet
traffic, which may cause generalized disruption even before the actual
attack is launched.
• Hit-List: The attacker first compiles a long list of potential vulnerable machines.
This can be a slow process done over a long period to avoid detection that
an attack is underway. Once the list is compiled, the attacker begins infecting
machines on the list. Each infected machine is provided with a portion of the
list to scan. This strategy results in a very short scanning period, which may
make it difficult to detect that infection is taking place.
• Topological: This method uses information contained on an infected victim
machine to find more hosts to scan.
• Local subnet: If a host can be infected behind a firewall, that host then looks
for targets in its own local network. The host uses the subnet address structure
to find other hosts that would otherwise be protected by the firewall.
20
21
A well-designed worm can spread rapidly and infect massive numbers of hosts. It is
useful to have a general model for the rate of worm propagation. Computer viruses
and worms exhibit similar self-replication and propagation behavior to biological
viruses. Thus we can look to classic epidemic models for understanding computer
virus and worm propagation behavior.
Figure 6.2 shows the dynamics of worm propagation using this model. Propagation
proceeds through three phases. In the initial phase, the number of hosts
increases exponentially. To see that this is so, consider a simplified case in which
a worm is launched from a single host and infects two nearby hosts. Each of these
hosts infects two more hosts, and so on. This results in exponential growth. After
a time, infecting hosts waste some time attacking already infected hosts, which
reduces the rate of infection. During this middle phase, growth is approximately linear,
but the rate of infection is rapid. When most vulnerable computers have been
infected, the attack enters a slow finish phase as the worm seeks out those remaining
hosts that are difficult to identify.
Clearly, the objective in countering a worm is to catch the worm in its slow
start phase, at a time when few hosts have been infected.
Zou, et al [ZOU05] describe a model for worm propagation based on an analysis
of network worm attacks at that time. The speed of propagation and the total
number of hosts infected depend on a number of factors, including the mode of
propagation, the vulnerability or vulnerabilities exploited, and the degree of similarity
to preceding attacks. For the latter factor, an attack that is a variation of a
recent previous attack may be countered more effectively than a more novel attack.
Zou’s model agrees closely with Figure 6.2.
Morris Worm
Earliest significant worm infection
Released by Robert Morris in 1988
Designed to spread on UNIX systems
Attempted to crack local password file to use login/password to logon to other systems
Exploited a bug in the finger protocol which reports the whereabouts of a remote user
Exploited a trapdoor in the debug option of the remote process that receives and sends mail
Successful attacks achieved communication with the operating system command interpreter
Sent interpreter a bootstrap program to copy worm over
22
Arguably, the earliest significant, and hence well-known, worm infection was
released onto the Internet by Robert Morris in 1988 [ORMA03]. The Morris
worm was designed to spread on UNIX systems and used a number of different
techniques for propagation. When a copy began execution, its first task was to discover
other hosts known to this host that would allow entry from this host. The
worm performed this task by examining a variety of lists and tables, including system
tables that declared which other machines were trusted by this host, users’ mail forwarding
files, tables by which users gave themselves permission for access to remote
accounts, and from a program that reported the status of network connections. For
each discovered host, the worm tried a number of methods for gaining access:
1. It attempted to log on to a remote host as a legitimate user. In this method, the
worm first attempted to crack the local password file and then used the discovered
passwords and corresponding user IDs. The assumption was that many users would
use the same password on different systems. To obtain the passwords, the worm
ran a password-cracking program that tried
a. Each user’s account name and simple permutations of it
b. A list of 432 built-in passwords that Morris thought to be likely candidates
c. All the words in the local system dictionary
2. It exploited a bug in the UNIX finger protocol, which reports the whereabouts
of a remote user.
3. It exploited a trapdoor in the debug option of the remote process that receives
and sends mail.
If any of these attacks succeeded, the worm achieved communication with the
operating system command interpreter. It then sent this interpreter a short bootstrap
program, issued a command to execute that program, and then logged off.
The bootstrap program then called back the parent program and downloaded the
remainder of the worm. The new worm was then executed.
Recent Worm Attacks
| Melissa | 1998 | E-mail worm First to include virus, worm and Trojan in one package |
| Code Red | July 2001 | Exploited Microsoft IIS bug Probes random IP addresses Consumes significant Internet capacity when active |
| Code Red II | August 2001 | Also targeted Microsoft IIS Installs a backdoor for access |
| Nimda | September 2001 | Had worm, virus and mobile code characteristics Spread using e-mail, Windows shares, Web servers, Web clients, backdoors |
| SQL Slammer | Early 2003 | Exploited a buffer overflow vulnerability in SQL server compact and spread rapidly |
| Sobig.F | Late 2003 | Exploited open proxy servers to turn infected machines into spam engines |
| Mydoom | 2004 | Mass-mailing e-mail worm Installed a backdoor in infected machines |
| Warezov | 2006 | Creates executables in system directories Sends itself as an e-mail attachment Can disable security related products |
| Conficker (Downadup) | November 2008 | Exploits a Windows buffer overflow vulnerability Most widespread infection since SQL Slammer |
| Stuxnet | 2010 | Restricted rate of spread to reduce chance of detection Targeted industrial control systems |
23
The Melissa e-mail worm that appeared in 1998 was the first of a new generation of
malware that included aspects of virus, worm, and Trojan in one package [CASS01].
Melissa made use of a Microsoft Word macro embedded in an attachment. If the
recipient opens the e-mail attachment, the Word macro is activated. Then it
1. Sends itself to everyone on the mailing list in the user’s e-mail package, propagating
as a worm; and
2. Does local damage on the user’s system, including disabling some security
tools, and also copying itself into other documents, propagating as a
virus; and
3. If a trigger time was seen, it displayed a Simpson quote as its payload.
In 1999, a more powerful version of this e-mail virus appeared. This version
could be activated merely by opening an e-mail that contains the virus, rather
than by opening an attachment. The virus uses the Visual Basic scripting language
supported by the e-mail package.
Melissa propagates itself as soon as it is activated (either by opening an e-mail
attachment or by opening the e-mail) to all of the e-mail addresses known to the
infected host. As a result, whereas viruses used to take months or years to propagate,
this next generation of malware could do so in hours. [CASS01] notes that it
took only three days for Melissa to infect over 100,000 computers, compared to the
months it took the Brain virus to infect a few thousand computers a decade before.
This makes it very difficult for anti-virus software to respond to new attacks before
much damage is done.
The Code Red worm first appeared in July 2001. Code Red exploits a security
hole in the Microsoft Internet Information Server (IIS) to penetrate and spread.
It also disables the system file checker in Windows. The worm probes random IP
addresses to spread to other hosts. During a certain period of time, it only spreads.
It then initiates a denial-of-service attack against a government Web site by flooding
the site with packets from numerous hosts. The worm then suspends activities
and reactivates periodically. In the second wave of attack, Code Red infected nearly
360,000 servers in 14 hours. In addition to the havoc it caused at the targeted server,
Code Red consumed enormous amounts of Internet capacity, disrupting service
[MOOR02].
Code Red II is another, distinct, variant that first appeared in August 2001,
and also targeted Microsoft IIS. It tried to infect systems on the same subnet as the
infected system. Also, this newer worm installs a backdoor, allowing a hacker to
remotely execute commands on victim computers.
The Nimda worm that appeared in September 2001 also has worm, virus, and
mobile code characteristics. It spread using a variety of distribution methods:
• E-mail: A user on a vulnerable host opens an infected e-mail attachment;
Nimda looks for e-mail addresses on the host and then sends copies of itself to
those addresses.
• Windows shares: Nimda scans hosts for unsecured Windows file shares; it can
then use NetBIOS86 as a transport mechanism to infect files on that host in
the hopes that a user will run an infected file, which will activate Nimda on
that host.
• Web servers: Nimda scans Web servers, looking for known vulnerabilities in
Microsoft IIS. If it finds a vulnerable server, it attempts to transfer a copy of
itself to the server and infects it and its files.
Web clients: If a vulnerable Web client visits a Web server that has been
infected by Nimda, the client’s workstation will become infected.
• Backdoors: If a workstation was infected by earlier worms, such as “Code Red
II,” then Nimda will use the backdoor access left by these earlier infections to
access the system.
In early 2003, the SQL Slammer worm appeared. This worm exploited a
buffer overflow vulnerability in Microsoft SQL server. The Slammer was extremely
compact and spread rapidly, infecting 90% of vulnerable hosts within 10 minutes.
This rapid spread caused significant congestion on the Internet.
Late 2003 saw the arrival of the Sobig.F worm, which exploited open proxy
servers to turn infected machines into spam engines. At its peak, Sobig.F reportedly
accounted for one in every 17 messages and produced more than one million copies
of itself within the first 24 hours.
Mydoom is a mass-mailing e-mail worm that appeared in 2004. It followed
a growing trend of installing a backdoor in infected computers, thereby enabling
hackers to gain remote access to data such as passwords and credit card numbers.
Mydoom replicated up to 1,000 times per minute and reportedly flooded the
Internet with 100 million infected messages in 36 hours.
The Warezov family of worms appeared in 2006 [KIRK06]. When the worm
is launched, it creates several executables in system directories and sets itself to
run every time Windows starts by creating a registry entry. Warezov scans several
types of files for e-mail addresses and sends itself as an e-mail attachment. Some
variants are capable of downloading other malware, such as Trojan horses and
adware. Many variants disable security-related products and/or disable their
updating capability.
The Conficker (or Downadup) worm was first detected in November 2008
and spread quickly to become one of the most widespread infections since SQL
Slammer in 2003 [LAWT09]. It spread initially by exploiting a Windows buffer
overflow vulnerability, though later versions could also spread via USB drives and
network file shares. In 2010, it still comprised the second most common family of
malware observed by Symantec [SYMA16], even though patches were available
from Microsoft to close the main vulnerabilities it exploits.
In 2010, the Stuxnet worm was detected, though it had been spreading quietly
for some time previously [CHEN11, KUSH13]. Unlike many previous worms, it deliberately
restricted its rate of spread to reduce its chance of detection. It also targeted industrial
control systems, most likely those associated with the Iranian nuclear program,
with the likely aim of disrupting the operation of their equipment. It supported a
range of propagation mechanisms, including via USB drives, network file shares,
and using no less than four unknown, zero-day vulnerability exploits. Considerable
debate resulted from the size and complexity of its code, the use of an unprecedented
four zero-day exploits, and the cost and effort apparent in its development.
There are claims that it appears to be the first serious use of a cyberwarfare weapon
against a nation’s physical infrastructure. The researchers at Symantec who analyzed
Stuxnet noted that while they were expecting to find espionage, they never expected
to see malware with targeted sabotage as its aim. As a result, greater attention is now
being directed at the use of malware as a weapon by a number of nations.
In late 2011 the Duqu worm was discovered, which uses code related to that in
Stuxnet. Its aim is different, being cyber-espionage, though it appears to also target
the Iranian nuclear program. Another prominent, recent, cyber-espionage worm is
the Flame family, which was discovered in 2012 and appears to target Middle-Eastern
countries. Despite the specific target areas for these various worms, their infection
strategies have been so successful that they have been identified on computer systems
in a very large number of countries, including on systems kept physically isolated
from the general Internet. This reinforces the need for significantly improved
countermeasures to resist such infections.
WannaCry
In May 2017, the WannaCry ransomware attack spread extremely rapidly over a
period of hours to days, infecting hundreds of thousands of systems belonging to both
public and private organisations in more than 150 countries (US-CERT Alert TA17-
132A) [GOOD17]. It spread as a worm by aggressively scanning both local and random
remote networks, attempting to exploit a vulnerability in the SMB file sharing service on
unpatched Windows systems. This rapid spread was only slowed by the accidental activation
of a “kill-switch” domain by a UK security researcher, whose existence was checked
for in the initial versions of this malware. Once installed on infected systems, it also
encrypted files, demanding a ransom payment to recover them, as we will discuss later.
24
Ransomware attack in May 2017 that spread extremely fast over a period of hours to days, infecting hundreds of thousands of systems belonging to both public and private organizations in more than 150 countries
It spread as a worm by aggressively scanning both local and random remote networks, attempting to exploit a vulnerability in the SMB file sharing service on unpatched Windows systems
This rapid spread was only slowed by the accidental activation of a “kill-switch” domain by a UK security researcher
Once installed on infected systems, it also encrypted files, demanding a ransom payment to recover them
25
The state of the art in worm technology includes the following:
• Multiplatform: Newer worms are not limited to Windows machines but can
attack a variety of platforms, especially the popular varieties of UNIX; or
exploit macro or scripting languages supported in popular document types.
• Multi-exploit: New worms penetrate systems in a variety of ways, using exploits
against Web servers, browsers, e-mail, file sharing, and other network-based
applications; or via shared media.
• Ultrafast spreading: Exploit various techniques to optimize the rate of spread
of a worm to maximize its likelihood of locating as many vulnerable machines
as possible in a short time period.
• Polymorphic: To evade detection, skip past filters, and foil real-time analysis,
worms adopt the virus polymorphic technique. Each copy of the worm has
new code generated on the fly using functionally equivalent instructions and
encryption techniques.
• Metamorphic: In addition to changing their appearance, metamorphic worms
have a repertoire of behavior patterns that are unleashed at different stages of
propagation.
• Transport vehicles: Because worms can rapidly compromise a large number of
systems, they are ideal for spreading a wide variety of malicious payloads, such as
distributed denial-of-service bots, rootkits, spam e-mail generators, and spyware.
• Zero-day exploit : To achieve maximum surprise and distribution, a worm
should exploit an unknown vulnerability that is only discovered by the general
network community when the worm is launched. In 2015, 54 zero-day exploits were
discovered and exploited, significantly more than in previous years [SYMA16].
Many of these were in common computer and mobile software. Some, though,
were in common libraries and development packages, and some in industrial
control systems. This indicates the range of systems being targeted.
Worm Technology
Multi-exploit
Ultrafast spreading
Polymorphic
Metamorphic
Multiplatform
Mobile Code
NIST SP 800-28 defines mobile code as
“programs that can be shipped unchanged to a heterogeneous collection of platforms and executed with identical semantics”
Transmitted from a remote system to a local system and then executed on the local system
Often acts as a mechanism for a virus, worm, or Trojan horse
Takes advantage of vulnerabilities to perform its own exploits
Popular vehicles include:
Java applets
ActiveX
JavaScript
VBScript
Most common ways of using mobile code for malicious operations on local system are:
Cross-site scripting
Interactive and dynamic Web sites
E-mail attachments
Downloads from untrusted sites or of untrusted software
NIST SP 800-28 (Guidelines on Active Content and Mobile Code , March 2008) defines
mobile code as programs (e.g., script, macro, or other portable instruction) that can
be shipped unchanged to a heterogeneous collection of platforms and executed with
identical semantics.
Mobile code is transmitted from a remote system to a local system and then
executed on the local system without the user’s explicit instruction [SOUP13]. Mobile
code often acts as a mechanism for a virus, worm, or Trojan horse to be transmitted to
the user’s workstation. In other cases, mobile code takes advantage of vulnerabilities
to perform its own exploits, such as unauthorized data access or root compromise.
Popular vehicles for mobile code include Java applets, ActiveX, JavaScript, and
VBScript. The most common ways of using mobile code for malicious operations on
local system are cross-site scripting, interactive and dynamic Web sites, e-mail attachments,
and downloads from untrusted sites or of untrusted software.
26
Mobile Phone Worms
First discovery was Cabir worm in 2004
Then Lasco and CommWarrior in 2005
Communicate through Bluetooth wireless connections or MMS
Target is the smartphone
Can completely disable the phone, delete data on the phone, or force the device to send costly messages
CommWarrior replicates by means of Bluetooth to other phones, sends itself as an MMS file to contacts and as an auto reply to incoming text messages
Worms first appeared on mobile phones with the discovery of the Cabir worm in
2004, and then Lasco and CommWarrior in 2005. These worms communicate through
Bluetooth wireless connections or via the multimedia messaging service (MMS).
The target is the smartphone, which is a mobile phone that permits users to install
software applications from sources other than the cellular network operator. All
these early mobile worms targeted mobile phones using the Symbian operating
system. More recent malware targets Android and iPhone systems. Mobile phone
malware can completely disable the phone, delete data on the phone, or force the
device to send costly messages to premium-priced numbers.
The CommWarrior worm replicates by means of Bluetooth to other phones
in the receiving area. It also sends itself as an MMS file to numbers in the phone’s
address book and in automatic replies to incoming text messages and MMS messages.
In addition, it copies itself to the removable memory card and inserts itself
into the program installation files on the phone.
Although these examples demonstrate that mobile phone worms are possible,
the vast majority of mobile phone malware observed use trojan apps to install themselves
[SYMA16].
27
Drive-By-Downloads
Another approach to exploiting software vulnerabilities involves the exploit of bugs
in user applications to install malware. A common technique exploits browser vulnerabilities
so that when the user views a Web page controlled by the attacker, it
contains code that exploits the browser bug to download and install malware
on the system without the user’s knowledge or consent. This is known as a drive-by-download
and is a common exploit in recent attack kits. Multiple vulnerabilities in the Adobe Flash
Player and Oracle Java plugins have been exploited by attackers over many years, to
the point where many browsers are now removing support for them. In most cases, this
malware does not actively propagate as a worm does, but rather waits for unsuspecting
users to visit the malicious webpage in order to spread to their systems [SYMA16].
28
Exploits browser and plugin vulnerabilities so when the user views a webpage controlled by the attacker, it contains code that exploits the bug to download and install malware on the system without the user’s knowledge or consent
In most cases the malware does not actively propagate as a worm does
Spreads when users visit the malicious Web page
Watering-Hole Attacks
A variant of drive-by-download used in highly targeted attacks
The attacker researches their intended victims to identify websites they are likely to visit, then scans these sites to identify those with vulnerabilities that allow their compromise
They then wait for one of their intended victims to visit one of the compromised sites
Attack code may even be written so that it will only infect systems belonging to the target organization and take no action for other visitors to the site
This greatly increases the likelihood of the site compromise remaining undetected
In general, drive-by-download attacks are aimed at anyone who visits a compromised
site and is vulnerable to the exploits used. Watering-hole attacks are a
variant of this used in highly targeted attacks. The attacker researches
their intended victims to identify web sites they are likely to visit, and then scans
these sites to identify those with vulnerabilities that allow their compromise with
a drive-by-download attack. They then wait for one of their intended victims to
visit one of the compromised sites. Their attack code may even be written so that it
will only infect systems belonging to the target organization, and take no action for
other visitors to the site. This greatly increases the likelihood of the site compromise
remaining undetected.
29
Malvertising
Malvertising is another technique used to place malware on websites without
actually compromising them. The attacker pays for advertisements that
are highly likely to be placed on their intended target websites, and which incorporate
malware in them. Using these malicious adds, attackers can infect visitors to
sites displaying them. Again, the malware code may be dynamically generated to
either reduce the chance of detection, or to only infect specific systems.
Malvertising has grown rapidly in recent years, as they are easy to place on desired websites with few questions asked,
and are hard to track. Attackers have placed these ads for as little as a few hours,
when they expect their intended victims could be browsing the targeted websites,
greatly reducing their visibility [SYMA16].
Other malware may target common PDF viewers to also download and install
malware without the user’s consent when they view a malicious PDF document
[STEV11]. Such documents may be spread by spam e-mail, or be part of a targeted
phishing attack, as we will discuss in the next section.
30
Places malware on websites without actually compromising them
The attacker pays for advertisements that are highly likely to be placed on their intended target websites and incorporate malware in them
Using these malicious ads, attackers can infect visitors to sites displaying them
The malware code may be dynamically generated to either reduce the chance of detection or to only infect specific systems
Has grown rapidly in recent years because they are easy to place on desired websites with few questions asked and are hard to track
Attackers can place these ads for as little as a few hours, when they expect their intended victims could be browsing the targeted websites, greatly reducing their visibility
Clickjacking
Also known as a user-interface (UI) redress attack
Using a similar technique, keystrokes can also be hijacked
A user can be led to believe they are typing in the password to their email or bank account, but are instead typing into an invisible frame controlled by the attacker
Vulnerability used by an attacker to collect an infected user’s clicks
The attacker can force the user to do a variety of things from adjusting the user’s computer settings to unwittingly sending the user to Web sites that might have malicious code
By taking advantage of Adobe Flash or JavaScript an attacker could even place a button under or over a legitimate button making it difficult for users to detect
A typical attack uses multiple transparent or opaque layers to trick a user into clicking on a button or link on another page when they were intending to click on the top level page
The attacker is hijacking clicks meant for one page and routing them to another page
Clickjacking, also known as a user-interface (UI) redress attack , is a vulnerability
used by an attacker to collect an infected user’s clicks. The attacker can force the
user to do a variety of things from adjusting the user’s computer settings to unwittingly
sending the user to Web sites that might have malicious code. Also, by taking
advantage of Adobe Flash or JavaScript, an attacker could even place a button
under or over a legitimate button, making it difficult for users to detect. A typical
attack uses multiple transparent or opaque layers to trick a user into clicking on a
button or link on another page when they were intending to click on the top level
page. Thus, the attacker is hijacking clicks meant for one page and routing them to
another page, most likely owned by another application, domain, or both.
Using a similar technique, keystrokes can also be hijacked. With a carefully
crafted combination of stylesheets, iframes, and text boxes, a user can be led to
believe they are typing in the password to their email or bank account, but are
instead typing into an invisible frame controlled by the attacker.
There is a wide variety of techniques for accomplishing a clickjacking attack,
and new techniques are developed as defenses to older techniques are put in place.
[NIEM11] and [STON10] are useful discussions.
31
Social Engineering
“Tricking” users to assist in the compromise of their own systems
The final category of malware propagation we consider involves social engineering,
“tricking” users to assist in the compromise of their own systems or personal
information. This can occur when a user views and responds to some SPAM
e-mail, or permits the installation and execution of some Trojan horse program or
scripting code.
Spam (Unsolicited Bulk) E-Mail
With the explosive growth of the Internet over the last few decades, the widespread
use of e-mail, and the extremely low cost required to send large volumes of e-mail, has
come the rise of unsolicited bulk e-mail, commonly known as spam. [SYMA16] notes
that more than half of inbound business e-mail traffic is still spam, despite a gradual
decline in recent years. This imposes significant costs on both the network infrastructure
needed to relay this traffic, and on users who need to filter their legitimate e-mails
out of this flood. In response to this explosive growth, there has been the equally rapid
growth of the anti-spam industry that provides products to detect and filter spam
e-mails. This has led to an arms race between the spammers devising techniques to
sneak their content through, and with the defenders, efforts to block them [KREI09].
However, the spam problem continues, as spammers exploit other means of
reaching their victims. This includes the use of social media, reflecting the rapid growth
in the use of these networks. For example, [SYMA16] described a successful weightloss
spam campaign that exploited hundreds of thousands of fake Twitter accounts,
mutually supporting and reinforcing each other, to increase their credibility and likelihood
of users following them, and then falling for the scam. Social network scams often
rely on victims sharing the scam, or on fake offers with incentives, to assist their spread.
While some spam e-mail is sent from legitimate mail servers using stolen user
credentials, most recent spam is sent by botnets using compromised user systems,
as we will discuss in Section 6.6. A significant portion of spam e-mail content is just
advertising, trying to convince the recipient to purchase some product online, such
as pharmaceuticals, or used in scams, such as stock, romance or fake trader scams, or
money mule job ads. But spam is also a significant carrier of malware. The e-mail may
have an attached document, which, if opened, may exploit a software vulnerability
to install malware on the user’s system, as we discussed in the previous section. Or, it
may have an attached Trojan horse program or scripting code that, if run, also installs
malware on the user’s system. Some Trojans avoid the need for user agreement by
exploiting a software vulnerability in order to install themselves, as we will discuss
next. Finally the spam may be used in a phishing attack, typically directing the user
either to a fake website that mirrors some legitimate service, such as an online banking
site, where it attempts to capture the user’s login and password details; or to complete
some form with sufficient personal details to allow the attacker to impersonate
the user in an identity theft. In recent years, the evolving criminal marketplace makes
phishing campaigns easier by selling packages to scammers that largely automate the
process of running the scam [SYMA16]. All of these uses make spam e-mails a significant
security concern. However, in many cases, it requires the user’s active choice
to view the e-mail and any attached document, or to permit the installation of some
program, in order for the compromise to occur. Hence the importance of providing
appropriate security awareness training to users, so they are better able to recognize
and respond appropriately to such e-mails, as we will discuss in Chapter 17.
Trojan Horses
A Trojan horse is a useful, or apparently useful, program or utility containing
hidden code that, when invoked, performs some unwanted or harmful function.
Trojan horse programs can be used to accomplish functions indirectly that
the attacker could not accomplish directly. For example, to gain access to sensitive,
personal information stored in the files of a user, an attacker could create a Trojan
horse program that, when executed, scans the user’s files for the desired sensitive
information and sends a copy of it to the attacker via a Web form or e-mail or text
message. The author could then entice users to run the program by incorporating it
into a game or useful utility program, and making it available via a known software
distribution site or app store. This approach has been used recently with utilities
that “claim” to be the latest anti-virus scanner, or security update, for systems, but
which are actually malicious Trojans, often carrying payloads such as spyware that
searches for banking credentials. Hence, users need to take precautions to validate
the source of any software they install.
Trojan horses fit into one of three models:
• Continuing to perform the function of the original program and additionally
performing a separate malicious activity
• Continuing to perform the function of the original program but modifying the
function to perform malicious activity (e.g., a Trojan horse version of a login
program that collects passwords) or to disguise other malicious activity (e.g., a
Trojan horse version of a process listing program that does not display certain
processes that are malicious)
• Performing a malicious function that completely replaces the function of the
original program
Some Trojans avoid the requirement for user assistance by exploiting some software
vulnerability to enable their automatic installation and execution. In this they share
some features of a worm, but unlike it, they do not replicate. A prominent example
of such an attack was the Hydraq Trojan used in Operation Aurora in 2009 and early
2010. This exploited a vulnerability in Internet Explorer to install itself, and targeted
several high-profile companies. It was typically distributed using either spam e-mail or
via a compromised website using a “watering-hole” attack. Tech Support Scams are a
growing social engineering concern. These involve call centers calling users about nonexistent
problems on their computer systems. If the users respond, the attackers try to
sell them bogus tech support or ask them to install Trojan malware or other unwanted
applications on their systems, all while claiming this will fix their problem [SYMA16].
Mobile Phone Trojans
Mobile phone Trojans also first appeared in 2004 with the discovery of Skuller. As
with mobile worms, the target is the smartphone, and the early mobile Trojans targeted
Symbian phones. More recently, a significant number of Trojans have been
detected that target Android phones and Apple iPhones. These Trojans are usually
distributed via one or more of the app marketplaces for the target phone O/S.
The rapid growth in smartphone sales and use, which increasingly contain valuable
personal information, make them an attractive target for criminals and other
attackers. Given five in six new phones run Android, they are a key target [SYMA16].
The number of vulnerabilities discovered in, and malware families targeting these
phones, have both increased steadily in recent years. Recent examples include a
phishing Trojan that tricks the user into entering their banking details, and ransomware
that mimics Google’s design style to appear more legitimate and intimidating.
The tighter controls that Apple impose on their app store, mean that many
iPhone Trojans target “jail-broken” phones, and are distributed via unofficial sites.
However a number of versions of the iPhone O/S contained some form of graphic
or PDF vulnerability. Indeed these vulnerabilities were the main means used to “jailbreak”
the phones. But they also provided a path that malware could use to target
the phones. While Apple has fixed a number of these vulnerabilities, new variants
continued to be discovered. This is yet another illustration of just how difficult it is, for
even well- resourced organizations, to write secure software within a complex system,
such as an operating system. We will return to this topic in Chapters 10 and 11. More
recently in 2015, XcodeGhost malware was discovered in a number of legitimate
Apple Store apps. The apps were not intentionally designed to be malicious, but their
developers used a compromised Xcode development system that covertly installed
the malware as the apps were created [SYMA16]. This is one of several examples
of attackers exploiting the development or enterprise provisioning infrastructure to
assist malware distribution.
32
Spam
Unsolicited bulk
Significant carrier of malware
Used for phishing attacks
Trojan horse
Program or utility containing harmful hidden code
Used to accomplish functions that the attacker could not accomplish directly
Mobile phone Trojans
First appeared in 2004 (Skuller)
Target is the smartphone
Payload System Corruption
Once malware is active on the target system, the next concern is what actions it
will take on this system. That is, what payload does it carry. Some malware has a
nonexistent or nonfunctional payload. Its only purpose, either deliberate or due to
accidental early release, is to spread. More commonly, it carries one or more payloads
that perform covert actions for the attacker.
An early payload seen in a number of viruses and worms resulted in data
destruction on the infected system when certain trigger conditions were met
[WEAV03]. A related payload is one that displays unwanted messages or content
on the user’s system when triggered. More seriously, another variant attempts to
inflict real-world damage on the system. All of these actions target the integrity of
the computer system’s software or hardware, or of the user’s data. These changes
may not occur immediately, but only when specific trigger conditions are met that
satisfy their logic-bomb code.
The Chernobyl virus is an early example of a destructive parasitic memory-resident
Windows-95 and 98 virus, that was first seen in 1998. It infects executable files when
they’re opened. And when a trigger date is reached, it deletes data on the infected
system by overwriting the first megabyte of the hard drive with zeroes, resulting in
massive corruption of the entire file system. This first occurred on April 26, 1999,
when estimates suggest more than one million computers were affected.
Similarly, the Klez mass-mailing worm is an early example of a destructive
worm infecting Windows-95 to XP systems, and was first seen in October 2001. It
spreads by e-mailing copies of itself to addresses found in the address book and in
files on the system. It can stop and delete some anti-virus programs running on the
system. On trigger dates, being the 13th of several months each year, it causes files
on the local hard drive to become empty.
As an alternative to just destroying data, some malware encrypts the user’s
data, and demands payment in order to access the key needed to recover this information.
This is known as ransomware . The PC Cyborg Trojan seen in 1989 was an
early example of this. However, around mid-2006, a number of worms and Trojans
appeared, such as the Gpcode Trojan, that used public-key cryptography with increasingly
larger key sizes to encrypt data. The user needed to pay a ransom, or to make
a purchase from certain sites, in order to receive the key to decrypt this data. While
earlier instances used weaker cryptography that could be cracked without paying the
ransom, the later versions using public-key cryptography with large key sizes could
not be broken this way. [SYMA16, VERI16] note that ransomware is a growing challenge,
comprising one of the most common types of malware installed on systems,
and is often spread via “drive-by-downloads” or via SPAM e-mails.
33
Chernobyl virus
Klez
Ransomware
First seen in 1998
Infects executable files when they are opened and when a trigger date is reached, the virus deletes data on the infected system by overwriting the first megabyte of the hard drive with zeroes, resulting in massive corruption of the entire file system
Mass mailing worm infecting Windows 95 to XP systems
On trigger date causes files on the hard drive to become empty
Encrypts the user’s data and demands payment in order to access the key needed to recover the information
PC Cyborg Trojan (1989)
Mid-2006 a number of worms and Trojans appeared that used public-key cryptography with incresasingly larger key sizes to encrypt data
Example of a destructive parasitic memory-resident Windows 95 and 98 virus
First seen in October 2001
Spreads by e-mailing copies of itself to addresses found in the address book and in files on the system
It can stop and delete some anti-virus programs running on the system
The user needed to pay a ransom, or to make a purchase from certain sites, in order to receive the key to decrypt this data
Ransomware
WannaCry
Infected a large number of systems in many countries in May 2017
When installed on infected systems, it encrypted a large number of files and then demanded a ransom payment in Bitcoins to recover them
Recovery of this information was generally only possible if the organization had good backups and an appropriate incident response and disaster recovery plan
Targets widened beyond personal computer systems to include mobile devices and Linux servers
Tactics such as threatening to publish sensitive personal information, or to permanently destroy the encryption key after a short period of time, are sometimes used to increase the pressure on the victim to pay up
The WannaCry ransomware, that we mentioned earlier in our discussion of
Worms, infected a large number of systems in many countries in May 2017. When
installed on infected systems, it encrypted a large number of files matching a list of
particular file types, and then demanded a ransom payment in Bitcoins to recover
them. Once this had occurred, recovery of this information was generally only possible
if the organization had good backups, and an appropriate incident response and disaster
recovery plan, as we will discuss in Chapter 17. The WannaCry ransomware attack
generated a significant amount of media attention, in part due to the large number of
affected organizations, and the significant costs they incurred in recovering from it. The
targets for these attacks have widened beyond personal computer systems to include
mobile devices and Linux servers. And tactics such as threatening to publish sensitive
personal information, or to permanently destroy the encryption key after a short
period of time, are sometimes used to increase the pressure on the victim to pay up.
34
Payload System Corruption
Real-world damage
Causes damage to physical equipment
Chernobyl virus rewrites BIOS code
Stuxnet worm
Targets specific industrial control system software
There are concerns about using sophisticated targeted malware for industrial sabotage
Logic bomb
Code embedded in the malware that is set to “explode” when certain conditions are met
A further variant of system corruption payloads aims to cause damage to physical
equipment. The infected system is clearly the device most easily targeted. The
Chernobyl virus mentioned above not only corrupts data, but attempts to rewrite
the BIOS code used to initially boot the computer. If it is successful, the boot process
fails, and the system is unusable until the BIOS chip is either re-programmed or
replaced.
More recently, the Stuxnet worm that we discussed previously targets some
specific industrial control system software as its key payload [CHEN11, KUSH13]. If control
systems using certain Siemens industrial control software with a specific configuration
of devices are infected, then the worm replaces the original control code with code
that deliberately drives the controlled equipment outside its normal operating range,
resulting in the failure of the attached equipment. The centrifuges used in the Iranian
uranium enrichment program were strongly suspected as the target, with reports of
much higher than normal failure rates observed in them over the period when this
worm was active. As noted in our earlier discussion, this has raised concerns over the
use of sophisticated targeted malware for industrial sabotage.
The British Government’s 2015 Security and Defense Review noted their
growing concerns over the use of cyber attacks against critical infrastructure by
both state-sponsored and non state actors. The December 2015 attack that disrupted
Ukrainian power systems shows these concerns are well-founded, given that much
critical infrastructure is not sufficiently hardened to resist such attacks [SYMA16].
A key component of data corrupting malware is the logic bomb. The logic bomb is
code embedded in the malware that is set to “explode” when certain conditions are
met. Examples of conditions that can be used as triggers for a logic bomb are the presence
or absence of certain files or devices on the system, a particular day of the week
or date, a particular version or configuration of some software, or a particular user
running the application. Once triggered, a bomb may alter or delete data or entire files,
cause a machine halt, or do some other damage.
A striking example of how logic bombs can be employed was the case of Tim
Lloyd, who was convicted of setting a logic bomb that cost his employer, Omega
Engineering, more than $10 million, derailed its corporate growth strategy, and
eventually led to the layoff of 80 workers [GAUD00]. Ultimately, Lloyd was
sentenced to 41 months in prison and ordered to pay $2 million in restitution.
35
Payload – Attack Agents Bots
Takes over another Internet attached computer and uses that computer to launch or manage attacks
Botnet - collection of bots capable of acting in a coordinated manner
Uses:
Distributed denial-of-service (DDoS) attacks
Spamming
Sniffing traffic
Keylogging
Spreading new malware
Installing advertisement add-ons and browser helper objects (BHOs)
Attacking IRC chat networks
Manipulating online polls/games
36
The next category of payload we discuss is where the malware subverts the computational
and network resources of the infected system for use by the attacker.
Such a system is known as a bot (robot), zombie or drone, and secretly takes over
another Internet-attached computer and then uses that computer to launch or manage
attacks that are difficult to trace to the bot’s creator. The bot is typically planted
on hundreds or thousands of computers belonging to unsuspecting third parties.
The collection of bots often is capable of acting in a coordinated manner; such a
collection is referred to as a botnet . This type of payload attacks the integrity and
availability of the infected system.
Uses of Bots
[HONE05] lists the following uses of bots:
• Distributed denial-of-service (DDoS) attacks: A DDoS attack is an attack on
a computer system or network that causes a loss of service to users. We examine
DDoS attacks in Chapter 7 .
• Spamming: With the help of a botnet and thousands of bots, an attacker is able
to send massive amounts of bulk e-mail (spam).
• Sniffing traffic: Bots can also use a packet sniffer to watch for interesting cleartext
data passing by a compromised machine. The sniffers are mostly used to
retrieve sensitive information like usernames and passwords.
Keylogging: If the compromised machine uses encrypted communication
channels (e.g. HTTPS or POP3S), then just sniffing the network packets on
the victim’s computer is useless because the appropriate key to decrypt the
packets is missing. But by using a keylogger, which captures keystrokes on the
infected machine, an attacker can retrieve sensitive information.
• Spreading new malware: Botnets are used to spread new bots. This is very
easy since all bots implement mechanisms to download and execute a file via
HTTP or FTP. A botnet with 10,000 hosts that acts as the start base for a
worm or mail virus allows very fast spreading and thus causes more harm.
• Installing advertisement add-ons and browser helper objects (BHOs): Botnets
can also be used to gain financial advantages. This works by setting up a fake
Web site with some advertisements: The operator of this Web site negotiates a
deal with some hosting companies that pay for clicks on ads. With the help of
a botnet, these clicks can be “automated” so that instantly a few thousand bots
click on the pop-ups. This process can be further enhanced if the bot hijacks
the start-page of a compromised machine so that the “clicks” are executed
each time the victim uses the browser.
• Attacking IRC chat networks: Botnets are also used for attacks against
Internet Relay Chat (IRC) networks. Popular among attackers is especially
the so-called clone attack: In this kind of attack, the controller orders each bot
to connect a large number of clones to the victim IRC network. The victim is
flooded by service requests from thousands of bots or thousands of channeljoins
by these cloned bots. In this way, the victim IRC network is brought
down, similar to a DDoS attack.
• Manipulating online polls/games: Online polls/games are getting more and
more attention and it is rather easy to manipulate them with botnets. Since
every bot has a distinct IP address, every vote will have the same credibility as
a vote cast by a real person. Online games can be manipulated in a similar way.
Remote Control Facility
Distinguishes a bot from a worm
Worm propagates itself and activates itself
Bot is initially controlled from some central facility
Typical means of implementing the remote control facility is on an IRC server
Bots join a specific channel on this server and treat incoming messages as commands
More recent botnets use covert communication channels via protocols such as HTTP
Distributed control mechanisms use peer-to-peer protocols to avoid a single point of failure
The remote control facility is what distinguishes a bot from a worm. A worm propagates
itself and activates itself, whereas a bot is controlled by some form of command-and-
control (C&C) server network. This contact does not need to be continuous,
but can be initiated periodically when the bot observes it has network access.
An early means of implementing the remote control facility used an IRC
server. All bots join a specific channel on this server and treat incoming messages
as commands. More recent botnets tend to avoid IRC mechanisms and use covert
communication channels via protocols such as HTTP. Distributed control mechanisms,
using peer-to-peer protocols, are also used, to avoid a single point of failure.
Originally these C&C servers used fixed addresses, which meant they could
be located and potentially taken over or removed by law enforcement agencies.
Some more recent malware families have used techniques such as the automatic
generation of very large numbers of server domain names that the malware will try
to contact. If one server name is compromised, the attackers can setup a new server
at another name they know will be tried. To defeat this requires security analysts to
reverse engineer the name generation algorithm, and to then attempt to gain control
over all of the extremely large number of possible domains. Another technique
used to hide the servers is fast-flux DNS, where the address associated with a given
server name is changed frequently, often every few minutes, to rotate over a large
number of server proxies, usually other members of the botnet. Such approaches
hinder attempts by law enforcement agencies to respond to the botnet threat.
Once a communications path is established between a control module and
the bots, the control module can manage the bots. In its simplest form, the control
module simply issues command to the bot that causes the bot to execute routines
that are already implemented in the bot. For greater flexibility, the control module
can issue update commands that instruct the bots to download a file from some
Internet location and execute it. The bot in this latter case becomes a more general purpose
tool that can be used for multiple attacks. The control module can also collect
information gathered by the bots that the attacker can then exploit. One effective counter
measure against a botnet is to take-over or shutdown its C&C network. Increasing
cooperation and coordination between law enforcement agencies in a number of
countries resulted in a growing number of successful C&C seizures in recent years
[SYMA16], and the consequent suppression of their associated botnets. These actions
also resulted in criminal charges on a number of people associated with them.
37
Payload – Information Theft Keyloggers and Spyware
We now consider payloads where the malware gathers data stored on the infected
system for use by the attacker. A common target is the user’s login and password
credentials to banking, gaming, and related sites, which the attacker then uses to
impersonate the user to access these sites for gain. Less commonly, the payload may
target documents or system configuration details for the purpose of reconnaissance
or espionage. These attacks target the confidentiality of this information.
Typically, users send their login and password credentials to banking, gaming, and
related sites over encrypted communication channels (e.g., HTTPS or POP3S),
which protects them from capture by monitoring network packets. To bypass this,
an attacker can install a keylogger , which captures keystrokes on the infected
machine to allow an attacker to monitor this sensitive information. Since this would
result in the attacker receiving a copy of all text entered on the compromised
machine, keyloggers typical implement some form of filtering mechanism that
only returns information close to desired keywords (e.g., “login” or “password” or
“paypal.com”).
In response to the use of keyloggers, some banking and other sites switched to
using a graphical applet to enter critical information, such as passwords. Since these
do not use text entered via the keyboard, traditional keyloggers do not capture this
information. In response, attackers developed more general spyware payloads,
which subvert the compromised machine to allow monitoring of a wide range of
activity on the system. This may include monitoring the history and content of
browsing activity, redirecting certain Web page requests to fake sites controlled by
the attacker, and dynamically modifying data exchanged between the browser and
certain Web sites of interest. All of which can result in significant compromise of
the user’s personal information.
The Zeus banking Trojan, created from its crimeware toolkit, is a prominent
example of such spyware that has been widely deployed in recent years [BINS10].
It steals banking and financial credentials using both a keylogger and capturing and
possibly altering form data for certain Web sites. It is typically deployed using either
spam e-mails or via a compromised Web site in a “drive-by-download.”
38
Keylogger
Captures keystrokes to allow attacker to monitor sensitive information
Typically uses some form of filtering mechanism that only returns information close to keywords (“login”, “password”)
Spyware
Subverts the compromised machine to allow monitoring of a wide range of activity on the system
Monitoring history and content of browsing activity
Redirecting certain Web page requests to fake sites
Dynamically modifying data exchanged between the browser and certain Web sites of interest
Payload – Information Theft Phishing
Exploits social engineering to leverage the user’s trust by masquerading as communication from a trusted source
Include a URL in a spam e-mail that links to a fake Web site that mimics the login page of a banking, gaming, or similar site
Suggests that urgent action is required by the user to authenticate their account
Attacker exploits the account using the captured credentials
Spear-phishing
Recipients are carefully researched by the attacker
E-mail is crafted to specifically suit its recipient, often quoting a range of information to convince them of its authenticity
Another approach used to capture a user’s login and password credentials is to
include a URL in a spam e-mail that links to a fake Web site controlled by the
attacker, but which mimics the login page of some banking, gaming, or similar site.
This is normally included in some message suggesting that urgent action is required
by the user to authenticate their account, to prevent it being locked. If the user is
careless, and doesn’t realize that they are being conned, then following the link and
supplying the requested details will certainly result in the attackers exploiting their
account using the captured credentials.
More generally, such a spam e-mail may direct a user to a fake Web site
controlled by the attacker, or to complete some enclosed form and return to an e-mail
accessible to the attacker, which is used to gather a range of private, personal, information
on the user. Given sufficient details, the attacker can then “assume” the user’s
identity for the purpose of obtaining credit, or sensitive access to other resources.
This is known as a phishing attack and exploits social engineering to leverage user’s
trust by masquerading as communications from a trusted source [GOLD10].
Such general spam e-mails are typically widely distributed to very large numbers
of users, often via a botnet. While the content will not match appropriate
trusted sources for a significant fraction of the recipients, the attackers rely on it
reaching sufficient users of the named trusted source, a gullible portion of whom
will respond, for it to be profitable.
A more dangerous variant of this is the spear-phishing attack. This again is an
e-mail claiming to be from a trusted source. However, the recipients are carefully
researched by the attacker, and each e-mail is carefully crafted to suit its recipient specifically,
often quoting a range of information to convince them of its authenticity. This
greatly increases the likelihood of the recipient responding as desired by the attacker.
This type of attack is particularly used in industrial and other
forms of espionage, or in financial fraud such as bogus wire-transfer authorizations,
by well-resourced organizations. Whether as a result of phishing, drive-by-download,
or direct hacker attack, the number of incidents, and the quantity of personal records
exposed, continues to grow. For example, the Anthem medical data breach in January
2015 exposed more than 78 million personal
information records that could potentially
be used for identity theft. The well-resourced Black Vine cyber-espionage group
is thought responsible for this attack [SYMA16].
Credential theft and identity theft are special cases of a more general reconnaissance
payload, which aims to obtain certain types of desired information and return
this to the attacker. These special cases are certainly the most common; however,
other targets are known. Operation Aurora in 2009 used a Trojan to gain access
to and potentially modify source code repositories at a range of high tech, security,
and defense contractor companies [SYMA16]. The Stuxnet worm discovered
in 2010 included capture of hardware and software configuration details in order to
determine whether it had compromised the specific desired target systems. Early
versions of this worm returned this same information, which was then used to
develop the attacks deployed in later versions [CHEN11, KUSH13]. There are a number of other
high-profile examples of mass record exposure. These include the Wikileaks leak of
sensitive military and diplomatic documents by Chelsea (born Bradley) Manning
in 2010, and the release of information on NSA surveillance programs by Edward
Snowden in 2013. Both of these are examples of insiders exploiting their legitimate
access rights to release information for ideological reasons. And both resulted in
significant global discussion and debate on the consequences of these actions. In
contrast, the 2015 release of personal information on the users of the Ashley Madison
adult website, and the 2016 Panama Papers leak of millions of documents relating to
off-shore entities used as tax havens in at least some cases, are thought to have been
carried out by outside hackers attacking poorly secured systems. Both have resulted
in serious consequences for some of the people named in these leaks.
APT attacks may result in the loss of large volumes of sensitive information,
which is sent, exfiltrated from the target organization, to the attackers. To detect
and block such data exfiltration requires suitable “data-loss” technical countermeasures
that manage either access to such information, or its transmission across
the organization’s network perimeter.
39
Payload – Stealthing Backdoor
Also known as a trapdoor
Secret entry point into a program allowing the attacker to gain access and bypass the security access procedures
Maintenance hook is a backdoor used by Programmers to debug and test programs
Difficult to implement operating system controls for backdoors in applications
The final category of payload we discuss concerns techniques used by malware to
hide its presence on the infected system, and to provide covert access to that system.
This type of payload also attacks the integrity of the infected system.
A backdoor, also known as a trapdoor, is a secret entry point into a program
that allows someone who is aware of the backdoor to gain access without going
through the usual security access procedures. Programmers have used backdoors
legitimately for many years to debug and test programs; such a backdoor is called
a maintenance hook . This usually is done when the programmer is developing an
application that has an authentication procedure, or a long setup, requiring the user
to enter many different values to run the application. To debug the program, the
developer may wish to gain special privileges or to avoid all the necessary setup and
authentication. The programmer may also want to ensure that there is a method of
activating the program should something be wrong with the authentication procedure
that is being built into the application. The backdoor is code that recognizes
some special sequence of input or is triggered by being run from a certain user ID or
by an unlikely sequence of events.
Backdoors become threats when unscrupulous programmers use them to
gain unauthorized access. The backdoor was the basic idea for the vulnerability
portrayed in the movie War Games . Another example is that during the development
of Multics, penetration tests were conducted by an Air Force “tiger team”
(simulating adversaries). One tactic employed was to send a bogus operating system
update to a site running Multics. The update contained a Trojan horse that could be
activated by a backdoor and that allowed the tiger team to gain access. The threat
was so well implemented that the Multics developers could not find it, even after
they were informed of its presence [ENGE80].
In more recent times, a backdoor is usually implemented as a network service
listening on some non-standard port that the attacker can connect to and issue commands
through to be run on the compromised system. The WannaCry ransomware,
that we described earlier in this chapter, included such a backdoor.
It is difficult to implement operating system controls for backdoors in
applications. Security measures must focus on the program development and
software update activities, and on programs that wish to offer a network service.
40
Payload - Stealthing Rootkit
Set of hidden programs installed on a system to maintain covert access to that system
Hides by subverting the mechanisms that monitor and report on the processes, files, and registries on a computer
Gives administrator (or root) privileges to attacker
Can add or change programs and files, monitor processes, send and receive network traffic, and get backdoor access on demand
41
A rootkit is a set of programs installed on a system to maintain covert access to that
system with administrator (or root) privileges, while hiding evidence of its presence
to the greatest extent possible. This provides access to all the functions and
services of the operating system. The rootkit alters the host’s standard functionality
in a malicious and stealthy way. With root access, an attacker has complete control
of the system and can add or change programs and files, monitor processes, send and
receive network traffic, and get backdoor access on demand.
A rootkit can make many changes to a system to hide its existence, making
it difficult for the user to determine that the rootkit is present and to identify what
changes have been made. In essence, a rootkit hides by subverting the mechanisms
that monitor and report on the processes, files, and registries on a computer.
Rootkit Classification Characteristics
A rootkit can be classified using the following characteristics:
• Persistent: Activates each time the system boots. The rootkit must store code
in a persistent store, such as the registry or file system, and configure a method
by which the code executes without user intervention. This means it is easier
to detect, as the copy in persistent storage can potentially be scanned.
• Memory based: Has no persistent code and therefore cannot survive a reboot.
However, because it is only in memory, it can be harder to detect.
• User mode: Intercepts calls to APIs (application program interfaces) and modifies
returned results. For example, when an application performs a directory
listing, the return results don’t include entries identifying the files associated
with the rootkit.
• Kernel mode: Can intercept calls to native APIs in kernel mode. The rootkit
can also hide the presence of a malware process by removing it from the
kernel’s list of active processes.
• Virtual machine based: This type of rootkit installs a lightweight virtual
machine monitor, and then runs the operating system in a virtual machine
above it. The rootkit can then transparently intercept and modify states and
events occurring in the virtualized system.
• External mode: The malware is located outside the normal operation mode
of the targeted system, in BIOS or system management mode, where it can
directly access hardware.
This classification shows a continuing arms race between rootkit authors, who
exploit ever more stealthy mechanisms to hide their code, and those who develop
mechanisms to harden systems against such subversion, or to detect when it has
occurred. Much of this advance is associated with finding “layer-below” forms of
attack. The early rootkits worked in user mode, modifying utility programs and
libraries in order to hide their presence. The changes they made could be detected
by code in the kernel, as this operated in the layer below the user. Later-generation
rootkits used more stealthy techniques, as we discuss next.
42
Persistent
Memory based
User mode
Kernel mode
Virtual machine based
External mode
43
The next generation of rootkits moved down a layer, making changes inside the
kernel and co-existing with the operating systems code, in order to make their
detection much harder. Any “anti-virus” program would now be subject to the
same “low-level” modifications that the rootkit uses to hide its presence. However,
methods were developed to detect these changes.
Programs operating at the user level interact with the kernel through system
calls. Thus, system calls are a primary target of kernel-level rootkits to achieve concealment.
As an example of how rootkits operate, we look at the implementation of
system calls in Linux. In Linux, each system call is assigned a unique syscall number .
When a user-mode process executes a system call, the process refers to the system
call by this number. The kernel maintains a system call table with one entry per
system call routine; each entry contains a pointer to the corresponding routine. The
syscall number serves as an index into the system call table.
[LEVI06] lists three techniques that can be used to change system calls:
• Modify the system call table: The attacker modifies selected syscall addresses
stored in the system call table. This enables the rootkit to direct a system call
away from the legitimate routine to the rootkit’s replacement. Figure 6.5
shows how the knark rootkit achieves this.
Modify system call table targets: The attacker overwrites selected legitimate
system call routines with malicious code. The system call table is not changed.
• Redirect the system call table: The attacker redirects references to the entire
system call table to a new table in a new kernel memory location.
Malware Countermeasure Approaches
Ideal solution to the threat of malware is prevention
If prevention fails, technical mechanisms can be used to support the following threat mitigation options:
Detection
Identification
Removal
The ideal solution to the threat of malware is prevention: Do not allow malware to
get into the system in the first place, or block the ability of it to modify the system.
This goal is, in general, nearly impossible to achieve, although taking suitable countermeasures
to harden systems and users in preventing infection can significantly reduce
the number of successful malware attacks. NIST SP 800-83 suggests there are four
main elements of prevention: policy, awareness, vulnerability mitigation, and threat
mitigation. Having a suitable policy to address malware prevention provides a basis
for implementing appropriate preventative countermeasures.
One of the first countermeasures that should be employed is to ensure all
systems are as current as possible, with all patches applied, in order to reduce the
number of vulnerabilities that might be exploited on the system. The next is to set
appropriate access controls on the applications and data stored on the system, to
reduce the number of files that any user can access, and hence potentially infect or
corrupt, as a result of them executing some malware code. These measures directly
target the key propagation mechanisms used by worms, viruses, and some Trojans.
We discuss them further in Chapter 12 when we discuss hardening operating systems
and applications.
The third common propagation mechanism, which targets users in a social engineering
attack, can be countered using appropriate user awareness and training. This
aims to equip users to be more aware of these attacks, and less likely to take actions
that result in their compromise. NIST SP 800-83 provides examples of suitable awareness
issues. We will return to this topic in Chapter 17.
If prevention fails, then technical mechanisms can be used to support the
following threat mitigation options:
• Detection: Once the infection has occurred, determine that it has occurred
and locate the malware.
• Identification: Once detection has been achieved, identify the specific malware
that has infected the system.
• Removal: Once the specific malware has been identified, remove all traces of
malware virus from all infected systems so that it cannot spread further.
If detection succeeds but either identification or removal is not possible, then the
alternative is to discard any infected or malicious files and reload a clean backup
version. In the case of some particularly nasty infections, this may require a complete
wipe of all storage, and rebuild of the infected system from known clean media.
To begin, let us consider some requirements for effective malware countermeasures:
• Generality: The approach taken should be able to handle a wide variety of attacks.
• Timeliness: The approach should respond quickly so as to limit the number of
infected programs or systems and the consequent activity.
• Resiliency: The approach should be resistant to evasion techniques employed
by attackers to hide the presence of their malware.
• Minimal denial-of-service costs: The approach should result in minimal reduction
in capacity or service due to the actions of the countermeasure software,
and should not significantly disrupt normal operation.
• Transparency: The countermeasure software and devices should not require
modification to existing (legacy) OSs, application software, and hardware.
• Global and local coverage: The approach should be able to deal with attack
sources both from outside and inside the enterprise network.
Achieving all these requirements often requires the use of multiple approaches.
Detection of the presence of malware can occur in a number of locations. It
may occur on the infected system, where some host-based “anti-virus” program is
running, monitoring data imported into the system, and the execution and behavior
of programs running on the system. Or, it may take place as part of the perimeter
security mechanisms used in an organization’s firewall and intrusion detection
systems (IDS). Lastly, detection may use distributed mechanisms that gather data
from both host-based and perimeter sensors, potentially over a large number of
networks and organizations, in order to obtain the largest scale view of the movement
of malware. We now consider each of these approaches in more detail.
44
Four main elements of prevention:
Policy
Awareness
Vulnerability mitigation
Threat mitigation
Generations of Anti-Virus Software
The first location where anti-virus software is used is on each end system. This gives the
software the maximum access to information on not only the behavior of the malware
as it interacts with the targeted system, but also the smallest overall view of malware
activity. The use of anti-virus software on personal computers is now widespread, in
part caused by the explosive growth in malware volume and activity. This software can
be regarded as a form of host-based intrusion detection system, which we discuss more
generally in Section 8.4. Advances in virus and other malware technology, and in antivirus
technology and other countermeasures, go hand in hand. Early malware used relatively
simple and easily detected code, and hence could be identified and purged with
relatively simple anti-virus software
packages. As the malware arms race has evolved,
both the malware code and, necessarily,
anti-virus software have grown more complex
and sophisticated.
[STEP93] identifies four generations of anti-virus software:
• First generation: simple scanners
• Second generation: heuristic scanners
Third generation: activity traps
• Fourth generation: full-featured protection
A first-generation scanner requires a malware signature to identify the malware.
The signature may contain “wildcards” but matches essentially the same structure
and bit pattern in all copies of the malware. Such signature-specific scanners are
limited to the detection of known malware. Another type of first-generation scanner
maintains a record of the length of programs and looks for changes in length as a
result of virus infection.
A second-generation scanner does not rely on a specific signature. Rather, the
scanner uses heuristic rules to search for probable malware instances. One class of
such scanners looks for fragments of code that are often associated with malware.
For example, a scanner may look for the beginning of an encryption loop used in a
polymorphic virus and discover the encryption key. Once the key is discovered, the
scanner can decrypt the malware to identify it, then remove the infection and return
the program to service.
Another second-generation approach is integrity checking. A checksum
can be appended to each program. If malware alters or replaces some program
without changing the checksum, then an integrity check will catch this change.
To counter malware that is sophisticated enough to change the checksum when
it alters a program, an encrypted hash function can be used. The encryption key
is stored separately from the program so that the malware cannot generate a new
hash code and encrypt that. By using a hash function rather than a simpler checksum,
the malware is prevented from adjusting the program to produce the same
hash code as before. If a protected list of programs in trusted locations is kept, this
approach can also detect attempts to replace or install rogue code or programs in
these locations.
Third-generation programs are memory-resident programs that identify
malware by its actions rather than its structure in an infected program. Such
programs have the advantage that it is not necessary to develop signatures and
heuristics for a wide array of malware. Rather, it is necessary only to identify the
small set of actions that indicate malicious activity is being attempted and then to
intervene.
Fourth-generation products are packages consisting of a variety of anti-virus
techniques used in conjunction. These include scanning and activity trap components.
In addition, such a package includes access control capability, which limits
the ability of malware to penetrate a system and then limits the ability of a malware
to update files in order to propagate.
The arms race continues. With fourth-generation packages, a more comprehensive
defense strategy is employed, broadening the scope of defense to more
general-purpose computer security measures. These include more sophisticated
anti-virus approaches.
45
First generation: simple scanners
Requires a malware signature to identify the malware
Limited to the detection of known malware
Second generation: heuristic scanners
Uses heuristic rules to search for probable malware instances
Another approach is integrity checking
Third generation: activity traps
Memory-resident programs that identify malware by its actions rather than its structure in an infected program
Fourth generation: full-featured protection
Packages consisting of a variety of anti-virus techniques used in conjunction
Include scanning and activity trap components and access control capability
Sandbox Analysis
Running potentially malicious code in an emulated sandbox or on a virtual machine
Allows the code to execute in a controlled environment where its behavior can be closely monitored without threatening the security of a real system
Running potentially malicious software in such environments enables the detection of complex encrypted, polymorphic, or metamorphic malware
The most difficult design issue with sandbox analysis is to determine how long to run each interpretation
One method of detecting and analyzing malware involves running
potentially malicious code in an emulated sandbox or on a virtual machine.
These allow the code to execute in a controlled environment, where its behavior
can be closely monitored without threatening the security of a real system. These
environments range from sandbox emulators that simulate memory and CPU of a
target system, up to full virtual machines, of the type we will discuss in Section 12.8,
that replicate the full functionality of target systems, but which can easily be restored
to a known state. Running potentially malicious software in such environments
enables the detection of complex encrypted, polymorphic, or metamorphic malware.
The code must transform itself into the required machine instructions, which it then
executes to perform the intended malicious actions. The resulting unpacked, transformed,
or decrypted code can then be scanned for known malware signatures, or its
behavior monitored as execution continues for possibly malicious activity [EGEL12,
KERA16]. This extended analysis can be used to develop anti-virus signatures for
new, unknown malware.
The most difficult design issue with sandbox analysis is to determine how long
to run each interpretation. Typically, malware elements are activated soon after a program
begins executing, but recent malware increasingly uses evasion approaches such
as extended sleep to evade detection in the analysis time used by sandbox systems
[KERA16]. The longer the scanner emulates a particular program, the more likely
it is to catch any hidden malware. However, the sandbox analysis has only a limited
amount of time and resources available, given the need to analyze large amounts of
potential malware.
As analysis techniques improve, an arms race has developed between malware
authors and defenders. Some malware checks to see if it is running in a sandbox or
virtualized environment, and suppresses malicious behavior if so. Other malware
includes extended sleep periods before engaging in malicious activity, in an attempt
to evade detection before the analysis terminates. Or the malware may include a logic
bomb looking for a specific date, or specific system type or network location before
engaging in malicious activity, which the sandbox environment does not match. In
response, analysts adapt their sandbox environments to attempt to evade these tests.
This race continues.
46
Host-Based Behavior-Blocking Software
Integrates with the operating system of a host computer and monitors program behavior in real time for malicious action
Blocks potentially malicious actions before they have a chance to affect the system
Blocks software in real time so it has an advantage over anti-virus detection techniques such as fingerprinting or heuristics
Unlike heuristics or fingerprint-based
scanners, dynamic malware analysis or behavior-blocking software integrates with the
operating system of a host computer and monitors program behavior in real time for
malicious actions [CONR02, EGEL12]. It is a type of host-based intrusion prevention
system, which we will discuss further in Section 9.6. This software monitors the
behavior of possibly malicious code, looking for potentially malicious actions, similar
to the sandbox systems we discussed in the previous section. However, it then has
the capability to block malicious actions before they can affect the target system.
Monitored behaviors can include the following:
• Attempts to open, view, delete, and/or modify files;
• Attempts to format disk drives and other unrecoverable disk operations;
• Modifications to the logic of executable files or macros;
• Modification of critical system settings, such as start-up settings;
• Scripting of e-mail and instant messaging clients to send executable content; and
• Initiation of network communications.
Because dynamic analysis software can block suspicious software in real time, it has
an advantage over such established anti-virus detection techniques as fingerprinting
or heuristics. There are literally trillions of different ways to obfuscate and rearrange
the instructions of a virus or worm, many of which will evade detection by a fingerprint
scanner or heuristic. But eventually, malicious code must make a well-defined
request to the operating system. Given that the behavior blocker can intercept all
such requests, it can identify and block malicious actions regardless of how obfuscated
the program logic appears to be.
Dynamic analysis alone has limitations. Because the malicious code must run on
the target machine before all its behaviors can be identified, it can cause harm before
it has been detected and blocked. For example, a new item of malware might shuffle
a number of seemingly unimportant files around the hard drive before modifying a
single file and being blocked. Even though the actual modification was blocked, the
user may be unable to locate his or her files, causing a loss to productivity or possibly
worse.
47
Limitations
Because malicious code must run on the target machine before all its behaviors can be identified, it can cause harm before it has been detected and blocked
Perimeter Scanning Approaches
Anti-virus software typically included in e-mail and Web proxy services running on an organization’s firewall and IDS
May also be included in the traffic analysis component of an IDS
May include intrusion prevention measures, blocking the flow of any suspicious traffic
Approach is limited to scanning malware
Two types of monitoring software
The next location where anti-virus software is used is on an organization’s firewall
and IDS. It is typically included in e-mail and Web proxy services running on these
systems. It may also be included in the traffic analysis component of an IDS. This
gives the anti-virus software access to malware in transit over a network connection
to any of the organization’s systems, providing a larger scale view of malware activity.
This software may also include intrusion prevention measures, blocking the flow
of any suspicious traffic, thus preventing it reaching and compromising some target
system, either inside or outside the organization.
However, this approach is limited to scanning the malware content, as it does
not have access to any behavior observed when it runs on an infected system. Two
types of monitoring software may be used:
• Ingress monitors: These are located at the border between the enterprise
network and the Internet. They can be part of the ingress filtering software
of a border router or external firewall or a separate passive monitor. A
honeypot can also capture incoming malware traffic. An example of a detection
technique for an ingress monitor is to look for incoming traffic to unused
local IP addresses.
• Egress monitors: These can be located at the egress point of individual LANs
on the enterprise network as well as at the border between the enterprise
network and the Internet. In the former case, the egress monitor can be part
of the egress filtering software of a LAN router or switch. As with ingress
monitors, the external firewall or a honeypot can house the monitoring software.
Indeed, the two types of monitors can be collocated. The egress monitor
is designed to catch the source of a malware attack by monitoring outgoing
traffic for signs of scanning or other suspicious behavior.
Perimeter monitoring can also assist in detecting and responding to botnet activity
by detecting abnormal traffic patterns associated with this activity. Once bots are
activated and an attack is underway, such monitoring can be used to detect the
attack. However, the primary objective is to try to detect and disable the botnet
during its construction phase, using the various scanning techniques we have just
discussed, identifying and blocking the malware that is used to propagate this type
of payload.
48
Ingress monitors
Located at the border between the enterprise network and the Internet
One technique is to look for incoming traffic to unused local IP addresses
Egress monitors
Located at the egress point of individual LANs as well as at the border between the enterprise network and the Internet
Monitors outgoing traffic for signs of scanning or other suspicious behavior
Summary
Propagation-social engineering-span E-mail, Trojans
Spam E-mail
Trojan horses
Mobile phone Trojans
Payload-system corruption
Data destruction
Real-world damage
Logic bomb
Payload-attack agent-zombie, bots
Uses of bots
Remote control facility
Payload-information theft-keyloggers, phishing, spyware
Credential theft, keyloggers, and spyware
Phishing and identity theft
Reconnaissance, espionage, and data exfiltration
Countermeasures
Malware countermeasure approaches
Host-based scanners
Signature-based anti-virus
Perimeter scanning approaches
Distributed intelligence gathering approaches
Types of malicious software (malware)
Broad classification of malware
Attack kits
Attack sources
Advanced persistent threat
Propagation-vulnerability exploit-worms
Target discovery
Worm propagation model
The Morris Worm
Brief history of worm attacks
State of worm technology
Mobile code
Mobile phone worms
Client-side vulnerabilities
Drive-by-downloads
Clickjacking
Payload-stealthing-backdoors, rootkits
Backdoor
Rootkit
Kernel mode rootkits
Virtual machine and other external rootkits
49
Chapter 6 summary.
Name Description Advanced persistent threat
Cybercrime directed at business and political targets, using a wide variety of intrusion technologies and malware, applied persistently and effectively to specific targets over an extended period, often attributed to state-sponsored organizations.
Adware Advertising that is integrated into software. It can result in pop-up ads or redirection of a browser to a commercial site.
Attack Kit Set of tools for generating new malware automatically using a variety of supplied propagation and payload mechanisms.
Auto-rooter Malicious hacker tools used to break into new machines remotely.
Backdoor (trapdoor) Any mechanisms that bypasses a normal security check; it may allow unauthorized access to functionality in a program, or onto a compromised system.
Downloaders Code that installs other items on a machine that is under attack. It is normally included in the malware code first inserted on to a compromised system to then import a larger malware package.
Drive-by download An attack using code in a compromised web site that exploits a browser vulnerability to attack a client system when the site is viewed.
Exploits Code specific to a single vulnerability or set of vulnerabilities. Flooders (DoS client) Used to generate a large volume of data to attack networked computer
systems, by carrying out some form of denial-of-service (DoS) attack.
Keyloggers Captures keystrokes on a compromised system. Logic bomb Code inserted into malware by an intruder. A logic bomb lies dormant
until a predefined condition is met; the code then triggers an unauthorized act.
Macro Virus A type of virus that uses macro or scripting code, typically embedded in a document, and triggered when the document is viewed or edited, to run and replicate itself into other such documents.
Mobile Code Software (e.g., script, macro, or other portable instruction) that can be shipped unchanged to a heterogeneous collection of platforms and execute with identical semantics.
Rootkit Set of hacker tools used after attacker has broken into a computer system and gained root-level access.
Spammer Programs Used to send large volumes of unwanted e-mail.
Spyware Software that collects information from a computer and transmits it to another system by monitoring keystrokes, screen data and/or network traffic; or by scanning files on the system for sensitive information.
Name Description
Advanced persistent
threat
Cybercrime directed at business and political targets, using a wide
variety of intrusion technologies and malware, applied persistently and
effectively to specific targets over an extended period, often attributed to
state-sponsored organizations.
Adware Advertising that is integrated into software. It can result in pop-up ads or
redirection of a browser to a commercial site.
Attack Kit Set of tools for generating new malware automatically using a variety of
supplied propagation and payload mechanisms.
Auto-rooter Malicious hacker tools used to break into new machines remotely.
Backdoor (trapdoor) Any mechanisms that bypasses a normal security check; it may allow
unauthorized access to functionality in a program, or onto a
compromised system.
Downloaders Code that installs other items on a machine that is under attack. It is
normally included in the malware code first inserted on to a
compromised system to then import a larger malware package.
Drive-by download An attack using code in a compromised web site that exploits a browser
vulnerability to attack a client system when the site is viewed.
Exploits Code specific to a single vulnerability or set of vulnerabilities.
Flooders (DoS client) Used to generate a large volume of data to attack networked computer
systems, by carrying out some form of denial-of-service (DoS) attack.
Keyloggers Captures keystrokes on a compromised system.
Logic bomb Code inserted into malware by an intruder. A logic bomb lies dormant
until a predefined condition is met; the code then triggers an
unauthorized act.
Macro Virus A type of virus that uses macro or scripting code, typically embedded in
a document, and triggered when the document is viewed or edited, to
run and replicate itself into other such documents.
Mobile Code Software (e.g., script, macro, or other portable instruction) that can be
shipped unchanged to a heterogeneous collection of platforms and
execute with identical semantics.
Rootkit Set of hacker tools used after attacker has broken into a computer
system and gained root-level access.
Spammer Programs Used to send large volumes of unwanted e-mail.
Spyware Software that collects information from a computer and transmits it to
another system by monitoring keystrokes, screen data and/or network
traffic; or by scanning files on the system for sensitive information.
Trojan horse A computer program that appears to have a useful function, but also has a hidden and potentially malicious function that evades security mechanisms, sometimes by exploiting legitimate authorizations of a system entity that invokes the Trojan horse program.
Virus Malware that, when executed, tries to replicate itself into other executable machine or script code; when it succeeds the code is said to be infected. When the infected code is executed, the virus also executes.
Worm A computer program that can run independently and can propagate a complete working version of itself onto other hosts on a network, usually by exploiting software vulnerabilities in the target system.
Zombie, bot Program activated on an infected machine that is activated to launch attacks on other machines.
Trojan horse A computer program that appears to have a useful function, but also has
a hidden and potentially malicious function that evades security
mechanisms, sometimes by exploiting legitimate authorizations of a
system entity that invokes the Trojan horse program.
Virus Malware that, when executed, tries to replicate itself into
other executable machine or script code; when it
succeeds the code is said to be infected. When the
infected code is executed, the virus also executes.
Worm A computer program that can run independently and can
propagate a complete working version of itself onto other
hosts on a network, usually by exploiting software
vulnerabilities in the target system.
Zombie, bot Program activated on an infected machine that is activated to launch
attacks on other machines.
macro Document_Open disable Macro menu and some macro security features if called from a user document copy macro code into Normal template file else copy macro code into user document being opened end if if registry key “Melissa” not present if Outlook is email client for first 50 addresses in address book send email to that address with currently infected document attached end for end if create registry key “Melissa” end if if minute in hour equals day of month insert text into document being opened end if end macro
Figure 6.1 Melissa Macro Virus Pseudocode
macro Document_Open
disable Macro m enu and some macro security features
if called from a user docum ent
copy macro code int o Normal template file
else
copy macro code into user docum ent being opened
end if
if registry key “Melissa” not present
if Outlook is email client
for first 50 addresses in address book
send email to that address
with currently infected docum ent attached
end for
end if
create registry key “Melissa”
end if
if minute in hour equals day of m onth
insert text into document being opened
end if
end macro
Figure 6.1 Melissa Macro Virus Pseudocode
0.2
0
Slow start phase
Fraction of hosts infected
Fraction of hosts not infected
Time
Figure 6.2 Worm Propagation Model
0.4
0.6
0.8
1.0
Fast spread sphase Slow finish phase
0.2
0
Slow start phase
Fraction of
hosts infected
Fraction of
hosts not
infected
Time
Figure 6.2 Worm Propagation Model
0.4
0.6
0.8
1.0
Fast spread sphase Slow finish phase
Figure 6.3 System Call Table Modification by Rootkit
(a) Normal kernel memory layout (b) After nkark install
fork entry
sys_fork( )
sys_read( )
sys_execve( )
sys_chdir( )
read entry
execve entry chdir entry
system call table
fork entry
sys_fork( )
sys_read( )
knark_fork( )
knark_read( )
knark_execve( )
sys_execve( )
sys_chdir( )
read entry
execve entry chdir entry
system call table
Figure 6.3 System Call Table Modification by Rootkit
(a) Normal kernel memory layout (b) After nkark install
fork entry
sys_fork( )
sys_read( )
sys_execve( )
sys_chdir( )
read entry
execve entry
chdir entry
system call
table
fork entry
sys_fork( )
sys_read( )
knark_fork( )
knark_read( )
knark_execve( )
sys_execve( )
sys_chdir( )
read entry
execve entry
chdir entry
system call
table