Malicious Threats to Personal Digital Assistants


Symantec AntiVirus Research Center
Malicious Threats to Personal Digital Assistants
Eric Chien
Symantec Ltd.
Schipholweg 103 2316XC Leiden, Netherlands
Tel 31 71 408 3111 " Email echien@symantec.com
ABSTRACT
In the 1980s, no one left home without his or her FiloFax. Today, no one leaves home
without his or her Personal Digital Assistant (PDA). However, while FiloFaxes
contained important names and numbers, PDAs are more than just an address book.
Combined with Internet access, the functionality of the PDA is moving towards a desktop
computer combined with a cellular phone, small enough to put in ones pocket.
As corporations begin to adopt PDAs as a standard computing device within their digital
infrastructure and applications become more robust and meaningful with the
standardization of wireless computing, threats from malicious code become more serious.
This paper will explore the malicious code threats on the three major PDA platforms
(PalmOS, EPOC32, and Windows CE) and the associated Virus Bulletin 2000
presentation will include demonstrations of such threats. Also, potential solutions to
PDA threats will be presented including demonstrations of prototype applications in
detecting malicious PDA code both on the PDA and associated devices.
2. Background
2.1 Palm
The leading platform for handheld computing devices is Palm OS. According to IDC,
Palm OS controlled 78.4% of the handheld market share in 1999. Overall, IDC expects
personal digital assistants to exceed 18.9 million units by 2003. With more than 4,000
applications for the Palm OS, devices running Palm OS are at greatest risk of malicious
code.
Palm OS does not use a traditional file system. The file system is optimized for
synchronization with a primary device (the desktop computer) and for the limited storage
area available. Data is stored in memory blocks called records. Related records are
grouped in databases where every record belongs to one and only one database. For
example, a database may be a collection of all address book entries or all calendar entries.
A database is analogous to a file. The difference is that data is broken down into multiple
records instead of being stored in one contiguous chunk. When modifying or accessing a
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database, the changes only take place in memory, instead of creating it in RAM and then
writing it out to storage.
Palm devices consist both of RAM and ROM. The ROM generally holds the operating
system and newer versions of Palm devices allow for flashing of the ROM to potentially
update system files. Palm clones such as Handspring devices can also utilize flash cards
adding additional memory or functionality. Palm devices do not use the traditional x86
architecture. The Palm uses the latest Motorola 68k Dragonball series CPU.
2.2 Psion
Psion originally started in 1981 by David Potter. Originally under the name Potter
Scientific Investments (PSI), the company soon changed the name to Psion. Since that
time, Psion has produced a range of personal digital assistants. In 1996 however, Psion
split into a separate organization known as Psion Software. The goal would be to license
the underlying EPOC operating system to other OEM hardware vendors. EPOC was
designed to work in many devices and not just the latest personal digital assistant
developed by Psion. By 1998, Psion software was transformed into Symbian a joint
venture of multiple mobile phone giants and Psion. The joint venture made it clear
smartphones and communicators would arrive in the future utilizing the EPOC operating
system.
EPOC runs on 32-bit CPUs and latest releases are designed for the ARM or StrongARM
CPUs. Applications are generally developed under Windows initially in PE (portable
executable) format using the EPOC emulator. Once the program has been debugged, the
code is recompiled for the ARM architecture and then transferred to the EPOC device.
For storage, Psion devices consist of ROM (Read Only Memory), RAM (Random Access
Memory), and optional CF (Compact Flash) cards.
The ROM not only contains the operating system, but also all the built-in applications
and middleware. In contrast, a standard personal desktop computer contains only the
bootstrap loader and BIOS in the ROM. Typically, applications on a desktop computer
are stored on a storage device and when executed are loaded to RAM.
However, files located on the Psion ROM are generally executed in place rather than
being loaded to RAM first. In addition, as suggested by the name, the ROM can only be
read from and not written to. Thus, in general programs located on the ROM can not be
modified. OEMs, administrators, and technicians can possibly re-flash or change the
ROM with the appropriate software, firmware, and hardware to provide updates to the
operating system or built-in applications.
The RAM is analogous to both the RAM and hard drive storage of a personal desktop
computer. The RAM in Psion devices contains the additional applications stored by the
user, active programs, and the active copy of the system kernel. The RAM disk maintains
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data when there is power and on warm boots. On cold boots, the data in the RAM is
completely wiped.
EPOC is versatile in both its usage and licensing. In general, OEMs can use the core
operating system of EPOC, but develop a completely different ROM. For example, a
device with no user interface would not require the user interface capabilities (EIKON) of
EPOC and thus, could be removed saving valuable memory. OEMs could also
potentially load a ROM image from CF card into RAM, and then mark it as read only.
Thus, when referring to EPOC features one must often do so in reference to a particular
implementation.
Hardware resources such as the system RAM are isolated from applications via a
privilege boundary. Running under privileged mode, the kernel controls all of the
device s hardware resources. The CPU will only perform privileged instructions for the
kernel. All other user-mode applications that need access to hardware resources must
access them via the kernel. Kernel APIs allow such applications to remain on the
unprivileged side of the boundary, while the kernel performs the necessary privileged
commands.
Finally, executables on Psion devices can be divided into two categories, applications and
servers.
Applications contain a user interface and when executed, run in a separate process space.
Thus, the system creates a virtual address space for each executed application. In this
way, traditional applications can not accidentally overwrite data area of another
application. The MMU, Memory Management Unit, manages the separate process
spaces so writable memory of one application is not accessible by an another process.
A server is an executable without a user interface. Servers generally provide APIs for
clients (clients can be applications or other servers). Some servers actually use the same
process.
2.3 Windows CE
Microsoft released Windows CE in 1996. It was designed by to be an operating system
that contained a subset of the Win32 API. The requirements were the operating system
should be for small ROM based systems. Initial devices that utilized Windows CE were
handheld PCs and since then many devices take advantage of Windows CE including
personal digital assistants. While Windows CE can be found in everything from the Auto
PC to PDAs, this section will concentrate on Windows CE relative to PDAs.
While source code is generally the same when developing a Windows CE application
(not all devices support all features in Windows CE), there are many hardware devices
with different CPUs which can utilize Windows CE. Thus, the resultant executable may
actually differ depending on the target CPU. In fact, the majority of PDAs running
Windows CE are not running Intel x86 compatible architectures.
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Windows CE programming can be considered similar to Windows programming just
with a subset of APIs and potentially reduced hardware resources (no hard disk, and
available RAM).
Since Windows malware is possible, Windows CE malware is of course also possible.
However, current Windows malware is often specific to the particular Windows
operating system. For example, many viruses take advantage of specific undocumented
kernel features of Windows NT, which do not exist in Windows CE. In addition, trojan
horses often make registry key changes, which also do not exist under Windows CE.
Unfortunately, analogous features can all be found in Windows CE. For example,
malware often utilizes the Run registry keys of Windows 9x. A similar key
(HKLM\Init\& ) can be found in Windows CE that allows for programs to similarly start
before the Explorer and thus, allowing stealth capabilities.
In summary, Windows CE runs on a variety of hardware and has been implemented for
many CPU architectures. This includes standard personal digital assistants such as the
new Microsoft Pocket PC to embedded devices, which contain no user interface.
3. Vectors of Delivery
Any method that allows the introduction of executable code onto the personal digital
assistant represents a vector of delivering potentially malicious code. While there are
many methods of introducing code, syncing currently represents the primary method and
in the future, Internet access will actually pose the greatest threat. Following is a brief
description of the potential vectors of delivery for each device.
3.1 Syncing
The primary method by which applications are transferred onto personal digital assistants
is via syncing functionality. All three operating systems have associated syncing
applications. The Palm device uses HotSync, Psions use EPOC Connect, and Windows
CE devices can install the ActiveSync application.
Syncing functionality is used primarily to synchronize data stored on the device with data
stored on the desktop computer, back up data to the desktop computer, manage files, and
install new device applications that are located on the desktop computer.
Currently, this provides the easiest means of introducing malicious code. For example, to
install a new program on the Palm, one may download the new program from the Internet
and save it to their desktop computer. Then, using the HotSync functionality, the
program is transferred from their desktop computer to the Palm. Now saved to the Palm,
the user can run the new program. The program could be anything from a new chess
game to a malicious program that emails out all ones contact records.
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In addition, the syncing functionality allows custom applications on a desktop PC to
connect and manipulate data on the personal digital assistants. For example, the EPOC
Connect APIs allow one to interface with the Message Center on the device. The
Message Center provides a single point of access to e-mail, fax, and SMS functionality.
Such programmability provides the ability of malware to potentially send mail and
manipulate files on the device from the desktop computer and vice versa. Fortunately,
this is not only advantageous for malware, but for potentially anti-virus solutions as well,
both of which will be discussed later.
3.2 IrDA
Personal digital assistants usually contain an IR (InfraRed) port allowing IR
communication capabilities. Such capabilities are generally compliant with IrDA
(Infrared Data Association) specifications and thus, one can easily interface with the IR
capabilities of the device.
However, the majority of devices utilize an associated application to allow the transfer of
data via the IR port. For example, the Palm OS Exchange Manager provides a simple
interface for Palm OS applications to send and receive data from a remote device using
standard protocols. In addition, low level access is obtained through the use of document
APIs. Psion allows applications to implement IR communication capabilities via the
ESOCK API.
With IR capabilities, devices are able to receive and send applications and thus,
potentially malicious code. Currently, devices are designed to trigger an incoming data
alert message however, this message can be disabled. Disabling such a message requires
specific agent code on the receiving device. Via IR, malicious programs could
potentially speak to other infected devices exchanging information and code, all
unbeknownst to the users.
3.3 Network Access
The most susceptible gateway of transferring malicious code is via network access. By
adding optional modem hardware to the device or utilizing newer wireless models, one
has access to many standard Internet protocols. In general, email access with attachments
is available and so is web browsing. One can easily receive emails with executables
attached, save those attachments, and run them. Such applications can easily contain
malicious code.
Devices generally contain pre-installed mail clients, which are also programmable. So,
malicious software writers may only need to interface with existing mail clients rather
than creating their own network capable agent.
Also, all three operating systems provide libraries to applications to easily establish a
connection with any other machine on the Internet and transfer data to and from that
machine using the standard TCP/IP protocols. Thus, malicious code is not limited to
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utilizing the programmability of the device s mail client or web browser, but can open
listening server ports allowing remote access, send confidential data, or receive additional
malicious code.
4. Architectural Threats
While the vectors of delivery provide the doors to enter the personal digital assistant,
architectural design provides the keys for opening or exploiting those doors.
4.1 Programmability
Many applications running on the devices are programmable. A third party program can
interact with the programs through a standard application-programming interface.
Psion devices contain a client-server architecture, which allows one applications to speak
to another, Windows CE applications generally utilize common APIs such as MAPI, and
Palm applications can send launch codes to each other. Using launch codes an application
can direct another application to perform some action or modify its data.
For example, in Palm OS, a malicious program could send a launch code to query all the
email addresses in the Address List application. Then, the same program could send a
launch code instructing the email application to queue and send email messages with
itself as an attachment. All of this functionality can be performed without user input, and
without the user s knowledge.
Such programmability easily allows for email type worms like W97M.Melissa and
VBS.LoveLetter. How far and how fast such threats may spread is discussed later.
4.2 File System Architecture
All three OS s provide file operation functions. The file streaming functions allow one to
read, write, seek to a specified offset, truncate, and do everything else you'd expect to do
with a desktop-style file. Such functionality is all that is needed for a viral threat to
spread.
In all three operating systems, viral threats may find other applications on the device,
append themselves to those applications, and change the entry point of the program to
ensure future execution and continued replication.
The Palm and some Windows CE and Psion implementations do not employ any inherent
access control to applications and data files. System applications are easily modified as
regular user applications. Of course, system applications stored in ROM can not be
permanently changed (unless the ROM is flashed). This allows malicious code to not
only modify some system files, but also destroy some system files. With a single click,
one could wipe out all the applications and data on their device.
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Luckily, most devices contain sensitive information on the ROM, which is not writable.
However, the amount of middleware or built-in applications that exist on the ROM vary
with each operating system and further depending on OEMs for each device. Since,
sensitive system information is generally stored on the ROM, uses can reset or cold boot
their devices losing applications and data, but still containing a functional PDA. Then,
potentially the user can restore their applications and data via synchronization.
4.3 Development Libraries and Languages
Programming libraries in all three operating systems are quite robust. All provide
communication libraries, which pose the greatest risk. Windows CE provides a subset of
the standard Windows API with the inclusion of Berkeley style sockets; Palm OS is
distributed with a range of libraries including the net library and IR library allowing Palm
OS applications to easily establish a connection with any other machine on the Internet or
in IR port range; and the Psion contains the ESOCK API and ETEL API allowing
network connectivity.
Such libraries make programming high-level threats very easily. For example, without
low-level knowledge of IR communications, one can easily create an agent that monitors
incoming IR data requests. Network libraries allows programmers to create Berkeley
sockets style network programs. Such programs could range from a small SMTP engine,
creating email capabilities on a device that may not even have a mail client, to a server
listening for incoming commands acting as a remote access trojan.
In addition, script languages are available on the Psion and some Windows CE devices.
Creating programs in script languages is traditionally easier. VBS.LoveLetter and
W97M.Melissa.A were both coded in script languages. By default, Psion for example,
offers a script language known as OPL and Windows CE, depending on applications
installed, can host a range of other potential script languages for creations of malware.
5. Spreadability
While the creation of viruses, worms, and trojans are all possible for popular personal
digital operating systems, their potential in-the-wild spread is influenced by a variety of
factors. One should not be surprised if a malicious threat is discovered tomorrow;
however, one should be surprised if such a threat posed an immediate widespread threat.
First, while Palm holds the largest market share of personal digital assistant users, the
number of personal digital assistant users is magnitudes lower than the number of PC
users. In addition, at this moment the number of network connected personal digital
assistant users is also magnitudes lower than the number of people with access to email.
Secondly, if the number of personal digital assistant users increases, the number of
different operating systems and their customizations still decreases the ability for a threat
to spread effectively to anything other than a smaller subset of personal digital assistant
users.
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Thus, a malicious personal digital worm would not spread nearly as fast as a Windows
worm.
Finally, the model of data exchange for personal digital assistants is still asymmetric.
Users still download application and data from a few primary sources rather than all PDA
users exchanging information with all other PDA users. It is this symmetric nature of
code exchange that can dramatically increase the threat of viral spread as seen with macro
viruses.
In addition, some operating systems contain further hurdles, which may limit spread. For
example, Psion devices require every EIKON application utilize a UID (Unique
IDentifier). These UIDs must be obtained from Symbian and thus could potentially be
traceable to a particular individual or computer. Programmers can utilize a set of test
UIDs prior to obtaining Symbian authorized UIDs; however, a Psion with two
applications with the same UID, will only recognize one of the two applications.
So, in order for PDA malware to spread, the cost of PDAs will need to continue to
decrease and become standard productivity devices issued in the corporate space. Also,
vendors will need to standardize protocols, be cannibalized by market competition, or a
clear market leader will need to emerge. Only then does the threat increase dramatically.
If we reach a day where we check email via our PDA and trade documents and other
executable attachments via our PDA, the chances of malicious code being inadvertently
executed rises. Luckily, solutions to detect PDA malware are already in development.
6. Solutions
The inherent difficulty with creating anti-virus solutions for personal digital assistants is
resource limitations. Obviously, the current megabyte signature files can not simply be
placed on a digital assistant with limited storage space and any CPU intensive activities
such as heuristic emulation may not be possible.
However, in addition to possible device solutions, one can also potentially utilize the
current infrastructure and create solutions on the associated device, namely the syncing
desktop computer. These systems allow for more CPU intensive activity and greater
storage space.
6.1 Current Infrastructure
Current infrastructure provides reasonable first level protection for personal digital
assistants. While no anti-virus product currently contains engines to specifically parse
the major PDA operating system file formats, the current engines should suffice in
detecting initial malware creations. Initial malware creations will probably not require
any special new technology and can most likely be detected by current scanning
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techniques. Thus, these anti-virus products can provide first level protection in scanning
potentially infected samples prior to their transfer to the personal digital assistant.
For example, those utilizing e-mail on their PDA can have e-mail scanned at the gateway
and those who primarily utilize syncing can scan executables on the desktop computer
prior to installation on the PDA.
In addition, as malware threats develop on PDA operating systems (polymorphism,
obfuscated entry point, etc.), engines and signatures can be created to specifically deal
with these threats and then deployed within the current infrastructure s ability to handle
engine upgrades.
Obviously, as e-mail gateway scanning isn t enough today (one also needs a desktop
scanner), neither is the current infrastructure in regards to personal digital assistants.
While desktop systems still can be infected via network shares and floppy diskettes,
personal digital assistants can also be infected via infrared transmission and potentially
other non-scanned network access from Internet webpages to other proprietary network
data transfer mechanisms.
In addition, new malware may be transferred to the personal digital assistant prior to the
update of signatures on top level scanning systems. Once transferred to the PDA, the
malware may remain undetected unless the actual device undergoes scanning.
So, while current infrastructure can clearly mitigate the spread of initial malware for the
personal digital assistant, the current infrastructure does not provide full-tier protection
leaving the PDA with open vectors of delivery.
6.2 Associated Device Solutions
Personal digital assistants are still closely linked to an associated device, generally the
desktop PC. Users of PDAs rarely go a week without performing some sort of
synchronization act with their desktop PC. This interaction between the desktop PC and
the PDA allows one to potentially place a more robust solution on the desktop computer,
which can remotely scan the PDA.
All three operating systems provide synchronization APIs. This allows custom programs
on the desktop computer to perform tasks on the PDA remotely when the PDA is linked
to the desktop computer.
From the desktop computer, one can scan files on the personal digital assistant, perform
intensive CPU or memory activity on the files utilizing the desktop computer resources,
and write to the personal digital assistant repairing or removing malware and side effects.
While such scanning can be invoked automatically each time the user performs a syncing
operation, the method still requires users to initiate the synchronization with the desktop
computer. The time gap between synchronization events leaves the personal digital
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assistant open to infection. For example, if the user receives a malicious attachment via
email, in order to verify the attachment is not infected, the user will need to first sync
their personal digital assistant with the desktop computer. This model of course
eliminates a distinct advantage of the PDA  a small device that may receive e-mail
independent of the desktop computer.
So, by utilizing associated device solutions, one can increase their protection, but only so
much as non-real time scanners do in today s infrastructure.
Associated device solutions are analogous to having the user manually scan for viruses
on their desktop computer (if not worse) and draws away from the advantages of having a
PDA  one might as well carry around their desktop computer. However, some level of
protection is of course better than no protection.
6.3 Device Solutions
All devices contain functionality to traverse the file system, open files, and write files
from the device itself. Thus, anti-virus solutions can simply be placed on the personal
digital assistant itself. For simple signature scanning, these anti-virus solutions can
actually be small enough to fit within the guidelines of resource limited devices.
However, dynamic heuristics and emulation techniques would be difficult to implement.
In contrast, malware that requires emulation techniques may be difficult to create for
personal digital assistants as well. Malware must also fall under the same restrictions as
the anti-virus itself. Thus, malware that spreads effectively will need to be simple and
non-resource intensive as well. Some simplicity of the malware itself may deem resource
intensive anti-virus unnecessary.
In addition, while signature files may be megabytes in size for current anti-virus
solutions, equivalent signature files for PDA malware may not be as large. The average
one to two megabyte signature files in the current infrastructure represent approximately
fifty thousand viruses. Clearly, there will not be fifty thousand PDA viruses in the near
future. In addition, most malware will not be able to execute on all personal digital
assistants, but only particular OS s and even then potentially only on certain devices due
to OEM customizations. Thus, signature files for PDA solutions will only necessitate
signatures for their device in contrast to current desktop solutions which scan for multiple
operating system files.
Current desktop solutions need to contain signatures for malware that affects not only
their system, but potentially other systems as well, for example, anti-virus on a file server
that holds both PC and Macintosh native files.
Personal digital assistants obviously will have difficulty storing current desktop operating
system applications and thus, may not require scanning for anything but threats to their
device.
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Technologies on the device can utilize many of the traditional techniques used today
including integrity checking, behavior blocking, and signature scanning. All of these
methods are relatively non-intensive and can be completed quickly making realtime
scanning non-prohibitive.
6.4 Inherent Protection
Although syncing provides a vector of delivery, syncing also provides inherent backups.
Users who utilizing syncing, automatically backup data to their desktop computer. Thus,
if they are infected by a virus or malicious software wipes out their applications, they can
easily restore from backups, if they are there.
Recall the same syncing event can also allow malicious software on the PDA to modify
data stored on the desktop computer. Nevertheless, the model built by PDAs allows one
to potentially return easily to a known clean state.
6.5 Non-Technology
While technology provides us with adequate protection, there is only a single silver
bullet, user education. User education can never be stressed enough. While there are
worms that spread without users executing attachments ( VBS.Bubbleboy,
Wscript.KakWorm), the majority of worms require a user to execute an attachment.
By educating users to scrutinize messages, many widespread worms can be avoided.
Clearly, users should not run attachments from unknown sources, and verify attachments,
which come from known colleagues. This applies not only to desktop computers, but
personal digital assistants as well. While some can not avoid downloading the latest
chess game, users should assure they are downloading traceable (usually commercial)
software and not anonymous freeware applications unless they have been verified to be
non-malicious.
In corporations where personal digital assistants are widely used, information security
administrators should ensure they have evaluated the functionality versus security and
potential security risks personal digital assistants pose. In addition, mobile telephones
often do not fall within information security sights, but as mobile telephones become
smart phones, they should require review by information security administrators.
Information security administrators should also begin the standardization of personal
digital assistants and smart phones within their organization. By approving a single
personal digital assistant in their corporations environment they will not only alleviate
helpdesk calls, but potential security risks as well.
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7. Summary
Unfortunately, there isn t a digital device that is 100% secure. To be 100% secure, one
should revert to the old FiloFax. However, while there is a threat, there are also potential
solutions.
Although, threats are possible, I would not predict a widespread threat at the current time.
In order for personal digital assistant threats to achieve the infection rates of
VBS.LoveLetter, many developments are still required. The current variety of operating
systems and customizations and the current lack of networking versus the desktop
computer clearly limits the spreadability.
However, once such executable code is run, the possibilities are limitless. PDA devices,
as discussed, are open for infection and can aid email worms by their robust
programmability and networking.
Information security administrators should be aware that the threats exist and if they have
not done so, yet begin review of the requirement of personal digital assistants and smart
phones within their corporate environment. By reigning in these devices now,
administrators may save potential headaches later.
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APPENDIX A.
The Virus Bulletin 2000 presentation associated with this paper will present the following
applications on the PalmOS, WindowsCE, or EPOC platforms. These applications will
not be available for distribution. Note that no viruses or malicious programs were created
in the research of this paper and presentation. Symantec researchers are ethically and
contractually against the creation of any such malware.
1. Ability to iterate through the Address book for email addresses.
2. Ability to programmatically send email with attachments.
3. Ability to automatically launch stealth programs on warm boots
4. Ability to write to application and data files.
5. Ability to delete applications, data files, and system files.
6. Perform remote tasks on the PDA via syncing
7. Stealth communication and data transfer between PDAs via IR ports
8. Networking communications via modem or wireless protocols including the ability to
perform remote control access.
9. ROM flashing
10. Prototype anti-virus device solutions.
11. Prototype anti-virus associated device solutions.
12. Current infrastructure scanning solutions.
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REFERENCES
[1] http://www.idc.com
[2] http:/www.symbiandevnet.com
[3] http://www.palmos.com/dev/
[4] http://www.microsoft.com/windowsce/
[5] Tasker, Martin,  Professional Symbian Programming , 2000
[6] Boling, Douglas,  Programming Microsoft Windows CE , 1998
[7] Mykland, Robert,  Palm OS Programming , 2000
[8] Palm Computing, Palm OS SDK Reference, Document Number 3003-002, March
2000
[9] Palm Computing, Palm OS Programmer s Companion, Document Number 3004-
002, March 2000
[10] Palm Computing, Conduit Programmer s Reference for Windows, Document
Number 3012-001, February 2000
[11] Palm Computing, Conduit Programmer s Companion for Windows, Document
Number 3013-001, February 2000
[12] Symbian, EPOC Release 5 C++ SDK, Release 004, 1999
[13] http://www.epocworld.com/
[14] ARM Ltd., ARM Instruction Set, ARM Document Number QRC 0001D, June
1995
[15] ARM Ltd., ARM ELF, Document Number SWS ESPC 0003 A-08, September
1999


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