1. Security Credit: most slides from Forouzan, TCP/IP protocol suit
Chapter 30
Security
Credit: most slides from Forouzan, TCP/IP protocol suit
TCP/IP Protocol Suite

2. Criminal Expoits and Attacks
Phishing: Masquerading as a well-known site to obtain a user’ personal info.
Denial of Service: Intentionally blocking a site to prevent business activities.
Loss of control: an intruder gains control of a system.
Loss of data: Steal or delete.
TCP/IP Protocol Suite

3. Attacks Software Based Attackes Hardware Based Attacks
Malware – Malicious software – damaging or annoying software. Viruses or worms.
Hardware Based Attacks
Bios, USB devices, NAS, Cell phones
Attacks on Virtualized Systems

4. Software based attacks: Viruses
Attaches to a legitimate software (carrier, a program or document) and then replicates through other programs, devices, s, instant messaging, etc.
Computer crashes, destruction of HD, fill up HD, Reduce security settings allowing others to come in, reformat HD, etc.
File infecting virus attaches to executables (such as cascade virus), resident virus loaded into RAM (such as Randex, Meve, MrKlunky), Boot virus infects MBR (Polyboot.B , AntiEXE), companion virus adds program to OS replacing legitimate OS programs (Stator, Asimove.1539), Macro virus written in any macro scripting (Melissa.A, Bablas.Pc).
Polymorphic virus changes itself to avoid detection

5. Worms Stand alone programs
Takes advantage of the OS/application vulnerabilities.
Worms uses networks to send copies of itself slowing down networks.
While virus requires user action to start an infected program, worms do not (can start executing itself).
Worms as they travel through internet can leave a payload behind on each system which can delete files or allow remote controlling of the system.

6. Concealing malware
Trojan horses, rootkits, logic bombs and privilege escalation.

7. Trojan Horse
Installed with the knowledge of the user. A program advertised as a utility but actually does something else (screen saver, calendar, player, etc.). These programs may do a legitimate activity, but also might capture credit card info, etc and send it.

8. Rootkits
Programs installed on computers that takes control of certain aspects of the computer by replacing OS utilities. Sony installed a program on their CDs (2005) preventing copying of the CD by operating system routines. Others used this idea and created their own, or added features to Sony’s program. Rootkits do not spread themselves. Very difficult to remove from HD. Boot from another device and see if problems disappear.

9. Logic Bombs
Lies Dormant until triggered by an event such as a date, person fired, etc. Usually done by employees. Very difficult to discover before triggered. Embedded in large programs.

10. Privilege Escalation
Either change own privilege to higher level, or use another employees higher privilege. Done by exploiting vulnerabilities of OS.

11. Malware for profit Spam, spyware and botnets Spam
Waste of time, checking and deleting. lists are sold by many ISPs, and other sites.

12. Spyware
Tracking software installed without the knowledge of the user. Advertises and Collects and distributes personal information. Harder to detect and remove than viruses. Causes the computer to slow down, freezes up, new browser toolbars or menus installed, hijacked homepage and increased popups.
Adware – a software that delivers advertising for gambling sites or pornography. Keeps track of browsing behavior and reports to give specific pop-ups for merchandize.
Keyloggers. A small hardware attached to the keyboard interface or a resident software that monitors and logs each keystroke.

13. Botnets
Programs that render your computer to be controlled remotely. The computer is called a zombie. Thousands of zombie computers under the control of a single attacker is called a botnet.
Attackers use internet relay chat (IRC) to remotely control the zombies.
Zombies are used for spamming, spreading malware, denying services, etc.

14. Hardware based attacks
BIOS
BIOS can be flashed with viruses or rootkits. Flashing the bios can render the computer useless until it is replaced. You can write protect BIOS to prevent this from happening.
USB devices
NAS and SANs can get all malware discussed.
Cell phones – infected messages, launch attacks, make calls, etc.

15. Attacks on Virtualized systems
Operating system virtualization with virtual machine
Storage virtualization
Multiple os on the same machine. However, existing anti virus/spam software do not work.
Additional concern – one existing virtual machine may infect another.
Protection approaches:
Hypervisor-runs on the physical machine and manages the virtual machines.
Run security software such as a firewall on the physical machine

16. Techniques used Wiretapping
Replay – sending packets captured from previous session such as username and password.
Buffer overflow: sending more data than receiver expects, thereby storing values in memory buffer.
Address spoofing. Faking IP source address
Name spoofing. Misspelling of a well-known name or poisoning name server.
SYN flood – sending stream of TCP SYN
Key breaking – guessing password
Port Scanning – to find vulnerability
Packet Interception – man in the middle attack.
TCP/IP Protocol Suite

17. Security Techniques Hardening Operating system Encryption
Digital Signatures
Firewall
Intrusion detection systems
Packet inspection and content scanning
VPN
TCP/IP Protocol Suite

18. Hardening Operating System
3 pronged approach:
operating system updates,
Protect against buffer overflows,
configuring operating system protections

19. Operating System updates
Security Patch: Covers discovered Vulnerabilities
Turn on automatic updates
Hotfix – specific to a customer situation
Service Pack – Cumulative security patches and other software updates.
Designate one server within your organization as the patch update service

20. Buffer Overflow Protection
Corrupts system memory and causes freezing
May change the return address (from a routine) to a different one where the malware is residing.
Programmers should write defensive programming. Show the textbook to the students.
For windows based programming use: Data execution prevention(DEP) and Address Space Layout Randomization (ASLR)

21. Defensive programming Microsoft environment
Data Execution Prevention (DEP)
DEP is available in VISTA and beyond
Designated memory only to hold data not code (No eXecute NX bit associated with the memory). Buffer overflow redirection would not work within a NX memory.
Programmers can turn on this feature.
Address Space Randomization (ASLR).
Each time Vista.. Is rebooted .EXE and .DLL are loaded randomly into 256 possible locations. Attackers find it difficult to work with unpredictable code locations.

22. Configuring Operating System Protection
Security Policy
A document that clearly defines the defense mechanisms an organization will employ in order to keep information secure.
Configuration baseline – permissions on files, registry permissions, logins, authentications, etc. You may want to create a Security template to handle it.
Deployment – individually or by group policy

23. Preventing Attacks that Target Web browser
Attacks through cookies, scripts, Java, ActiveX and cross-site scripting.

24. Cookies
information about visits saved on user’s computer. First party cookie is created by the site that the user is currently viewing. Third-party cookies are cookies created by some one else is accessed in a current visit to a different site.
Cookies do not present a security threat, but is a privacy risk. Track browsing habits, etc. Also provides IP address.

25. Scripts (Java, VB, etc.)
Web pages containing scripts download the scripts to the computer and is executed. The program can send information about the user to a host. Scripts can’t access files on the computer, so limited risk exists.

26. Java
Java can create applets that run on local computers. Defense against hostile jave applets is a Sandbox (a fence). Unsigned java applet does not come from a trusted source and must be run within the sandbox and gives warning to the users. If users do not read the message, or understand the risk, it can cause serious trouble. Sandbox warnings are given at the bottom left. Signed java applets are from trusted sources and have not been altered.

27. ActiveX – Add-ons
framework for defining reusable software components (known as controls) that perform a particular function or a set of functions in Microsoft Windows in a way that is independent of the programming language. A software application can then be formed from one or more of these components in order to provide its functionality. They do not run in a sandbox. It can do anything on the computer such as creating, modifying and deleting files. A signed ActiveX control is generally safe. Unsigned is riskier.

28. Cross Site Scripting (XSS)
Scripts that extract information from victim and pass it to the attacker.
Changes contents of dynamic websites and injects a script into it that asks for personal information through input validation.
A web site that displays bad login screens with login name is a good one for these types of attacks.
It could send a URL to click

29. SMTP Open Relays
A user can set up a receiving address and a sending address. Usually they are the same like pop.dia.sbc.net and smtp.dia.sbc.net. Some smpt servers are configured to sned mail through other domains (known as relays). An attacker can send spam through such relays without getting caught.

30. Instant Messaging
Once a user signs up with the instan message server, the client’s IP and port is sent to all buddies and communication can take place directly. With direct connection virus and worms can be spread. Attacker can also view contents of messages.

31. Peer-to peer
All types of attacks can take place through P2P networks. BitTorrent is more secure than P2P. However, both can be used to download illegal software or music.

32. Defenses
Antivirus – always a step behind, update with definition files.
Pop-up blockers. Now incorporated into the browser.
Anti-spam. Spam filter with smtp server. Install spam filter with pop3
Personal firewals.
Host Intrusion Detection systems (HIDS) monitoring files systems and logfiles.

33. CRYPTOGRAPHY
The word cryptography in Greek means “secret writing.” The term today refers to the science and art of transforming messages to make them secure and immune to attacks.
The topics discussed in this section include:
Symmetric-Key Cryptography
Asymmetric-Key Cryptography
Comparison
TCP/IP Protocol Suite

34. Figure 28.1 Cryptography components
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35. Note:
In cryptography, the encryption/decryption algorithms are public; the keys are secret.
TCP/IP Protocol Suite

36. Note:
In symmetric-key cryptography, the same key is used by the sender (for encryption) and the receiver (for decryption). The key is shared.
TCP/IP Protocol Suite

37. Figure 28.2 Symmetric-key cryptography
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38. Note:
In symmetric-key cryptography, the same key is used in both directions.
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39. Figure Caesar cipher
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40. Figure 28.4 Transpositional cipher
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41. Data encryption Standard (DES)
Is a block cipher
Takes 64-bit plaintext and creates a 64-bit ciphertext. The cipher key is a 56-bit key.
It uses 16 rounds, each round mixes and swapps (left half with right half)
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42. Figure 28.5 DES (Data Encryption Standard)
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43. Note:
The DES cipher uses the same concept as the Caesar cipher, but the encryption/ decryption algorithm is much more complex.
TCP/IP Protocol Suite

44. Asymmetric-key ciphers
The secret key is personal and unshared.
Symmetric key scheme would require n(n-1)/2 keys, for a million people it would require half a billion shared secret keys. Whereas, in asymmetric scheme we would only require a million secret keys.
Asymmetric ciphers use two keys, private and public.
Asymmetric is much slower. Both symmetric and asymmetric can be used if need to be. Think: if you want to send a secret symmetric key, you can use asymmetric.
TCP/IP Protocol Suite

45. Protocols
IPSec (internet Security Protocol) operates in the network layer. Used in VPN.
IP sec supports Authentication Header (AH) protocal and Encapsulation Security Payload (ESP) protocol
The SSL (Secure Socket Layer) protocol serves as a security for transferring encrypted data.
WEP (Wired Equivalent Privacy) standard. Data stream is encrypted with RC4 algorithm. RC4 is simple, it is not very secure.
WPA (Wi-Fi Protected Access) specification and AES (Advanced Encryption standard) I more secure for encrypting wireless data.
TCP/IP Protocol Suite

46. Figure 28.8 Public-key cryptography
TCP/IP Protocol Suite

47. Symmetric-key cryptography is often used for long messages.
Note:
Symmetric-key cryptography is often used for long messages.
TCP/IP Protocol Suite

48. Asymmetric-key algorithms are more efficient for short messages.
Note:
Asymmetric-key algorithms are more efficient for short messages.
TCP/IP Protocol Suite

49. Note:
Digital signature can provide authentication, integrity, and nonrepudiation for a message.
TCP/IP Protocol Suite

50. DIGITAL SIGNATURE
Digital signature can provide authentication, integrity, and nonrepudiation for a message.
The topics discussed in this section include:
Signing the Whole Document
Signing the Digest
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51. Figure 28.12 Signing the whole document
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52. Note:
Digital signature does not provide privacy. If there is a need for privacy, another layer of encryption/decryption must be applied.
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53. Figure Hash function
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54. Figure Sender site
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55. Figure Receiver site
The digest is much shorter than the message. The message itself may not lend itself to asymmetric cryptography because it is too long.
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56. Hash functions
Message of arbitrary length is made into a fixed length message.
MD2, MD4, MD5
SHA (Secure Hash Algorithm) developed by NIST.
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57. Non-repudiation
If alice signs a message then denies it, the message can be verified. That means we have to keep the messages.
A trusted center can be created. Alice send the digitally signed message to the trusted center who verifies it, saves a copy of the message, recreates the message with its own signature and send to bob. Bob can verify the trusted center’s public key.
TCP/IP Protocol Suite

58. 28.5 KEY MANAGEMENT
In this section we explain how symmetric keys are distributed and how public keys are certified.
The topics discussed in this section include:
Symmetric-Key Distribution
Public-Key Certification
Kerberos
TCP/IP Protocol Suite

59. Note:
A symmetric key between two parties is useful if it is used only once; it must be created for one session and destroyed when the session is over.
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60. Figure 28.19 Diffie-Hellman method
TCP/IP Protocol Suite

61. Note:
The symmetric (shared) key in the Diffie-Hellman protocol is K = G xy mod N.
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62. Example 1
Let us give an example to make the procedure clear. Our example uses small numbers, but note that in a real situation, the numbers are very large. Assume G = 7 and N = 23. The steps are as follows:
1. Alice chooses x = 3 and calculates R1 = 73 mod 23 = 21.
2. Alice sends the number 21 to Bob.
3. Bob chooses y = 6 and calculates R2 = 76 mod 23 = 4.
4. Bob sends the number 4 to Alice.
5. Alice calculates the symmetric key K = 43 mod 23 = 18.
6. Bob calculates the symmetric key K = 216 mod 23 = 18.
The value of K is the same for both Alice and Bob; G xy mod N = 718 mod 23 = 18.
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63. Figure 28.20 Man-in-the-middle attack
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64. Figure 28.21 First approach using KDC
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65. Figure 28.22 Needham-Schroeder protocol
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66. Figure 28.23 Otway-Rees protocol
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67. Note:
In public-key cryptography, everyone has access to everyone’s public key.
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68. Table X.509 fields
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69. Figure PKI hierarchy
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70. Figure 28.25 Kerberos servers
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71. Figure 28.26 Kerberos example
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72. 28.6 SECURITY IN THE INTERNET
In this section we discuss a security method for each of the top 3 layers of the Internet model. At the IP level we discuss a protocol called IPSec; at the transport layer we discuss a protocol that “glues” a new layer to the transport layer; at the application layer we discuss a security method called PGP.
The topics discussed in this section include:
IP Level Security: IPSec
Transport Layer Security
Application Layer Security: PGP
TCP/IP Protocol Suite

73. Figure Transport mode
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74. Figure Tunnel mode
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75. Figure AH
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76. Note:
The AH protocol provides message authentication and integrity, but not privacy.
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77. Figure ESP
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78. ESP provides message authentication, integrity, and privacy.
Note:
ESP provides message authentication, integrity, and privacy.
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79. Figure Position of TLS
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80. Figure TLS layers
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81. Figure 28.33 Handshake protocol
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82. Figure 28.34 Record Protocol
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83. Figure 28.35 PGP at the sender site
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84. Figure 28.36 PGP at the receiver site
TCP/IP Protocol Suite

85. FIREWALLS
A firewall is a device (usually a router or a computer) installed between the internal network of an organization and the rest of the Internet. It is designed to forward some packets and filter (not forward) others.
The topics discussed in this section include:
Packet-Filter Firewall
Proxy Firewall
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86. Figure Firewall
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87. Figure 28.38 Packet-filter firewall
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88. A packet-filter firewall filters at the network or transport layer.
Note:
A packet-filter firewall filters at the network or transport layer.
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89. Figure Proxy firewall
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90. A proxy firewall filters at the application layer.
Note:
A proxy firewall filters at the application layer.
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