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Protection and Security

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Protection and Security Sarah Diesburg Operating Systems COP 4610 Pentagon Traffic Analysis So much for the element of surprise Tenex Used to be the most popular ... – PowerPoint PPT presentation

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Title: Protection and Security


1
Protection and Security
  • Sarah Diesburg
  • Operating Systems
  • COP 4610

2
Definitions
  • Security policy of authorizing accesses
  • Prevents intentional misuses of a system
  • Protection the actual mechanisms implemented to
    enforce the specialized policy
  • Prevents either accidental or intentional misuses

3
Security Goals
  • Data confidentiality secret data remains secret
  • Data integrity unauthorized users should not be
    able to modify data
  • System availability nobody can make a system
    unusable

4
Security Components
  • Authentication determines who the user is
  • Authorization determines who is allowed to do
    what
  • Enforcement makes it so people can do only what
    they are allowed to do

5
Authentication
  • The most common approach passwords
  • If I know the secret, the machine can assume that
    Im the user
  • Problems
  • 1. Password storage
  • 2. Poor passwords

6
Password Storage
  • Encryption
  • Uses a key to transform the data
  • Difficult to reverse without the key
  • UNIX stores encrypted passwords in /etc/passwd
  • Uses one-way transformations
  • Encrypts a typed password and compares encrypted
    passwords

7
Poor Passwords
  • Short passwords
  • Easy to crack
  • Long passwords
  • Tend to be written down somewhere

8
Original UNIX
  • Required only lower-case, 5-lettered passwords
  • 265 or 1 million combinations
  • In 1975, it would take one day to crack one
    password
  • Today, we can go through all those combinations lt
    1 second

9
Partial Solutions
  • Extend password with a unique number
  • Require more complex passwords
  • 6 letters of upper, lower cases, numbers, and
    special characters
  • 706 or 100 billion combinations
  • Unfortunately, people still pick common words

10
Partial Solutions
  • Delay every login by 1 second
  • Assign very long passwords
  • Give everyone a password calculator (credit card)
  • Requires a physical theft to steal the password

11
Authentication in Distributed Systems
  • Private key encryption of data
  • Encrypt(Key, Plaintext) Cipher text
  • Decrypt(Key, Cipher text) Plaintext
  • Hard to reverse without the key
  • With the plaintext and the cipher text, one
    cannot derive the key
  • Provides secrecy and authentication, as long as
    the key stays secret

12
How to distribute the keys?
  • Authentication server
  • Keeps a list of keys

13
Kerberos Protocol
  • Keyxy is needed to talk between x and y

Server S
Client B
Client A
KeyBS
KeyAS
14
Kerberos Protocol
  • Keyxy is needed to talk between x and y

Server S
Client B
Client A
KeyBS
KeyAS
15
Kerberos Protocol
  • Keyxy is needed to talk between x and y

Server S
Client B
Client A
KeyBS
KeyAS
16
Additional Details
  • Expiration timestamp for a key
  • Prevents a machine from replaying messages (e.g.,
    deposit 100)
  • Checksum for an encrypted message
  • Prevents modifications to a message (e.g.,
    deposit 1000)
  • KeyAS and KeyBS are renewed periodically to
    reduce their exposures

17
Public Key Encryption
  • Separates authentication from secrecy
  • Involves a public key and private key
  • Encrypt(Keypublic, plaintext) cipher text
  • Decrypt(Keyprivate, cipher text) plaintext
  • Encrypt(Keyprivate, plaintext) cipher text
  • Decrypt(Keypublic, cipher text) plaintext

18
Public Key Encryption
  • Idea
  • Private key is kept secret
  • Public key is advertised

19
Public Key Encryption
  • Encrypt(Keymy_public, Hi, Sarah)
  • Anyone can create it, but only I can read it
    (secrecy)
  • Encrypt(Keymy_private, Im Sarah)
  • Everyone can read it, but only I can create it
    (authentication)

20
Public Key Encryption
  • Encrypt(Keyyour_public, Encrypt(Keymy_private,
  • I know your secret))
  • Only I can create it, and only you can read it

21
Authorization
  • Access matrix describes who can do what
  • -The matrix tends to be sparse

File 1 Lisas diary File3
Bart read,write read
Lisa read, write
Maggie
22
Access Control List
  • Stores all permissions for all users with each
    object
  • Analogy a guard in front of a door
  • Checks for a list of people allowed to enter
  • UNIX permission of each file is specified
    according to its owner, group, and the world

23
Capability List
  • Stores all objects a process can touch
  • Analogy Keys
  • A key owner has the right of entry
  • Example page tables
  • Each process has a list of pages that it can
    access

24
Access Control List vs. Capability List
  • Access control list (commonly used)
  • Easy to know who can access the object
  • Hard to know which objects a user can access
  • Capability list
  • A user knows the list of objects to access
  • Hard to know who can access an object
  • More difficult to revoke capabilities

25
Enforcement
  • Enforcer programs check passwords, access control
    lists, and so on
  • In UNIX, enforcers are run as superuser
  • If there is a bug, you are hosed!

26
The State of the World in Security
  • Authentication
  • Poor passwords
  • Nobody encrypts emails
  • Authorization
  • Coarse-grained access control list
  • Often turned off for sharing
  • Enforcement
  • Buggy operating systems

27
Classes of Security Problems
  • Eavesdropping is the listener approach
  • Tap into the Ethernet and see everything
  • Countermeasure pressurized cabled
  • Abuse of privilege
  • If the superuser is evil, there is nothing you
    can do

28
Classes of Security Problems
  • Imposter breaks into the system by pretending to
    be someone else
  • Recorded voice and facial image
  • Countermeasure behavioral monitoring to look
    for suspicious activities
  • Overwriting the boot block

29
Classes of Security Problems
  • A Trojan horse is a seemingly innocent program
    that performs an unexpected function
  • Countermeasure integrity checking
  • Periodically, check binaries against their
    checksums

30
Classes of Security Problems
  • Salami attack builds up an attack, one-bit at a
    time
  • Example send partial pennies to a bank account
  • Countermeasure code reviews

31
Classes of Security Problems
  • Logic bombs a programmer may secretly insert a
    piece of code into the production system
  • A programmer feeds the system password
    periodically
  • If the programmer is fired, the logic bomb goes
    off
  • Countermeasure code reviews

32
Classes of Security Problems
  • Denial-of-service attacks aim to reduce system
    availability
  • A handful of machines can flood a victim machine
    to disrupt its normal use
  • Countermeasure open

33
Pentagon Traffic Analysis
  • Before the 1991 Persian Gulf War
  • Foreign intelligence tried to predict the
    starting date of the war

34
Pentagon Traffic Analysis
  • So much for the element of surprise

35
Tenex
  • Used to be the most popular system at
    universities before UNIX
  • Thought to be very secure

36
Tenex
  • Source code for the password check
  • for (j 0 j lt 8 j)
  • if (inputj ! pwj)
  • // go to error
  • Need to go through 2568 combinations

37
Tenex
  • Unfortunately, Tenex used virtual memory
  • A fast password check means that the first
    character is wrong (error)
  • A slow check means that the first character is
    correct (page fault)

password
in memory
on disk
38
Tenex
  • 2568 checks to crack a password is reduced down
    to 256 8 checks

39
The Internet Worm
  • In 1988, a Cornell graduate student, RTM,
    released a worm into the Internet
  • The worm used three attacks
  • rsh
  • fingerd
  • sendmail

40
The Internet Worm
  • Some machines trust other machines, the use of
    rsh was sufficient to get into a remote machine
    without authentication

41
The Internet Worm
  • finger command did not check the input buffer
    size
  • finger name_at_location
  • Overflow the buffer
  • Overwrite the return address of a procedure
  • Jump and execute a shell (under root privilege)

42
The Internet Worm
  • sendmail allowed the worm to mail a copy of the
    code and get it executed
  • The worm was caught due to multiple infections
  • People noticed the high CPU load
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